Towards Trustworthy AI in Inclusive Education: A Co-Creation Approach Rooted in Ecological Frameworks Valeria Cesaroni1,* , Martina Galletti2,3 , Eleonora Pasqua3,4 and Daniele Nardi3,5 1 University of Perugia, Italy 2 Sony Computer Science Laboratories-Paris (Sony CSL-Paris) - France 3 Sapienza University of Rome - Italy 4 Centro Ricerca e Cura di Roma - Italy 5 CINI-AIIS - Italy Abstract The integration of digital technology and AI systems has prompted extensive inquiries into their ethical design and im- plementation. Trustworthy AI, essential for fairness, robustness, safety, and transparency, is recognized as fundamental, transcending pure technological interaction. This is particularly pivotal in contexts involving minors, and especially within technologies fostering inclusion for students with disabilities and special educational needs (SEND). Inclusive education hinges on trustworthiness due to inherent asymmetries in learning structures and the relational aspect of educational environments. This paper starting from a case studies, i.e. an AI interface tailored to children with text comprehension difficulties, it introduces a co-creation strategy with different stakeholders. It develops an ecological framework for trustworthiness, rooted in value-sensitive design. Our approach emphasizes ethical and trustworthy AI development, prioritizing responsibility, reliability, and inclusivity. It addresses the concept of trustworthiness as a systemic relationship between multiple contexts (such as clinical and school environments) in the development of children’s proximal processes and scaffolding, as outlined by Bronfenbrenner’s system ecological theory. Keywords Trustworthiness, Inclusion, Natural Language Processing, Text Comprehension 1. Introduction most multifaceted and the most interconnected with all the others domains. In recent years, the increasingly technologically medi- This is especially true and even more crucial if we ated nature of our societies, fueled by the systematic think about the use of AI with and by minors and, partic- integration of digital technology and the escalating ubiq- ularly, within technologies aimed at fostering inclusion uity of AI systems have prompted increasingly profound in contexts of students with disability and special educa- inquiries into the ethical, responsible, and trustworthy tional needs (SEND). Within the framework of inclusive design and implementation of AI. This trend is further education and learning, the aspect of trustworthiness is underscored by the ongoing legislative endeavors at an pivotal for several reasons: European and international level. • The inherent asymmetry in the structure of learn- While there is no universally accepted definition of ing, educational, and rehabilitative interactions. trustworthy AI, it is widely acknowledged as a fundamen- • The relational aspect of educational and rehabili- tal principle [1], underpinning the validity of other es- tative environments, grounded in trust and com- sential characteristics such as fairness, robustness, safety, municative exchanges. and transparency. Contrary to the notion that trust is • The developmental trajectory of the child, which solely tied to technology interaction, as suggested by encompasses cognitive and psychological dimen- Luhmann, trust is deemed indispensable for any form of sions. interaction to occur [2]. Consequently, in the domain of Considering the intricate nature of the educational and AI ethics, the concept of trustworthiness is probably the learning dynamics, the conscientious and trustworthy integration of AI-based technologies within this domain, Ital-IA 2024: 4th National Conference on Artificial Intelligence, orga- particularly when involving vulnerable subjects, neces- nized by CINI, May 29-30, 2024, Naples, Italy sitates a thorough evaluative analysis. Such an analysis * Corresponding author. should encompass an examination of the interplay among $ valeria.cesaroni@dottorandi.unipg.it (V. Cesaroni); martina.galletti@sony.com (M. Galletti); e.pasqua@crc-balbuzie.it the different systems and players involved. (E. Pasqua); nardi@diag.uniroma1.it (D. Nardi) In this paper, we start by a case study to illustrate the  0000-0001-9881-1597 (V. Cesaroni); 0009-0002-2079-8999 example of a technology built for therapeutic and ed- (M. Galletti); 0000-0002-7153-6094 (E. Pasqua); ucational purposes, with a focus on inclusivity, ethical 0000-0001-6606-200X (D. Nardi) © 2024 Copyright for this paper by its authors. Use permitted under Creative Commons License considerations, and trustworthiness. More, in particular, Attribution 4.0 International (CC BY 4.0). CEUR ceur-ws.org Workshop ISSN 1613-0073 Proceedings we first introduce the ARTIS project, which aims to de- tion, inclusion is addressed primarily through the lens of velop software using natural language processing (NLP) non-discrimination and data accuracy [11]. While ensur- tailored to therapeutic practices for children with text ing data quality and mitigating bias are crucial for trust- comprehension difficulties. Unlike technologies primar- worthy AI systems, this approach risks oversimplifying ily targeted at disabilities and later repurposed for edu- inclusion as a technical issue, detached from the complex- cation, ARTIS is conceived as an inherently educational ity of learning environments. Therefore, it’s imperative tool and subsequently tailored for the clinical world. to broaden the discourse beyond technical considera- Secondly, we propose a co-creation approach grounded tions and adopt a perspective that encompasses diverse in value-sensitive design, involving key stakeholders to stakeholders, design aspects, and values promoted in the ensure the ethical development of the AI interface. Draw- development and implementation process. Despite the ing from ecological frameworks, such as Bronfenbren- recognized importance of stakeholder involvement, re- ner’s ecological systems theory [3] , and considering search indicates a lack of participation from clinicians, that