Janet M Dubinsky

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    Taking an educational psychology course improves neuroscience literacy but does not reduce belief in neuromyths
    (Public Library of Science, 2018-02-18) Im, Soo-hyun; Cho, Joo-Yun; Dubinsky, Janet M; Varma, Sashank
    Educators are increasingly interested in applying neuroscience findings to improve educational practice. However, their understanding of the brain often lags behind their enthusiasm for the brain. We propose that educational psychology can serve as a bridge between basic research in neuroscience and psychology on one hand and educational practice on the other. We evaluated whether taking an educational psychology course is associated with increased neuroscience literacy and reduced belief in neuromyths in a sample of South Korean pre-service teachers. The results showed that taking an educational psychology course was associated with the increased neuroscience literacy, but there was no impact on belief in neuromyths. We consider the implications of these and other findings of the study for redesigning educational psychology courses and textbooks for improving neuroscience literacy.
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    The neuroscience of active learning and direct instruction
    (Elsevier, 2024-05-23) Dubinsky, Janet M; Hamid, Arif A
    Throughout the educational system, students experiencing active learning pedagogy perform better and fail less than those taught through direct instruction. Can this be ascribed to differences in learning from a neuroscientific perspective? This review examines mechanistic, neuroscientific evidence that might explain differences in cognitive engagement contributing to learning outcomes between these instructional approaches. In classrooms, direct instruction comprehensively describes academic content, while active learning provides structured opportunities for learners to explore, apply, and manipulate content. Synaptic plasticity and its modulation by arousal or novelty are central to all learning and both approaches. As a form of social learning, direct instruction relies upon working memory. The reinforcement learning circuit, associated agency, curiosity, and peer-to-peer social interactions combine to enhance motivation, improve retention, and build higher-order-thinking skills in active learning environments. When working memory becomes overwhelmed, additionally engaging the reinforcement learning circuit improves retention, providing an explanation for the benefits of active learning. This analysis provides a mechanistic examination of how emerging neuroscience principles might inform pedagogical choices at all educational levels.
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    Acceptability of Neuroscientific Interventions in Education
    (Springer, 2021-08-05) Schmied, Astrid; Varma, Sashank; Dubinsky, Janet M
    Researchers are increasingly applying neuroscience technologies that probe or manipulate the brain to improve educational outcomes. However, their use remains fraught with ethical controversies. Here, we investigate the acceptability of neuroscience applications to educational practice in two groups of young adults: those studying bioscience who will be driving future basic neuroscience research and technology transfer, and those studying education who will be choosing among neuroscience- derived applications for their students. Respondents rated the acceptability of six scenarios describing neuroscience applications to education spanning multiple methodologies, from neuroimaging to neuroactive drugs to brain stimulation. They did so from two perspectives (student, teacher) and for three recipient populations (low-achieving, high-achieving students, students with learning disabilities). Overall, the biosciences students were more favorable to all neuroscience applications than the education students. Scenarios that measured brain activity (i.e., EEG or fMRI) to assess or predict intellectual abilities were deemed more acceptable than manipulations of mental activity by drug use or stimulation techniques, which may violate body integrity. Enhancement up to the norm for low-achieving students and especially students with learning disabilities was more favorably viewed than enhancement beyond the norm for high-achieving students. Finally, respondents rated neuroscientific applications to be less acceptable when adopting the perspective of a teacher than that of a student. Future studies should go beyond the acceptability ratings collected here to delineate the role that concepts of access, equity, authenticity, agency and personal choice play in guiding respondents’ reasoning.
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    Active Learning in a Neuroethics Course Positively Impacts Moral Judgment Development in Undergraduates
    (Faculty for Undergraduate Neuroscience, 2015-03-09) Abu-Odeh, Desiree; Dziobek, Derek; Torres Jimenez, Natalia; Barbey, Christopher; Dubinsky, Janet M
    The growing neuroscientific understanding of the biological basis of behaviors has profound social and ethical implications. To address the need for public awareness of the consequences of these advances, we developed an undergraduate neuroethics course, Neuroscience and Society, at the University of Minnesota. Course evolution, objectives, content, and impact are described here. To engage all students and facilitate undergraduate ethics education, this course employed daily reading, writing, and student discussion, case analysis, and team presentations with goals of fostering development of moral reasoning and judgment and introducing application of bioethical frameworks to topics raised by neuroscience. Pre- and post-course Defining Issues Test (DIT) scores and student end-of-course reflections demonstrated that course objectives for student application of bioethical frameworks to neuroethical issues were met. The active-learning, student-centered pedagogical approaches used to achieve these goals serve as a model for how to effectively teach neuroethics at the undergraduate level.
