BSCS Biology: A Human Approach & Insights in Biology: Curriculum Responses to Calls for Biology Education Reform

Training the future synthetic biology workforce requires opportunity and exposure to biotechnology concepts and activities in secondary education. Detecting Wolbachia bacteria in arthropods using PCR has become a common way for secondary students to investigate and apply DNA technology in the science classroom. Despite this framework, cutting-edge biotechnologies like CRISPR-based diagnostics have yet to be widely implemented in the classroom. To address this gap, we present a freeze-dried CRISPR-Cas12 sensing reaction to complement traditional DNA technology education and teach synthetic biology concepts. The reactions accurately detect Wolbachia from arthropod-derived PCR samples in under 2 hours and can be stored at room temperature for over a month without appreciable degradation. The reactions are easy-to-use and cost less than $40 to implement for a classroom of 22 students including the cost of reusable equipment. We see this technology as an accessible way to incorporate synthetic biology education into existing biology curriculum, which will expand biology educational opportunities in science, technology, engineering, and mathematics (STEM) education.

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Reflecting on Graphs: Attributes of Graph Choice and Construction Practices in Biology

CBE—Life Sciences Education ◽

10.1187/cbe.16-08-0245 ◽

2017 ◽

Vol 16 (3) ◽

pp. ar53 ◽

Cited By ~ 7

Author(s):

Aakanksha Angra ◽

Stephanie M. Gardner

Keyword(s):

Graduate Students ◽

Experimental Design ◽

Education Reform ◽

Undergraduate Students ◽

Research Question ◽

Biology Education ◽

Scientific Practices ◽

Undergraduate Biology ◽

Student Difficulties ◽

Competence Framework

Undergraduate biology education reform aims to engage students in scientific practices such as experimental design, experimentation, and data analysis and communication. Graphs are ubiquitous in the biological sciences, and creating effective graphical representations involves quantitative and disciplinary concepts and skills. Past studies document student difficulties with graphing within the contexts of classroom or national assessments without evaluating student reasoning. Operating under the metarepresentational competence framework, we conducted think-aloud interviews to reveal differences in reasoning and graph quality between undergraduate biology students, graduate students, and professors in a pen-and-paper graphing task. All professors planned and thought about data before graph construction. When reflecting on their graphs, professors and graduate students focused on the function of graphs and experimental design, while most undergraduate students relied on intuition and data provided in the task. Most undergraduate students meticulously plotted all data with scaled axes, while professors and some graduate students transformed the data, aligned the graph with the research question, and reflected on statistics and sample size. Differences in reasoning and approaches taken in graph choice and construction corroborate and extend previous findings and provide rich targets for undergraduate and graduate instruction.

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Building Community-Based Approaches to Systemic Reform in Mathematical Biology Education

Bulletin of Mathematical Biology ◽

10.1007/s11538-020-00781-4 ◽

2020 ◽

Vol 82 (8) ◽

Cited By ~ 2

Author(s):

Olcay Akman ◽

Carrie Diaz Eaton ◽

Dan Hrozencik ◽

Kristin P. Jenkins ◽

Katerina V. Thompson

Keyword(s):

Mathematical Biology ◽

Education Reform ◽

Education System ◽

Biology Education ◽

Careful Consideration ◽

Systemic Reform ◽

Community Based ◽

Community Based Education ◽

Wide Range ◽

Building Community

AbstractStarting in the early 2000’s, several reports were released recognizing the convergence of mathematics, biology and computer science, and calling for a rethinking of how undergraduates are prepared for careers in research and the science and technology workforce. This call for change requires careful consideration of the mathematical biology education system to identify key components and leverage points for change. This paper demonstrates the wide range of resources and approaches available to the mathematical biology education community to create systemic change by highlighting the efforts of four community-based education reform organizations. A closer look at these organizations provides an opportunity to examine how to leverage components of the education system including faculty, academic institutions, students, access to resources, and the power of community.

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Evolution in Action in the Classroom: Engaging Students in Science Practices to Investigate and Explain Evolution by Natural Selection

The American Biology Teacher ◽

10.1525/abt.2018.80.2.92 ◽

2018 ◽

Vol 80 (2) ◽

pp. 92-99 ◽

Cited By ~ 3

Author(s):

Wendy R. Johnson ◽

Amy Lark

Keyword(s):

Natural Selection ◽

Biology Education ◽

Model Organisms ◽

Science Content ◽

Science Standards ◽

Science Practices ◽

Curriculum Framework ◽

Current Reform ◽

Evolution By Natural Selection ◽

Biology Curriculum

Current reform efforts at all levels of biology education advocate for the integration of science content and practices and emphasize the importance of phenomena-driven inquiry. We describe an instructional sequence for teaching evolution by natural selection that addresses these goals by engaging students in parallel selection experiments with biological and digital model organisms. These activities address multiple learning objectives in the AP Biology Curriculum Framework and the Next Generation Science Standards while engaging students in authentic science practices to learn about natural selection. We also report results from pre and post assessments in an AP Biology class which demonstrate students' learning gains and increased acceptance of evolution.

