Monthly Archives: April 2024

Exploring Thought Patterns in Those with a History of Adverse Childhood Events and Trauma: An AIEmpowered Mind Genomics Cartography

DOI: 10.31038/ASMHS.2024812

Abstract

Respondents evaluated vignettes comprising a combination of simple phrases, designed to describe ordinary, common experiences that may be upsetting for individuals who have undergone adverse childhood events (ACE) and childhood trauma. The vignettes were systematic combinations of 2-4 stand-alone answers to four questions, each question generating four answers (aka messages, elements). The four questions generated phrases describing reactions to different types of childhood trauma, namely history of childhood sexual abuse, exposure to a caretaker or other adult with substance abuse, living in a lower socioeconomic status, and exposure to crime and gun violence, respectively. Each respondent rated a unique set of 24 vignettes constructed according to an underlying experimental design, with the 24 vignettes comprising an experimental design ready for regression modeling. The respondents rated each vignette on a five-point scale, assessing their immediate emotional reaction if they were to experience the events in the vignette and the likelihood that experiencing the events would evoke negative memories from the past. In addition to the 24 vignettes, respondents answered 8 yes/no questions regarding experience with Adverse Childhood Events (ACE). Regression analysis linked the elements in the vignettes to ratings. Three mind-sets emerged, defined by the pattern of coefficients: a strong response to emergency precautions, safety barriers, and depictions of substance abuse; a strong response to financial hardship or perceived hardship; and a strong response to startling sensory input and sexual content, respectively, The regression coefficients showed varied by individuals who answer “yes” to different ACE questions.. By employing AI within the framework of Mind Genomics, this study reveals relations between the what a person suffers as a child and how the person relates to emotionally-sensitive messages, evaluated years later. The Mind Genomics approach coupled with AI creates a new tool to understand the nuances of emotional responses associated with distinct types of traumas.

How Mind Genomics works

Mind Genomics works by presenting respondents with vignettes. A vignette is a combination of messages (elements, answers to questions), with the elements being ‘stand-alone’ phrases. An underlying experimental design prescribes the elements appearing in each vignette. The design used here is a so-called ‘permuted design.’ Each respondent evaluates the same design of 24 vignettes, but the actual combinations differ from respondent to respondent. Mind Genomics provides a way to obtain information from people without the people ‘gaming the system,’ and indeed without any prior knowledge being necessary.

There are two features of Mind Genomics which make it valid and reliable:

  1. Mind Genomics works at the granular, concrete level, the everyday, to generate both the test elements: The elements paint ‘word pictures.’ The test stimuli become short word pictures, albeit not connected but rather seemingly put together at random. The combination is more realistic, more similar to the world of the everyday, with the different aspects of the daily word present together in no clear pattern. Yet people are able to navigate through the ordinary world. In the same fashion, the vignettes comprise these stand-alone phrases. After a moment of shock, the respondent usually relaxes, and simply ‘grazes; through the information in what seems to be a relaxed fashion. Thus, Mind Genomics measures responses to ‘real information, viz., particulars such as descriptions of events as opposed to general ideas. Starting the evaluations from a granular experience differs from conventional scales of today in that it does not only restrict the responses to an intellectualized version of a response. Most researchers find themselves restricted to working with and considering only generalized ideas rather than specifics, but with Mind Genomics, the survey respondent is the one who more easily “abstracts” the general ideas as they are based on their answers to the particulars. by this method.
  2. Mind Genomics makes it impossible for people to ‘game’ the system. People do not necessarily tell the truth, either by deliberately lying, or unconsciously misrepresenting themselves to be more agreeable or more correct as they interact with the interviewer. It remains the nature of today’s science to rely on scales that can be easily ‘gamed [1]. Due to human nature and the inherent drive to be positively perceived, the validity of a scale cannot be easily assured using conventional methods.

The history of Mind Genomics traces back to three sources, the combination of which ended up synthesizing this new discipline. The history traces back to experimental psychology, particularly in the realm of psychophysics; statistical specifically in experimental design; and consumer research, with a focus on discerning and delineating patterns in decision-making processes. The ‘experiment’ in Mind Genomics presents respondents with vignettes, combinations of succinct, stand-alone phrases which create a scenario. The respondent reads the vignettes, one at a time, and then rates the vignettes. Afterwards, the underlying experimental design enables the deconstruction of the responses into the contribution of the individual elements. In order to make the analysis simple and the results straightforward for a manager to understand, the Mind Genomics program transforms the ratings into new binary variables, taking on the value of 0 or 100. The transformations are explained below. Mind Genomics endeavors to uncover interpretable patterns within the construct, such as trauma, doing so with simple stimuli, but ‘cognitively meaningful’ ones. In the Mind Genomics study, respondents ultimately generate cohesive patterns of data, as illustrated in the results below. It is crucial to underscore that throughout the study, respondents are intentionally guided to abstain from delving into the messages within the various combinations in an attentive way, pondering the message. Instead, the subconscious assumes control, steering respondents towards responses that may initially seem arbitrary. However, it is important to recognize that these responses are far from random.

Introduction to the Study

The science behind Mind Genomics allows researchers to explore the human experience in the context of a wide array of topics. Among these factors, childhood trauma stands out as a potent force shaping an individual’s perception and interaction with the world [2]. Childhood trauma, defined as adverse experiences occurring before the age of 18, encompasses a range of events such as abuse, neglect, and household dysfunction. Its profound impact on psychological development and overall well-being has been extensively documented in psychological and medical literature [3,4]. One of the most significant consequences of childhood trauma is the development of complex post-traumatic stress disorder (cPTSD) and hypervigilance [5]. These conditions manifest as heightened sensitivity to potential threats, pervasive feelings of fear and anxiety, and difficulty regulating emotions. Individuals who have experienced childhood trauma often navigate daily experiences through a lens colored by these psychological scars, which significantly alters their perceptions and reactions compared to neurotypical individuals. Whereas the neurotypical individual may take for granted the ability to engage with daily experiences without undue distress, those who have experienced childhood trauma face unique challenges. Simple tasks such as witnessing conflict, engaging in social activities, and managing emotions may turn into formidable obstacles. The omnipresent threat of triggering memories or emotions associated with past trauma can cast a shadow over even the most mundane activities, leading to avoidance behaviors and social isolation. The power behind the use of AI in the context of Mind Genomics allows researchers to expand this existing knowledge about psychology and medicine.. By applying Mind Genomics techniques to the study of reactions to daily experiences among individuals who experienced childhood trauma, researchers can identify differences in cognitive processing and information integration. This approach allows for a more comprehensive understanding of how past trauma influences the interpretation and response to everyday stimuli.

Setting up the Mind Genomics study on trauma

The raw material for vignettes – questions and answers: The first step registers the study, gives it a name, and proceeds to the heart of the approach, namely creating four questions, and then for each question creating four answers. The answers themselves must be simple, stand-alone phrases which paint a word picture. These answers, called ‘elements’ will end up being combined with each other in vignettes. Figure 1, Panel A shows the schematic request for the four questions. It is in this first encounter with the requirement to think of four questions than many researchers encounter difficulties. While discussing the etiology of trauma is manageable, crystallizing these etiologies proves challenging when the task is to create standard questions with answers which reflect mundane life experiences triggering trauma. Producing the questions separates the diagnosticians/therapists from statistically oriented researchers. Diagnosticians and therapists aim for a comprehensive understanding of the patient, whereas statisticians prefer straightforward numerical data for tallying questions. Consequently, the task of creating a list of questions that tells a coherent story becomes arduous. The answer to the dilemma is AI, in the form of Idea Coach, which embodies SCAS (Socrates as a Service). SCAS was created to make the process less arduous, and in some cases make the process a learning experience. Figure 1, Panel B introduces the Idea Coach, embodying SCAS. In this stage, the user articulates the issue by writing the ‘squib,’ a colloquial term for the text typed into the box. The squib may undergo multiple edits to refine the type of question desired. Panel C showcases some of the AI’s output. Finally, Panel D displays the four questions selected after user editing, preparing them for answers. Users can also rerun the Idea Coach, doing so in an iterative fashion, editing the squib when desired to see what emerges. Within the program (www.bimileap) the SCAS system embedded in Idea Coach requires about 10-15 seconds per iteration. Even with squib editing, users can generate 10 pages of 15 questions in about 8-10 minutes. The resulting ‘question book,’ combined with AI summarization, proves to be a valuable resource, as further illustrated below.

FIG 1

Figure 1: The first part of the Mind Genomics study, showing the four panels to help the user select questions.

Figure 2 the second phrase, the selection of answers to each of the four questions. Panel A shows the request for four answers. The user can simply press the Idea Coach button. The ‘squib’ is the question selected by the user. Panel B shows 8 of the 15 answers emerging with 10-15 seconds. Once again the user can iterate to educate themself by looking at the different answers to the question, or the user can actually edit a particular question.

 

FIG 2

Figure 2: The Mind Genomics Template showcasing the question and the AI-generated possible answers to the question that the user can select. Panel A shows the template for the four answers for Question #2. The question comprises the full set of modifications to the prompts, to create answers which are in the proper form. Panel B shows eight out of 15 answers for this iteration.

In summary, the Mind Genomics study entails a structured process to generate questions and answers, incorporating AI assistance (SCAS) and iterative refinement. The outcome is for a comprehensive exploration of complex topics, such as the effects of trauma on daily responses to various stimuli. This phase often becomes a critical juncture where researchers may encounter challenges, finding it easier to discuss cases of trauma but challenging to crystallize the discussion into standard questions. Those focused on diagnostics and therapy seek a closer, deeper understanding of the patient, whereas those concentrating on statistical analysis prefer simple numbers to tally on questions. Both will end up being satisfied with the combination of AI, creative thinking, and quantitative analysis using qualitative inputs.The final set of questions and answers appear in Table 1. These crafted inquiries and responses embody the collaborative effort to mold the content and structure of the answers. The overarching goal is to create a collection of meaningful standalone phrases (elements) which paint word pictures about the topic, and which can be combined together in small vignettes comprising 2-4 elements.

Table 1: The final set of questions and answers emerging from the collaboration of the user and SCAS (the AI embedded in the Idea Coach).

TAB 1

The self-profiling classification question: The setup process advances by formulating classification questions. The classification questions are simple questions which provide additional information about who the respondent IS, what the respondent has EXPERIENCED, etc. In this study, eight questions based on the original ten Adverse Childhood Events questions were asked as part of the study introduction to each respondent. Adverse Childhood Experiences (ACEs) and the ACE survey are integral components of research aimed at understanding the long-term impacts of childhood trauma on health and well-being. The concept of ACEs originated from a groundbreaking study conducted by the Centers for Disease Control and Prevention (CDC) in collaboration with Kaiser Permanente’s Health Appraisal Clinic in San Diego, California, in 1997.The ACE study surveyed over 17,000 adult respondents, collecting information about their childhood experiences of abuse, neglect, and household dysfunction. The study identified ten specific types of adverse experiences [3]:

  1. Physical abuse
  2. Emotional abuse
  3. Sexual abuse
  4. Physical neglect
  5. Emotional neglect
  6. Household substance abuse
  7. Household mental illness
  8. Parental separation or divorce
  9. Domestic violence
  10. Incarcerated household member

Respondents were asked to indicate whether they experienced any of these events during their childhood and adolescence. The study revealed a significant association between ACEs and a myriad of negative outcomes across the lifespan, including physical and mental health issues, substance abuse, risky behaviors, and socioeconomic challenges. For the purposes of Mind Genomics, the original ten questions were reduced to eight (Table 2) questions as seen in Table 2. Figure 3 shows the templated format in the Mind Genomics set-up for the ACE question.

Table 2: The eight ACE questions presented to respondents in the self-profiling classification part of the Mind Genomics interview, BEFORE the evaluation of the 24 test vignettes.

TAB 2

 

FIG 3

Figure 3: How the ACE question is inserted into the Mind Genomics study at the time of set-up.

The final phase of the setup process involves crafting the introduction to the study and then establishing the scale to be utilized. Table 3 shows the introduction and the rating scale in table form. Figure 4, Panel A displays the introduction presented to the respondent. Typically, brief and direct, this introduction focuses the respondent’s attention on the task. Recognizing the increased shortening of attention spans, the introduction is written in an abbreviated way. In some cases, however, such as legal cases involving childhood trauma, the introduction to a Mind Genomics might warrant a more detailed introduction to ensure that respondents are informed of the case’s background. Panel B illustrates the five-point rating scale, customizable by the user to align with the project objectives. In this study, the rating scale captures two dimensions. The first dimension of the scale assesses the immediate feeling of being upset if one or more of the events in the vignette were to occur. The second dimension of the scale gauges the perceived ability of the vignette to evoke a distressing memory.

Table 3: The introduction to the respondent and the text of the five answers to the question

TAB 3

 

FIG 4

Figure 4: Respondent orientation. Panel A shows the set-up screen for the orientation that the respondent reads. Panel B shows the set-up screen for the rating scale that the respondent will use to rate each vignette.

The Respondent Experience

The respondent experience begins with the completion of a questionnaire which asks them demographic questions followed by the 8 questions about Adverse Childhood Event (Figure 5). The respondent’s experience was simplified by a pull-down questionnaire, with each tab had to be individually pulled down.

FIG 5

Figure 5: The pull-down menu for the self-profiling classification questionnaire

After the self-profiling classification, the Mind Genomics program initiates the presentation of vignettes to respondents. Figure 6 shows an example, the top presenting a concise introduction to the study at the top, middle showing the rating, and the bottom showing both the vignette presented as a set of lines (two to four elements shown in three successive lines), followed by the rating scale. This format enables respondents to ‘graze’ through the information, avoiding the fatigue that could result from reading 24 dense paragraphs, each consisting of two to four sentences with connectives.

FIG 6

Figure 6: Example of a vignette

The vignettes were developed with the following properties.

  1. Each respondent assessed a total of 24 vignettes, the 24 vignettes comprising a complete experimental design.
  2. The 24 vignettes for each respondent each comprised a minimum of two elements and a maximum of four.
  3. Each vignette contained at most one answer (referred to as ‘element’) from a specific category, ensuring that no vignette presented conflicting information of the same type.
  4. Every element appeared five times among the 24 vignettes and was absent 19 times,.
  5. Each question or category contributed to 20 out of the 24 vignettes.
  6. Each respondent evaluated unique vignettes, a distinctive feature of Mind Genomics studies. The creation of the different sets of vignettes means that the research covered a great deal of the design pace, freeing the user from having to select the ‘most promising’ elements ahead of the research. This approach, called the permutated design [6] allows the researcher to use the approach at any stage of the research.
  7. Every respondent assessed a precisely crafted set of 24 vignettes, with all 16 elements being statistically independent of each other, and capable of independent analysis, particularly OLS (ordinary least squares) regression analysis, also known as curve fitting. This approach enhances the statistical significance of each respondent’s contribution to the study.

Field Specifics and Data Preparation

As demonstrated in Figures 1-6, the system has transitioned into a do-it-yourself (DIY) framework. Within this DIY paradigm, user engagement extends to recruiting respondents through an online panel aggregator equipped with a built-in API. The Mind Genomics platform empowers users to define the target population based on criteria such as country and age, which is then incorporated into the API. Users incur a nominal recruitment fee, gaining access to a pool of online volunteers facilitated by the provider, Luc.id Inc., boasting access to hundreds of millions of volunteer panelists worldwide. In the context of this study, test respondents were invited based on their prior agreement to participate in studies, accruing points towards rewards for their participation. The user’s role involved specifying the details, completing the payment through a credit card, and triggering email invitations to the target respondents. This streamlined process demonstrated efficiency, with the study involving 101 respondents, requiring less than four hours for completion. From the perspective of the study respondent, the actual duration was approximately 3-4 minutes. Respondents initiated the study by clicking on the embedded link, progressing through a brief ‘hello’ page, a self-profiling classification (Figure 5), and an introduction to the study itself. Subsequently, respondents evaluated the set of 24 unique vignettes organized according to the aforementioned experimental design (Figure 6). Figure 7 shows the median response time by test order, indicating that once respondents grasped the task, the median response time dropped to less than two seconds. The ability to swiftly inspect a vignette and assign a rating meant that the effort to read the vignettes amounted to 2-3 minutes. As noted above, in this type of study respondents adopt a ‘grazing’ approach, akin to superficially inspecting their surroundings, aligning with the Mind Genomics objective to capture data from individuals engaged in casual observation and rating. This approach aims to derive patterns not from deliberate, conscious efforts but from the more typical automatic and almost instinctive responses. Psychologist Daniel Kahneman’s conceptualization of rapid evaluation as ‘System 1,’ distinct from the considered and slower ‘System 2,’ aligns with the behavioral outcomes shaped by Mind Genomics [7].

FIG 7

Figure 7: How the median response time to the vignette changes across the 24 test positions, from start (test order 1) to end (test order 24).

The respondent provided a rating for each vignette on a five-point scale, constructed to encompass two dimensions: the immediate negative feeling upon imaging one or more elements in the vignette were to happen to them and/or the sense of the vignette potentially evoking a memory of a negative feeling. To extract meaningful information from the scale for statistical analysis, it is necessary to create new ‘binary dependent variables’ through simple transformations. These transformations yield variables suitable for OLS (ordinary least-squares) regression, allowing the researcher to uncover the relation between the presence/absence of the element and the respondent’s ratings. Table 4 shows the transformations. After the transformations, a prophylactic step was taken, adding a vanishingly small random number (<10-5) to every newly created binary scale value.. This addition ensured a slight variability in each binary dependent variable, a requisite for the regression analysis to function effectively and prevent potential ‘crashes’ due to the lack of variability in the dependent variable.

Table 4: The transformations

TAB 4

 

Initial Analyses – Do the Averages of the Binary Variables Different Across Key Subgroups?

The initial analysis examines the average of each newly created binary variable, first for the total panel, and then for the key groups defined by the self-profiling classifications. Three new subgroups were created, based upon the speed of rating the vignette (quick, intermediate, slow). The Mind Genomics system produce a great deal of data, especially with the many newly created binary variables, such as R1x to R5x, etc. To make the analysis more tractable, we consider only two newly created binary variables, R5x (most negative response to the vignette) and R1x (least negative response to the vignette), along with response time. Table 5 presents the average ratings. Particularly noteworthy is the inverted U pattern for R5x concerning respondent age, with the highest R5x occurring in the age group of 35-44. Additionally, respondents who answered quickly exhibited a notably high value for R5x. This finding means quite simply that when the respondent finds the vignette stressful, the respondent is likely to react more quickly to the vignette.

Table 5: Average ratings of R5x, R1X and response time by key groups

TAB 5

Relating the Presence/Absence of the Elements to R5x (Strongest Negative Response to a Vignette)

The next level of analysis is to link together the assignment of the most strongly negative response (R5x) to the 16 elements appearing in the vignettes. OLS regression will uncover the pattern. The equation estimated by OLS regression uses all the relevant data from the respondents in the defined group. The equation is expressed as R5x = k1A1 + k2A2.. k16D4. These coefficients appear in Table 6 as 16 rows, with each column corresponding to a key subgroup. The coefficient shows the link between the presence of the element as the average value of R5x. We look for high linkages, viz., a coefficient of 15 or higher. Table 6 shows elements with strong linkages of coefficients 15 or higher. These are all shaded. Table 6 It also shows coefficients greater than 10-14, meaning relevant elements, but not strong drivers of R5x. Empty cells correspond to coefficients less than 10. With large numbers of coefficients to be displayed it is often more productive to eliminate low values for the coefficients, making it easier to discover the patterns, and see elements with strong linkages. Table 6 shows some strong elements, but the pattern is difficult to discern. Most groups show very few coefficients above 10 (viz., Total Panel, males, females), which can make those elements which show a coefficient of 15 or higher stand out more amongst the total elements. What is also interesting is how certain traumatic experiences had more significant elements. Individuals who reported economic disadvantages had five strong performing elements, whereas Childhood Sexual Abuse showed only two strong performing elements. Respondents who had a caretaker or exposure to mental illness or suicidality and subjects who had a caretaker or exposure to someone who was in jail or involved in criminal activity showed only one strongly performing element. Only one element,, witnessing a bar fight, turned out to be a strong performer for more than one group of traumatic events. This element was a strong performer for three groups, those reporting childhood sexual abuse, those reporting poverty, and those reporting having an incarcerated household member.

Table 6: How the elements ‘drive’ R5x by Total panel and by key subgroups. Note: F. Female, M. Male, Q1x. Sexual Abuse, Q2x. Emotional Neglect, Q3x. Poverty, Q4x. Emotional Abuse, Q5x. Physical Abuse, Q6x. Household Substance Abuse, Q7x. Household Mental Illness, Q8x. Incarcerated Household Member.