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    Tiered Neuroscience and Mental Health Professional Development in Liberia Improves Teacher Self-Efficacy, Self-Responsibility, and Motivation.
    (Frontiers Journals, 2021-05-11) Brick, Kara; Cooper, Janice L; Mason, Leona; Faeflen, Sangay; Monmia, Josiah; Dubinsky, Janet M
    After acquiring knowledge of the neuroscience of learning, memory, stress and emotions, teachers incorporate more cognitive engagement and student-centered practices into their lessons. However, the role understanding neuroscience plays in teachers own affective and motivational competencies has not yet been investigated. The goal of this study was to investigate how learning neuroscience effected teachers’ self-efficacy, beliefs in their ability to teach effectively, self-responsibility and other components of teacher motivation. A pilot training-of-trainers program was designed and delivered in Liberia combining basic neuroscience with information on social, emotional, behavioral and mental health issues faced by students. Tier I of the professional development was a 2 weeks workshop led by a visiting neuroscientist. A subset of the 24 Tier I secondary science teachers formed a Leadership Team who adapted the content to the Liberian context and subsequently led additional workshops and follow-up sessions for the Tier II secondary science teachers. Science teachers in both tiers completed the affective-motivational scales from the internationally vetted, multiscale Innovative Teaching for Effective Learning Teacher Knowledge Survey from the OECD. Tier II teachers completed the survey in a pre-post-delayed post design. Tier I teachers completed the survey after the workshop with their attitudes at that time and separately with retrospective projections of their pre-workshop attitudes. Ten of the 92 Tier II teachers participated in structured interviews at follow-up. Statistical analysis of survey data demonstrated improved teacher self-efficacy, self-responsibility for student outcomes, and motivation to teach. Qualitatively, teachers expressed more confidence in their ability to motivate students, engage them through active learning, and manage the class through positive rather than negative reinforcement. Teachers’ own self regulation improved as they made efforts to build supporting relationships with students. Together, these results demonstrated that (i) teacher affective-motivational attitudes can be altered with professional development, (ii) basic neuroscience, as knowledge of how students learn, can improve teacher competency, and (iii) a training-of-trainers model can be effective in a low and middle income country for disseminating neuroscience knowledge, increasing teachers’ knowledge of students’ social and emotional needs, and promoting educational improvement.
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    Neuroscience Concepts Changed Teachers’ Views of Pedagogy and Students
    (Frontiers Journals, 2021-08-11) Chang, Zhengsi; Schwartz, Mark S; Hinseley, Vicki; Dubinsky, Janet M
    Advances in neuroscience reveal how individual brains change as learning occurs. Translating this neuroscience into practice has largely been unidirectional, from researchers to teachers. However, how teachers view and incorporate neuroscience ideas in their classroom practices remains relatively unexplored. Previously fourteen non-science teachers participated in a 3-week three credit graduate course focusing on foundational ideas in neuroscience. The current work was undertaken to gain insight into if and how individual teachers choose to later apply the proposed set of educational neuroscience concepts (ENCs) in their classrooms. This qualitative follow up study examined commonalities in how teachers of diverse ages and subjects utilized their new neuroscience understandings. To this end, a year after the course, all participants assessed their perceived usefulness of the ENCs in a survey. Six of those teachers permitted classroom observations and participated in interviews that focused on how the ENCs may have influenced their lesson planning and teaching. The survey revealed that irrespective of subject areas or grade levels taught, teachers found the ENCs useful as organizing principles for their pedagogy now and in the future. Overall teachers estimated that the ENCs’ influence on lesson design had increased from 51% prior to the course to an estimated 90% for future lessons. A cross-case analysis of classroom observations and interviews revealed how teachers used ENCs to inform their pedagogical decisions, organize actions in their classroom, influence their understanding of students, and respond to individual contexts. Teachers recognized the importance of student agency for engaging them in the learning process. The ENCs also offered teachers explanations that affirmed known practices or helped justify exploring untried techniques. The foundational neuroscience concepts offered a small group of teachers a lens to reconsider, re-envision and re-design their lessons. Some teachers applied these ideas more broadly or frequently than others. This case study provided insights into how teachers can directly apply neuroscience knowledge to their practice and views of students.