learning environments are both physical and social parents, and teachers in decision-making processes [12], contexts [4], we emphasize the importance of consid- [13], with limited focus on the broader impact of AI tools ering the systemic interaction between individuals and on learning environments [14]. This underscores the their environments in the design process. Our strategy necessity for a more holistic approach to AI education prioritizes the responsible and trustworthy introduction that considers the multifaceted nature of inclusion and of AI technology, reflecting our commitment to ethical, engages diverse stakeholders to ensure its effectiveness reliable, and inclusive development practices. and relevance. This broader perspective aligns with the The issue of AI trustworthiness is therefore positioned framework proposed by [9], which emphasizes inclusive at the crossroads of various interaction systems known as AI education grounded in Universal Design for Learning proximal processes. These processes are pivotal because principles. they serve as the conduit through which individuals learn The integration of Artificial Intelligence holds promise and adapt over time within their interactional environ- for children with special learning needs, including those ments [5]. with visual, mobility, or hearing impairments, offering opportunities for diverse learning materials and adapt- able content strategies [15]. However, achieving true 2. AI and Inclusion inclusion extends beyond technological solutions alone. Literature emphasizes the importance of striking a bal- The ARTIS project presented in this paper positions itself ance between individualization and socialization, valuing in the debate on the relationship between AI and inclu- differences while addressing diverse needs [16]. There- sion in an innovative way. It develops a technology that fore, inclusive contexts must embrace both technological assists children with special educational needs and learn- advancements and nuanced pedagogical approaches to ef- ing disorders, thus aligning itself with the field of assis- fectively support diverse learners. This perspective aligns tive technologies. Yet, it doesn’t stop at the deterministic with the holistic framework proposed earlier, which ad- association that sees inclusion as directly conveyed by vocates for inclusive AI education grounded in Universal technology, but problematises this relationship through Design for Learning principles and comprehensive stake- a systemic vision of inclusion and through an approach holder engagement. It It becomes crucial, therefore, to based on the ethics of AI and the active involvement reflect on how the relationship between technology, dis- of numerous stakeholders in all phases of the project. ability, and inclusion should be conceptualized. While there is extensive literature on AI and inclusion, The concept of inclusion, related to that of disability, few studies explore the intersection of these fields, such has changed significantly over time as the work of [17] as those by Kazimzade et Al. [6] and Gibellini et Al. [7]. and [18] testifies. In 1980, the International Classification Similarly, in the domain of AI ethics in education and of Impairments, Disabilities, and Handicaps [19] estab- learning, research is limited, with Mouta et Al. [8] being lished the first definition of disability, which is commonly among the few contributors. The only paper addressing associated with a medical model of disability. Accord- this gap is Song et Al.’s recent study [9] introduces a ing to this view, disability is interpreted as an individual framework grounded in Universal Design for Learning problem, which must be corrected in terms of restitutio principles [10], guiding the development of inclusive AI ad integrum. In this publication, an important distinction education. By incorporating essential AI concepts and was made between impairment (an anomaly or loss of diverse pedagogical examples, this framework aims to physiological or anatomical functions), disability (the loss foster broader participation and bolster competitiveness or difficulty, resulting from the impairment, of perform- within the AI workforce. ing activities considered normal for healthy individuals), In the context of European and international guide- and handicap (the condition of disadvantage resulting lines, as outlined by UNESCO specifically for AI in educa- from the objectification of the impairment). According to this conception, disability is seen as something exclu- renders it a critical resource for enhancing people’s lives sively pertaining to the individual and limits her ability to and expanding their opportunities. However, it is essen- live a full and satisfying life and to flourish in society [20]. tial to recognize its situated nature, shaped by social and Disability movement activists in the late 20th century value determinants. Technology thus becomes a matter posed a significant challenge to this prevailing paradigm. of justice. Consider, within the realm of education, the They critically examined the connection between impair- extent to which knowledge can be made accessible to ment and disability, thus affirming the social model of diverse needs and characteristics through design—both disability [21]. This conception emphasises the role of the technological and otherwise—that is attentive to differ- material organisation of society in creating conditions ences, as articulated in Universal Design for Learning of disability from a deficit. Therefore, in this view an (UDL). inclusive society is one that can eliminate the disabling These considerations are particularly pertinent regard- contexts and barriers that society possesses in relation ing AI-based systems. Fourth-order technologies [28], to the diversity of human functioning. One of the most capable of replicating human actions in the absence of hu- significant steps in this debate was the development of man intelligence, bring with them potentials, challenges, the ICF model [22]. At the centre of the bio-psycho-social and risks well-documented in literature and institutional approach, there is the individual-environment interac- discourse. For inclusive learning objectives, AI-based tion. Disabilities are considered beyond an exceptionalist technologies must be designed and implemented with logic and are placed at the centre of the human condition adherence to various criteria to ensure accountability itself. What links disability and health, according to this and reliability within an inclusive learning environment. model, depends on the functionings or, in other words, Beginning with an assessment of the ethical treatment the capabilities that each human being in relation to the of data (bias, privacy) and algorithms (fairness, trans- social context of reference is capable of having and being. parency, explainability), an inclusive perspective on tech- Thus, the ICF model, and the Capability Approach (CA), nology prompts a critical examination of its embedding [23],[24] although not totally overlapping, emphasise context and its interaction with and involvement of key how well-being (individual and collective) arises from stakeholders. Moreover, from a technical perspective, the dynamic between internal dispositions/opportunities technologies for inclusion should be designed so that the and external dispositions/powers, a dynamic that is to be users can personalize their interaction with the AI system understood both as the absence of external impediments through adjusting parameters and controls according to (negative freedom) and as an analysis of the conditions their preferences or specific needs. and quality of life that people are able to lead (positive freedom). In this context, the role of technology acquires a cen- 3. ARTIS: system description tral function, in fact, the use of technology in relation In designing AI-based technologies for inclusive learn- to disability could play a crucial role in the expansion ing objectives, such as the interface ARTIS developed by of individuals’ capabilities [25]. Technology finds a spe- Sony Computer Science Laboratories Paris and Centro cific place within the Environmental Factors of the bio- Ricerca e Cura, ensuring accountability and reliability psycho-social perspective of the ICF. Starting from the within an inclusive learning environment is paramount. assumption that people can function in different ways This necessitates adherence to various criteria, beginning depending on their environments and that disability is with an ethical assessment of data and algorithms, encom- therefore the result of a mode of interaction between passing considerations of bias, privacy, fairness, trans- the individual and the environment, the ICF considers parency, and explainability. An inclusive perspective on technologies as tools that mediate this interaction. Tech- technology calls for a critical examination of its embed- nologies thus, depending on the way they are designed, ding context and its interaction with key stakeholders. implemented, and used, can act as facilitators or, on the ARTIS, as an interface powered by artificial intelligence contrary, as barriers in performing normal activities and to support text comprehension, exemplifies this approach creating an inclusive society. It would be naive to con- by drawing on neuro-psycholinguistic models of reading sider technology’s relationship with disability solely in comprehension, thus integrating linguistic components instrumental terms. As extensively debated in the lit- into its design to enhance accessibility and inclusivity in erature ([26], [27]), technologies always exist within a learning contexts. ARTIS [29] is an interface, powered specific context and invariably embody certain underly- by artificial intelligence, designed to support text com- ing values and orientations. In the context of disability, prehension. Born as a collaboration between Sony Com- technology assumes a pivotal role, often becoming an puter Science Laboratories Paris 1 and Centro Ricerca integral part of an individual’s interaction with their environment. Technology’s capacity to mediate this re- lationship between the individual and the environment 1 https://csl.sony.fr/ e Cura 2 in Rome, Italy. The interface was developed 4. Ecological framework for a from neuro-psycholinguistic models of reading compre- hension, focusing on the linguistic components of text trustworthy AI with children processing. The project description underlines how the objectives of In particular, subjects with poor text comprehension this project are multifaceted. It emphasize rigorous re- present difficulties related to the processing of syntactic search to ensure computational functionality, facilitating and semantic sentence components [30], the analysis of integration into rehabilitation and educational activities. lexical components of words [31] and deficits in the syn- Additionally, specialized research is essential to examine tactic representation of words and oral comprehension the impact, acceptance and feasibility within inclusive skills [32]. Moreover, [33] stated that the same subjects educational and rehabilitative contexts. To address this, report significant deficits in receptive vocabulary and se- we framed future research directions in a conceptual mantic processing. Finally, [34] and [35] addressed the framework considering impacts on child development issue of grammar, claiming that children and adolescents and the interplay between inter-subjective and objectual with problems in text comprehension show difficulties dimensions of proximal development. in understanding the role of pronouns within sentences, The literature on AI trustworthiness is vast and mul- especially if these are in clitic form. Considering this ap- tidisciplinary. With regard to HCI (human computer proach, ARTIS allows for personalized practice on texts interaction), the issues that are most focused on concern at different levels. Using AI algorithms, the interface can the design and perception