TAB 6

Mind-Sets Emerging from Clustering the Respondents based on R5x

A hallmark of Mind Genomics is the search for underlying groups of people based upon their ways of perceiving the presented elements. Rather than looking for general groups of people defined by how they behave or how they look at the world in general, Mind Genomics focuses on the ‘granular,’ where experience is real and immediate. The approach to clustering combines mathematics and interpretation. The mathematics uses the coefficients emerging from the OLS regression, those coefficients showing how each of the elements ‘drives’ the response. Recall that each binary dependent variable could be expressed as a linear combination of ‘weights,’ expressed by the equation: BDV (Binary Dependent Variable) = k1A1 + k2A2… k16D4. The mathematics creates an individual equation for each of the 101 respondents, relating the presence/absence of the elements to that individual’s ratings of R5x, the key dependent variable. The data returning from this first step comprises 16 columns, each column corresponding to one of the 16 elements, and 101 rows, each row corresponding to one of the 101 respondents. The numbers inside the cells are the coefficients. The second step clusters the 101 respondents, dividing the respondents first into two groups, and then into three groups, called clusters. The clusters are defined as comprising ‘similar patterns’ of coefficients, similarity in turn defined as high Pearson correlation between the 16 coefficients of pairs of respondents. The actual mechanics of computation do not consider the meaning of the elements. Rather, each cluster comprises individuals who show highly correlated patterns of coefficients. The centroids of the different clusters are quite different from each other [8]. The process of clustering ends up generating different groups of respondents, the patterns with a group or cluster being similar, and the average pattern of each cluster differing from the average pattern of the other clusters. Once each respondent is assigned to a cluster, the clusters become new subgroups, allowing the user to estimate the coefficients for each cluster. When the 101 respondents are clustered by the pattern of their coefficients, viz., by their responses to test elements, three radically different mind-sets emerge, each mind-set comprising elements with far higher coefficients. It is in the nature of clustering by mind-sets that the user isolates groups of people with clearly different and clashing responses to the same elements. The conflicting answers frequently obscure the underlying patterns as they negate each other, creating the misleading notion that there is nothing to examine. However, a clearer picture can emerge by reconciling these contradictions. Table 7 shows these three emergent mind-sets, and the substantially higher coefficients which emerge once the mutually canceling effects are diminished by separating the mind-sets from each other. We are left with several R5x coefficients of 20 and greater. AI was able to find a general pattern between each mind-set- MS1- “strong response to safety issues”, MS2- “strong responses to financial realities of the everyday”, and MS3- “strong response to everyday events that could be misinterpreted.”

Table 7: The three emergent mind-sets after clustering on the basis of R5x

TAB 7

By dissecting the specific elements within each mind-set, we gain insight into the commonalities among them and uncover potential narratives about the individuals they represent. For instance, in MS1, characterized by a “strong response to safety issues,” individuals exhibit a pronounced negative reaction to seven specific elements, as Table 7 shows. These elements collectively reflect situations involving safety drills, emergency scenarios, and the witnessing of potential crisis situations. Individuals within this mind-set possess a heightened sensitivity to safety and emergency preparedness. Without considering additional factors such as Adverse Childhood Experiences (ACE), a psychologist might infer that these individuals have likely encountered various forms of heightened emergency situations, perhaps including military veterans or individuals with backgrounds in high-stress environments. Specifically, those who endured childhood sexual abuse exhibited a strong negative reaction to mishandling a firearm. Whereas it may be challenging to directly infer the correlation between childhood sexual abuse and firearm mishandling, it underscores the complex psychological impact of trauma and its potential influence on perceptions of safety and threat. In contrast, individuals who grew up in poverty, often residing in high-crime areas in the USA, displayed heightened reactions to elements such as sirens, active shooter drills, high-security measures, and witnessing excessive alcohol and drug consumption. This connection is more readily understandable, as individuals from socioeconomically disadvantaged backgrounds may have been exposed to environments characterized by increased risk and danger, thus developing heightened sensitivities to these specific stimuli. These findings highlight the intricate interplay between childhood experiences, trauma, and individual reactions to various elements. By elucidating these connections, we gain valuable insights into the nuanced ways in which past experiences shape perceptions and responses, guiding more targeted and effective interventions for those impacted by trauma. Mind-Set 2 is dominated by individuals with obvious financial insecurities whether that be real- struggling to pay bills or make ends meet and being unable to afford necessary medical treatment- or imagined such as feeling pressured to keep up with fashion trends or brands. An intriguing observation is that none of the elements within Mind-Set 2 corresponded to any Adverse Childhood Experiences (ACE). This absence of ACE alignment in Mind-Set 2 aligns with the nature of financial insecurity, which may predominantly stem from present-day circumstances rather than from childhood traumas. Financial pressures, both real and perceived, can exert substantial influence on individuals’ daily lives and psychological well-being, often overshadowing the impact of past adverse experiences. Furthermore, the unique composition of elements within Mind-Set 2 underscores the diverse manifestations of financial insecurity, ranging from tangible economic hardships to more intangible pressures of societal expectations. This multifaceted nature highlights the complexity of individuals’ experiences and the various factors contributing to their mind-set and behavior. For example, experiencing childhood poverty did not correlate to a mind-set of financial insecurities as an adult, which may seem perplexing at first glance. However, a deeper analysis reveals that individuals who endure childhood poverty might develop coping mechanisms to navigate persistent financial pressures, thereby mitigating the fear of financial strain in adulthood. Alternatively, they could be driven by an increased motivation to break free from the cycle of poverty, thereby reducing the impact of financial insecurities on their mind-set as adults. Finally, Mind-Set 3, characterized by a “strong response to everyday events that may be misinterpreted,” shares some similarities with Mind-Set 1. The difference, however, comes from the focus on situations commonly encountered by everyone, albeit with an elevated response. These elements encompass everyday occurrences which might typically evoke minor reactions but can trigger heightened distress for individuals belonging to this mind-set. For instance, encountering sudden or expected loud noises, such as a car backfiring, may prompt annoyance or momentary surprise for many individuals. However, for someone with a history of childhood trauma and hypervigilance, this noise could induce a more profound and prolonged state of distress. Moreover, the only specific adverse childhood event associated with Mind-Set 3 is having a household member with mental illness or suicide. This association underscores the profound impact of familial dynamics and mental health struggles within the household on an individual’s psychological well-being. The absence of other ACEs in this mind-set suggests that the elevated responses to everyday events may be influenced primarily by experiences within the immediate family environment, rather than broader childhood traumas. However, this is a hypothesis that would benefit from further exploration given the nature of the elements strongly responded to by MS3, specifically crowded places, loud noises, and sexually explicit content, respectively. A final point to make is that only out of all of the elements that were significant within a specific ACE category as seen in Table 6, each element had an intersection with one of the three Mind-Sets in Table 7. The only except was witnessing a bar fight, which elicited a strong negative response for individuals with a history of poverty, and those who had a household member who involved in criminal activity or incarcerated. This unique response suggests that the impact of witnessing a bar fight may transcend the typical associations with specific ACE categories and instead be influenced by broader environmental factors, such as socioeconomic status and exposure to violence in the community. This insight underscores the complexity of trauma and its intersectionality with various life experiences. By recognizing the specific elements that trigger strong responses within each ACE category and their corresponding mind-sets, we gain a deeper understanding of the interconnected factors contributing to individuals’ psychological well-being.

Meta-analysis: Contribution of Gender, Adverse Childhood Events, and Elements to Responses

Table 6 shows how the elements were associated with the eight ACE questions. Table 7 shows which elements strongly drive negative responses among respondents in the three mind-sets. The final analysis reveals patterns emerging when we reduce the stringency of our criterion importance by reducing the cut-off level of a coefficient of +8 or higher. using a coefficient of 8 or higher to represent strong coefficient. In this analysis, ACE, elements, and the three mind-sets were analyzed in a meta-analysis. The three objectives of this meta-analysis were: 1) Uncover the specific ACE questions and elements associated with the three mind-sets, 2) Explore gender association with each mind-set, 3) Explore response time (RT) as a function of gender and ACE experience. Table 8 shows the grand models, incorporating all predictors, for Total and for mind-sets. The grand model was created by OLS regression, using the presence/absence of the 16 elements for each vignette, but incorporating two new sets of predictor variables. One group was gender. Since there were only two genders considered, male and female, respectively, there was only one predictor. This was ‘Female.’ A respondent could either be a female or not a female. Thus, in Table 8 there is no coefficient for males. The second group was the ACE experience. For each of the eight ACE questions, the respondent was coded ‘1’ when the respondent reported having that ACE experience, and coded ‘0’ when the respondent reported not having that ACE experience. The result was a new set of 25 predictors for OLS, comprising 16 elements, one gender, and eight ACE experiences. Table 8 shows the strong performing elements shaded, as well as long response times shaded. For the binary dependent variable, R5x, a great deal has to do with who the respondent is, as show by the gender and by the ACE variable, with little additional effect due to the element. In contrast, response time is affected more by mind-set and by specific message. In this meta-analysis, few elements emerge as drivers of negative feelings. In fact, only one element “hearing someone make an inappropriate sexual joke or comment” was associated with a specific mind-set, in this case Mind-Set 1. Mind-Set 1, characterized by heightened concerns about safety issues, is associated with emotional abuse, household mental illness, sexual abuse and household substance abuse. These experiences likely contribute to a heightened sensitivity to safety, and a tendency to perceive threats more acutely. In contrast, Mind-Set 2, marked by strong responses to real or perceived financial insecurities, exhibits correlations with household mental illness, sexual abuse, incarcerated household member and emotional neglect. Noteworthy, childhood poverty, which might intuitively be thought to align with concerns about financial stability in adulthood, does not fit into this mind-set. Additionally, Mind-Set 2 stands out as the only mind-set to display a gender bias toward female respondents, indicating potential gender-specific vulnerabilities related to financial insecurities. Within this mind-set, one of the elements was “feeling pressured to keep up with expensive fashion trends or brands,” which tends to weigh more heavily on individuals identifying as women. Mind-Set 3, characterized by strong responses to everyday events that could be misinterpreted, shows correlations with emotional neglect, poverty, and household substance abuse. This suggests that individuals in this mind-set may have experienced childhood environments where misinterpretation of everyday events was prevalent, potentially leading to heightened sensitivity to ambiguous stimuli in adulthood.The overlap of household mental illness, sexual abuse, emotional neglect, and household substance abuse across two out of the three identified mind-sets in this meta-analysis highlights the profound and interconnected nature of these adverse childhood experiences (ACEs) as shaping individuals’ psychological profiles and responses to their environment. Furthermore, it is noteworthy that physical abuse is the only ACE that does not align with any of the three identified mind-sets. These discrepancies underscore the complexity of trauma and its varied manifestations, indicating that some ACEs may elicit responses which transcend the thematic boundaries of the identified mind-sets. Overall, the patterns observed in the correlation between ACEs and mind-sets highlight the diverse pathways through which childhood traumas influence adult psychological profiles.

Table 8: Meta analysis, relating the rating of 5x (negative feelings) and RT (response times) to gender, to the eight ACE experiences, and to the presence/absence of the 16 elements.

TAB 8

Discussion and Conclusions

Traditionally, studying human cognition and emotion has been a complex and labor-intensive process, all too often relying on subjective assessments and limited sample sizes. The particular questions to ask, the elements, have always been a stumbling block to the researcher seeking to understand the ‘unwritten rules for appropriate stimuli’, relevant when working with patients in particular, with people in general. The AI contribution here through SCAS, focusing as it does on questions to ask and answers to use, provides a new tool to explore how people think. SCAS and its underlying AI empower the user the ability to iterate again and again in real time, understanding the topic more deeply by reading, thinking, and revising questions and answers, all in real time. The research ‘teaches’ as the user sets up the study, doing so in a way which engages because the material, ranging from the squib to the questions to the answers, is relevant, and the AI is hyper-focused. One should view AI as a tool that to enhance and to augment the capabilities of human researchers rather than something which replaces them.. In the context of Mind Genomics research, AI is a powerful ally, extending the reach and scope of human imagination in the creation of the test stimuli. As shown here with the study of trauma, it is the human researcher who can set up the study, and who can guide the analysis. Mind Genomics, with its focus on vignettes as experimental stimuli, offers a platform to delve into the complexities of trauma. These vignettes serve as windows into the subconscious, allowing individuals to explore thoughts and emotions, thinking and feeling. With AI’s assistance, the researcher can generate the elements, the raw material of the vignettes, ensuring that these elements resonate with diverse audiences to capture the essence of trauma across various contexts. The elements generated in this study by SCAS in the Idea Coach are witness to the ease with which Mind Genomics coupled with AI create some of the raw material needed to understand the mind. By gaining a deeper understanding of how trauma affects emotional processing, researchers can develop more effective interventions and treatments for individuals who have experienced childhood adversity. Overall, the integration of AI into the study of emotional responses to childhood trauma represents a convergence of cutting-edge technology and compassionate inquiry. AI-driven algorithms could potentially help identify personalized treatment plans tailored to an individual’s specific needs and circumstances, leading to better outcomes and improved quality of life. By harnessing the power of AI, researchers can unlock new insights into the complex interplay between personal experiences and psychological outcomes, ultimately paving the way for more effective interventions and support systems for those affected by trauma. Ultimately, the fusion of Mind Genomics, AI, vignettes, and statistics represents a paradigm shift in the study of trauma. It offers a holistic framework for unraveling the complexities of human experience, empowering us to explore, understand, and address trauma with unprecedented depth and precision. Through this interdisciplinary approach, we pave the way for innovative solutions and interventions which resonate with the intricacies of the human mind.

References

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  3. Felitti VJ, Anda RF, Nordenberg D, Williamson DF, Spitz AM, Edwards V, Marks JS, et al. (1998) Relationship of childhood abuse and household dysfunction to many of the leading causes of death in adults: The Adverse Childhood Experiences (ACE) Study. American Journal of Preventive Medicine 14: 245-258. [crossref]
  4. Austin A. (2018) Association of Adverse Childhood Experiences with Life Course Health and Development. North Carolina Medical Journal 79: 99-103. [crossref]
  5. Cloitre M, Courtois CA, Charuvastra A, Carapezza R, Stolbach BC, Green BL, et al. (2011) Treatment of complex PTSD: Results of the ISTSS expert clinician survey on best practices. Journal of Traumatic Stress 24: 615-627. [crossref]
  6. Gofman A, Moskowitz H [. Isomorphic permuted experimental designs and their application in conjoint analysis. Journal of Sensory Studies 25: 127-145.
  7. Kahneman D, (2011) Thinking, Fast and Slow. Macmillan.
  8. Aristidis Likas, Vlassis NA, Verbeek JJ (2003) The global k-means clustering algorithm. Pattern Recognition 36: 451-461.

Mind Genomics and Today’s Realpolitik: The Conflict About Teaching Young Students Ideas that Could Be Propaganda

DOI: 10.31038/JIAD.2024121

Abstract

AI embedded in the platform of Mind Genomics was used to synthesize mind-sets regarding the attitudes of parents towards what is being taught to their children. The AI program emerged with the three mind-sets being Traditionalists, Concerned Parents, and Progressives, respectively. The AI program clearly summarized the values of these three mind-sets when instructed to define what the mind-sets believed to be wrong with today’s education, to be ok with today’s education, and finally to be excellent with today’s education. The AI program, Idea Coach, was instructed to create 20 statements, and to predict how each of the three mind-sets would score each statement in terms of whether or not it bothered them, and whether or not this statement described what was happening in their schools. The answers made intuitive sense. The process shows the power of AI as an aid to critical thinking and understanding, as well as a novel way to deal with a complicated topic even before doing any reading or research.

Introduction

During the past several years a variety of news stories have appeared regarding the discovery that students in classrooms around the United States may be receiving propaganda in their daily lessons. One need only read stories about propaganda to realize that something may be going on, although we do not know. This issue has come to the fore recently with the spread of news about the influence of the Chinese Communist Part (CCP), such as this headline from the Oklahoma Council of Public Affair in August 2023 Tulsa Schools Linked to Chinese Communist Entity [1]. We are accustomed to hearing this in other countries and situations, such as the recently revealed but long-known fact that the ‘teachers’ in Gaza, supported by the United Nations (UNWRA) are teaching anti-Israel and anti-Semitic material, lesson material that is found in their textbooks [2]. The issue is here in the United States as well, as expressed in a November 22, 2023, story by Zachary Faria in the Washington Examiner: The Democratic Party’s panic over losing control of narratives in schools has led it to pursue a new path to propagandize to children: mandatory “media literacy” classes to teach students about “fake news.”. Media literacy lessons are now mandatory in California in English, science, history, and even math classes throughout every grade level, thanks to a law signed by Gov. Gavin Newsom (D-CA) last month. Delaware, Illinois, and New Jersey are also among the states requiring these lessons. Among other things, the California law worries about the effects of “online misinformation” that has “threatened public health.” [3]

The issue of teachers teaching what the parent’s believe the student should not be learning appears to be a systemic issue, perhaps one plaguing all of society. Increasingly, teacher values clash with parent’s values, the conflict played out in the arena of education. ‘School boards have a central position in educational governance. They have to guarantee quality, monitor results and intervene if needed’ [4]. The issue is explained even more elegantly by [5]’…while school administrators are challenged to turn schools around with limited time and resources quickly, their efforts are not a silver bullet. Engaging community requires committed partnerships that support schools to advance quality learning. Community school councils, an organizing strategy, focus on addressing potential threats and enhancing strengths for student success’.

In the United State, irate parents have verbally attacked the local school boards, often the attack making news. The complaining parents are called ‘terrorists’. The local education establishment gather around to defend the teacher and castigate the irate parents. . “New whistleblower information has revealed that the FBI targeted parents who spoke out against their local school boards’ COVID policies, after prodding from education officials. It all started in September, when the National School Boards Association (NSBA) sent a letter to the Department of Justice (DOJ) requesting federal intervention into the alleged “domestic terrorism” that is citizens disagreeing with school board officials” [6]

The conflict between parents and the educational system has created the opportunity for academic investigation on a broad front, ranging from who is teaching to whom, and most important, what is taught, with what emphasis, and with what objective [7-9].

The opportunity to explore these issues using AI embedded in the Mind Genomics platform, www.bimileap, allows us to look at the topic in a new way, and with some new tools. The tool, Idea Coach, allows us to specify a problem, and after specifying the problem, put AI to work to generate the data.

The approach presented here originates in the effort by the authors to change the way we discover how people think. The traditional methods began with qualitative discussions, in which people could surface their concerns, and in which a trained ‘listener’ or ‘moderator’ could elicit information from people leading to insights. There is an entire discipline of qualitative research, popular, growing, requiring training to understand what is really being communicated in an interview or in a group discussion. It is from these qualitative interviews with parents as well as observing what is being reported in the media that the importance of the curriculum being used with the students has emerged.

Beyond qualitative work is the effort by researchers to measure the minds of peoples, or if not the minds, then measure the attitudes of people. These measurements are done by surveys, in which the researcher creates a list of questions about topics, and instructs the respondent, the survey taker, to rate the different topics or questions on one or another scale. Most of the readers by now should be familiar with surveys which seem to follow every transaction of a business nature, with the survey attempting to quantify the different aspects of the experience. Typically the surveys are either done for general attitudes or for specific attitudes, but in either case the surveys fail to get to the granularity of the experience. Nonetheless, the researcher executing the survey ends up with a measure of performance or importance of an experience relevant to the group commissioning the survey

It was against this background of surveys and the failure to deal with the granularity of the data that the notion of presenting respondents with combinations of messages emerged. The research leading to this effort had been developed by mathematical psychologists under the name conjoint measurement [10], and popularized by Wharton professors [11]. The underlying idea was to present the respondent with combinations of messages about a situation, obtain their reaction to the messages and then deconstruct the messages into the contribution of the components.

The trajectory of science would lead to some developments in this effort to understand the mind of the person. The first effort was the creation of a DIY, do-it-yourself system, to run these experiments on topics, with the user providing questions which told a story, and for each question provide four answers, and then mix and match the answers (also called elements), to create a set of combinations (called vignettes). The respondent or survey taker would be presented with these combinations and instructed to rate the combination. Each respondent evaluated a full set of combinations, these combinations constructed by an underlying experimental design which prescribed the component elements of the vignette. The later analysis generated an estimate of the contribution of each element.

The requirement to develop the four questions which tell a story proved to be a stumbling block. It was to address this issue that the approach, now called Mind Genomics, first attempt to teach users, but then with increased effort changed direction. Rather than teaching students, it became easier to create an AI-powered system called Idea Coach which, upon receiving a background of the study, would come up with the offering of 15 questions, and then for each question 15 answers. The task facing the researcher was now to write a coherent ‘squib’ requesting the 15 questions. Once the questions were chosen it was easy to create 15 answers for each question. Figure 1 shows the process.

fig 1

Figure 1: The basic Mind Genomics set-up. Panel A shows the request for four questions which tell a story. Panel B shows the AI-powered Idea Coach. The user can instruct the embedded AI to provide information.

