让学生参与在线群体遗传学:遗传轮活动

IF 1.2 4区 教育学 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY Biochemistry and Molecular Biology Education Pub Date : 2023-03-20 DOI:10.1002/bmb.21722
Lara Grollo, Daniel Andrews, Lauren Salo
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引用次数: 0

摘要

随着2020-2021年为应对COVID-19大流行而转向在线学习,许多高等教育工作者发现学生的参与度明显下降。1-3澳大利亚大学的可取之处是在疫情之前全部门对在线学习管理系统(LMS)的投资,为在线学生参与提供了一个可用的(如果以前未充分利用的话)平台然而,正如Harsha等人5所说,有大量的电子学习技术可用于在线教学,但重要的是要选择适合目的的技术,从而促进学生的参与。在这里,我们描述了一种方法,通过使用遗传轮活动的在线版本,向学生介绍群体遗传学的概念。群体遗传学是对特定群体内遗传变异的研究。在一个健康的人群中,有各种各样的基因,它们以多种方式结合在一起,形成我们在个体中看到的各种各样的特征。遗传轮是一项活动,通常用于高中和入门级的三级生物学,以调查人类在七个可见的单基因性状上的变异。这些都是相对简单的特征,通常由一个基因控制,人们要么表现出来,要么不表现出来。该活动使学生能够依次评估每个特征的存在与否,最终根据他们的特征得出一个单一的数字(1-128),他们可以实时与同龄人进行比较。在BIOM10002:探索生物医学中,遗传车轮很容易转化为在线活动,因此被用作向学生介绍群体遗传学的工具。在Zoom介绍了遗传轮理论以及如何识别每个特征之后,学生被随机分配到20个分组讨论室(≈6名学生)中的一个。最初,每个学生决定自己的“遗传轮号”。然后,他们可以选择与小组分享他们的数字,并讨论与遗传轮有关的问题,以及种群中遗传多样性的重要性和影响。随后,每个学生被要求匿名在轮盘的交互式课堂视觉上标记自己的数字(图1)。这个交互式轮盘是在PollEv中开发的,但也可以在Padlet或Miro等免费平台上轻松创建。这提供了一个更大的群体(约120名学生)遗传多样性模式的图片。学生们发现这项活动非常吸引人,因为他们很容易将任务与自己联系起来(自我情境),同时也能以一种安全、无评判的方式将自己与更广泛的群体进行比较。一旦PollEV被填满,学生们就被带回到主要的Zoom房间进行小组讨论,并解开与活动相关的挑战问题。学生们通过麦克风或Zoom聊天选项来回应。当每个班级完成练习时,遗传之轮的结果被合并。这使学生们能够理解遗传多样性和群体大小之间的关系(约650名学生)。在所有课程完成后,活动(匿名数据)被放置在LMS上供学生查看。遗传车轮活动为学生提供了一个易于访问的平台,可以在在线环境中调查他们自己和他们的队列的遗传变异。
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Engaging students in population genetics online: Genetic wheel activity

With the switch to online learning in 2020–2021 in response to the COVID-19 pandemic, many tertiary educators saw a marked decline in student engagement.1-3 The saving grace for Australian universities was the sector-wide investment in online learning management systems (LMS) prior to the pandemic, providing an available, if previously underutilized platform for online student engagement.4 However, as Harsha et al.5 state, there is an immense amount of e-learning technology available for teaching online, but it is important to select the one(s) that are fit for purpose, and consequently facilitate student engagement. Here we describe a method for introducing students to the concept of population genetics by using an online version of the Genetic Wheel activity.

Population genetics is the study of genetic variation within a given population. In a healthy population there is a wide variety of genes that combine in many ways to form the broad diversity of characteristics we see in individuals. The Genetic Wheel is an activity which is commonly used both in high schools and introductory level tertiary biology to investigate human variation in seven visible, single gene traits. These are relatively simple traits, generally controlled by one gene, which people either exhibit or not. The activity enables students to sequentially assess the presence or absence of each trait to ultimately derive a single number (1–128) based on their traits, which they can compare to their peers in real time.

In BIOM10002: Exploring Biomedicine, the Genetic Wheel easily converted to an online activity and so used as a tool to introduce students to population genetics. Following a Zoom presentation outlining the Genetic Wheel theory and how to identify each trait, students were then randomly assigned to one of 20 breakout rooms (≈ 6 students). Initially each student determined their individual “Genetic Wheel number”. They then had the option to share their number with the small group and discuss the questions relating to the Genetic Wheel and the importance of, and influences on, genetic diversity in the population. Subsequently, each student was asked to anonymously place a marker on their number on an interactive class visual of the wheel (Figure 1). This interactive wheel was developed in PollEv but could also be readily created in free platforms like Padlet or Miro. This provided a picture of the patterns of genetic diversity in a larger population (≈ 120 students).

The students found this activity highly engaging as they were easily able to relate the task to themselves (self-context), while also comparing themselves to the wider cohort in a safe, non-judgment-free way. Once the PollEV was populated, students were brought back to the main Zoom room for a group discussion and to unpack the challenge questions related to the activity. Students responded by either microphone or the Zoom chat option.

As each class completed the exercise, the Genetic Wheel results were merged. This allowed the students to appreciate the relationship between genetic diversity and population size (≈650 students). After all classes were complete, the activity the anonymous data was placed on the LMS for the students to view. The Genetic Wheel activity provided a readily accessible platform for students to investigate genetic variation in themselves and their cohort in an online environment.

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来源期刊
Biochemistry and Molecular Biology Education
Biochemistry and Molecular Biology Education 生物-生化与分子生物学
CiteScore
2.60
自引率
14.30%
发文量
99
审稿时长
6-12 weeks
期刊介绍: The aim of BAMBED is to enhance teacher preparation and student learning in Biochemistry, Molecular Biology, and related sciences such as Biophysics and Cell Biology, by promoting the world-wide dissemination of educational materials. BAMBED seeks and communicates articles on many topics, including: Innovative techniques in teaching and learning. New pedagogical approaches. Research in biochemistry and molecular biology education. Reviews on emerging areas of Biochemistry and Molecular Biology to provide background for the preparation of lectures, seminars, student presentations, dissertations, etc. Historical Reviews describing "Paths to Discovery". Novel and proven laboratory experiments that have both skill-building and discovery-based characteristics. Reviews of relevant textbooks, software, and websites. Descriptions of software for educational use. Descriptions of multimedia materials such as tutorials on various aspects of biochemistry and molecular biology.
期刊最新文献
Issue Information Cinemeducation improves early clinical exposure to inborn errors of metabolism. The development of supplemental multimedia learning modules and their impact on student learning in food biotechnology courses. Encourage self-learning and collaborative learning through gamification during COVID-19 pandemic: A case study for teaching biochemistry. A plant mutant screen CURE integrated with core biology concepts showed effectiveness in course design and students' perceived learning gains.
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