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    Learning Neuroscience with Technology: a Scaffolded, Active Learning Approach
    (Springer, 2018-08-24) Schleisman, Katrina; Guzey, S. Selcen; Lie, Richard; Michlin, Michael; Desjardins, Christopher; Schackleton, Hazel; Schwerdfeger, August C.; Michalowski, Martin; Dubinsky, Janet M
    Mobile applications (apps) for learning technical scientific content are becoming increasingly popular in educational settings. Neuroscience is often considered complex and challenging for most students to understand conceptually. iNeuron is a recently developed iOS app that teaches basic neuroscience in the context of a series of scaffolded challenges to create neural circuits and increase understanding of nervous system structure and function. In this study, four different ways to implement the app within a classroom setting were explored. The goal of the study was to determine the app’s effectiveness under conditions closely approximating real-world use and to evaluate whether collaborative play and student-driven navigational features contributed to its effectiveness. Students used the app either individually or in small groups and used a version with either a fixed or variable learning sequence. Student performance on a pre- and post-neuroscience content assessment was analyzed and compared between students who used the app and a control group receiving standard instruction, and logged app data were analyzed. Significantly, greater learning gains were found for all students who used the app compared to control. All four implementation modes were effective in producing student learning gains relative to controls, but did not differ in their effectiveness to one another. In addition, students demonstrated transfer of information learned in one context to another within the app. These results suggest that teacher-led neuroscience instruction can be effectively supported by a scaffolded, technology-based curriculum which can be implemented in multiple ways to enhance student learning.
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    Infusing Neuroscience Into Teacher Professional Development
    (American Educational Research Association, 2013-08-01) Dubinsky, Janet M; Roehrig, Gillian; Varma, Sashank
    Bruer advocated connecting neuroscience and education indirectly through the intermediate discipline of psychology. We argue for a parallel route: The neurobiology of learning, and in particular the core concept of plasticity, have the potential to directly transform teacher preparation and professional development, and ultimately to affect how students think about their own learning. We present a case study of how the core concepts of neuroscience can be brought to in-service teachers—the BrainU workshops. We then discuss how neuroscience can be meaningfully integrated into preservice teacher preparation, focusing on institutional and cultural barriers.
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    Neuroscientists’ Classroom Visits Positively Impact Student Attitudes
    (PLOS one, 2013-12-16) Fitzakerley, Janet; Michlin, Michael; Paton, John; Dubinsky, Janet M
    The primary recommendation of the 2010 President’s Council of Advisors on Science and Technology report on K-12 education was to inspire more students so that they are motivated to study science. Scientists’ visits to classrooms are intended to inspire learners and increase their interest in science, but verifications of this impact are largely qualitative. Our primary goal was to evaluate the impact of a longstanding Brain Awareness classroom visit program focused on increasing learners understanding of their own brains. Educational psychologists have established that neuroscience training sessions can improve academic performance and shift attitudes of students from a fixed mindset to a growth mindset. Our secondary goal was to determine whether short interactive Brain Awareness scientist-in-the-classroom sessions could similarly alter learners’ perceptions of their own potential to learn. Teacher and student surveys were administered in 4th-6th grade classrooms throughout Minnesota either before or after one hour Brain Awareness sessions that engaged students in activities related to brain function. Teachers rated the Brain Awareness program as very valuable and said that the visits stimulated students’ interest in the brain and in science. Student surveys probed general attitudes towards science and their knowledge of neuroscience concepts (particularly the ability of the brain to change). Significant favorable improvements were found on 10 of 18 survey statements. Factor analyses of 4805 responses demonstrated that Brain Awareness presentations increased positive attitudes toward science and improved agreement with statements related to growth mindset. Overall effect sizes were small, consistent with the short length of the presentations. Thus, the impact of Brain Awareness presentations was positive and proportional to the efforts expended, demonstrating that short, scientist-in-the-classroom visits can make a positive contribution to primary school students’ attitudes toward science and learning.