Introducing the Problem to AI

The remainder of this paper shows the process of creating an orientation to AI, instructing AI to provide the relevant information, and then generating the necessary materials from the internal processing of AI. The approach can be done on the current Mind Genomics platform (www.bimileap.com). The one caveat is that with the same orientation to AI the output from Idea Coach varies, even when run several times. The reason for the variation is not known. The AI does try to follow instructions. Occasionally the AI returns with a message saying that it cannot fulfill the task, providing one or another reason for not be able to do so. Yet, despite the lack of perfect reproducibility, it is the very richness and instructional value from the AI output which motivates this paper.

Table 1 shows the introductory ‘squib’ or description provided to the Idea Coach program embedded in the BimiLeap program. The structure of Table 1 is important to elucidate because with AI small deviations from the pattern can end up causing the AI to deliver the wrong material., or to be incomplete. The parts of the introductory squib play different roles.

Table 1: The input ‘squib’ to Idea Coach. The input describes generalities of the mind-sets, requesting that AI provide specifics for each mind-set.

tab 1

Topic (Sentences 1-3)

In the ‘topic’ the user must provide the AI with some sort of background. The AI output from Idea Coach is sensitive to the phrases. In order to allow a systematic exploration of the impact of the set-up on the results, the set-up material is structured into three short sentences, each sentence spatially separated from the others by a blank line. In this way it becomes possible to change the orientation quickly, either help the AI provide the necessary information, or even to help explore what happens when the orientation is changed by adding something about the year in history for which the information is desired, or the country and year for which the information is desired

Posited Mind-Sets (Sentence 4)

The orientation states that there are three mind-sets, but does not define what a mind-set is, nor give any information about the mind-sets, other than there are three. In other uses of Mind Genomics and specifically Idea Coach, the authors have occasionally defined the mind-sets, whether these definitions be very tight and specific, or whether these definitions be ‘broad stroke.’ As will be shown in the next few paragraphs, simply defining that there are three mind-sets suffices for the AI to provide three radically different groups. From iteration to iteration there may be some changes in the nature of the three mind-sets, but each iteration makes sense.

Request for AI to Generate 20 Statements (Sentence 5)

These statements pertain to what the education process should do to ensure that the children are not subject to propaganda in the form of education. The instruction to AI is to provide a reasonably short phrase (15 words or less), that statement is realistic, and that each statement is a stand-alone sentence. AI has no problem following these directions.

Instruct AI to ‘Rate’ Each Statement on a Defined Four-point Scale (Sentences 6 and 7)

The AI is to assume that the statement was read by each of the three mind-sets, respectively. The scale is defined completely. The ingoing assumption is that the AI understands the meaning of the question, understands the meaning of the rating scale, and can assume the role of the mind-set.

Provide an Addition Eight Pieces of Information about Each Mind-set (Sentence 8)

Once presented with the request in the squib, it takes the Idea Coach approximately 10-15 seconds to provide answers. Each the user requests a new ‘run’ the Idea Coach begins anew. Occasionally Idea Coach cannot immediately answer the question immediately, returning with an apology. Later, however, after the effort has finished, Idea Coach will return with each of the iterations summarized. Those iterations that could not be addressed immediately and about which the Idea Coach apologized end up having been answered, however. The only problem seems to be the ability to provide the answers immediately and then move on to the next iteration.

We move on with the section of the squib requesting information about the three mind-sets. The information appears in Table 2. The columns show the three mind-sets, the rows show the answers to the eight questions. If were to trace back the mind-sets to the complaint about propaganda in education, it would be Mind-Set 2, the so-called ‘Concerned Parents’ who would be the ones most likely to fear the propaganda.

Table 2: Specifics for the three mind-sets created by AI

tab 2

It is important to recognize that the user provided no information to the Idea Coach other than the ‘operating hypothesis’ that there exist three different mind-sets in the population. Despite the paucity of direction given to the AI in Mind Genomics, Table 2 shows a quite reasonable division of points-of-view across the mind-sets. Table 2 also shows hypothesized demographic distributions which make intuitive sense.

Perhaps the strongest evidence for the usefulness of AI comes from ratings assigned to the mind-sets. Part of the request to Idea Coach was to suggest the likely rating to be assigned to each of 20 statements. The rating scale was two-sided, one side of the scale talking about ‘bothers me’, and the other side of the scale talking about ‘occurs in my school’. The mind-sets emerging from AI focus on topics of opinion. The AI did not request any guidance about the mind-sets, but rather simply presented them. The three mind-sets differ in their concerns and values, as Table 3 shows.

Table 3: AI-generated ratings for the 20 statements according to the three hypothesized mind-sets, as well as the deconstruction of the ratings into what statements ‘bother me’, and what statements describe ‘what occurs in my school’.

tab 3

The pattern of scaled responses appears to be more intuitively correct than might have been expected. The middle and right sets of columns show two letters, N corresponding to ‘NO’ for that rating category, Y corresponding to ‘YES’ for that rating category. The pattern of Y’s make sense. The ‘Traditionalists’ are not bothered by any of the statements. The ‘Concerned’ are bothered by the content of what is being taught. The ‘Progressives’ are concerned about fairness of what is being taught, and the ability of students to become ‘critical thinkers’.

Table 3 does not show dramatic ideological differences among the hypothesized mind-sets, but rather gives a sense of modest, nuanced differences. Furthermore, the pattern breaks down when we consider the second part of the scale dealing with ‘occurs in my school’. There seems to be no clear pattern here for any of the hypothesized mind-sets.

At the end of the iteration, once the user has either gone to the next iteration to obtain new ideas from AI in the Idea Coach routine or has proceeded to select questions and answers, the material created by Idea Coach is sent to a summarizer. The summarizer comprises a series of prompts which end up deconstructing the information and reconstructing the material into new perspectives. The first summarization comprises the analyses shown in Table 4. This summarization shows 15 new questions, 20 key ideas, and 20 themes. This pattern of summarizations is a legacy from the original summarizer, done when the focus of the Idea Coach was to present sets of 15 question to a simple squib, and set of 15 answers to a question. Despite being a legacy summarization, the three sets of statements provide additional topics for consideration, as well as different ways of stating the key issues.

Table 4: AI-generated summarization of the of the key issues, presented to the user in the Idea Book. The analysis is a legacy summarization used in simpler forms of the Idea Coach.

tab 4(1)

tab 4(2)

The Idea Coach further analyzes the material, presenting ideas, and for each idea three aspects. These aspects are called Plus (positive aspect), Minus (negative aspect or difficulty), and Interesting (long term benefit). The perspectives appear in Table 5.

Table 5: Perspective on the different ideas, showing short term benefits (Plus), short term problems (Minus), and long-term benefits (Interesting).

tab 5(1)

tab 5(2)

The next set of analyses provided in the Idea Book by the Summarizer deal with the different receptions that the ideas will receive. The first is the Alternative Viewpoints, or different ways of dealing with the topic. The second is the Interested Audiences, those who will accept the ideas. The third is the Opposing Audiences, those who will reject the ideas. Once again the AI embedded in Idea Coach provides a fairly thorough analysis of these viewpoints and responses to the material, an analysis which dramatically augments the understanding of the topic. Table 6 shows these groups of analyses.

Table 6: How the ideas are received, by three different groups suggested by Idea Coach

tab 6

The final set of analyses appears in Table 7. These analyses consider what is missing, and innovation. Once again, the analyses are done completely by AI, working only the information generated from the input squib given to Idea Coach. That information, in turn, comprised only the suggestion of three mind-sets, as well as some modest background of a few lines provided to Idea Coach at the start of the process.

Table 7: Suggestions for the future, based upon an analysis of ‘what is missing’, and suggested ‘innovations’.

tab 7

Discussion and Conclusions

This paper was generated in response to issues about possible propaganda in schools, a response to news articles and broadcasts from the media. The issue of propaganda is school emerged out of an interest in the actions of the Federal Government versus local school boards, where protesters were considered to be part of a rebellious criminal element. It is issues such as these, issues which inflame the emotions and which call into question the basic rights and liberties of people, which become interesting topics for Mind Genomics.

The original approach of Mind Genomics would have been to introduce the topic by a small squib, the writeup given to the Idea Coach, that writeup simply describing the situation as reported by the media and specifying questions to ask. The next step in the original Mind Genomics would have been to generate sets of 15 questions, select four questions which ‘told a story’, and for each question generate four answers. The respondent would then have been exposed to small vignettes; combinations of these messages would have rated the vignettes with each respondent rating a different set of 24 vignettes. The analysis of the ratings would be by accepted statistics (Ordinary Least Squares to relate elements to ratings; Clustering to define new to the world groups or mind-sets). The outcome of this straightforward approach, done in the space of an hour or two using human respondents would have generated the type of data shown in Table 2 (ratings of each statement by each group).

The approach presented here takes Mind Genomics into an entirely new direction, one fully directed by the artificial intelligence built into the Idea Coach. What emerges as most remarkable is the depth of information from a few lines of request. The AI builds upon itself, providing information at the basic level, viz., the statements, and then building on that information and nothing else to generate the wealth of information presented. What is even more interesting is that the paper deals with the results of one iteration taking about 15-30 seconds for immediate results, and about 30 minutes wait for the summarizer in the Idea Book. Not reported here are the results of 20 of the iterations, each done in 15-30 seconds, occasionally with a small change to the squib, for example to specify that the analysis is to reflect what would have happened say in 1900 vs 2000, or what would have happened had the user specified two mind-sets, or four or five or even many more mind-sets. That parametric investigation awaits the attention of a graduate student for their thesis work.

References

  1. Carter R (2023) Tulsa school linked to Chinese Communist entity. August 3, 2023 Oklahoma Council of Public Affairs. 2023.
  2. UN Watch (2023) UN Teachers Call To Murder Jews, Reveals New Report
  3. Faria Z (2023) The newest Democratic propaganda in schools: ‘Fake news’ classes. Washington Examiner, November 22. 2023.
  4. Honignh M, Honingh MR, van Thiel S (2020) Are school boards and educational quality related? Results of an international literature review, Educational Review 157-172.
  5. Medina MA, Grim J, Cosby G, Brodnax R (2020) The power of community school councils in urban schools. Peabody Journal of Education 95: 73-89.
  6. Institute for Free Speech (2020) FBI Targets Outspoken Parents, School Boards Silence Them.
  7. Rubin JS, Good RM, Fine M (2020) Parental action and neoliberal education reform: Crafting a research agenda. Journal of Urban Affairs 42: 492-510.
  8. Sampson C, Bertrand M (2022) “This is civil disobedience. I’ll continue.”: The racialization of school board meeting rules. Journal of Education Policy 37: 226-246.
  9. Shuffelton A (2020) What parents know: risk and responsibility in United States education policy and parents’ responses. Comparative Education 56: 365-378.
  10. Luce RD, Tukey JW (1964) Simultaneous conjoint measurement: A new type of fundamental measurement. Journal of Mathematical Psychology 1: 1-27.
  11. Green PE, Krieger AM, Wind Y (2001) Thirty years of conjoint analysis: Reflections and prospects. Interfaces 31(3_supplement), S56-S73.

Evolving the Doctor’s Waiting Room: Applying AI to Visioning the Future, a Cartographic Approach

DOI: 10.31038/IMROJ.2024911

Abstract

SCAS (Socrates as a Service), incorporating ChatGPT 3.5, was instructed to create ten visions for the future waiting room of the doctor, based upon positioning the waiting room as part of the continuum of healthcare, rather than just a room housing people before they are admitted to see the medical professionals. SCAS ‘fleshed out’ each of the 10 visions in paragraph form, and then generated 15 questions about aspects of implementing these visions. In the subsequent iteration, SCAS was given the 15 questions it had previously created, and instructed to provide answers to each question, as well as estimate the difficulty involved in achieving what the answer specified. At the end of the process, about 15 minutes later, the program returns with a detailed Microsoft Excel file, the Idea Book, showing each iteration, and providing additional insights generated by the AI-based ‘Summarizer.’ The process presented here shows the power of AI to help create the future by allowing easy-to-create, quick-to-run queries, and providing detailed answers and additional subsequent analysis. With the turn-around time in seconds, and with a system which is iterative, the user can explore a topic in depth, generating a strong educational experience for any topic that one can imagine. The strength of the approach is the ability to help one think and envision in a way which is absorbing, user-driven, and often filled with surprises.

Introduction

What the future will bring is always a topic of conversation. It becomes especially interesting when the focus is on something relevant to the daily lives of people, and when the evolution may improve the quality of life. This paper is an attempt to envision the doctor’s waiting room as part of a smooth transition from greeting the patient to treating the patient. The strategy uses AI to help envision the future, doing so in a way which requests specificity from AI. Furthermore, the objective is to integrate OpenAI’s freely available AI ChatGPT 3.5, a large language model (LLM), into an easy-to-use system with a limited number of queries, automatically built-in. All the work is done behind the scenes by ChatGPT 3.5 [1]. The objective is to create a system which lets the user focus on the work, not on the effort to code. As a result, the user spends time learning through iterations, the immediate feedback allowing a quick change of query, with the iterations eventually generating the information desired. The notion here is that AI becomes the collaborator in the up-front development, and in some cases a participant who estimates the difficulty of the task [2,3].

The approach used in this paper is called SCAS, an abbreviation for Socrates as a Service. The name comes from the belief that the approach presented here is a coach to creative thinking. Rather than Socrates ‘pulling out’ ideas from the mind of slaves through questioning, the idea is for people to pull out ideas from the mind of AI through questioning. The questions are not meant to be factual, but conceptual. The user is challenged to let Socrates give expansive answers, not constrained ones, while at the same time ensuring that these expansive answers are feasible and produce something tangible. [4] called this approach ‘Homo Silicus.’

Systematizing New Idea Creation

Creating new ideas is a well-accepted business objective. Business always needs to create ‘new’ for the simple reasons that business must keep up with changes, whether the changes be responses to truly new situations and their requirements, or activities to maintain the interest of fickle customers. The world changes, people get tired of what they have, the two of these factors combining to force the creation of the new as a standard part of one’s operations, one’s business.

With all the focus on ‘new,’ it should come as no surprise that there are myriad publications with their pronouncements of how to create the new, hundreds of thousands of experts who are ready to advise about the ‘new’ at a moment’s notice and for an agreed-upon fee, not to mention the multitudinous best practices which dot the horizon of business.

The introduction of AI has changed the world of new product development. With user-friendly technology such as that embedded in Open AI’s ChatGPT 3.5, it has become possible to provide AI with a specification, a request, and let AI return with the suggestions. It is from experience with AI in this format that the study reported here arose. The paper focuses on the application of AI to envision the patient’s waiting room, an integral part of the medical facility, as a room where the healing process begins.

The process presented here grew out of the effort to understand how people respond to the world. The typical process of understanding the mind of a person with respect to something like the patients’ waiting room is to ask questions about the waiting room, to identify the relevant features, and their importance. The typical approach is to use some type of scale and instruct the respondent to rate the importance of different features that the waiting room might feature. It is from this type of scaling that the designer gets a sense of what is important. It is up to the designer to then take the information and create the prototype rooms to be evaluated for acceptance, utility, and so forth. Sometimes the survey is put aside or occurs after a discussion with participants about the new patient’s waiting room. In this case a trained interviewer discusses the nature of the waiting room, either with one or two people in a so-called ‘depth interview’ or convenes a group of people called a ‘focus group’. In both cases the researcher ends up conducting a structured interview in the form of a conversation. The foregoing process is a standard part of most research approaches to understand what is needed in a new product.

One emerging problem embedded deeply in the foregoing conventional process is the failure to deal with the details. Surveys, discussions, and so forth can provide direction, but it is the execution of these ideas which is important. In research this is known as the gap between ‘strategy,’ the big idea, and ‘execution,’ making the particulars a reality and bringing that into the world. The emerging science of Mind Genomics was developed to incorporate the specifics, the executions, into the research process [5]. Rather than instructing the respondent to rate general ideas, hoping that these ideas would end being well executed, the Mind Genomics approach took its cue from nature. The approach was to create small vignettes, combinations of concrete ideas, specific descriptions, instruct respondents to rate these vignettes, and then through statistics (regression, clustering) deconstruct the response to the part-worth contribution of the individual concrete elements, the granular information shown to the respondent . The outcome was the recognition that valuable data could be obtained by focusing on the specifics of a situation, rather than focusing on large, featureless, general ideas. A good strategy was to generalize from the pattern of particulars, easier to do than particularizing from a featureless generality. It was this realization which pushed the focus of Mind Genomics to focus on the concrete, the granular.

It was the pattern of questions and answers, begun with Mind Genomics, which was to evolve to the approach presented here. In its current form, Mind Genomics requests the user to create four questions regarding a topic (see Figure 1, Panel A), and then for each of the four questions create four answers (see Figure 1, Panel B). The process thus creates 16 elements, the four sets, each comprising four answers. It was the ensuing difficulty with having a user, develop four questions which eventuated in introducing AI was used as a coach, called, not surprisingly, the Idea Coach. The user would type background to a topic in the form of an AI prompt, which Mind Genomics calls a ‘squib’ (Figure 1, Panel C). In turn, the Idea Coach would then use AI to develop the four questions. (Figure 1, Panel D). The same approach could be used to create four answers to each question. The process of using AI a system to generate questions for a specific topic, or answers for a specific question soon moved AI to a central role in Mind Genomics.

fig 1

Figure 1: The original process in the set-up of a Mind Genomics study. Panel A shows the request for four questions which ‘tell a story’. Panel B shows one question, with the request to provide four answers. Panel C shows the background to the project and the desired results, the so-called ‘squib’, typed into the Idea Coach. Panel D shows 5 of the 15 questions provided by SCAS operating within Idea Coach.

It soon became apparent that the embedded AI in Mind Genomics was being used far more to create ‘books of knowledge’. The user would create a set of questions to ‘brief’ the AI, and then run the AI several times, occasionally just iterating, but often changing the input slightly and then iterating. The emerging focus was using the embedded AI to provide a range of alternative answers to the same question. Furthermore, the AI had been programmed to provide additional summarization, viz., post-emergent analysis. The system ended up being renamed SCAS, Socrates as a Service, in recognition of this evolution from a system which recommended questions and answers into a system to educate people on a topic, using AI to help people think critically about a topic, imagine alternative realities, and create by typing descriptions of those realities.

Using AI to Drive the Future

The immediate stimulus driving this set of experiments resulted from a fortunate accident. than simply asking a question and getting the SCAS to provide 15 answers, something that was done a dozen times in the set up of a Mind Genomics study, the user this time created a more detailed briefing, by writing down both the relevant input for Idea Coach, but then additional, background information that was usually part of the thinking, but never submitted to the AI in Idea Coach. The AI was ‘briefed’ in a far more detailed way, with thoughts, requests, hypotheses, and so forth, again by accident, but an accident which proved remarkably productive as shown below.

Table 1 show the entire briefing. Table 1 is divided into two parts, shaded and unshaded, respectively. The shaded parts provide modest details, specifically the nature of the room (part of the flow, first room in a sequence of room), followed by a statement of ‘fact’, viz., that there are ten mind-sets. There is no supporting evidence given for the statement about ten mind-sets, however. The user could just have easily specified three mind-sets or 13 mind-sets. The second part of Table 1 shows the general instructions to the AI. These are to focus on the room itself, and afterwards on the reaction of people to this room. Again, Table 1 is far more extensive. We can contrast this extensive brief with the ordinary brief of that time, which would be something like: ‘What are questions to ask about the nature of the patient’s waiting room, if we think of the next decade, starting in 2030?’

Table 1: The briefing given to AI about the waiting room outside the doctor’s office

tab 1

The actual creation of the AI briefing takes a few minutes. Once the AI is provided with the briefing, the AI is invoked through SCAS, the Socrates as a Service procedure, embedded in the Mind Genomics program. Within 10-20 seconds the AI returns with preliminary answers along with an additional set of 15 questions for consideration..

Table 2 presents the 10 visions of the patient’ waiting room, attempting to follow the request to discuss the room itself as an integral part of the visit, and of the continuum from waiting room to examination room. Each of the 10 visions is labelled, followed by a description of the room itself, and then followed by the response of the patient in that room.

Table 2: The 10 visions for the patient’s waiting room as part of the continuum for health and healing. Each vision comprises a name, a description of the room, and then a description of the feelings of people towards that ‘now-evolved’ space.

tab 2

The important thing to keep in mind is that the AI was not given any information at all, other than this was to be a patient’s waiting room but was also going to be part of the spatial continuum, and thus an integral part of the ‘path’ for health and healing.

As noted above, each iteration was accompanied by 15 questions to answer. These questions are based on the topic. The questions emerge automatically. The next step was to copy the 15 questions into a new run of Idea Coach. Table 3 shows the 15 questions (underlined), two answers to each question provided by SCAS and for each question an estimate of the difficulty of achieving that answer (Easy vs Difficult).

