从学生的表情出发,打造高效的翻转式神经科学实验室。

Zhuo Fu
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摘要

在大流行病期间,我们拍摄了神经科学实验室的视频,现在这些视频为翻转实验室提供了很好的资源。然而,我们的实验室涵盖了从大体解剖、免疫组化(IHC)染色、荧光成像到蟑螂显微手术、测量蠕虫和人体神经传导速度等各种复杂的课题,要让学生看完这些复杂的实验是很有挑战性的。学生在观看这些实验演示时面临的最大挑战是自己的情绪。我们在剪辑实验影片时,并没有降低复杂程度,而是用学生已经熟悉的概念和物品来解释概念,这样就不会引发学生的焦虑。为了减少枯燥感,我们主要采用了三种方法:提问、幽默和加快节奏。为了消除学生可能对亲自参加实验的部分产生的焦虑或不情愿,我们在每次实验课开始时都会提到,犯错误是完全可以接受的,而且在他们犯错误时,我们会帮助他们了解出错的原因以及如何改正。我们还在一些实验课上引入额外的活动,以激发他们的兴趣。例如,我们要求学生测试红牛对蟋蟀的影响,调查玩电子游戏越多的学生正中神经的传导速度是否越高。到目前为止,我们的翻转实验室在保持视频保留率和现场出勤率方面相当成功。蟑螂显微手术就是一个显著提高动手能力的例子。在实施翻转实验室之前,只有 10% 的学生能够成功完成手术并获得神经活动记录。而在翻转实验室中,90% 的学生都能独立获取记录。
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Making an Effective Flipped Neuroscience Lab by Approaching Students from Their Emoticons.

During the pandemic, we filmed our neuroscience labs, and now the videos provide a great resource to flip the lab. Our lab, however, covers a wide range of complicated topics, ranging from gross anatomy, immunohistochemistry (IHC) staining, and fluorescence imaging to cockroach microscopic surgery and measuring nerve conduction velocity on worms and human subjects, and it is challenging to get students to finish watching these complicated experiments. The biggest challenge that students face while watching these experiment demonstrations is their own emotions. When we were editing the films of the labs, we did not reduce the complexity, but we explained concepts by using concepts and objects that students are already familiar with so we do not trigger anxiety. To reduce boredom, we employed three major methods: questioning, humor, and increasing the pace. To address potential anxiety or reluctance about the in-person part of the lab, we mention at the beginning of every lab session that making mistakes is completely acceptable and, as they make mistakes, we help them understand what went wrong and how to correct it. We also introduce additional activities in some lab sessions to pique their interest. For instance, we ask students to test the effects of Red Bull on crickets and investigate whether students who play more video games have higher conduction velocities in the median nerve. Thus far, our flipped lab has been quite successful in terms of maintaining video retention rates and in-person attendance rates. A notable example of the effectiveness of improved hands-on skills is the cockroach microscopic surgery. Before implementing the flipped lab, only 10% of students were able to successfully complete the surgery and acquire nerve activity recordings. With the flipped lab, 90% of students were able to obtain a recording independently.

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