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    Teaching Neuroscience to Science Teachers: Facilitating the Translation of Inquiry-Based Teaching Instruction to the Classroom
    (The American Society for Cell Biology, 2012-07-30) Roehrig, Gillian; Michlin, Michael; Schmitt, Lee; MacNabb, Carrie; Dubinsky, Janet M
    In science education, inquiry-based approaches to teaching and learning provide a framework for students to building critical-thinking and problem-solving skills. Teacher professional development has been an ongoing focus for promoting such educational reforms. However, despite a strong consensus regarding best practices for professional development, relatively little systematic research has documented classroom changes consequent to these experiences. This paper reports on the impact of sustained, multiyear professional development in a program that combined neuroscience content and knowledge of the neurobiology of learning with inquiry-based pedagogy on teachers’ inquiry-based practices. Classroom observations demonstrated the value of multiyear professional development in solidifying adoption of inquiry-based practices and cultivating progressive yearly growth in the cognitive environment of impacted classrooms
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    Neuroscience Education for Prekindergarten–12 Teachers
    (The Society for Neuroscience, 2010-06-16) Dubinsky, Janet M
    A debate rages concerning the ability of neuroscience to inform prekindergarten–12 teaching practice (Hirsh-Pasek and Bruer, 2007; Varma et al., 2008). Some educators charged with training future teachers argue that the mechanistic issues that concern neuroscientists are too far removed from the classroom context to be able to effectively inform practice (Hirsh-Pasek and Bruer, 2007). At the far end of our field, neuroscientists attempt to apply the techniques of cognitive neuroscience to educationally relevant issues. Understanding the physiological processes mediating dyslexia or attention-deficit hyperactivity disorder has the potential to lead to biomarkers for diagnosis and strategies for successful early interventions (Fischer, 2009; Goswami, 2009). Studies of the cognitive capacities of infants and toddlers are leading to strategies for incorporating innate lexical and mathematical abilities into educational progressions (Meltzoff et al., 2009; Gilmore et al., 2010). Psychologists view neuroscience research as providing the physiological justification for the behavioral interventions they have long studied (Diamond and Amso, 2008). Businessmen view neuroscience as an exploitable body of information that can be used to successfully market educational products and services (e.g., Jensen Learning, Brain Gym). Teachers view neuroscience as a complicated body of knowledge that may explain what goes on in their students’ heads (Brandt, 1999). Teachers feel that they need to understand both. However, the majority of neuroscientists are unaware of all of these issues.
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    Altered Reality. An inquiry-based neuroscience lesson for helping students understand neuroplasticity and its role in learning
    (National Science Teachers Association, 2020) Ellingson, Charlene; Dubinsky, Janet M
    Effective science instruction requires knowledge of subject matter and scientific practices (Next Generation Science Standards (NGSS), 2013), as well as the context within which learning occurs (Anthony, Hunter and Hunter, 2014). For science teachers, there is often a tension between the efficiency of lecture and student engagement that comes with hands-on activities. In this article, we present Altered Reality, an inquiry-based neuroscience lesson that can bridge the gap between efficiency and engagement by concurrently teaching neuroscience, scientific practices, and modelling neuroplasticity.
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    Neuroscience knowledge enriches pedagogical choices
    (Elsevier, 2019-04-19) Schwartz, Mark S; Hinesley, Vicki; Chang, Zhengsi; Dubinsky, Janet M
    Teachers face a daunting challenge in balancing the demands of employing student-centered pedagogies in contexts where mandated testing and district teaching expectations can easily constrain or compromise their pedagogy. In this pilot study, we investigated how professional development based on the “neuroscience of learning” impacted non-science teacher understanding of basic neuroscience; and, in turn, how that knowledge impacted their reflections on pedagogy. In a pre/post design, teacher understanding of neuroscience improved significantly after the 36-h course based upon a set of educational neuroscience concepts. Furthermore, teacher revisions of their lesson plans after the course revealed the integration of more student-centered pedagogies.