Table 3: The 15 questions generated by SCAS when it provided information about the vision, along with two answers to each question, and the estimated difficulty of implementing the answer. The questions were ‘answered’ by a separate run of SCAS, where the questions were inserted as part of the briefing to AI.

tab 3

Summarizing and Expanding the Ideas; Themes and Perspectives

SCAS generates a great deal of information when it creates visions (Table 2) and generates questions (Table 3). One of the benefits of AI is the ability to summarize the information in a succinct way. Table 4 shows two summarizations. The top of Table 4 shows the key ideas. The bottom of Table 4 shows the four themes identified by SCAS, followed by the good (plus), bad (minus) and novel (interesting) aspects of each theme. It is in Table 4 that we begin to see a secondary analysis by AI of the information generated by AI.

Table 4: Key ideas, themes and perspectives

tab 4

Table 5 moves the analysis to who would be interested in these ideas, and who would be opposed to them. Once again we see a deeper secondary analysis of the information provided by AI.

Table 5: Interested versus opposing audience to the topic ideas

tab 5

Driving Towards Innovation

Table 6 shows the final analysis provided by AI, comprising three sets of analyses/questions which drive towards innovation. The first comprises a set of 10 questions about what is missing. This first set is meant to challenge the user. The second comprises a set of 16 alternative viewpoints, contrasting answers to a question. The third focuses on innovations, comprising a set of four general categories or topics, each with several suggestions.

Table 6: Steps toward innovation, comprising ‘what is missing,’ alternative viewpoints, and then categories or topics with several suggestions each.

tab 6(1)

tab 6(2)

tab 6(3)

Discussion and Conclusions

The focus of this paper is to present an approach to solving specific problems, once these problems are specified and provided to AI in a useful manner. The AI approach used here, SCAS, Socrates as a Service, was developed to help critical thinking, and to focus attention on potential answers. Rather than focusing the time on elaborating the question, SCAS builds on the richness of AI, especially in the world of design. The effort shown here revolves around the desire to structure a development effort, or perhaps even a research effort.

As we consider what has been presented here, it should be kept in mind that the work presented here belongs to the world of philosophy of science, specifically the topic of ‘hard to define’ problems [6]. [7] presented the issue which summarizes the thrust of this paper. In their words: “‘The formulation of a problem is often more essential than its solution’….To raise new questions, new possibilities, to regard old problems from a new angle, requires imagination’ Yet, how the creative process unfolds in framing ill-defined problems remains an open question. Indeed, untangling the interrelation between problem framing and the creative process in its lower-level aspects can inform scholars.. Problem framing entails building mental representations that simplify the problem..”

At this point, once the results of the effort have been presented, it may well be productive to contrast what has gone on in this paper versus the standard scientific or brainstorming effort which characterizes current research. Conventional research begins with observations, a hypothesis, and then establishes the validity or the falseness of that hypothesis through one or more experiments. The objective of science is to amass many hypotheses that have been shown to be correct, or more precisely, have not been falsified from experiments. The current research follows a different approach, one which ‘explores’ rather than confirms. The term ‘cartography’ is appropriate here. The approach here is ‘mapping’ the topic, almost as an explorer maps an area that is unknown. Knowledge becomes the accretion of these cartographies, and human advancement may end up through the application of these cartographies, the applications showing up in changes in the worlds of the material and of experience, respectively.

References

  1. Binz M, Schulz E (2023) Using cognitive psychology to understand GPT-3. Proceedings of the National Academy of Sciences 120(6)
  2. Kitadai A, Tsurusaki Y, Fukasawa Y, Nishino N (2023) Toward a novel methodology in economic experiments: Simulation of the Ultimatum Game with large language models. 2023 IEEE International Conference on Big Data 3168-3175.
  3. Gray K, Dillon D, Tandon N, Yuling G (2023) Can AI language models replace human participants? Science & Society. Trends Cogn Sci 27: 597-600. [crossref]
  4. Horton J.J (2023) Models as Simulated Economic Agents: What Can We Learn from Homo Silicus? National Bureau of Economic Research Working Paper 31122.
  5. Moskowitz HR (2012) ‘Mind Genomics’: The experimental, inductive science of the ordinary, and its application to aspects of food and feeding. Physiology & Behavior 606-613. [crossref]
  6. Garbuio M, Lin N (2021) Innovative idea generation in problem finding: Abductive reasoning, cognitive impediments, and the promise of artificial intelligence. Journal of Product Innovation Management 38: 701-725.
  7. Pham CTA, Magistretti S, Dell’Era C (2023) How do you frame ill-defined problems? A study on creative logics in action. Creativity and Innovation Management 32: 493-516.

Synthesis and Biological Evaluation of Chalcone Analogues as HIV Latency Reversing Agents

DOI: 10.31038/JPPR.2024713

Abstract

The primary barrier of eradicating HIV virus is the existence of latent reservoirs. To overcome this problem, it is urgent to identify specific and effective agents that can activate HIV latent reservoirs and bind with effective anti-retroviral therapy to eventually eliminate HIV virus. In previous study, we reported a chalcone analogue called Amt-87 that can significantly reactivate the transcription of latent HIV. However, it is of limited use due to high toxicity. Here, we have synthesized a series of structurally modified analogues of Amt-87 and evaluation for their reactivation of HIV-1 latency revealed one excellent active compound 4k, which can be taken up for further studies.

Introduction

It is more than 30 years passed since HIV was first reported in 1981 [1]. There are many drugs designed by targeting enzymes which are important for replication event during different stages of HIV-1 life cycle, preventing HIV-1 virus replication, therefore decrease the virus in the host blood to an undetectable level [2,3]. However, HAART is unable to completely eliminate the virus due to the existence of latent viral reservoirs, which are formed early after host infection and undetectable by common clinical tests [4], thus the host immune system can be invaded again upon the treatment interruption. HIV latency reservoir in the host CD4 T cell is the main obstacle to cure HIV-1 as reported recent years. Effective curative strategies aiming at eradication of HIV-1 virus are being developed [5-7]. One significant therapy which is called “shock and kill” has been proposed to achieve HIV eradication, there are two steps in this approach, using latency-reversing agents (LRAs) to reactivate the latent proviruses in the “shock” phase and then combining with the HAART to make the reactivated cells be sensitive to host immune system and cytopathogenicity response in the “kill” phase [8,9]. In this strategy, finding drugs to activate HIV latency catches much attention. Currently there are several activators have been proved, for example HMAB, SAHA, prostration JQ1 and so on, but most of these drugs are toxic to host cell and have some side effects [9]. Thus, highly efficient and specific drugs for reactivating HIV latency is important for HIV-1 eradication. Chalconoids, natural phenol compounds, have an array of biological activities including anti-inflammatory, antioxidant, antitumor and antibacterial activities and inhibit angiogenesis in vivo and in vitro [10-14]. Chalcone analogues have attracted a great deal of interest due to their synthetic and biological importance in medicinal chemistry. In our previous study, we reported the synthesis and biological evaluation of a chalcone analogue Amt-87, which can significantly reactivate the transcription of latent HIV proviruses and act synergistically with known LRAs such as prostratin and JQ1 to reverse HIV latency [15]. Unfortunately, Amt-87 is less active and requires high concentrations to reactivate latent HIV. Herein, we describe the optimization and characterization of the structure−activity relationship (SAR) of chalcone scaffold to generate a series of compounds with enhanced HIV latency reactivation activity.

Results

Synthesis of Chalcone Derivatives

Chalcone derivatives 4a-4k were prepared according to a two-step procedure (Scheme 1) previously reported. Condensation of 1-(2-hydroxy-5-methylphenyl)ethanone with 2- or 3-carboxybenzaldehyde in the presence of alkali gave carboxylic acid derivatives 3a and 3b. Treatment of 3a or 3b in CH2Cl2 with various amines in the presence of 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDCI) and N-hydroxybenzotriazole (HOBt) afforded various amides 4a-4k with yields ranged from 30% to 50% (Scheme 1).

scheme 1

Scheme 1: Synthesis of chalcone amide derivatives 4a-4k. Reagents and conditions: (a) NaOH, EtOH, r.t., 24 h. (b) various amines, anhydrous HOBt, EDCI, DCM, 12 h.

Reactivation of latent HIV-1 in J-Lat A2 cells and structure–activity relationship. In order to identify compounds that can efficiently reactivate latent HIV-1, the J-LatA2 latency model was used in a screen that involved flow cytometry. This cell line was generated by infecting Jurkat T cells with viral particles containing an HIV-1 vector expressing Tat and GFP under the control of the viral 5’ LTR, with an IRES (internal ribosome entry site) separating the two open reading frames [15]. All synthesized chalcone compounds were evaluated for their activation of latent HIV-1 in J-Lat A2 cells and Amt-87 was used as the positive control. The results are presented in Table 1. The structure–activity relationship (SAR) was further explored as described below. Among these structurally related chalcone derivatives, we found that 4b, 4d, 4g were more active than Amt-87 in terms of HIV latency-reversing activity. Specifically, 4g showed the most optimal properties in the latent HIV-1 reactivation activity, inducing 14.6 ± 2.1% and 20.5 ± 2.8% GFP production in J-Lat A2 cells at 25 μg/mL and 50 μg/mL, respectively. What’s more, compound 4g has no significant cytotoxicity at a concentration of 50 μg/mL. These observations may demonstrate the potential of chalcone derivatives as LRA leads.

Table 1: Summary of HIV reactivation of Chalconoids in J-Lat cells

tab 1

Levels of HIV-1 activation and cell viability were evaluated by FACS analysis. Data are presented as mean ± SD of at least three independent experiments performed in triplicate.

Discussion

In this study, we synthesized and biologically evaluated chalcone derivatives for their HIV latency-reversing activity using HIV-LTR based cell model. Among these new derivatives, compound 4g effectively induced GFP production in J-Lat A2 cells at 25 and 50 μg/mL, while displaying no significant cytotoxicity at these concentrations. This study provides valuable data for the future development of chalcone as effective LRAs.

Materials and Methods

Chemistry

General procedure for the synthesis of Chalcones [15]. Claisene Schmidt condensation. To a solution of the corresponding aldehyde (1 equiv) and corresponding acetophenone (1 equiv) in EtOH (3 mL for 1 mmol of acetophenone) was added NaOH (5 equiv). The reaction mixture was stirred at room temperature for 24 h and neutralized with 10% HCl solution to form yellow precipitate. The yellow precipitate was filtered and washed with appropriate amount of water. The crude product was purified by chromatography using hexane/EtOAc and recrystallized by MeOH to give the desired compounds.

(E)-2-(3-(2-Hydroxy-5-Methylphenyl)-3-Oxoprop-1-en-1-yl)Benzoic Acid (3a)

Following the general procedure for the Claisen-Schmidt condensation, 1-(2-hydroxy-5-methylphenyl)ethanone 1 (1.1 mmol, 165.2 mg) and 2-carboxybenzaldehyde (1.0 mmol, 150.1 mg) were used to give 3a as a yellow solid. Yield 45.7%. 1H NMR (600 MHz, C5D5N): δ 8.41 (d, J=8. 2 Hz, 2H), 8.19 (d, J=15.5 Hz, 1H) , 8.12 (d, J=17.2 Hz, 1H), 8.07 (d, J=1.0 Hz, 1H), 7.88 (d, J=8.2 Hz, 2H), 7.31 (dd, J=1.8, 8.4 Hz, 1H), 7.1l (d, J=8.4 Hz, 1H), 2.18 (s, 3H). 13C-NMR (150 MHz, C5D5N): δ 193.9, 168.3, 161.6, 143.9, 138.7, 137.7, 137.2, 130.5 (2C), 129.0 (2C), 128.3, 126.4 (2C), 120.5, 118.2, 20.0. ESI-HRMS (-): m/z [M-H]- calcd for C17H13O4, 281.0819, found, 281.0816.

(E)-3-(3-(2-Hydroxy-5-Methylphenyl)-3-Oxoprop-1-en-1-yl)Benzoic Acid (3b)

Following the general procedure for the Claisen-Schmidt condensation, 1-(2-hydroxy-5-methylphenyl)ethanone 1 (1.1 mmol, 165.2 mg) and 3-carboxybenzaldehyde (1.0 mmol, 150.1 mg) were used to give 3b as a yellow solid. Yield 50.5%. 1H NMR (600 MHz, DMSO-d6): δ 12.3 (s, 1H), 8.40 (s, 1H), 8.18 (d, J=7.9 Hz, 1H), 8.08-8.14 (m, 2H), 8.03 (d, J=7.7 Hz, 1H), 7.89 (d, J=15.6 Hz, 1H), 7.62 (t, J=7.7 Hz, 1H), 7.40 (dd, J=1.7, 8.3 Hz, 1H), 6.92 (d, J=8.3 Hz, 1H), 2.33 (s, 3H); 13C NMR (150 MHz, DMSO-d6): δ 193.9, 167.4, 160.3, 144.0, 137.8, 135.4, 133.5, 132.2, 131.8, 131.0, 130.2, 129.7, 128.5, 123.5, 120.8, 118.0, 20.4; ESI-HRMS (-): m/z [M-H]- calcd for C17H13O4, 281.0819, found, 281.0814.

General Procedure for Synthesis of Amide Compounds 1a-1p. A Mixture of 3 (3a or 3b)

(1 equiv), HOBt (1.2 equiv) and EDCI (1.2 equiv) was dissolved in CH2Cl2, and stirred for 30 min. The mixture was then added with appropriate amine (2.0 equiv), and stirred at the room temperature for 12 h. After completion of the reaction, the mixture was concentrated in vacuum to give the crude product. The crude product was purified by column chromatography with hexane/EtOAc, and recrystallized with EtOAc to afford pure products.

(E)-N-(2-(1H-Indol-2-yl)Ethyl)-2-(3-(2-Hydroxy-5-Methylphenyl)-3-Oxoprop-1-en-1-yl)Benzamide (4a)

The title compound 4a was obtained by the reaction of compound 3a with 2-(1H-indol-2-yl)ethan-1-amine following the general procedure. Yellow solid, yield 57.5%, mp 182-183°C. 1H-NMR (600 MHz, CHLOROFORM-d): δ 12.49 (s, 1H), 8.08 (d, J=15.6 Hz, 1H), 7.57-7.59 (m, 1H), 7.52 (d, J=7.9 Hz, 1H), 7.45 (td, J=3.2, 8.9 Hz, 4H), 7.38 (dt, J=1.6, 7.5 Hz, 1H), 7.30-7.35 (m, 2H), 7.26 (dd, J=2.0, 8.4 Hz, 1H), 7.23 (d, J=8.1 Hz, 1H), 7.09 (t, J=7.6 Hz, 1H), 7.06 (d, J=2.2 Hz, 1H), 6.99-7.03 (m, 1H), 6.88 (d, J=8.4 Hz, 1H), 3.80 (d, J=6.2 Hz, 2H), 3.05 (t, J=6.5 Hz, 2H), 2.27 (s, 3H); 13C-NMR (151 MHz, CHLOROFORM-d): 192.6, 167.6, 166.7, 160.5, 141.7, 136.9, 136.6, 132.0, 131.3, 129.9, 129.2, 128.6, 127.8, 127.0, 126.7, 126.4, 121.9, 121.3, 121.2, 118.6, 118.5, 117.6, 117.4, 110.3, 64.6, 39.0, 29.5; HRMS calcd for C27H24N2O3 [M-H]- 423.1714, found 423.1718.

(E)-2-(3-(2-Hydroxy-5-Methylphenyl)-3-Oxoprop-1-en-1-yl)-N-(2-(Thiophen-2-yl)Ethyl)Benzamide (4b)

The title compound 4b was obtained by the reaction of compound 3a with 2-thiopheneethanamine following the general procedure. Yellow solid, yield 57.5%, mp 182-183°C. 1H-NMR (600 MHz, CHLOROFORM-d): δ 12.47 (s, 1 H), 8.08 (d, J=15.41 Hz, 1H), 7.67 (d, J=7.70 Hz, 1H), 7.58 (s, 1H), 7.46 (d, J=15.41 Hz, 1H), 7.37-7.42 (m, 2H), 7.34 (t, J=7.4 Hz, 1H), 7.22-7.25 (m, 1H), 7.04 (d, J=5.0 Hz, 1H), 6.85 (d, J=8.4 Hz, 1H), 6.81-6.83 (m, 1H), 6.79 (d, J=3.1 Hz, 1H), 5.98 (br. s., 1H), 3.68 (q, J=6.4 Hz, 2H), 3.10 (t, J=6.6 Hz, 2H), 2.26 (s, 3H); 13C-NMR (151 MHz, CHLOROFORM-d): 193.5, 168.6, 161.5, 142.6, 141.0, 137.6, 137.6, 133.3, 130.4, 130.2, 129.6, 128.0, 127.7, 127.5, 127.1, 125.6, 124.1, 123.0, 119.6, 118.4, 41.5, 29.7, 20.6; HRMS calcd for C23H21NO3S [M-H]- 390.1169, found 390.1171.

(E)-2-(3-(2-Hydroxy-5-Methylphenyl)-3-Oxoprop-1-en-1-yl)-N-Octylbenzamide (4c)

The title compound 4c was obtained by the reaction of compound 3a with octan-1-amine following the general procedure. Yellow solid, yield 57.5%, mp 182-183°C. 1H-NMR (600 MHz, CHLOROFORM-d): 12.47 (s, 1H), 8.09 (s, 1H), 7.69 (d, J=7.7 Hz, 1H), 7.59-7.61 (m, 1H), 7.50 (d, J=15.4 Hz, 1H), 7.45 (dd, J=1.3, 7.5 Hz, 1H), 7.42 (dt, J=1.2, 7.6 Hz, 1H), 7.36-7.39 (m, 1H), 7.24 (dd, J=2.0, 8.4 Hz, 1H), 7.19 (s, 1H), 6.86 (d, J=8.4 Hz, 1H), 3.38-3.42 (m, 2H), 2.27 (s, 3H), 1.14-1.33 (m, 12H), 0.80 (t, J=7.1 Hz, 3H); 13C-NMR (151 MHz, CHLOROFORM-d): 192.4, 167.6, 160.5, 141.6, 137.0, 136.6, 132.1, 129.2, 129.2, 128.5, 126.9, 126.8, 126.6, 122.0, 118.5, 117.3, 39.3, 30.8, 28.6, 28.2, 28.2, 26.0, 21.6, 19.6, 13.1; HRMS calcd for C25H31NO3 [M-H]- 392.2231, found 392.2233.

(E)-N-Benzyl-2-(3-(2-Hydroxy-5-Methylphenyl)-3-Oxoprop-1-en-1-yl)Benzamide (4d)

The title compound 4d was obtained by the reaction of compound 3a with benzylamine following the general procedure. Yellow solid, yield 57.5%, mp 182-183°C. 1H-NMR (600 MHz, CHLOROFORM-d): 12.48 (s, 1H), 8.11 (d, J=15.6 Hz, 1H), 7.65 (d, J=7.7 Hz, 1H), 7.55 (s, 1H), 7.42-7.45 (m, 2H), 7.39 (t, J=7.4 Hz, 1H), 7.31-7.34 (m, 1H), 7.21-7.25 (m, 3H), 7.16-7.19 (m, 1H), 6.83 (d, J=8.4 Hz, 1H), 6.21 (br. s., 1H), 4.54 (d, J=5.5 Hz, 2H), 2.24 (s, 3H), 1.18 (br. s., 1H); 13C-NMR (151 MHz, CHLOROFORM-d): 193.5, 168.5, 161.5, 142.6, 137.7, 137.6, 137.5, 133.2, 130.4, 130.2, 129.6, 128.9, 128.0, 128.0, 127.8, 127.7, 127.6, 123.0, 119.5, 118.3, 44.3, 20.6; HRMS calcd for C24H21NO3 [M-H]- 370.1449, found 370.1448.

(E)-N-(Tert-Butyl)-2-(3-(2-Hydroxy-5-Methylphenyl)-3-Oxoprop-1-en-1-yl)Benzamide (4e)

The title compound 4e was obtained by the reaction of compound 3a with 2-methylpropan-2-amine following the general procedure. Yellow solid, yield 57.5%, mp 182-183°C. 1H-NMR (600 MHz, CHLOROFORM-d): 12.48 (s, 1H), 8.06 (d, J=15.4 Hz, 1H), 7.64 (d, J=7.5 Hz, 1H), 7.58-7.60 (m, 1H), 7.47 (d, J=15.5 Hz, 1H), 7.32-7.41 (m, 3H), 7.22 (dd, J=2.0, 8.4 Hz, 1H), 6.83 (d, J=8.6 Hz, 1H), 5.63 (br. s., 1H), 2.26 (s, 3H), 1.41 (s, 9H); 13C-NMR (151 MHz, CHLOROFORM-d): 192.5, 167.2, 160.5, 141.7, 137.9, 136.5, 131.7, 129.2, 128.9, 128.5, 126.9, 126.7, 126.6, 121.8, 18.5, 117.3, 51.3, 28.7, 27.8, 19.5, 13.1; HRMS calcd for C21H23NO3 [M-H]- 336.1605, found 336.1607.

