Assembling a physical model helps students grasp human somatosensory pathways.

IF 1.7 4区 教育学 Q2 EDUCATION, SCIENTIFIC DISCIPLINES Advances in Physiology Education Pub Date : 2024-12-01 DOI:10.1152/advan.00092.2024
Jeremy S Morris, G R Davis, Lori Cruze, John F Moeller, Stacey R Hettes
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引用次数: 0

Abstract

Mastering the complexity of the nervous system is essential for education programs in physiology, anatomy, and neuroscience. Students often struggle when learning somatosensory pathways, which convey information from sensory neurons to the somatosensory cortex in the brain. Active learning activities incorporating physical models have been shown to increase content comprehension as well as enjoyment of the learning process. Here, we present a three-dimensional physical model of somatosensory pathways constructed of durable, affordable, and widely available materials. In an upper level human physiology lab, students assembled the model and then used it to complete case study questions connecting damage to the spinal cord to resulting sensory deficits. This model-based activity was highly effective as indicated by significant increases in content knowledge and positive responses to survey questions on the effectiveness of the activity. This activity incorporates many evidence-based teaching practices that have been shown to increase engagement, inclusion, and mastery of content and provides an effective and fun way for students to learn a challenging topic.NEW & NOTEWORTHY This model-building activity for learning somatosensory neural pathways increases students' content knowledge and is an enjoyable way to learn a complex system. This activity adds to an ever-growing collection of evidence-based learning activities for human physiology courses.

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组装实物模型有助于学生掌握人类的躯体感觉通路。
掌握神经系统的复杂性对于生理学、解剖学和神经科学的教学计划至关重要。学生在学习从感觉神经元向大脑躯体感觉皮层传递信息的躯体感觉通路时往往会感到吃力。事实证明,结合物理模型的主动学习活动可以提高对学习内容的理解,并增加学习过程的乐趣。在此,我们介绍一种三维躯体感觉通路物理模型,该模型由耐用、经济和广泛使用的材料制成。在一个高年级人体生理学实验室中,学生们组装了该模型,然后用它来完成案例研究问题,将脊髓损伤与由此导致的感觉障碍联系起来。这项以模型为基础的活动效果显著,学生们在活动中掌握了大量知识,并对活动效果的调查问题做出了积极回应。这项活动结合了许多循证教学实践,这些实践已被证明能提高学生的参与度、融入度和对内容的掌握程度,并为学生提供了一种有效而有趣的方式来学习一个具有挑战性的课题。本活动为日益增多的人体生理学课程循证学习活动锦上添花。
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来源期刊
CiteScore
3.40
自引率
19.00%
发文量
100
审稿时长
>12 weeks
期刊介绍: Advances in Physiology Education promotes and disseminates educational scholarship in order to enhance teaching and learning of physiology, neuroscience and pathophysiology. The journal publishes peer-reviewed descriptions of innovations that improve teaching in the classroom and laboratory, essays on education, and review articles based on our current understanding of physiological mechanisms. Submissions that evaluate new technologies for teaching and research, and educational pedagogy, are especially welcome. The audience for the journal includes educators at all levels: K–12, undergraduate, graduate, and professional programs.
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