of the user and the psycho- automatically extract keywords, associate pictograms, logical mechanisms that impact the perception of trust- identify more complex vocabulary and generate semantic worthiness and thus the subsequent usage behaviour networks, and practice grammatical components. ARTIS [36],[37],[38]. Therefore, one of the main focuses is on is aimed at primary and secondary school children with predictability, transparency, explainability, robustness of difficulties in text comprehension, but it can also be used the system. Trust is generally interpreted as a psycholog- as a support for L2. ical mechanism that occurs in social or intersubjective We had three main goals in mind when designing interaction to reduce the uncertainty of the other’s be- our prototype. Firstly, we aimed to develop a system haviour. specifically for children from second grade to adoles- According to the OECD, Organisation for Economic cents diagnosed with reading comprehension difficulties. Co-operation and Development : “AI might be considered Secondly, we wanted an interface suitable for therapeu- trustworthy when it does properly what it is supposed to do, tic sessions, always under professional supervision for but also when one can trust that human beings will use it younger age groups. Lastly, we aimed to involve end- in a fair and appropriate way”[39]. The trustworthiness users and stakeholders from the outset of the design of AI is also considered a crucial element within the edu- process, collaborating with skilled speech and language cational literature, and involves the aspects of reliability, therapists for evaluation and feedback. Drawing inspi- fairness, transparency, explainability, data protection and ration from Kitsch and Van Dijk’s model, we integrated bias. functionalities to enhance the superficial representation However, we believe that the context of the ARTIS of language, focusing on lexical and morphosyntactic project poses an even greater challenge to the concept understanding. Our interface consists of three modules: of trustworthy AI, because it must be ensured in such a the first aids in understanding words and sentences, the way that this characteristic ’collapses’ within different second focuses on coherent sequence representations, settings and interactions: rehabilitation, school, family and the third aims at creating a broader mental model of and individual use. The interface, in fact, not only hy- language. We also implemented a Synset Networks fea- bridises the educational and rehabilitative relationship ture to link words encountered in the text with previous in a consistent manner, but also assumes a scaffolding knowledge. This approach fosters vocabulary expansion function for the child, crucial for proximal development and deeper understanding of word meanings. Overall, processes: that is, the difference between an individual’s our design reflects a comprehensive approach to address actual level of development and the level that can be reading comprehension challenges reached, through the help of a tutor or through social interaction [40]. Therefore, the ARTIS project shows how it is necessary to take a holistic view in order to correctly interpret the issue of trustworthiness within an inclusive learning context. In particular, the ecological system theory elaborated by Bronfenbrenner turns out to be a strategic framework. According to the author of the ecological theory of 2 https://www.crc-balbuzie.it/ human development, there are two forms of proximal to trustworthy in inclusive education and speech and development processes: a) those with other persons and language therapy through the cooperation with a broad b) those with symbols and objects; and these processes number of stakeholders. Moreover, we outlined the occur in a dynamic of reciprocal influence and determi- general framework to carry on future research on the nation of several environmental levels: the microsystem ARTIS project rooted in an developmental ecological (in which interpersonal relationships occur directly and theory and cooperation strategies. Future work in this in defined contexts, such as family, school, peers), the area should focus on developing an integrated approach mesosystem (relationships between microsystems, for to assess the impact and acceptance of technology in example), the macrosystem (cultural and social norms), educational settings, with a particular emphasis on the exosystem (environments that influence indirectly, engaging a more diverse range stakeholders such as such as parental work) and the chronosystem (temporal teachers, children and families. Building upon existing changes, such as historical events and life transitions). research, future studies could explore innovative However, the nature of digital and AI technologies methodologies that combine quantitative metrics with is precisely to hybridise these systems and their inter- qualitative insights to gain a holistic understanding of actions [41]. The proximal process therefore occurs in the complex dynamics involved. Additionally, there is a a hybridised manner, involving both interpersonal re- need to investigate the long-term effects of technology lations and object relations, and collapsing the interac- integration on learning outcomes and socio-emotional tions between different levels even more directly, There- development across various age groups. Collaborative fore, it is crucial to ask, for example, in ARTIS how does efforts involving researchers, educators, policymakers, the macrosystem and exosystem (the decisions made by and technology developers will be essential to address the developers) affect the interactions in the microsys- the multifaceted concerns raised by teachers, families, tem? How does the hybridisation of the microsystem therapists, and children, thereby fostering a more (class, family, rehabilitation) reshape the concepts and inclusive and supportive educational environment. processes of inclusion? 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