(E)-2-(3-(2-Hydroxy-5-Methylphenyl)-3-Oxoprop-1-en-1-yl)-N-Phenethylbenzamide (4f)

The title compound 4f was obtained by the reaction of compound 3a with 2-phenylethan-1-amine following the general procedure. Yellow solid, yield 57.5%, mp 182-183°C. 1H-NMR (600 MHz, CHLOROFORM-d) 12.48 (s, 1H), 8.09 (d, J=15.41 Hz, 1H), 7.68 (d, J=7.70 Hz, 1H), 7.59 (s, 1H), 7.47 (d, J=15.59 Hz, 1H), 7.41 (br. s., 1H), 7.33-7.36 (m, 2H), 7.25 (d, J=8.25 Hz, 1H), 7.18-7.22 (m, 3H), 7.15-7.17 (m, 2H), 7.12 (d, J=7.15 Hz, 1H), 6.87 (d, J=8.44 Hz, 1H), 3.67-3.72 (m, 2H), 2.89 (t, J=6.79 Hz, 2H), 2.27 (s, 3H);13C NMR (151 MHz, CHLOROFORM-d) 192.5, 167.6, 160.5, 141.5, 137.5, 136.7, 136.6, 132.2, 129.3, 129.2, 128.5, 127.7, 127.7, 126.9, 126.7, 126.5, 125.6, 122.0, 118.5, 117.4, 40.1, 34.5, 19.6;HRMS calcd for C25H23NO3 [M-H]- 384.1605, found 384.1603.

(E)-3-(3-(2-Hydroxy-5-Methylphenyl)-3-Oxoprop-1-en-1-yl)-N-(2-Methoxyphenyl)Benzamide (4g)

The title compound 4g was obtained by the reaction of compound 3b with 2-methoxyaniline following the general procedure. Yellow solid, yield 57.5%, mp 182-183°C. 1H-NMR (600 MHz, CHLOROFORM-d): 12.49 (br. s., 1H), 8.49 (br. s., 1H), 8.42 (d, J=7.0 Hz, 1H), 8.12 (br. s., 1H), 7.75-7.83 (m, 2H), 7.68 (d, J=7.3 Hz, 1H), 7.61-7.65 (m, 1H), 7.59 (br. s., 1H), 7.42-7.45 (m, 1H), 7.18-7.22 (m, 1H), 7.00 (dt, J=1.7, 7.8 Hz, 1H), 6.90-6.94 (m, 1H), 6.81-6.84 (m, 2H), 3.83 (s, 3H), 2.25 (s, 3H); 13C-NMR (151 MHz, CHLOROFORM-d): 192.3, 163.4, 160.5, 147.2, 142.8, 136.7, 135.0, 134.3, 130.9, 128.4, 127.5, 127.1, 126.4, 126.1, 123.2, 120.4, 120.1, 118.9, 118.5, 117.3, 109.0, 54.8, 19.5; HRMS calcd for C24H21NO4 [M+Na]+ 410.1363, found 410.1358.

(E)-3-(3-(2-Hydroxy-5-Methylphenyl)-3-Oxoprop-1-en-1-yl)-N-Octylbenzamide (4h)

The title compound 4h was obtained by the reaction of compound 3b with octan-1-amine following the general procedure. Yellow solid, yield 57.5%, mp 182-183°C. 1H-NMR (600 MHz, CHLOROFORM-d): 12.51 (s, 1H), 8.05 (s, 1H), 7.77 (d, J=15.4 Hz, 1H), 7.68 (d, J=7.7 Hz, 1H), 7.61-7.65 (m, 2H), 7.59 (s, 1H), 7.38 (t, J=7.6 Hz, 1H), 7.22 (d, J=8.4 Hz, 1H), 6.83 (d, J=8.4 Hz, 1H), 6.41-6.49 (m, 1H), 3.39 (q, J=6.2 Hz, 2H), 2.26 (s, 3H), 1.24-1.31 (m, 3H), 1.17-1.24 (m, 9H), 0.78-0.81 (m, 3H); 13C-NMR (151 MHz, CHLOROFORM-d): 193.4, 166.9, 161.5, 144.0, 137.7, 135.7, 135.1, 131.7, 129.4, 129.2, 128.6, 128.1, 126.9, 121.3, 119.6, 118.3, 40.3, 31.8, 29.7, 29.3, 29.2, 27.1, 22.6, 20.6, 14.1; HRMS calcd for C25H31NO3 [M+Na]+ 416.2196, found 416.2193.

(E)-3-(3-(2-Hydroxyphenyl)-3-Oxoprop-1-en-1-yl)-N-(2-(Thiophen-2-yl)Ethyl)Benzamide (4i)

The title compound 4i was obtained by the reaction of compound 3b with 3-thiopheneethanamine following the general procedure. Yellow solid, yield 57.5%, mp 182-183°C. 1H-NMR (600 MHz, CHLOROFORM-d): 12.49 (br. s., 1H), 7.99 (br. s., 1H), 7.70-7.76 (m, 1H), 7.62 (t, J=8.5 Hz, 2H), 7.55-7.59 (m, 2H), 7.33-7.37 (m, 1H), 7.21 (dd, J=1.9, 8.3 Hz, 1H), 7.07-7.09 (m, 1H), 6.87 (dd, J=3.3, 5.0 Hz, 1H), 6.81-6.83 (m, 1H), 6.79 (d, J=2.8 Hz, 1H), 6.63 (br. s., 1H), 6.56 (br. s., 1H), 3.64-3.68 (m, 2H), 3.07-3.10 (m, 2H), 2.25 (s, 3H); 13C NMR (151 MHz, CHLOROFORM-d): 193.4, 167.0, 161.5, 143.9, 141.1, 137.8, 135.4, 135.1, 131.9, 129.4, 129.3, 128.7, 128.1, 127.2, 126.8, 125.5, 124.1, 121.3, 119.6, 118.3, 41.5, 29.8, 20.6; HRMS calcd for C23H21NO3S [M+Na]+ 414.1134, found 414.1129.

(E)-3-(3-(2-Hydroxyphenyl)-3-Oxoprop-1-en-1-yl)-N-Phenethylbenzamide (4j)

The title compound 4j was obtained by the reaction of compound 3b with 2-phenylethan-1-amine following the general procedure. Yellow solid, yield 57.5%, mp 182-183°C. 1H-NMR (600 MHz, CHLOROFORM-d): 12.49 (br. s., 1H), 7.96 (s, 1H), 7.69-7.75 (m, 1H), 7.57-7.60 (m, 2H), 7.53-7.57 (m, 2H), 7.31-7.35 (m, 1H), 7.22-7.25 (m, 1H), 7.19-7.22 (m, 2H), 7.14 (d, J=7.3 Hz, 3H), 6.80-6.82 (m, 1H), 6.49 (br. s., 1H), 6.44 (br. s., 1H), 3.64 (q, J=6.8 Hz, 2H), 2.86 (t, J=6.9 Hz, 2H), 2.25 (s, 3H); 13C-NMR (151 MHz, CHLOROFORM-d): 192.3, 165.9, 160.5, 142.9, 137.8, 136.7, 134.4, 134.0, 130.8, 128.4, 128.2, 127.8, 127.7, 127.6, 127.1, 125.7, 125.6, 120.2, 118.5, 117.3, 40.3, 34.6, 19.5; HRMS calcd for C25H23NO3 [M+Na]+ 408.1570, found 408.1565.

(E)-N-(2-(1H-Indol-3-yl)Ethyl)-3-(3-(2-Hydroxy-5-Methylphenyl)-3-Oxoprop-1-en-1-yl)Benzamide (4k)

The title compound 4k was obtained by the reaction of compound 3b with 2-(1H-indol-3-yl)ethan-1-amine following the general procedure. Yellow solid, yield 57.5%, mp 182-183°C. 1H-NMR (600 MHz, CHLOROFORM-d): 12.49 (s, 1H), 8.08 (d, J=15.6 Hz, 1H), 7.57-7.59 (m, 1H), 7.52 (d, J=7.9 Hz, 1H), 7.45 (td, J=3.2, 8.9 Hz, 4H), 7.38 (dt, J=1.6, 7.5 Hz, 1H), 7.30-7.35 (m, 2H), 7.26 (dd, J=2.0, 8.4 Hz, 1H), 7.23(d, J=8.1 Hz, 1H), 7.09 (t, J=7.6 Hz, 1H), 7.06 (d, J=2.2 Hz, 1H), 6.99-7.03 (m, 1H), 6.88 (d, J=8.4 Hz, 1H), 3.80 (d, J=6.2 Hz, 2H), 3.05 (t, J=6.5 Hz, 2H), 2.27 (s, 3H); 13C NMR (151 MHz, CHLOROFORM-d): 192.6, 167.6, 166.7, 160.5, 141.7, 136.9, 136.6, 132.0, 131.3, 129.9, 129.2, 128.6, 127.8, 127.0, 126.7, 126.4, 121.9, 121.3, 121.2, 118.6, 118.5, 117.6, 117.4, 110.3, 64.6, 39.0, 29.5; HRMS calcd for C27H24N2O3 [M+Na]+ 447.1679, found 447.1674.

Biochemistry

Reagents and Cell Lines

All the cell line used in this study were either purchased from American Type Culture Collection (ATCC, Manassas, VA) or described as previously [16].

Flow Cytometry Screening

The Flow cytometry screening assay was performed in Jurkat-based cells line(J-LatA2), containing LTR-Tat-IRES-GFP-LTR [15]. After incubation with Amt-87 as indicated or 0.1% dimeththyl sulfoxide (DMSO) as negative control, J-Lat A2 were harvested and washed twice with 1× phosphate buffered saline (PBS) and analyzed the expression level of GFP by flow cytometer (Epics Altra, BECKMAN COULTER). The changes of GFP expression level can indirectly reflect the transcription level of HIV.

Notes

The authors declare no competing financial interest.

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The Use of Pine Apple Juice in the Elimination of Egg Stickiness in Catfish (Clarias gariepinus), Reared in a Hatchery, Sebeta, Ethiopia

DOI: 10.31038/CST.2021115

Abstract

This study was conducted from May to June 2018 at the National Fishery Hatchery in Ethiopia and aimed to assess the effectiveness of pineapple juice in the elimination of egg stickiness and improved hatchability rate in Clarias gariepinus. There were four different concentrations of pineapple juice tested: 0% (without juice), 1%, 3%, and 5%. The result revealed that egg stickiness was reduced dose-dependently (p < 0.05), with the 5% concentration showing the greatest reduction (59%) compared to the control group (77%). However, it was noted that higher concentrations of pineapple juice have adversely affected egg hatching and fertilization rates. The minimum observed fertilization rate (45%) was observed at the highest concentration tested (5%), while the maximum (77%) was observed at lower concentrations (1%). Similarly, the minimum hatching rate (51.5%) was observed at higher concentrations (5%), with the maximum (71.3%) at 3% pineapple concentrations. Despite these variations, no significant difference (p > 0.05) in the survival rate of juvenile catfish was observed across different concentrations of pineapple juice. This finding highlights the potential of pineapple juice as a practical and accessible approach for improving catfish hatching operations. This study helps to optimize catfish breeding procedures and demonstrates the efficacy of natural treatments in aquaculture practices.

Keyword

Clarias gariepinus, Pineapple juice, Egg stickiness, Hatchability, Fertilization

Introduction

Aquaculture is crucial for meeting the world’s expanding food demand. Sustainable aquaculture output is strongly dependent on good reproduction and efficient hatching methods. Fish seed mass propagation, whether artificial or semi-artificial, is essential to modern fish farming. Due to seasoned breeding habits in most culturable species and the fact that fish must be caught at a time that may not coincide with ideal production conditions, the natural supply of fingerlings is erratic, unstable, and insufficient. Of these species, the African catfish (C. gariepinus) reproduces according to its seasonal breeding behavior at particular periods of the year [1-3].

The African catfish is a valuable tropical aquaculture fish in Africa, Asia, and Europe. This is because the species is suitable for aquaculture due to its fast growth rate, tolerance of high stocking density and poor water quality, acceptance of both artificial and natural feeds, and high market demand, and high production in the pond, 2.5 times higher than tilapia. It is also the second most important commercial fish species in Ethiopia’s capture fishery next to the Nile tilapia. Despite this, the lack of good quality and quantity of seeds has been a major constraint in aquaculture development. Thus, at larvae and fry stages, low survival rates and poor growth performance are the major challenges in catfish production in Ethiopia. This is most probably related to egg stickiness, which needs to be reduced before eggs can be incubated successfully [3-7].

Chemical treatments like tannic acid, urea, and acylase enzyme are frequently used in traditional ways for reducing egg stickiness. However, the extensive use of such chemicals raises concerns about potential detrimental implications on water quality, fish health, and the general ecological balance of the aquaculture system. This procedure also takes a minimum of one hour and a great deal of labor and experience. As a result, this circumstance forces people to look for more eco-friendly alternatives, like pineapple juice [8-12].

In catfish hatcheries, recent studies on the use of pineapple juice as an alternate egg-sticking reduction agent have produced encouraging results. According to preliminary research, bromelain in pineapple juice significantly decreased the stickiness of catfish eggs, offering a healthy and natural alternative. Pineapple is widely available in many tropical nations, including Ethiopia. It includes several proteolytic enzymes, primarily bromalinases, which can breakdown proteins. The skin and hump of pineapple contain tannin chemicals, which belong to the phenol group. Tannins can eliminate egg adhesion because they can bind and precipitate protein compounds due to the presence of functional bond groups that interact strongly with protein molecules, resulting in large and complex cross-links, known as tannin-protein [13-17].

With sustainability becoming a top priority in the aquaculture sector, this study attempts to thoroughly explore green ways to enhance the hatchability of catfish eggs. Therefore, in order to overcome the drawbacks of chemical agents, this study aimed to evaluate pineapple juice’s potential as a natural substance to remove egg stickiness and increase the hatchability rate in catfish. This is in line with the necessity of ethical and ecologically friendly aquaculture methods, guaranteeing the sustainability of Ethiopia’s catfish aquaculture sector.

Materials and Methods

Broodstock Selection and Hormone Administration

The experiment was conducted from May to June 2018 at the National Fisheries and Aquatic Life Research Center, NFALRC, hatchery. Three males and three females of C. gariepinus broodstock, weighing between 958 and 1000 grams, were taken from the NFALRC ponds. Priority was given to individuals presenting an elongated papilla and a slightly swollen reddish urogenital organ for male brooder selection. While, criteria including a well-rounded and soft abdomen, extending anteriorly beyond the pectoral fins to the genital opening were used for female brood stock selection. The broodstocks were acclimatized in separated tanks in hatchery for 24 hours.

The female brooders were artificially stimulated using 0.3 ml of common carp pituitary gland per kilogram of body weight, as described by Olanrewaju et al. The injection was done intramuscularly above the lateral line just below the dorsal fin. The female brooder was given light abdominal pressure twelve hours following the injection, at which point the ovulated eggs were gathered and weighed to the closest 0.01 g in a dry, clean plastic dish. The milt was collected by sacrificing the male broodstock. The milt and eggs were mixed and two drops of saline water were added to activate the milt and stirred gently with a feather to fertilize the eggs. The eggs were left for one minute to provide sufficient contact with the milt [18,19].

Pineapple Juice Preparation and Application

Pineapple juice was prepared by squeezing freshly peeled fruit from a local market in Sebeta, Ethiopia. Three pineapple juice concentrations, including 1% (1 ml of juice to 99 ml of clean water), 3% (3 ml of juice to 97 ml of clean water), and 5% (5 ml of juice to 95 ml of clean water), as well as a control group without pineapple juice, were prepared to investigate dose-dependent effects. In order to represent each concentration of pineapple juice, the fertilized eggs were divided into four equal parts weighing 800 g each. These portions were then divided in triplicate. After pouring the juice solution over the eggs, the mixture was constantly swirled for approximately three minutes using a feather.

Experimental Design and Water Management

For egg hatching, a total of twelve 200-liter plastic bowls were utilized, one for each of the four treatments in triplicate. A mesh was placed above the water surface within the bowl to provide a platform for placing fertilized catfish eggs treated with pineapple juice. The eggs were gently poured over the mesh, ensuring uniform distribution above the water surface. In order to guarantee sufficient oxygenation, a constant water flow was maintained during the trial. The ideal conditions for embryonic development were preserved by controlling the flow rate. In order to facilitate the incubation of catfish eggs, the water temperature was carefully monitored and changed to 24 to 27°C. Water quality indicators such as temperature, pH, and dissolved oxygen levels were carefully monitored at regular intervals throughout the 36-hour experiment. The hatching success criterion was defined as the emergence of larvae from egg capsules. Dead eggs, which are white and transparent, are removed immediately.

Data Collection

Egg adhesiveness was assessed by determining the percentage of eggs that formed clumps. After 15 minutes of incubation, the eggs that had formed clumps within each container were counted. The percentage of adhesion, fertilization, hatching, and survival rate were determined using the standard formula (Eq1 to Eq4) [20,21].

FOR

Statistical Analysis

The collected data on egg stickiness and hatchability rates for each concentration was statistically analyzed using R statistical software, with a one-way ANOVA used determine the significant differences between the treatment and different variables. Pearson’s correlation was used to assess the relationship between pineapple juice concentrations and fertilization and hatchability parameters [22].

Results and Discussion

Physicochemical Parameters

The result of major physicochemical parameters is presented in Table 1. Our study indicated that water temperature (24-27°C), dissolved oxygen (>5 mgL-1), pH (7.12-7.16), and ammonia levels (< 0.1 mgL-1) remained within optimal ranges for effective hatching in catfis. Effective water quality management strategies are critical for providing an optimal environment for catfish embryogenesis [23,24].

Table 1: Physicochemical water quality parameters with mean ± SD

Parameters

Range

Mean ± SD

DO (mgL-1)

5.8 – 6.6

6.2 ± 0.4

pH

7.12 – 7.16

7.1 ± 0.2

Temperature (°C)

24 – 27.5

25 ± 0.3

Ammonia (mgL-1)

0.1 – 0.15

0.1 ± 0.05

Effect of Pineapple Juice Concentrations on Cat Fish Egg Stickiness

Supplementing catfish eggs with pineapple juice resulted in a significant reduction in stickiness (ANOVA, p < 0.05) at varied doses (Figure 1). It was found that all of the treatments reduced the adhesiveness of C. gariepinus eggs to varying degrees. The control group, without pineapple juice, had the highest adhesion value (78.6%) showing the least reduction in egg stickiness. Interestingly, the greatest concentration, 5%, showed the highest reduction in egg adhesion (61%). The 3% pineapple juice concentration resulted in a medium reduction (67.3%). Subsequent post-hoc Tukey’s tests indicated a significant decrease in egg stickiness for the 3% and 5% concentrations compared to the control. This could be explained by the different concentrations of the enzyme bromelain in pineapple juice, which breaks down protein in a sticky fish egg layer. Fish eggs are sticky when they come into touch with water because of their high protein cortical envelope. The more easily the bromelain enzyme can break protein molecules into smaller forms, the more effective it is at eroding the protein layer found in catfish eggs. Our findings corroborate this theory because we found that the amount of egg stickiness decreased more noticeably at greater pineapple juice concentrations [25-28].

FIG 1

Figure 1: Egg adhesion across different pineapple juice concentrations. Letters a and b indicate significant differences between treatments (P < 0.05).

Our result aligns with previous studies indicating the potential of pineapple juice to affect adhesive properties with dose-dependent stickiness reduction in catfish eggs. The egg of C. gariepinus has a sticky layer, which is composed of glycoprotein. Because of its proteolytic action, bromelain may interact with the glycoproteins on the egg surface, changing their sticky characteristics and changing the way the egg clumps.

Furthermore, the slight decrease in stickiness that was seen at lower pineapple juice concentrations (1%), which points to a possible threshold effect wherein enzyme activity might not be enough to cause appreciable changes in sticky characteristics. This suggests a dose-dependent effect of pineapple juice on egg adhesiveness, with lower concentrations potentially leading to greater egg aggregation. Excessive egg clumping may result in restricted water flow around individual eggs and poor oxygenation. Furthermore, it reduces oxygen levels and increases fungal infection, leading to higher mortality rates.

Fertilization and Hatchability Rate

The result of fertilization and hatching rates are presented in Figure 2 with significant variation among treatments (ANOVA, p < 0.05). In comparison to the control group, treatment with 1% concentration resulted in a higher improvement in fertilization rates (77%), which was less than the values reported by Nwerich and Igill-Iboi (88%), Sukendi et al. (89.5%), Egwenomhe et al. (98.6%) in C. gariepinus, and Thal and Ngo (89.5%) in C. carpio. Surprisingly, the 5% concentration, despite reducing egg stickiness significantly, showed a decline in fertilization rates (45%). The highest fertilization value obtained in this study was not related to the smallest adhesion value obtained, which suggests that additional influencing elements as well as the egg adhesion value affect the fertilization value. This is in agreement with the previous studies which reported the highest fertilization rate in the lowest concentrations of pineapple juice solution. This research implies that pineapple juice improves fertilization rates at specific concentrations, while greater concentrations may have a negative impact on sperm-egg interactions [13-16].

