LISA ChatGPT
Well-being and mental health are fundamental components of children's development and their educational success. Yet, more than one in four children face challenges such as neurodevelopmental and learning disorders (like Specific Learning Disorder, Autism Spectrum Disorder, Attention deficit hyperactivity disorder, etc.), mood disorders (like anxiety, depression), or emotional and behavioral disorders.
In the absence of detection and intervention, these challenges often lead to severe consequences for the child and those around them: lack of interest, dropping out, bullying, violence, suicidal actions...
The LISA research-action program provides educational stakeholders with tools to identify, understand, and collaborate, to support each child, both in and outside of school, based on their strengths and needs. Co-constructed by teachers, families, researchers, clinicians, and other educational actors, LISA develops a community, a training program, and a digital platform.
LISA is originally developed and prototyped in France, initiated by iféa, a network of innovative schools, and the Learning Planet Institute. LISA is developed Under the supervision of its scientific committee, including Ariel B. Lindner, Bennett L. Leventhal, Richard Delorme, Bruno Falissard, Caroline Huron, Yasser Kazhaal, and others; a dedicated team including Anirudh Krishnakumar, Naima Page, Kseniia Konischeva, Arno Klein, and others; and key partner institutions including the Child Mind Institute, INSERM U1284, CléPsy, and the Robert Debré Hospital in Paris.
The project has received support from the French government to be deployed in 200 schools within the Académie de Créteil, Académie de Paris, Académie de Versaille, and the Mission laïque française.
LISA aims to provide stakeholders in the education of children and adolescents with evidence-based, actionable, and accessible training and guidance in the process of identifying and supporting their unique strengths and needs. As part of this effort, LISA is building a database of resources, Lisapedia.
While all Lisapedia content will be carefully written, reviewed, and validate by a scientific and editorial committee, this page represents a technological proof of concept of combining structured knowledge from field experts with generative AI to draft content, which can then be reviewed and edited by experts.
THIS CONTENT IS DISPLAYED HERE FOR DEMONSTRATION PURPOSES ONLY. IT IS NOT INTENDED TO BE USED AS A REFERENCE. SOME CONTENT MAY BE IRRELEVANT, OR EVEN OUTRIGHT FALSE. IF YOU SUSPECT A MEDICAL CONDITION, IMMEDIATLY REFER TO A TRAINED PROFESSIONAL.
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I am a 6th grade math teacher. I am looking for suggestions on how to support my student according to their strengths and needs. You are a child and adolescent psychiatrist. Your role is to provide guidance to a 6th grade math teacher on how to support student according to their strengths and needs. My student has been assessed for the following dimension: Mathematics - cognitively and mechanically performing mathematical operations: Math, or arithmetic, is the ability to manage numerical and/or quantitative ideas, both conceptually and in graphical representations. Mathematical skills evolve over time, beginning using numbers for the concrete counting of objects, evolving into the appreciation that numbers can represent various constructs such as quantity, time, space, etc., that can be manipulated through mathematical operations. Success with math can be confounded by writing difficulty as "imprecise" presentation of numbers leads to errors. <h3><slot data-nx-ref="value-0"></slot></h3> <slot data-nx-ref="value-0-desc"></slot> <h3><slot data-nx-ref="value-50"></slot></h3> <slot data-nx-ref="value-50-desc"></slot> <h3><slot data-nx-ref="value-100"></slot></h3> <slot data-nx-ref="value-100-desc"></slot> His/her profile is as follows: Use of numbers, variables, and mathematical operations and/or processes is efficient, effective, and age/developmentally appropriate: Individuals flexibly and appropriately recognize both the concrete and abstract meaning of numbers and mathematical operations. They carefully observe the precision necessary to executive mathematical tasks effectively and appreciate the transformative value of results derived from mathematical operations. Create a guide that I can use and share to best support my student. The guide MUST have the following structure: 1. Overview of the challenges associated with this profile Present this section as a markdown table with 2 columns: - Challenges, - How they manifest. 2. Efficient, evidence-based strategies to support this student In this section, include 3 to 5 strategies. Each strategy must have: - A title, - A brief description and why it is efficient, - Specific implementation steps, - Parameters to monitor and adjust. Present this information in a markdown table with 4 columns. Each strategy must be sustainable and easy to implement in the classroom, and lead to this student nurturing his strengths and building resilience. 3. Do and don'ts List common mistakes to avoid and best practices to follow when supporting this student. Present this information in a markdown table with 2 columns. 4. Further reading and research List resources that can help me learn more about this profile, as well as a choice of keywords to use in my own research. Be concise and use simple language. Prefer using bullet points and/or markdown tables instead of long text paragraphs.
- Overview of the challenges associated with this profile
| Challenges | How they manifest |
|---|---|
| Complacency | Because they grasp mathematical operations quickly, these students may become complacent and neglect to exercise skill reinforcement. |
| Lack of challenges | Not facing any difficulty in performing mathematical tasks, the student may not encounter substantial challenges leading to lack of motivation. |
| High expectations | High proficiency in mathematical skills can create unrealistic expectations from others, which may be stressful for the student. |
- Efficient, evidence-based strategies to support this student
| Strategy | Description & Efficiency | Implementation Steps | Parameters to Monitor |
|---|---|---|---|
| Advanced Learning Opportunities | Give your student advanced tasks/projects to encourage critical thinking and deeper understanding of concepts. | Assign challenging tasks that require higher-level thinking; Consider dividing class into groups and assign leadership role to advanced students; Introduce advanced tools such as algebra or geometry if suitable. | Assess student's progress, engagement levels, reaction to stress, and behaviors within the group. |
| Scaffolded Learning | Promote resilience and problem-solving skills by slightly increasing the difficulty level of tasks over time. | Gradually introduce tasks that are slightly beyond their comfort zone. Assess and give feedback. | Monitor student's confidence, motivation, and improvement. Make sure to step in if stress levels seem high. |
| Varied Instructional Methods | Incorporate various delivery methods like visual aids and interactive activities to ensure sustained interest. | Implement technology through educational games and digital tools; use visualization for complex concepts. | Measure engagement, motivation and ask for student's feedback on how much they enjoy varied methods. |
- Do and don'ts
| Do | Don't |
|---|---|
| Regularly communicate with this student about their progress. | Assume the student will always understand everything just because they're good at math. |
| Offer opportunities for advanced learning and engagement. | Just give them harder work without adequate support. |
| Recognize and reward effort and progress, not just achievement. | Overload them with expectations and create unnecessary pressure. |
- Further reading and research
- "Mathematics Learning in Early Childhood: Paths Toward Excellence and Equity" by Christopher T. Cross, Taniesha A. Woods, and Heidi Schweingruber
- "Differentiation in the Math Classroom" by Dr. Felicia Durden
Keywords for your own research:
- Mathematics cognitive development
- Challenges for mathematically gifted students
- Scaffolding in advanced mathematics learning
- Variance in instructional methods in math
- High achievers coping strategies in math.