Overcoming Obstacles for the Inclusion of Visually Impaired Learners through Teacher–Researcher Collaborative Design and Implementation
Abstract
:1. Introduction and Literature Review
“Adaptive teaching is an important area in the CCF [Core Content Framework]. Alongside important content relating to the most effective approaches to adapting teaching in response to pupil needs, it sets out some specific content relating to knowledge and experience that all trainees must acquire relating specifically to pupils with Special Educational Needs and Disabilities (SEND). It is critical that all teachers begin their teaching career with adequate basic knowledge and expertise in this area, and all ITT curriculums, whatever the context, must set out specific content relating to SEND which trainees will learn and put into practice during training. As with all areas of the trainee curriculum, learning about SEND must be planned and specific, and there must be an assurance that all trainees have covered and learnt what has been planned.”([5] p. 13)
“… alongside the universal SEND knowledge and expertise which all trainees should possess, there is scope for those preparing to specialise in SEND, either in specialist provision or in mainstream schools, to be able to access a specialist training curriculum that focuses in more depth on SEND-relevant knowledge and expertise. Such a training curriculum, which must be rigorously evidence based, should equally meet the expectations for detailed and specific planning, as should the expectations for school placement and mentoring, to ensure that the curriculum is delivered to trainees with the same standard of quality and consistency that we envisage elsewhere.”([5] p. 13-14)
2. Theoretical Framework
2.1. Influences from the Social Model of Disability
2.2. Influences from the Vygotskian Sociocultural Theory of Learning
“The positive particularity of a child with a disability is created not by the failure of one or other function observed in a normal child but by the new structures which result from this absence […] The blind or deaf child can achieve the same level of development as the normal child, but through a different mode, a distinct path, by other means. And for the pedagogue, it is particularly important to know the uniqueness of the path along with the child should be led”.([21] p. 17)
2.3. Influences from Gallese and Lakoff’s Theory of Embodied Cognition
3. Methodology
3.1. The Research Design of the Study
3.2. Context and Participants of the Study
3.3. Data Collection
3.4. Data Analysis
4. Data Analysis and Findings
4.1. Opportunities and Challenges in Digital/Physical Resource Use for Inclusive Mathematics Education (and MTE Issues Thereof)
4.1.1. Teacher Positioning: When Teaching Becomes Inadvertently Inaccessible
4.1.2. A VI Pupil’s Desire to Not Stand out and School Narratives about Disability as Deficit, Not Difference
4.1.3. Coordinating a Teacher’s and a Teaching Assistant’s Interventions in Assisting a VI Pupil
and from a teacher’s point of view,“The students had explained to us that it was rare for them to interact with representations of geometrical shapes, and an important aspect of designing the tasks was to produce tactile materials that would make this possible”([24] p. 134)
“According to the two teachers the lack of materials had a great impact on Nefeli’s haptic apprehension and for this the researchers prepared and provided the teachers material following exactly the activities suggested in the school textbook”.([6] p. 129)
4.2. Teacher–Researcher Collaborative Design and Implementation of Inclusive Mathematics Lessons (and Critical Reflection Thereof)
4.2.1. Overview of Design Priorities and Issues
4.2.2. First Auditory Task on Number Sequences
- discern numbers;
- discern number sequences;
- say what the next number is in the sequences;
- explore place value;
- say if the sequence increases or decreases—and by how much.
“I did think music still allowed him to access that, so often Ned is not focussed—I mean he is not looking at the board, so he is missing key learning—but, because he wasn’t looking necessarily up, I think maybe he can still listen to what was going on, so he could still kind of grasp what was going on.”
4.2.3. Second Auditory Task on Number Sequences
- discern number sequences
- express the rule in the sequences
- create number sequences
- The VI pupil (Ivor) was better included in the class, he was no longer a separate member from the sighted community of learners. Ivor particularly acknowledged that today’s mathematics lesson was “[t]otally different” to the one he normally has. One of the differences that he pointed to was that “we were put in partners today”. He pinpointed that he likes working with a peer because “[t]hey can help one another”. He found it “[k]ind of easy and odd” that he did not work with the teaching assistant tin the lesson: “Easy because it was just like stuff and sequences, and I just knew what sequences were”;
- There was mutual appreciation between the VI pupil and his sighted peer (Frank), both mathematically and socially. For example, Ivor helped Frank with the last number in their sequence: While Ivor correctly did not play any Tens for “6”, Frank did not play any Ones—he possibly thought that it was Ivor’s turn and he did not look at the number. Ivor made a facial expression to Frank showing that it was Frank who had to play that number. Frank played it. Therefore, while in Phase 1 Ivor was helped by others and appeared to be weak and distracted in Mathematics, in Phase 2 Ivor helped his sighted peer. This finding from Phase 2 illustrates Ivor’s very good understanding of place value and also the very good collaborative skills between Ivor and his partner;
- Pupils liked the collaborative production of mathematical ideas.