FIG 2

Figure 2: The fertilization and hatching rate across treatments. Letters indicate a significant difference between treatments (p < 0.05).

The egg’s adhesiveness makes it more difficult for the embryo to hatch successfully in artificial breeding. This is because the eggs have become agglutinated, covering the micropyles and making it more difficult for sperm to fertilize them. As a result, there are less opportunities for sperm to come into touch with the eggs, which lowers the likelihood that the eggs will be fertilized. Other substances, such as pineapple juice, are used to crack the egg layer, which accelerates fertilization by allowing sperm to make direct contact with the eggs without being impeded by the mucus coating on the egg surface [14-16].

There was significant variation in hatching rate among treatments (p < 0.05). The highest hatching rate was obtained in the 3% pineapple juice concentrations (71.3) and showed a decrease (51.5%) in the 5% concentrations. Similar results were found in the previous studies confirming the dose-dependent trend in egg hatchability of 86.6 % at 1% concentration and decreasing to 25.3 % at 5% concentration. Similarly reported 78.1 % hatching rate at 0.75% pineapple juice concentration and decreased to 75.6% at 1% concentration [18].

This emphasizes the critical role of optimal pineapple juice concentration in influencing not only fertilization but also hatchability in catfish. This shows the effect of pineapple juice in reducing the adhesive layer of catfish eggs. In normal cases, when the eggs come in contact with water for a while, and clump reducing the prospect of the eggs hatching. In general, destocking of eggs using pineapple is quick and simple and requires three minutes only instead of the one hour for conventional desticking techniques. This technique is easy to adopt and advantageous by dramatically reducing the egg handling period.

Survival Rates of Hatched Fish

The survival rates of fish in treatment groups were extensively observed after hatching (Table 2). The larvae survival rate varied from 84% in 1% pineapple concentration to 90% in 3% pineapple concentration, with no significant difference across treatments (p > 0.05). The general survivability of the growing larvae may not be directly impacted by the enzymatic activity of bromelain, which mainly modifies protein structures and sticky characteristics. Similar results were observed in the previous studies [16,17].

Table 2: Survival rate of catfish fries at different pineapple juice concentrations

Concentrations

Number of hatchlings

Survival rate (%)

0% (control)

261

87

1%

259

84

3%

315

90

5%

291

89

The Response of Different Variables to Pineapple Concentrations

The relationship between different parameters and pineapple juice concentrations is indicated using Pearson’s correlation (Figure 3). The pineapple juice concentrations exhibited a strong negative correlation with egg adhesion (ANOVA, p < 0.001, r2=-0.93), indicating that higher concentrations of pineapple juice led to reduced egg adhesiveness. This is associated with the presence of proteolytic enzymes in the pineapple juice that can inhibit the activities of glycoprotein which could have the potential of increasing the sticky layer of fish eggs. Similar reports were found on the negative correlation between pineapple concentrations and fish egg adhesiveness. Although not statistically significant, there was a negative correlation found between the concentrations of pineapple juice and the rates of fertilization and hatching. Similarly, report state a decrease in fertilization and hatching rate with a corresponding increase in the concentration of the pineapple juice. On the other hand, hatching rates and fertilization rates exhibited a positive correlation (ANOVA, p < 0.001, r2=0.87), indicating a comparable response to the concentrations of pineapple [16,17].

FIG 3

Figure 3: Person’s correlation showed the relationship between pineapple juice concentrations and different parameters.

The findings underscore the potential of pineapple juice as a natural agent for manipulating reproductive parameters in aquatic organisms, offering insights into its application in aquaculture practices for improving breeding success and egg quality. However, pineapple juice concentration matters at a certain concentration and might be detrimental over the optimal dosage.

Conclusion and Recommendation

In conclusion, the application of pineapple juice solution has demonstrated efficacy in reducing the stickiness of Clarias gariepinus eggs, offering a practical solution for hatcheries in Ethiopia. Our findings suggest that this method not only effectively mitigates the adhesive properties of the eggs but also presents a user-friendly approach that does not necessitate specialized expertise for implementation. Moreover, while higher concentrations of pineapple juice may have adversely affected egg hatching and fertilization rates, it’s noteworthy that the positive impact on egg-destocking adhesiveness was observed. Therefore, this approach holds promise as a simple and accessible solution for hatchery operations, allowing for improved handling and management of catfish eggs without requiring extensive training or technical skills. To optimize hatchery operations and improve the management of Clarias gariepinus eggs in Ethiopia, the following recommendations are proposed:

  • Incorporate pineapple juice solution application to reduce egg stickiness effectively.
  • Utilize lower concentrations of pineapple juice to maintain optimal hatching and fertilization rates while mitigating egg adhesiveness.

Acknowledgements

We would like to acknowledge the National Fisheries and Aquatic Life Research Center (NFALRC) for financing the research work.

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Verbal Judo and Prospective Crime – How AI + Mind Genomics Can Synthesize Mind Sets for Training

DOI: 10.31038/MGSPE.2024434

Abstract

This paper shows how the emerging technology of AI (large language models), coupled with the world-view of the importance of mind-sets contributed by Mind Genomics can help negotiators to learn how to deal with situations where violence may take place unless the hostage situation is defused. The approach technique uses artificial intelligence embedded in the Mind Genomics platform to specify the situation, and then to hypothesize the thinking and appropriate actions for the negotiator in the presence of different mind-sets. The paper shows how to interact with AI to synthesize these mind-sets, then how to recognize them, what these mind-sets might be thinking, and suggested communications. The paper focuses on educating police negotiators through the use of easy-to-access technology, and inexpensive, rapid learning by iterating the questions asked to AI. Rather than waiting for actual data, the paper uses artificial intelligence based in large language models to provide information that can be adjusted to a specific situation, providing the opportunity to look at the same issue but from different perspectives provided by the nature of the situation and the mind-set of the person who must be disarmed without causing damage.

Keywords

Artificial intelligence, Mind genomics, Mind-set, Synthesize, Training

Introduction

Look at the daily news to see how many times persons or groups turn hostile to police officers or conduct harm to property or people and must be bargained with by police negotiators. The problem is what police and other negotiators should say in specific instances, when they are immersed in the situation. Negotiations, such as family violence and criminal hostage-taking, requires talent, sensitivity to others, and understanding what to say, knowing what works, knowing what doesn’t. After years of experience, expert negotiators learn what to say and its consequences. How do we teach new hires about new situations? Can negotiation opportunities be synthesized? Artificial bodies designed to offer feedback are used in medicine. Is it possible with artificial minds to teach negotiation skills?

There are many different situations where individuals or groups become hostile to police officers, or where these groups become hostile and do hostile acts to property or to people and must be negotiated with by police negotiators. The issue is what to do in particular situations. The knowledge base of negotiating with criminals is not new, spanning centuries, a fixed part of the human comedy. The characters may change, the causes may evolve, society may change what it considered to be “out of bounds” behavior, but the problem remains [1-3]. In the end where the crime or prospective crime is under the “control” of a person, one may have the opportunity to “talk through” that situation with the person, reaching a positive outcome. What does one say, how does one say it, and when? This ability to talk through requires a skill that must be developed, a sensitivity to individuals, a sense of knowing what to say, what will work and what will not work.

Over many years of experience, professional negotiators begin to understand what they can say, what they should say, the repercussions of what they say. The question becomes, how do we transmit this information for new situations to people who are just coming on the job? Is there a way to synthesize negotiation opportunities?

Advances in artificial intelligence based on LLMs (large language models) have made AI more attractive [4,5]. Data analysis using statistics used to be challenging. Once the data were analyzed, the user faced the onerous task of interpreting the results, and then putting that interpretation into text. The result was often tortured prose rather than felicitous and well expressed. Today’s LLMs now enable an almost-human teaching interface, both at the level of the input, and at the level of the output. More important, however, is the emerging reality that the LLMs need not produce factual results, requiring statistical and factual accuracy. We can instruct the LLM to suggest how reality is structured, and then investigate the different nuances within that constructed reality. Everything offered today is assumed to be generalities presented for learning purposes.

The emerging science of Mind Genomics — which has been developing for almost 40 years — helps when it becomes the precursor to LLM simulation. Mind Genomics is empirical, working with combinations of phrases, having people read the combinations, and rate each one. Through statistical modeling (regression and clustering), Mind Genomics discovers the language which “convinces,” which makes the person answer “yes.” The process uncovers mind-sets, groups of individuals who respond differently to the same set of phrases or messages. These mind-sets are uncovered through empirical evaluations with real people [6,7]. Subjects such as law, medicine, as well as the minds of children and adults have been topics of Mind Genomics studies [8-11].

The combination of Mind Genomics thinking about mind-sets and LLMs to provide “content” generates a new world of opportunities to understand the way people think, doing so quickly by simulation. The approach taken in this paper uses LLMs to provide deep, albeit simulated content, for these mind-sets. In a sense, we use Mind Genomics “thinking” to inform and guide the start of the LLM on a topic area, with the result that we generate a system to learn quickly.

The actual system is embedded in the Mind Genomics platform (BimiLeap.com). The access to the LLM is through the embedded Idea Coach. Idea Coach, in turn, uses an entire structure of inquiry called SCAS, Socrates as a Service. With Idea Coach, the user can type in the topic, and a request to the LLM. The SCAS translates this request, giving it to the LLM. The process is straightforward, requiring only an account, and the proper information provided to Idea Coach.

Phase 1 – Setting up the scenario for the LLM

After creating a Bimileap account and studying, the user is instructed to use Idea Coach to enter ideas. The format is a “squib” similar to that shown in Table 1. One has to be certain that the syntax is correct, and that everything is closed-ended. The LLMs are powerful, but in this case not particularly forgiving. After tries, however, with feedback given in 15 seconds, one eventually understands the syntax and what to do for the specific case.

Table 1: The “squib” or query (background, specific request) given to SCAS (Socrates as a Service), the AI embedded in the Mind Genomics platform, BimiLeap.com.

tab 1

Table 1 shows the request, the aforementioned squib. Table 1 supplies very little information to the AI, Socrates as a Service, but requests a fair amount of testable, actionable information that can be validated because of their concrete nature.

There is no underlying “reason” for selecting six mind-sets, other than the desire to see what the system returns. In fact, across the different iterations, seven iterations emerged, not six. They can be discussed and even tested in real-life.

As a point of information, the brief or squib in Table 1 is the toughest aspect of the procedure and sometimes requires many iterations, viz., attempts. It takes the large language model about 15 seconds per iteration. An inexperienced user might require 20 iterations to get the “syntax” of the request “just right.” Those 20 iterations might require 5-10 minutes.

The artificial intelligence SCAS generates seven mind-sets, shown in Tables 2A-2G, one more mind-set than was specified in Table 1. This over-delivery, as well as corresponding under-delivery, often happens because the mind-sets are developed in separate iterations. Generally, each iteration produces one or two mind-sets. The user ends up requesting more iterations to complete the full number. The under-delivery of one, two, occasionally three, mind-sets in an iteration ends up being not problematic because, as noted above, each iteration requires about 10-15 seconds. The speed and ease to iterate often ends up with some mind-sets repeated in different iterations, and the happy coincidence of more mind-sets than were planned for. Finally, when a mind-set repeats in several iterations, the language surrounding the mind-set may change, and some of the finer points may change from iteration to iteration. Most of the “knowledge” will be the same, but some may be fresh ideas across iterations.

Table 2A: Results for the MACHO Mind-Set

tab 2A

Table 2B: Results for the RADICALIZED Mind-Set

tab 2B

Table 2C: Results for the MENTALLY ILL Mind-Set

tab 2C

Table 2D: Results for the EXTREMISTS Mind-Set

tab 2D

Table 2E: Results for the ANGRY INDIVIDUALS Mind-Set

tab 2E

Table 2F: Results for the CRIMINAL Mind-Set

tab 2F

Table 2G: Results for the DESPERATE INDIVIDUALS Mind-Set

tab 2G

From Tables 2A-2G, it becomes apparent that there is an education to be had. Whether any of these results represent actual mind-sets or not, whether these are the slogans or not, the results are interesting and educational. One even gets a sense of the effectiveness of the rating by artificial intelligence, which is fascinating in and of itself. We might even have put in things like, provide slogans that are not effective, and we could do that for each of these as well. In the interest of space and brevity, we have limited our exploration of the mind-set.

Deeper Analyses through SCAS

Early empirical investigations in Mind Genomics in the late 1990s and onward revealed these mind-sets in topic after topic, study after study. It was the task of the user to understand these mind-sets. Fortunately, the mind-sets were clearly demarcated, and easy to differentiate and to discuss.

In order to discover patterns, SCAS in the BimiLeap program has been set up with a set of fixed analyses in order to extract more information from each iteration. Table 3 shows a summary table about what was learned. The results were analyzed in eight ways, such as key concepts, topics, views, interested audiences, opposing audiences, and three stages toward innovation (alternate viewpoints, what is lacking, and potential innovations). For this paper, this deeper AI analysis was reduced to one summary table.

Table 3: Summarized “deeper analysis” of the results, combining the results from all seven mind-sets, although ordinarily done on a mind-set basis.

tab 3(1)

tab 3(2)

The actual deeper analysis does not occur at the time that the user goes through the iterations. Rather, for each iteration, the material is stored in an Excel workbook as a separate worksheet. Only afterwards, when the study is closed, does the second level of analysis take place. This deeper analysis is done separately for each worksheet, going through all eight steps, returning with recommendations, analyses, themes, and so forth. The seven deeper analyses were put into the “Excel Idea Book.” The Idea Book was returned by e-mail approximately 15 minutes after the project was closed.

It is important to keep in mind that despite the “hand-craft” work to combine information from seven deeper analyses, one per mind-set, the actual sentences and information shown in Table 3 are taken directly from the AI-generated output. Thus, the reality is that we have AI providing second level, deeper analysis of AI-generated ideas, those ideas originally emerging from a simple squib and a paragraph of very little detailed information, viz., Table 1.

Discussion and Conclusions

Artificial intelligence-generated results are only now becoming of interest to scientists in the world of behavior, such as psychologists. It is only now that there is a focus on the nature of ideas generated by AI. The reason may be the increasing use of AI to act as an aid-to-thought, perhaps a “technical aid to creative thought” in the words of the late Harvard professor of computer science, Anthony Gervin Oettinger [12].

In the words of the late Harvard professor may appear off-putting for a scientific publication but they should not be. We are not offering factual knowledge, but frameworks in which one may incorporate certain bits of information to obtain insight. We are not interested in factual information that can be obtained by digging into the data, such as how do the mind-sets distribute in the population, or really anything better understood empirically. This whole text has been a teaching tool to comprehend a possibly extreme situation in an hour or two. The approach presented here empowers novices and professionals alike to describe a scenario and understand its aspects, ranging from attitudes, behaviors, motives, public reactions, and far more.

Much more should be said about this realistic approach. Pragmatism will succeed. In fact, the late psychologist George Miller says that most of one’s knowledge gets “chunked,” with just the general structure maintained [13]. We might consider this approach to be a “cartography,” a mapping of the relevant features of a topic. As a cartographer explores an area, looking at its geographies, lay of the land, and flora and fauna, the professional might explore the mind of a criminal for the best way to communicate.

In the end, the world-view espoused by this paper is pragmatics. The age of enhanced learning is coming. This paper may provide in a short time a new approach, a new way of extracting insights, of synthesizing the real world. The approach demonstrated here emerges not so much by slow learning from books and the formation of concepts, but rather human thinking augmented by the “creative powers” embedded in artificial intelligence, ready to be released through the appropriate prompts. With the power of AI embedded in accessible LLMs, people can now ask more focused questions using a simple set of queries, the power of easy use through SCAS. The final output is made user-friendly, the outcome of the AI efforts returned in the form of easy-to-read material.

In the end, the goal of this project is to suggest ways to think about the topic of communicating in a situation which is potentially dangerous. To reiterate the caveat, we’re not looking for an accurate description of each mind-set, but rather interested in providing a general framework. It would be interesting to see whether or not the untutored person, inexperienced in criminology and verbal negotiations with criminals, would use this information, or perhaps even just specific parts of the information. Which parts are useful? Which parts seem useful, but are really irrelevant to practice? The approach is well worth the try, simply because the format here presented by Socrates as a Service, SCAS, using LLMs, generates the key information easily with virtually instant analyses of iteration after iteration, each iteration returned in 15 seconds, with a deeper analysis an hour later returned by email, and done for each iteration.

Acknowledgement

The authors wish to thank Vanessa Marie B. Arcenas for her assistance in preparing this manuscript.

Abbreviations

AI: Artificial Intelligence; LLM: Large Language Model; SCAS: Socrates as a Service

Competing Interests

The authors have no conflict of interest to disclose.

References

  1. Thomson JB (1870) The psychology of criminals. Journal of Mental Science 16(75): 321-350.
  2. Abrahamsen D (1944) Crime and the human mind. Columbia University Press.
  3. Samenow S (2014) Inside the Criminal Mind (Newly Revised Edition). Crown.
  4. Kasneci E, Seßler K, Küchemann S, Bannert M, et al. (2023) ChatGPT for good? On opportunities and challenges of large language models for education. Learning and Individual Differences 103: 102274.
  5. Chang Y, Wang X, Wang J, Wu Y, et al. (2023) A survey on evaluation of large language models. ACM Transactions on Intelligent Systems and Technology.
  6. Sen A and Srivastava M (2012) Regression analysis: theory, methods, and applications. Springer Science & Business Media.
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  8. Moskowitz HR, Wren J and Papajorgji P (2020) Mind genomics and the law. LAP LAMBERT Academic Publishing.
  9. Gabay G and Moskowitz HR (2019) “Are We There Yet?” Mind-Genomics and Data-Driven Personalized Health Plans. The Cross-Disciplinary Perspectives of Management: Challenges and Opportunities, 7-28.
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  11. Mendoza C, Mendoza C, Rappaport S, Deitel Y, et al. (2023) Empowering Young Students to Become Researchers: Thinking of Today’s Gasoline Prices. Mind Genomics Studies in Psychology and Experience Volume 2(2): 1-14.
  12. Bossert WH and Oettinger AG (1973) The Integration of Course Content, Technology and Institutional Setting. A Three Year Report, 31 May 1973. Project TACT, Technological Aids to Creative Thought.
  13. Saaty T (2016) Seven is the magic number in nature. Proceedings of the American Philosophical Society 160(4): 335-360.

What Israel Will Have Done to Help Gaza in the Next 30 Days – Strategic Envisioning Using AI with Mind Genomics Thinking to Look at the Future as if it were Describing the Past

DOI: 10.31038/MGSPE.2024433

Abstract

This paper presents a continuation of the issue of Gaza and what’s next to rebuild Gaza after the debacle which has happened. The paper starts off with the issue of how to help Gaza become the Singapore of the Middle East. The paper continues by asking Artificial Intelligence to provide it with questions, provide it with a general summary, then provide it with questions, and then answer those questions. The result suggests that Artificial Intelligence can act as an aid to thinking and to springboard creative analysis and ideas for the future. The notion of having Artificial Intelligence assume that what is going to be done has already been done allows us to ask questions such as the specifics of what was done. In this respect, positioning Artificial Intelligence as a looking back of that which has not happened yet provides a new level of specificity to help the decision maker.

Artificial Intelligence as a Coach

The objective of this paper is to show what might happen when artificial intelligence is provided with a scenario and asked to specify what would happen, as well as what might be the reactions. In this respect, AI can become a colleague and a trusted advisor of a person who has to make decisions. By using different prompts for different aspects of the situation, it’s quite possible in a matter of an hour or two to get a sense of the different ramifications of a situation, what to do to ‘repair,’ and how people might react. We’re not saying of course that this is correct, but we’re simply saying that this is in the category of a best guess by AI. And if that is accepted, then we have a tool now to help understand policy. Furthermore, AI offers superior predictions over experts due to its ability to process vast data at a faster pace. AI can provide objective insights, identify unusual patterns, and mitigate human biases, resulting in more accurate and reliable predictions for future events [1-3].

The strategy used here is letting AI forecast the future by asking it to report on ‘what occurred’ in the future. By believing that artificial intelligence is looking back from the future, policymakers might acquire a unique perspective on the prospective implications of their actions and change their plans appropriately [4-6]. Predicting the future by asking artificial intelligence to describe it as the past provides a unique perspective that can uncover hidden patterns and trends. By modeling the future after the past, AI algorithms can identify connections and relationships that may not be immediately apparent to human experts. This approach can also help to eliminate bias and preconceived notions that experts may bring to the table, allowing for a more objective analysis of potential scenarios. AI’s ability to process vast amounts of data and make accurate predictions based on historical patterns makes it a valuable tool for forecasting future events.

