Brains–Computers–Machines: Neural Engineering in Science Classrooms     

Eric H. Chudler  Kristen Clapper Bergsman 《CBE life sciences education》2016,15(1)

Neural engineering is an emerging field of high relevance to students, teachers, and the general public. This Feature presents online resources that educators and scientists can use to introduce students to neural engineering and to integrate core ideas from the life sciences, physical sciences, social sciences, computer science, and engineering into the classroom.  相似文献   

Does mathematics have a life of its own?     

James Robert Brown 《Metascience》2011,20(3):487-493

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Blurring the Line between Mosque and State: Public Education in the Twin Cities     

Katherine Kersten 《Academic Questions》2011,24(1):32-49

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Academe’s House Divided     

Daniel B. Klein 《Academic Questions》2011,24(3):365-370

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U Crazy     

Harry Stein 《Academic Questions》2011,24(4):489-493

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Bubble Trouble     

Carol Iannone 《Academic Questions》2011,24(3):258-261

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Catholic in Name Only     

Anne Hendershott 《Academic Questions》2011,24(3):376-383

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Decoding general relativity     

Daniel Kennefick 《Metascience》2011,20(1):91-93

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Neuroanatomy Learning: Augmented Reality vs. Cross-Sections     

Dylan J.H.A. Henssen  Loes van den Heuvel  Guido De Jong  Marc A.T.M. Vorstenbosch  Anne-Marie van Cappellen van Walsum  Marianne M. Van den Hurk  Jan G.M. Kooloos  Ronald H.M.A. Bartels 《Anatomical sciences education》2020,13(3):353-365

Neuroanatomy education is a challenging field which could benefit from modern innovations, such as augmented reality (AR) applications. This study investigates the differences on test scores, cognitive load, and motivation after neuroanatomy learning using AR applications or using cross-sections of the brain. Prior to two practical assignments, a pretest (extended matching questions, double-choice questions and a test on cross-sectional anatomy) and a mental rotation test (MRT) were completed. Sex and MRT scores were used to stratify students over the two groups. The two practical assignments were designed to study (1) general brain anatomy and (2) subcortical structures. Subsequently, participants completed a posttest similar to the pretest and a motivational questionnaire. Finally, a focus group interview was conducted to appraise participants’ perceptions. Medical and biomedical students (n = 31); 19 males (61.3%) and 12 females (38.7%), mean age 19.2 ± 1.7 years participated in this experiment. Students who worked with cross-sections (n = 16) showed significantly more improvement on test scores than students who worked with GreyMapp-AR (P = 0.035) (n = 15). Further analysis showed that this difference was primarily caused by significant improvement on the cross-sectional questions. Students in the cross-section group, moreover, experienced a significantly higher germane (P = 0.009) and extraneous cognitive load (P = 0.016) than students in the GreyMapp-AR group. No significant differences were found in motivational scores. To conclude, this study suggests that AR applications can play a role in future anatomy education as an add-on educational tool, especially in learning three-dimensional relations of anatomical structures.  相似文献   

Concepts and interests in twentieth-century health policy     

Cecily Hunter 《Metascience》2016,25(1):71-74

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