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    Training-of-Trainers Neuroscience and Mental Health Teacher Education in Liberia Improves Self-Reported Support for Students
    (Frontiers Journals, 2021-06-18) Brick, Kara; Cooper, Janice L; Mason, Leona; Faeflen, Sangay; Monmia, Josiah; Dubinsky, Janet M
    Education programs have been central to reestablishing social norms, rebuilding public educational institutions, and addressing public attitudes toward mental illness in Liberia following a protracted civil war and the Ebola epidemic. The aim of this study was to determine if a program combining an understanding of neuroscience with mental health literacy content could increase teachers’ awareness of students’ mental health issues and produce changes in teacher attitudes and classroom practices. A tiered Training-of-Trainers approach was employed. The first workshop trained 24 Liberian secondary science teachers in the neurobiology of learning, memory, emotions, stress and adolescent brain development. A Leadership Team formed from eight of the Tier I participants then adapted the curriculum, added in more mental health literacy content and led four Tier II workshops and four follow-up Refresher sessions. Participants completed a neuroscience knowledge test and surveys assessing stigma, general perceptions of people with mental illness, and burnout. A subset of Tier II teachers participated in a structured interview at the Refresher time point. Teachers in both tiers acquired basic neuroscience knowledge. Tier I, but not Tier II teachers significantly improved their surveyed attitudes toward people with mental illness. No changes were found in overall teacher burnout. Despite these survey results, the interviewed Tier II teachers self-reported behavioral changes in how they approached their teaching and students in their classrooms. Interviewees described how they now understood social and emotional challenges students might be experiencing and recognized abnormal behaviors as having a biopsychosocial basis. Teachers reported reduced use of verbal and corporal punishment and increased positive rewards systems, such as social and emotional support for students through building relationships. Refresher discussions concurred with the interviewees. In contrast to previous teacher mental health literacy programs which did not bring about a change in helping behaviors, this pilot program may have been successful in changing teacher knowledge and self-reported behaviors, improving teacher–student relationships and decreasing harsh discipline. The combination of basic neuroscience concepts with training on how to recognize mental health issues and refer students should be investigated further as a strategy to promote teacher mental health literacy.
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    A Place for Neuroscience in Teacher Knowledge and Education
    (Mind, Brain, and Education published by International Mind, Brain, and Education Society and Wiley Periodicals LLC., 2022-08-22) Dubinsky, Janet M; Roehrig, Gillian; Varma, Sashank
    The foundational contributions from neuroscience regarding how learning occurs in the brain reside within one of Shulman’s seven components of teacher knowledge, Knowledge of Students. While Knowledge of Students combines inputs from multiple social science disciplines that traditionally inform teacher education, teachers must also (and increasingly) know what happens inside students’ brains. Neuroscience professional development provides neuroscience principles that teachers can learn and apply to distinguish among pedagogical choices, plan lessons, guide in-the-moment classroom decisions, and inform the views of students. Neuroscience does not directly invent new pedagogies. Rather, knowledge of neuroscience guides teachers in choosing appropriate pedagogies, pragmatically informing teaching. By providing physiological explanations for psychological phenomena relevant to education, teachers benefit from neuroscience content in their training and professional development.
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    Neuroscience in Middle Schools: A Professional Development and Resource Program That Models Inquiry-based Strategies and Engages Teachers in Classroom Implementation
    (The American Society for Cell Biology, 2006-02-07) MacNabb, Carrie; Schmitt, Lee; Michlin, Michael; Harris, Ilene; Thomas, Larry; Chittendon, David; Ebner, Timothy J; Dubinsky, Janet M
    The Department of Neuroscience at the University of Minnesota and the Science Museum of Minnesota have developed and implemented a successful program for middle school (grades 5–8) science teachers and their students, called Brain Science on the Move. The overall goals have been to bring neuroscience education to underserved schools, excite students about science, improve their understanding of neuroscience, and foster partnerships between scientists and educators. The program includes BrainU, a teacher professional development institute; Explain Your Brain Assembly and Exhibit Stations, multimedia large-group presentation and hands-on activities designed to stimulate student thinking about the brain; Class Activities, in-depth inquiry-based investigations; and Brain Trunks, materials and resources related to class activities. Formal evaluation of the program indicated that teacher neuroscience knowledge, self-confidence, and use of inquiry-based strategies and neuroscience in their classrooms have increased. Participating teachers increased the time spent teaching neuroscience and devoted more time to “inquiry-based” teaching versus “lecture-based teaching.” Teachers appreciated in-depth discussions of pedagogy and science and opportunities for collegial interactions with world-class researchers. Student interest in the brain and in science increased. Since attending BrainU, participating teachers have reported increased enthusiasm about teaching and have become local neuroscience experts within their school communities.