A continuing issue in the adoption of artificial intelligence to help decision-making is the belief or the aversion to mechanical methods for creative thinking. Whenever artificial intelligence is brought up, almost always there are people who talk about the fact that artificial intelligence cannot create anything new. To them, artificial intelligence is not really new thinking, but simply going through lots of data and looking for patterns. And in fact, that is quite correct, but not relevant. To the degree that artificial intelligence can present us with ordinary, typical types of scenes, questions, and even synthesize the responses of Gazans is itself remarkable and should be used. If artificial intelligence were simply doing this randomly, we might not be able to interpret the data. But the data, the language, the meanings of that which we are reading seem to be real. All things considered, it is probably productive for society to use artificial intelligence as a coach, to suggest ideas, to be springboards to thinking. In other words, to be a coach, a consultant. Artificial intelligence need not provide the answer, as much as it gives us a sense of the alternative ideas from which to choose.

Edward Bellamy, Visioning the Future, and Its Application to Today’s Gaza

Edward Bellamy wrote about the future through Looking Backward by creating a utopian society set in the year 2000, where all resources are shared equally, work is replaced by leisure, and everyone lives in harmony. Bellamy’s style was descriptive and detailed, painting a vivid picture of this ideal society. But more than that. Bellamy’s style suggests the possibility of predicting the future but positioning it as a historical exercise of ‘looking backward’ at that which has not happened [7]. The style of ‘looking back’, attributed to Edward Bellamy, is quite similar to what we are doing here by analyzing a month of Israel trying to transform Gaza into the Singapore of the Middle East. Bellamy’s approach involved reflecting on past events and envisioning potential future scenarios, which is exactly what we are doing as we look back on Israel’s efforts and speculate on the outcome of their actions in Gaza. By examining this one month of work, we are essentially anticipating the potential consequences and impact it may have on the region, much like Bellamy did in his literary works.

One similarity between the two is the concept of idealistic visions for the future. Bellamy’s writings often portrayed a utopian society, while Israel’s goal of turning Gaza into a thriving economic hub reminiscent of Singapore also embodies a vision for a better future. Both involve the imagining of a better world based on certain actions and decisions taken in the present. However, a key difference lies in the context and the means by which these visions are pursued – Bellamy’s works were fictional narratives, whereas Israel’s efforts in Gaza are very much real and come with their own set of challenges and complexities. The act of looking back to a month of work yet to come in Today’s Israel hearkens back to Bellamy’s style as it requires a blend of reflection on past actions and anticipation of future outcomes. By analyzing the progress and developments in Israel’s project to transform Gaza, we are essentially engaging in a form of speculative thinking that mirrors Bellamy’s approach in envisioning alternative societal structures. Both involve a form of projection into the future based on current events and decisions, highlighting the interconnectedness of past, present, and future in shaping our understanding of the world around us.

Visioning the Future of a Gaza Becoming a New Singapore

In a previous paper we looked at what Israel might do to help Gaza become a Singapore [8]. Singapore of course is a remarkably successful city-nation in Asia, carved out of Malaysia. Singapore was not always well-off, Singapore was once poor, it was subject to the Japanese occupation and the damage that the Japanese did to Singapore. With a wise government, Singapore began to modernize, until today it’s held up as one of the most successful countries or really city-states in the world. With that in mind, we wanted to look at what would happen if in fact Israel had unilaterally begun work on creating or recreating Gaza as a Singapore of the Middle East. On our first work, we looked at what it should do. In this work, we are assuming that Gaza is now, we are assuming now, again, stop. In this work, we are now assuming that during the month of June, Israel unilaterally took action to do non-harmful reconstruction and restructuring of Gaza to begin its path to become Singapore. It is now August, or it is now July, and the question is, what can we report, and what do the Gazans say? The strategy here is to envision the future, not in general terms, but in specific terms, and see whether it would be possible, using artificial intelligence, to get a sense of what would be the things that one would be most proud of, and therefore this paper. The approach follows the use of Mind Genomics embedded in the platform BimiLeap.com. The AI in BimiLeap is SCAS, Socrates as a Service, based in part on ChatGPT. With SCAS, we are able to phrase a request, and many times with the proper phrasing, we’re able to get at a series of answers appropriate to the question. The objective here was to figure out what would be reported if, after the fact, people were to know that Israel did this. What exactly would have happened, and what would have been the responses of Gazans who were asked to comment on the results? Keep in mind that the Artificial Intelligence, SCAS, was never told precisely what happened, but only that which Israel was doing was unilaterally able to do.

What AI Produces When Asked to ‘Look Backward’

Table 1 shows the request to AI about what Israel did. The assumption here is that we are reporting after the fact, and we want a more or less factual report.

Table 1: Instructions to the AI (SCAS) to imagine looking background a day after Israel unilaterally began to recreate Gaza as a Singapore of the Middle East.

tab 1

Note: We requested six paragraphs, but we may not get them. One could request from SCAS a certain number of paragraphs and a certain number of sentences but that will not always be delivered. It’s a matter of repeating the questions iteration after iteration. Each iteration takes about 15 seconds. At some point, the artificial intelligence returns with what is desired.

Table 2 the result from one iteration which satisfied the request in Table 1. The important thing to look at is the fact that artificial intelligence can return with a variety of reports of what it thinks Israel did, and these in turn can be specific suggestions about what might be the obvious things to do in the future. Of course, we have to take into account the fact that this is the point of view of artificial intelligence and not necessarily representing the reality what’s possible, what’s straightforward to do. Nonetheless, by using artificial intelligence, it becomes much more possible to get a sense of what the accomplishments will look like. It is straightforward to run tens or iterations on the platform, changing the instructions to the AI until the appropriate type of information emerges. The platform, BimiLeap.com, was constructed to make the iterations sufficiently rapid (about 15 seconds per iteration), allowing the user to satisfy the objective simply through trial and error.

Table 2: The results from one iteration (of several) which produced answers from AI in the format presented in Table 1. The was generated by SCAS (Socrates as a Service).

tab 2

Continuing this approach, Table 3 shows hypothetical interviews and points of view of random Palestinians who are assumed to have seen what was going on and are asked to comment. Not all the comments are positive. There is no request on the part of the artificial intelligence, no prompt at all, to be positive but just to say what happened based upon these things. One could of course change the nature of the prompts, put in various types of information about what happened and see the results in terms of the phrasing and tonality of the ‘synthesized interview comments.’ Artificial intelligence now serves up new ‘information’, a synthesized retrospective of something that has not yet happened, among a population that will be the best ones to give the content to that respective.

Table 3: Background to the interview, request to AI, and 15 synthesized reactions to having experienced Israel’s effort

tab 3

Our final analysis looks at specific things that were done, asking for the reaction of Palestinians to those, by a quote, and then creating three slogans. It is this kind of specificity which allows artificial intelligence to become more of an aid in decision making. Table 4 presents the request to SCAS and the AI synthesis of ‘what happened.’

Table 4: Twelve questions about what was done, and for each question, respectively, the answer to that question, opinion of a local Gazan, and three slogans emblemizing the effort. All the text was synthesize by SCAS, and slightly edited for clarity.

tab 4(1)

tab 4(2)

Discussion and Conclusions

Artificial intelligence analyzing the hypothetical scenarios regarding what ‘Israel did in June 2024 unilaterally to help Gaza evolve into the Singapore of the Middle East’ can reveal surprising insights into potential strategies for economic development and peace-building in the region. By examining Israel’s actions through the lens of AI, we may uncover innovative approaches and solutions that traditional experts may not have considered. AI can also identify potential pitfalls and challenges that Israel may face in its efforts to transform Gaza into a prosperous and thriving area. This analysis can inform policymakers and stakeholders about the possible outcomes of different decisions and help to guide future actions.

Using artificial intelligence to synthesize comments and interviews about the development of Gaza into the Singapore of the Middle East can offer a comprehensive and objective overview of the public sentiment. AI can analyze a large volume of data quickly and identify common themes or concerns among the population. However, there are risks of bias or misinterpretation in AI-generated content because AI may not fully grasp the nuances of human emotions and experiences. Ultimately, the synthesized comments can provide valuable insights into the diverse perspectives and reactions towards the proposed transformation of Gaza.

Creating slogans to symbolize ideas helps to distill complex emotions and concepts into a simple and memorable phrase. These slogans can serve as a rallying cry or a unifying message for a community. Witness, for example, the power of slogans like “Free Palestine” and “End the Occupation” which reflect the deep-seated resentment and anger towards Israel. Positive slogans can be developed for Israel’s unilateral efforts to transform Gaza into a Singapore of the Middle East.

Artificial intelligence to shape a future by simulating a ‘looking back’ perspective can help countries anticipate and prepare for potential challenges and opportunities. By analyzing possible future scenarios, policymakers can develop proactive strategies to address emerging issues before they escalate, minimizing the impact on the country’s stability and prosperity. This forward-thinking approach enables countries make informed decisions which align with their long-term goals. By harnessing the power of artificial intelligence in the mode of ‘Looking Backwards’ there is the definite potential of better navigating the complex seas of geopolitics, where storms are the rule, and calm the blessed exception.

References

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  7. Levi AW (1945) Edward Bellamy: Utopian. Ethics 55: 131-144.
  8. Moskowitz HR, Rappaport SD, Wingert S, Moskowitz D, Braun M (2024) Gaza as a Middle East Singapore – Enhanced Visioning of Opportunities Suggested by AI.

Gaza as a Middle East Singapore – Enhanced Visioning of Opportunities Suggested by AI (Socrates as a Service)

DOI: 10.31038/MGSPE.2024423

Abstract

The project objective was to explore the opportunity of Gaza as a new Singapore, using AI as th source of s suggestions to spark discussion and specify next steps. The results shows the ease and directness of using AI as a ‘expert’ when the materials presented here were developed through the Mind Genomics platform BimiLeap.com and SCAS (Socrates as a Service). The results show the types of ideas developed, slogans to summarize those ideas, AI-developed scales to profile the ideas on a variety of dimensions, and then five ideas expanded in depth. The paper finishes with an analysis of types of positive versus negative responses to the specific solutions recommended, allowing the user to prepare for next steps, both to secure support from interested parties, and to defend against ‘nay-sayers’.

Introduction

Europe had been devastated by Germany’s World War II invasion. The end of World War II left Germany in ruins. The Allies had deported many Germans, leveled Dresden, destroyed the German economy, and almost destroyed the nation. From such wreckage emerged a more dynamic Germany with democratic values and a well-balanced society. World War II ended 80 years ago, yet the effects are being felt today. The Israel-Hamas battle raises the issue of whether Gaza can be recreated like Germany, or perhaps more appropriately Singapore Can Gaza become Middle East Singapore? This article explores what types of suggestions might work for Gaza to become another Singapore, with Singapore used here as a metaphor.

Businesses have already used AI to solve problem [1,2]. The idea of using AI as an advisor to help with the ‘social good’ is alo not new [3-5]. What is new is the wide availability of AI tools, such as Chat GPT and other larger language models [6]. ChatGPT are instructed to provide replies to issues of social importance, specifically how to re-create Gaza as another Singapore. As we shall see, the nature of a problem’s interaction with AI also indicates its solvability, the acceptance by various parties and the estimated years to completion

The Process

First, we prompt SCAS, our AI system, to answer a basic question. The prompt appears in Table 1. The SCAS program is instructed to ask a question, respond in depth, surprise the audience, and end with a slogan. After that, SCAS was instructed to evaluated the suggestion rate its response on nine dimensions, eight of which were zero to 100, and the ninth was the length of years it would take this program or idea to succeed.

Table 1: The request given to the AI (SCAS, Socrates as a Service)

tab 1

The Mind Genomics platform on which this project was run allows the user to type in the request and press the simple button and within 15 seconds the set of answers appears. Although the request is made for 10 different solutions, usually the program returns with far fewer. To get more ideas, we simply ran the program for several iterations, meaning that we just simply pressed the button and ran the study once again. Each time the button was pressed by the user, the program returned anew with ideas, with slogans and with evaluations. Table 2 shows 37 suggestions. emerging from nine iterations, the total time taking about 10 minutes. The importance of many iterations is the AI program does all the ‘thinking,’ all the ‘heavy lifting’.

Table 2: The suggestions emerging from eight iterations of SCAS, put into a format which allows these suggestions to be compared to each other.

tab 2(1)

tab 2(2)

tab 2(3)

tab 2(4)

tab 2(5)

tab 2(6)

Table 2 is sorted by the nature of the solution, the categories for the sorting provided by the user. Each iteration ends up generating a variety of different types of suggestions, viz., some appropriate for ‘ecology’, others for ‘energy’, other for ‘governance’ and so forth. Each iteration came up with an assortment of different suggestions. Furthermore, across the many iterations, even the ‘look’ of the output change. Some outputs comprised detailed paragraphs, other outputs comprised short paragraphs. Looking at the physical format gave a sense that the machine seemed to be operated by a person whose attention to details was oscillating from iteration to iteration. Nonetheless, the AI did generate meaningful questions, seemingly meaningful answers to those questions, and assigned the ratings in a way that a person might.

The table is sorted by the types of suggestions. Thus the same topic (e.g., ecology) may come up in different iterations, and with different content. The AI program does not make any differentiation, but rather seems to behave in a way that we would call ‘does whatever comes into its mind.. It can be seen that by doing this 10, 20, 30 times and having two or three or four suggestions for each, the user can create a large number of alternative solutions for consideration. Some of these will be, of course, duplicate. Many will not. A number will be different responses, different points of view, different things to do about the same problem, such as economy.

Expanding the Ideas

The next was to selected five of the 37 ideas, and for each of these five ideas instructed AI (SCAS) to ‘flesh out’ the idea with exactly eight steps. Table 3 shows the instructions. Tables 4-7 show the four ideas, each with the eight steps (left to SCAS to determine). At the bottom of each table are ‘ideas for innovation’ provided by SCAS when it summarizes the data at the end of the study. The Mind Genomics platform ‘summarizes’ each iteration. One of the summaries is the ideas for innovation. These appear at the bottom section of each of the five sections, after the presentation of the eight steps.

Table 3: The prompts to SCAS to provide deeper information about the suggestion previously offered in an iteration

tab 3

Table 4: The eight steps to help Gaza become a tourism hotspot like Singapore

tab 4

Table 5: The eight steps to make Gaza ensure inclusive and sustainable growth for all its residents

tab 5

Table 6: The eight steps to help Gaza improve its economy and living standards

tab 6

Table 7: The eight steps to help Gaza promote entrepreneurship and small business development

tab 7

The Nature of the Audiences

Our final analysis is done by the AI, the SCAS program in the background after the studies have been complete. The final analysis gives us a sense of who the interested audiences might be for these suggestions and where we might find opposition. Again, this material is provided by the AI itself and the human prodding. Table 8 shows these two types of audiences, those interested versus those opposed, respectively.

Table 8: Comparing interested vs opposing audiences

tab 8

Relations Among the ‘Ratings’

The 37 different suggestions for many topic areas provides us with an interesting set of ratings assigned by the AI. One question which emerges is whether these ratings actually mean anything. Some ratings are high, some ratings are low. There appears to be differentiation across the different rating scales and within a rating scale across the different suggestions developed by AI. That is, across the 37 different suggestions, each rating scale shows variability. The question is whether that is random variability, which makes no sense, or whether that is meaningful variation, the meaning of which we may not necessarily know. It’s important to keep in mind that each set of ratings was generated entirely independently, so there is no way for the AI to try to be consistent. Rather, the AI is simply instructed to assign a rating. Table 8 shows the statistics for the nine scales. The top part shows the three decriptive statistics, range, arithmetic mean, and standard error of the meant. Keeping in mind that these ratings were assigned totally independently for each of the 37 proposed solutions (Table 2), it is surprising that there is such variability.

The second analysis shows something even more remarkable. A principal components factor analysis [7] enables the reduction of the nine scales to a limited set of statistically independent ‘factors’. Each original scale correlates to some degree with these newly created independent factors. Two factors emerged. The loadings of the original nine scales suggest that Factor 1 are the eight scale of performance as well as novelty, whereas Factor 2 is years to complete. The clear structure generated across independent ratings by AI of 37 suggestions is simply very clear, totally unexpected, and at some level quite remarkable. At the very least, one might say that there is hard-to-explain consistency (Table 9).

Table 9: Three statistics for the nine scales across 37 suggested solutions

tab 9

Discussion and Conclusions

This project was undertaken in a period of a few days. The objective was to determine whether AI could provide meaningful suggestions for compromises and for next steps, essentially to build a Singapore from Gaza. Whether in fact these suggestions will actually find use or not is not the purpose. Rather the challenge is to see whether artificial intelligence can become a partner in solving social problems where the mind of the person is what is important. We see from the program that we used, BimiLeap.com and its embedded AI, SCAS, Socrates as a Service, that AI can easily create suggestions, and follow up these suggestions with suggested steps, as well as ideas for innovation.

These suggestions might well have come from an expert with knowledge of the situation, but in what time period, at what cost, and with what flexibility? All too often we find that the ideation process is long and tortuous Our objective was not to repeat what an expert would do, but rather see whether we could frame a problem, Gaza as a new Singapore, and create a variety of suggestions to spark discussion and next steps, all in a matter of a few hour.

The potential of using artificial intelligence to help spark ideas is only in its infancy. There’s a good likelihood that over the years as AI becomes quote smarter and the language models become better, suggestions provided by AI will be far more novel, far more interesting. Some of the suggestions are interesting, although many suggestions are variations on the ‘pedestrian’. That reality not discouraging but rather encouraging because we have only just begun.

There’s a clear and obvious result here that with the right questioning, AI can become a colleague spurring on creative thoughts. In the vision of the late Anthony Gervin Oettinger of Harvard University, propounded 60 years ago, we have the beginnings of what he called T-A-C-T, Technical Aids to Creative Thought [8]. Oettinger was talking about the early machines like the EDSAC and programming the EDSAC to go shopping [9,10]. We can only imagine what happens when the capability shown in this paper falls into the hands of young students around the world who can then become experts in an area in a matter of days or so. Perhaps solving problems, creative thinking, and even creating a better world will become fun rather than just a tantalizing dream from which one reluctantly must awake.

References

  1. Kleinberg J, Ludwig J, Mullainathan S (2016) A guide to solving social problems with machine learning. In: Harvard Business Review.
  2. Marr B (2019) Artificial Intelligence in Practice: How 50 Successful Companies Used AI and Machine Learning To Solve Problems. John Wiley & Sons.
  3. Aradhana R, Rajagopal A, Nirmala V, Jebaduri IJ (2024) Innovating AI for humanitarian action in emergencies. Submission to: AAAI 2024 Workshop ASEA.
  4. Floridi L, Cowls J, King TC, Taddeo M (2021) How to design AI for social good: Seven essential factors. Ethics, Governance, and Policies in Artificial Intelligence, Sci Eng Ethics 125-151. [crossref]
  5. Kim Y, Cha J (2019) Artificial Intelligence Technology and Social Problem Solving. In: Koch, F, Yoshikawa, A, Wang, S, Terano, T. (eds) Evolutionary Computing and Artificial Intelligence. GEAR 2018. Communications in Computer and Information Science vol 999. Springer, [crossref]
  6. Kalyan KS (2023) A survey of GPT-3 family large language models including ChatGPT and GPT-4. Natural Language Processing Journal100048.
  7. Abdi H, Williams LJ (2010) Principal component analysis. Wiley Interdisciplinary Reviews: Computational Statistics 2: 433-459.
  8. Bossert WH, Oettinger AG (1973) The Integration of Course Content, Technology and Institutional Setting. A Three-Year Report,Project TACT, Technological Aids to Creative Thought.
  9. Cordeschi R (2007) AI turns fifty: revisiting its origins. Applied Artificial Intelligence 21: 259-279.
  10. Oettinger AG (1952) CXXIV. Programming a digital computer to learn. The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science 43: 1243-1263.

Creating a Viable Gaza the ‘Day After’: How Mind Genomics and AI Can Suggest and Inspire

DOI: 10.31038/MGSPE.2024432

Abstract

This paper introduces the combination of Mind Genomics thinking with AI for the solution of practical issues, focusing specifically on what to do to create a viable Gaza after the hostilities cease. The approach allows the user to specify the problem, and the type of answers required. In seconds, the AI returns with actionable suggestions. The user can iterate, either using the same problem-specification, or changing the problem specification. After the user finishes the iterations and receives the initial results. The system returns within 30 minutes with a detailed summarization of each iteration. The summarization shows the key ideas, the reactions of audiences (acceptors vs rejectors), and ideas for innovative solutions. The approach is proposed as a way to think of new solutions, doing so at the level of the granular.