- All children participated in and were actively engaged in the lesson;
- There seemed to be no pattern in the work of High Achieving Pupils (HAPs), Middle Achieving Pupils (MAPs) and Low Achieving Pupils (LAPs) in the auditory task. This task helped blur the boundaries across ability groups (and cast some doubt on the utility and purpose of such groupings). Specifically, some LAPs found it easy and some HAPs found it hard. This finding raises the need to discuss on which terms “ability groups” are decided and how accurate these decisions are.
- the pupils’ active involvement in the construction of mathematics through music;
- the rest of the class’s development of the auditory modality in the construction of mathematical meaning. For example, Ivor told the first author that “listening to the bits of music” and “listen[ing] […] about the sequences” were what made him concentrate. In Phase 1, Ivor told her that he felt distracted and did not concentrate much in the lesson when he did not work with the teaching assistant. In the Phase 2 lesson, he told her that he concentrated even though he did not work with the teaching assistant. He also told her that, in the Phase 2 lesson, he did not find it hard to follow the lesson from the class teacher. In Phase 1, he told her that he found it hard to follow the maths lesson from his class teacher and that he instead found it helpful to work with the teaching assistant in mathematics. He specifically said: “I couldn’t keep up with the teacher but now I can”.
4.2.4. First Tactile Task, Number Sequences
- ‘read’ numbers. We enclose “read” in quotation marks because this term is contextualised in this task differently—not through the visual sense. More specifically, “read” is contextualised as discerning numbers through the tactile sense;
- discern number sequences;
- explore place value.
4.2.5. Second Tactile Task, Shapes
- name particular shapes (e.g., “rectangle”, “hexagon”);
- discern whether these particular shapes are 2D or 3D;
- name the properties of these particular shapes with regard to
- ○
- sides: number of sides, if any sides are equal to each other, if any sides are parallel to each other, if there are straight and/or curved sides
- ○
- vertices: number of vertices
- ○
- angles: number of angles, types of angles.
- Touch allowed pupils to “count the edges, sides, corners and vertices”;
- Touch allowed pupils to realise “the hidden facts on the shapes”;
- Touch allowed pupils to “have to feel around to get it”;
- Touch allowed pupils to “realis[e] […] the differences”;
- Touch allowed pupils to “move the shapes”.
- “touching the shapes and describing them”;
- “closing my eyes and feeling the shapes, trying to figure out what they were”;
- “picking into the bag and describing it”;
- “the different way to learn about shapes”;
- “feeling the shape and getting it correct”;
- “feeling” the shapes/the “feel” of the shapes;
- the “weird” feeling that touch generated for them.
- gestures as a tool for construction—and expression—of mathematical meaning. Gestures were particularly used by sighted pupils, the VI pupil, and the teacher in the construction and expression of mathematical meaning;
- the verbal mathematical language that is elicited through tactile experiences (e.g., “it feels”).
5. Towards Inclusive Mathematics Classrooms: Implications for Teacher Education
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
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Stylianidou, A.; Nardi, E. Overcoming Obstacles for the Inclusion of Visually Impaired Learners through Teacher–Researcher Collaborative Design and Implementation. Educ. Sci. 2023, 13, 973. https://doi.org/10.3390/educsci13100973
Stylianidou A, Nardi E. Overcoming Obstacles for the Inclusion of Visually Impaired Learners through Teacher–Researcher Collaborative Design and Implementation. Education Sciences. 2023; 13(10):973. https://doi.org/10.3390/educsci13100973
Chicago/Turabian StyleStylianidou, Angeliki, and Elena Nardi. 2023. "Overcoming Obstacles for the Inclusion of Visually Impaired Learners through Teacher–Researcher Collaborative Design and Implementation" Education Sciences 13, no. 10: 973. https://doi.org/10.3390/educsci13100973
APA StyleStylianidou, A., & Nardi, E. (2023). Overcoming Obstacles for the Inclusion of Visually Impaired Learners through Teacher–Researcher Collaborative Design and Implementation. Education Sciences, 13(10), 973. https://doi.org/10.3390/educsci13100973