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    Connecting the Dots from Professional Development to Student Learning
    (American Society for Cell Biology, 2021-12-01) Ellingson, Charlene L; Edwards, Katherine; Roehrig, Gillian H; Hoelscher, M. Clark; Haroldson, Rachelle A; Dubinsky, Janet M
    Following professional development (PD), implementation of contemporary topics into high school biology requires teachers to make critical decisions regarding integration of novel content into existing course scope and sequence. Often exciting topics, such as neuroscience, do not perfectly align with standards. Despite commitment to enacting what was learned in the PD, teachers must adapt novel content to their perceptions of good teaching, local context, prior knowledge of their students, and state and district expectations. How teachers decide to integrate curricula encountered from PD programs may affect student outcomes. This mixed-methods study examined the relationship between curricular application strategies following an inquiry-based neuroscience PD and student learning. Post-PD curricular implementation was measured qualitatively through analysis of teacher action plans and classroom observations and quantitatively using hierarchical linear modeling to determine the impact of implementation on student performance. Participation in neuroscience PD predicted improved student learning compared with control teachers. Of the two distinct curricular implementation strategies, enacting a full unit produced significantly greater student learning than integrating neuroscience activities into existing biology units. Insights from this analysis should inform teacher implementation of new curricula after PD on other contemporary biology topics.
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    Acceptability of Neuroscientific Interventions in Education
    (2021-03-22) Schmied, Astrid; Varma, Sashank; Dubinsky, Janet M; sashank@umn.edu; Varma, Sashank; University of Minnesota Departments of Neuroscience and Educational Psychology
    Researchers are increasingly applying neuroscience technologies that probe or manipulate the brain to improve educational outcomes. However, their use remains fraught with ethical controversies. Here, we investigate the acceptability of neuroscience applications to educational practice in two groups of young adults: those studying bioscience who will be driving future basic neuroscience research and technology transfer, and those studying education who will be choosing among neuroscience-derived applications for their students. Respondents rated the acceptability of six scenarios describing neuroscience applications to education spanning multiple methodologies, from neuroimaging to neuroactive drugs to brain stimulation. They did so from two perspectives (student, teacher) and for three recipient populations (low-achieving, high-achieving students, students with learning disabilities). Overall, the bioscience students were more favorable to all neuroscience applications than the education students. Scenarios that measured brain activity (i.e., EEG or fMRI) to assess or predict intellectual abilities were deemed more acceptable than manipulations of mental activity by drug use or stimulation techniques, which may violate body integrity. Enhancement up to the norm for low-achieving students and especially students with learning disabilities was more favorably viewed than enhancement beyond the norm for high-achieving students. Finally, respondents rated neuroscientific applications to be less acceptable when adopting the perspective of a teacher than that of a student. Future studies should go beyond the coarse acceptability ratings collected here to delineate the role that concepts of access, equity, authenticity, agency and personal choice play in guiding respondents’ reasoning.
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    Abnormal Recovery from Acute Stress in Huntingtons Disease Mice
    (2018-03-12) Zacharoff, Lori; Hamid, Arif; Engeland, William C; Dubinsky, Janet M; dubin001@umn.edu; Dubinsky, Janet M
    Comparisons of hypothalamic dysfunction between Huntington’s Disease (HD) patients and rodent models of HD have not always yielded similar results. Cortisol levels in HD patients have been contradictory, with reports ranging from hypo- to hypercorticoidism of morning measurements. Initial reports of major elevations in circulating corticosterone levels in the R6/2 mouse model of HD have only been followed up in one other closely related model, the R6/1 mouse, and the results were not perfectly congruent. To determine if abnormal stress hormones were a characteristic of disease, we examined diurnal and stress-induced corticosterone levels in multiple HD mouse models.