Introduction

The 1993 and 1995 Oslo Peace Accords between Palestinian and Israeli leaders negotiated for Israel’s withdrawal from Gaza and other key areas. This happened in 2005 under Prime Minister Ariel Sharon. An Islamist political group called Hamas won elections and took control of Gaza in 2006. Since then, Hamas has occupied the strip, which has become a site for protests, bombings, land assaults and other acts of violence. Israel and the United States, as well as several other countries, consider Hamas a terrorist organization [1].

The Hamas charter called for the abolition of Israel, and death to Israelis and Jews, world-wide. The Hamas charter did not have any proviso for co-existence, but rather called for a radical form of Islam. Hamas became the de facto government of Gaza, creating a massive military infrastructure. On October 7, 2023, during the Jewish holiday of Succoth, a Rave music festival was held in Israel, in areas abutting Gaza. An attack by Hamas terrorists ended up killing 1200 Israelis, and the abduction of more than, 200 many of whom were later killed. The Israeli response was justifiably furious, resulting in the wholesale destruction of Hamas, the destruction of the infrastructure of Gaza in a way resembling the destruction of Nazi Germany by the Allies. The academic literature is filled with the background to these issues, the public press filled with accusations, counter-accusations, and the brouhaha of seeming irreconcilable differences rooted in politics, education and Islam.

With the foregoing as a background, the question arose as what to do on the ‘day after,’ when Hamas would be declared ‘gone.’ What creative ideas about Gaza could emerge. The same problems occurred 80+ years ago upon the occasion of the Allied victory. What would happen the day after? Would the Allies follow the Morgenthau Plan of returning Germany to a more primitive country to punish it for the horrible crimes the Nazi’s had committed? Or would other plans for reconstruction be adopted, plans which guided Germany towards democracy, and towards a renewed place in ‘civil society.’ Fortunately for the world as well as for Germany, it was the latter plan that was adopted.

Using AI to Provide Suggestions about Rebuilding Gaza

The origins of this work come from at least three distinct sources. It is the combination of these sources which provides the specifics about what to do ‘the day after.’ These sources are Mind Genomics [2], then collaboration with Professor Peter Coleman at Columbia University [3], and finally the introduction of artificial intelligence into Mind Genomics and now the use of that AI technology to suggest ideas for rebuilding Gaza.

The first source is the emerging science of Mind Genomics [4]. Mind Genomics can best be thought of as an approach to understanding what the important factors are driving attitudes and decisions, the focus being the granular quotidian world, th world of the ordinary, the world of the everyday. Studies of decision making are the daily bread of those involved in consumer research, political polling, and so forth. Studies of decision making use a variety of techniques, such an observation, interpersonal discussions with individuals or groups, surveys, and even experiments creating artificial situations in which the pattern of behaviors gives an idea of what rules of decision making are being used. Within this framework, Mind Genomics provides a simple but powerful process, best described as presenting the respondent (survey taker) with systematically constructed combinations (vignettes), getting ratings of these vignettes, and then deconstructing the ratings into the contribution of the individual elements which constitute the building blocks the vignettes.

The second source is the recognition that quite often the research effort in Mind Genomics seems to be unduly difficult for the typical user. More often than not, a user investigating a topic may feel overwhelmed when asked to generate four questions about the topic, and then for each question, provide four answers. This is the way the science of Mind Genomics works. The problem is that ordinary people feel quite intimidated. It is the introduction of artificial intelligence a way to generate ideas (questions, answers to questions) which provides a way through the thicket, a way to do the study [5] The AI provided ere, SCAS, Socrates as a Service, becomes a tutor to the user, and in turn, a much appreciate feature of Mind Genomics.

The third source is the re-framing of the input to the AI. Rather than simply abiding by the request to provide simple questions and answers, the user can provide AI with a complete story, and ask the AI to provide appropriate answers. In most, although to be not in all the times, the change in focus ends up delighting, as the SCAS provides a far more integrated approach to solving a problem.

It is important to keep in mind that the approach presented here deals with suggestions about the practical solution of a problem, rather than with the more conventional academic approach of defining a narrow problem and seeking a testable solution.

Example – One of Many Iterations Dealing with the Reconstitution of Gaza

The remainder of this paper shows what SCAS, the artificial intelligence embedded in Mind Genomics, produces when properly queried. The process begins with the creation of a Mind Genomic study, as shown in Figure 1, Panel A. The creation of the study is templated, with Panel A showing that the user simply names the study, selects a language, and then agrees not to request nor accept private information.

fig 1

Figure 1: Panel A – Project initiation. Panel B – Request for AI help (Idea Coach), or user-provided questions. Panel C – Rectangle where the user types the relevant information to prompt SCAS. Panel D – The rectangle filled with the relevant information.

Once the study has been created, the Mind Genomics program, www.bimileap, presents the user with a screen requesting four questions. It is at this point that the user can work with SCAS, the AI embedded in the program. Rather than providing four questions, the user presses the ‘Idea Coach’ button, and is led to a screen requesting that user type in the request. That screen appears in Figure 1, Panel C. Finally, the user provides background materials and the requests, as shown in Figure 1, Panel D.

Table 1 presents the full text version of the request that the user simply created and copied into the rectangle in Panel D. It is important to note that the language in Table 1 is simple, written in the way one might talk, filled with material which is both relevant (e.g., the phrase I want to find 14 different ways to do this. For each way, give the way a name and write that name in all titles. Then, in a paragraph tell me exactly what i should do) as well as personal and not particularly germane to the actual task (e.g., How do I do this as a private citizen who only can offer them Mind Genomics as a way to help business and education).

Table 1: The prompting information provided to SCAS (Socrates as a Service), the AI in Mind Genomics

tab 1

Within a minute or so after the user presses the ‘submit’ button in Figure 1, Panel D, the embedded AI generates the first response. The first response is a set of 15 questions. These questions are assigned sequential numbers and are shown in Table 2. Afterwards, material such as that in Table 3 will appear.

Table 2: Results from immediately using SCAS to answer the 15 questions provided by SCAS as the ‘first answer’ to its request (see Table 2). Each question posed by SCAS in its initial response to the user is shown as a three-component paragraph (question posed, answer provided, SCAS-estimated performance of the answer). This step is a slight detour.

tab 2

Table 3: The 14 efforts requested to SCAS in the squib, along with the elaboration of these efforts in simple-to-understand prose English.

tab 3

The Short, Momentary Detour, to Answer the Newly Presented Questions Which are Part of the Answer

Before proceeding, it is relevant to note an additional step that can be done, almost immediately. That step is to ask SCAS to ‘answer’ the 15 questions through an immediate next iteration. When the 15 questions appear, those shown in Table 2, SCAS has already done its work, responding to the request in Table 1. The program has also recorded all that needs to be recorded from the output of SCAS. The user is free now either to read all the information provided by AI, run another iteration, or take a quick detour to answer the 15 questions, before proceeding.

Table 2 shows what happens when the user copies the 15 questions, and then moves to the next iteration. The user presses requests permission to modify the input instructions to SCAS (Figure 1, Panel C). The user requests that SCAS repeat the question in text, then answer the question, and then rate the answer provided on three attributes, all on a 0–100-point scale. These three attributes are likelihood of success, degree of difficulty implementing the answer, and originality of the answer.

It is at Table 2 that one can see the power of the AI to help the user. It is not clear whether the user could have come up with these 15 questions, and certainly not in the time of 30 seconds. Should the user not like the questions, the user can continue to iterate until the user finds 15 questions of interest as outputs to the request made in Table 1. Once the set of questions are identified, it is straightforward to copy the set of questions, and mov in another direction by requesting SCAS to answer the 15 questions, and ‘scale the answer’ on the three dimensions. Finally, when that action, Table 2 is produced, the user now returns to the main study.

Once the first set of materials have been delivered, SCAS can be re-rerun for a second iteration. The user provided ‘squib’ or information about the topic and request to the AI, either remain the same, or can be edited ‘on the fly’ by the user. SCAS is now ready for a second run, and so forth. Iterations can be done in periods of about 30 seconds (excluding editing the squib to change the information to SCAS). Thus, the system becomes a tool for immediate iteration, learning, and fine tuning.

Once the user finishes the iterations and closes the study, either by working with respondents or simply by ‘logging off’, as was done here, the program puts each iteration into a separate Excel tab, and for that iteration performs a number of ‘summarizations’ explained and demonstrated below. Each iteration is analyzed thoroughly by its own ‘summarization,’ meaning that SCAS both generated the information from a minimal input shown in Table 1, and then created deep analyses of that information (Tables 2-6). For each study, the user receives the information in the ‘Idea Book,’ the aforementioned Excel book. For example, when the user decides to work with the program 15 times, iterating and then changing some of the squib, or even simply re-running the squib without changing it at all, the program will return within 30 minutes with the fully summarized material.

The remainder of this paper presents the results, discussing the nature of the results, the implications of the analyses presented, and so forth. It is important to keep in mind that for this particular study, it was possible to run the SCAS module more than 15 times, each iteration requiring less than 30 seconds, unless the squib was manually changed to shift direction in the effort to understand.

Ideas Presented – Answering the Statement ‘Mind Genomics for Business and Education

The initial request to SCAS was to provide 14 ideas for initiatives and programs, and then to explicate them. Again, the input information was minimal, focusing on business and education. Table 3 shows the results in detail, with the level of detail sufficient to ‘paint the picture’.

The summarization further proceeds with a variety of analyses about the ideas themselves. Table 4 shows three summarizations, as follows:

  1. Key ideas in the topic questions. As an aid to thinking, the summarization restates each of the questions in a simple manner.
  2. Further summarization occurs by distilling the ideas into general themes, and then for each theme showing the specific ideas relevant to that theme.
  3. Perspectives: For each theme, listing the positive and the negatives,

Table 4: Summarization of ideas into key questions, themes, and perspectives relevant to those themes

tab 4

The expansion of the ideas continues, with the ‘summarizer’ considering which groups would be positive to the ideas (interested audiences) and which groups with be against the ideas (opposing audiences). Once again it is important to stress that these groups emerged from the AI further ‘working up’ the material that it generated before. Table 5 shows these two groups, interested audiences versus opposing audiences, emerging from this one iteration presented in depth in this paper.

Table 5: Responses to the suggestions, divided into interested audiences and opposing audiences

tab 5

The final summarization presents the basis for new ideas, new strategies, and new products. Table 6 shows different ‘steps’ towards creating the ‘new’. The first comprises ‘alternative viewpoints,’ about the need for other perspectives. The second comprises ‘what is missing?’ focuses on additions to the 14 suggestions. The third comprises ‘innovations,’ first presenting the innovation and then providing some detail.

Table 6: Steps towards innovation; Alternative viewpoints, What is missing, and Innovations

tab 6(1)

tab 6(2)

Discussion and Conclusions

As emphasized in the introduction to this paper, the focus here is to find so-called actionable solutions to the issue of what to do ‘the day after.’ There are many studies about the problems, their history, and their manifestations. The academic literature is replete with such analyses, and with suggested solutions, although the stark reality is that analysis often leads to its own implicit paralysis because the focus is on the ‘why,’ and not on the ‘what to do’.

The inspiration for the Mind Genomics work and its evolution presented here came from the world of consumer psychology, whose academic goal of ‘knowledge’ was deeply intertwined with the ultimate desire by some to improve business by understanding the mind of people. It was from that beginning and from the experience in medicine, and actually changing people’s behavior for the better [6] that the approach presented here evolved. The notion that SCAS (Socrates as a Service) could produce actionable results further motivated us, once it became apparent that one could challenge AI with issues, and have AI first provide solutions given minimal input, and then ‘work up’ those minimal solutions into far more profound results.

Finally, it is important to close with the realization that the information presented here required no more than a minute to create, or perhaps more correctly, nor more than 30 seconds to create. The important thing about that short time is that it permitted the user, whether researcher or policy maker, to explore many different alternatives with on-the-fly modifications of the input squib shown in Table 1. In effort after effort author HRM has discovered that one iteration did not suffice. Rather, natural curiosity promoted many iterations, almost in a way that could be called ‘results-addiction.’ The immediate information returning with 15 seconds, and then the receipt of the Idea Book by email within 30 minutes made the process almost irresistible, similar to consuming dessert for those who are so addicted to sweet things. Eventually the process stops, the Idea Book arrives, and the ideas contained therein take over, to be put into practice.

References

  1. https://www.history.com/news/gaza-conflict-history-israel-palestine (accessed February 13, 2024)
  2. Papajorgji P, Moskowitz H (2023) The ‘average person’ thinking about radicalization: A Mind Genomics cartography. Journal of Police and Criminal Psychology 38: 369-380. [crossref]
  3. Coleman PT (2021) The Way Out: How to Overcome Toxic Polarization. Columbia University Press.
  4. Moskowitz HR (2012) ‘Mind genomics’: The experimental, inductive science of the ordinary, and its application to aspects of food and feeding. Physiology & Behavior 107: 606-613. [crossref]
  5. Wu Y (2023) Integrating Generative AI in Education: How ChatGPT Brings Challenges for Future Learning and Teaching. Journal of Advanced Research in Education 2: 6-10.
  6. Nikolić E, Masnic J, Brandmajer T, Nikolic A (2022) Chronic pain control using Mind Genomics in patients with chronic obstructive pulmonary disease knowledge. International Journal 52: 455-459.

How Open Education Can Facilitate Digital Competence Development

DOI: 10.31038/PSYJ.2024631

Abstract

In today’s digitalized world, proficiency in digital skills is crucial for employability and academic success in higher education. However, there is a gap between students’ perceived and actual digital competence , which is rather limited.This paper explores how open education can foster the development of digital competence in higher education, employing theoretical frameworks alongside a practical example. The article examines theoretical approaches that combine open education concepts, specifically Open Educational Practices (OEP), with the principle of constructive alignment. Open education aims to democratize knowledge access and promote collaboration, making it conducive to digital competence development through OEPs. The principle of constructive alignment emphasizes aligning learning goals, assessments, and activities to foster competence development. One example illustrates the effectiveness of this approach, showing a significant improvement in students’ digital competence through participatory Open Educational Resource (OER) production. In conclusion, the paper emphasizes the significance of integrating OEPs into higher education pedagogy to assist students in acquiring essential digital competencies.

Keywords

Digital competence, Open educational practices, Open educational resources, Open education, Higher education

Introduction

Digital Competence in Higher Education

In the age of digitalization, digital competence is becoming increasingly important. Many jobs today require some level of digital competence, particularly in communication and collaboration. Digital competence enables individuals to effectively navigate online platforms, search for information, and distinguish credible sources from misinformation. In the digital age, civic engagement increasingly relies on digital platforms for activities such as voting, accessing government services, and participating in public discourse. Technology is constantly evolving, and new digital tools and platforms emerge regularly. The European Commission [1] describes digital competence in five areas. The five key areas of digital literacy are: “(1) Information and data literacy, including management of content; (2) Communication and collaboration, and participation in society; (3) Digital content creation, including ethical principles; (4) Safety; and (5) Problem solving.”

Higher education institutions should support students in developing their competencies in employability, academia, and personal responsibility [2]. Despite students’ high self-perception of their digital competence [3], their actual digital competence is inadequate [4]. This paper aims to explore how open education can promote the development of digital competence in higher education. To achieve this, we take a theoretical and practical approach. Firstly, we review literature on open education. Secondly, we provide an example of teaching and learning in open education.

Theoretical Approaches to Open Education and Digital Competence Development

To answer this question, we need to combine two theoretical approaches to higher education: conceptualizations and frameworks of open education and its design in higher education, and the principle of constructive alignment in the case of digital competence development.

There are several definitions of open education, with two major strands in the discussion [5]. First, there are those who discuss Open Educational Practices (OEP) in the context of open educational resources (OER). The most influential in this group are Wiley and Hilton [6], who focus their discussion of OER-enabled pedagogy on the different open educational practices enabled by the 5Rs (i.e., retain, reuse, revise, remix, and redistribute). Second, there are those who discuss OEP in relation to open scholarship, open learning, open teaching or pedagogy, open systems and architectures, and open-source software. Exemplary, DeRosa, and Robison [7] focus on open pedagogy and learner-driven practices. In the present article we focus on Cronins’ definition, which combines both aspects regarding OERs and learning processes in OEPs, that she defines as “collaborative practices that include the creation, use, and reuse of Open Educational Resources, as well as pedagogical practices employing participatory technologies and social networks for interaction, peer-learning, knowledge creation, and empowerment of learners” [8]. Open education aims to democratize access to knowledge, promote collaboration and innovation in teaching and learning, and address barriers to education such as cost, geography, and institutional constraints [8]. Regarding the research question above, the implementation of OEPs with a focus on student activity in OER production may facilitate digital competence development in higher education.

One theoretical approach for designing education towards competence development is the principle of constructive alignment [9]. This principle is fulfilled when learning outcomes are communicated in advance, performance assessments measure students’ achievement of those outcomes, and teaching and learning activities help students to achieve them. Consequently, the development of digital competence can be achieved by defining and communicating the learning goal in advance, assessing digital competence development, and supporting digital learning through activities that focus on information and data literacy, communication and collaboration, participation in society, digital content creation, safety, and problem-solving.

Based on the conceptualizations of open education and the principle of constructive alignment, educators can facilitate the development of digital competence in higher education by implementing OEPs that enable students to construct their own learning through engagement in relevant digital activities. The application of the principle of constructive alignment in OEP design could enhance digital competence, provided that the learning goal addressing digital competence is achieved through appropriate open learning activities and assessment formats. Therefore, students can acquire digital competencies if they are informed of this objective beforehand, if their learning activities concentrate on creating digital content, collaborating, and solving problems, and if the chosen assessment format also covers these learning areas. To enhance students’ digital competence, educators and students concentrate on generating digital OERs, and the assessment is based on this production.

Open Education and Digital Competence Development: A Practical Example

To answer the question on a practical level, we draw on an example study by Braßler [10]. The study presents a teaching-learning arrangement that implements OEPs to enable students to co-produce OER. The planning and implementation of the OER production course followed the principle of constructive alignment. To improve students’ digital competence development, the course educators and students focused on creating digital OERs in the form of videos and scripts covering various topics related to sustainability. The implemented learning activities were designed to develop the students’ digital competence. These activities included interdisciplinary peer learning, empowering learners in self-directed problem-solving, providing discipline-based expertise on demand by educators, technical expertise in shooting and editing videos on demand, and several feedback loops on the OER product by students and educators. The assessment was also based on the production of OERs. All interdisciplinary student teams were graded on their OER products. The study indicates a significant increase in digital competence over time among students who produced OERs in the production course, compared to their peers enrolled in courses unrelated to OER content development. In summary, the implementation of OEPs can enable students to co-construct their own learning towards digital content creation, with a clearly defined learning goal of digital competence, and assessment on digital content. This can lead to the development of digital competence through open education.

Conclusion

The purpose of this article is to analyze how open education can facilitate the development of digital competence in higher education. The key points of the theoretical and practical results are summarized below:

  • Implementing OEPs that enable students to actively participate in teamwork and co-creation.
  • Implementing OEPs that empower students in digital content creation.
  • Defining digital competence development as a learning goal and communicating this to students.
  • Implementing OEPs that enable students to co-create digital OERs as a product of their learning process.
  • Implementing OEPs that support students in their OERs production.

Consequently, educators should familiarize themselves with the opportunities for implementing OEPs in their teaching to support students’ development of digital competence.

Conflict of Interest

The author claims no conflict of interest.

Funding

No funding was received for this paper.

References

  1. European Commission (2018) Recommendation on Key Competences for Lifelong Learning. Proceedings of the Council on Key Competences for Lifelong Learning, Brussels, Belgium.
  2. Kolmos A, Hadgraft RG, Holgaard JE (2016) Response strategies for curriculum change in engineering. International Journal of Technology and Design Education 26: 391-411.
  3. Zhao Y, Sánchez Gómez MC, Pinto Llorente AM, Zhao L (2021) Digital Competence in Higher Education: Students’ Perception and Personal Factors. Sustainability 13: 12184.
  4. Marrero-Sánchez O, Vergara-Romero A (2023) Digital competence of the university student. A systematic and bibliographic update. Amazonia Investiga 12: 9-18.
  5. Koseoglu S, Bozkurt A (2018) An exploratory literature review on open educational practices. Distance Education 39: 441-461.
  6. Wiley D, Hilton J (2018) Defining OER-enabled pedagogy. International Review of Research in Open and Distributed Learning 19: 133-147.
  7. DeRosa R, Robison S (2017) From OER to open pedagogy: Harnessing the power of open. In R. S. Jhangiani & R. Biswas-Diener (Eds.), Open: The philosophy and practices that are revolutionizing education and science Ubiquity Press.
  8. Cronin C (2017) Openness and praxis: Exploring the use of open educational practices in higher education. International Review of Research in Open and Distributed Learning 18: 15-34.
  9. Biggs J, Tang C (2011) Teaching for Quality Learning at University. The Society for Research into Higher Education & Open University Press.
  10. Braßler M (2024) Students’ Digital Competence Development in the Production of Open Educational Resources in Education for Sustainable Development. Sustainability 16: 1674.