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Surging Interest in Biology Education Reform: Scientists Play an Expanded Role

Bulletin of the Ecological Society of America ◽

10.1890/0012-9623(2008)89[176:siiber]2.0.co;2 ◽

2008 ◽

Vol 89 (2) ◽

pp. 176-179

Author(s):

Teresa Mourad

Keyword(s):

Education Reform ◽

Biology Education

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Conceptual Elements: A Detailed Framework to Support and Assess Student Learning of Biology Core Concepts

CBE—Life Sciences Education ◽

10.1187/cbe.16-10-0300 ◽

2017 ◽

Vol 16 (2) ◽

pp. ar24 ◽

Cited By ~ 8

Author(s):

Tawnya Cary ◽

Janet Branchaw

Keyword(s):

Biological Sciences ◽

Biology Education ◽

The United States ◽

Instructional Materials ◽

Assessment Instruments ◽

Core Concept ◽

Undergraduate Biology ◽

Core Concepts ◽

Biology Curriculum ◽

Concept Framework

The Vision and Change in Undergraduate Biology Education: Call to Action report has inspired and supported a nationwide movement to restructure undergraduate biology curricula to address overarching disciplinary concepts and competencies. The report outlines the concepts and competencies generally but does not provide a detailed framework to guide the development of the learning outcomes, instructional materials, and assessment instruments needed to create a reformed biology curriculum. In this essay, we present a detailed Vision and Change core concept framework that articulates key components that transcend subdisciplines and scales for each overarching biological concept, the Conceptual Elements (CE) Framework. The CE Framework was developed using a grassroots approach of iterative revision and incorporates feedback from more than 60 biologists and undergraduate biology educators from across the United States. The final validation step resulted in strong national consensus, with greater than 92% of responders agreeing that each core concept list was ready for use by the biological sciences community, as determined by scientific accuracy and completeness. In addition, we describe in detail how educators and departments can use the CE Framework to guide and document reformation of individual courses as well as entire curricula.

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An Imaging Roadmap for Biology Education: From Nanoparticles to Whole Organisms

CBE—Life Sciences Education ◽

10.1187/cbe.07-10-0094 ◽

2008 ◽

Vol 7 (2) ◽

pp. 202-209 ◽

Cited By ~ 2

Author(s):

Daniel J. Kelley ◽

Richard J. Davidson ◽

David L. Nelson

Keyword(s):

Imaging Techniques ◽

Biology Education ◽

Ways Of Knowing ◽

Structure And Function ◽

Introductory Course ◽

Course Materials ◽

Teaching Unit ◽

And Function ◽

Biology Curriculum ◽

Nih Roadmap

Imaging techniques provide ways of knowing structure and function in biology at different scales. The multidisciplinary nature and rapid advancement of imaging sciences requires imaging education to begin early in the biology curriculum. Guided by the National Institutes of Health (NIH) Roadmap initiatives, we incorporated a nanoimaging, molecular imaging, and medical imaging teaching unit into three 1-h class periods of an introductory course on ways of knowing biology. Activities were derived from NIH Roadmap initiatives in nanomedicine, regenerative medicine, and nuclear medicine. The course materials we describe contributed positively to student learning gains in quantifying and interpreting images, in characterizing imaging methods that provide ways of knowing biological structure and function, and in understanding scale in biology and imaging. The NIH Roadmap provides a useful context to educate students about the multidisciplinary imaging continuum.

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Summit of the Research Coordination Networks for Undergraduate Biology Education

CBE—Life Sciences Education ◽

10.1187/cbe.16-03-0147 ◽

2016 ◽

Vol 15 (4) ◽

pp. mr1 ◽

Cited By ~ 3

Author(s):

Carrie Diaz Eaton ◽

Deborah Allen ◽

Laurel J. Anderson ◽

Gillian Bowser ◽

Mark A. Pauley ◽

...

Keyword(s):

Education Reform ◽

Online Communication ◽

Biology Education ◽

Washington Dc ◽

Coordination Networks ◽

Undergraduate Biology ◽

National Science ◽

Effective Network ◽

Key Aspects ◽

Science Educators

The first summit of projects funded by the National Science Foundation’s Research Coordination Networks for Undergraduate Biology Education (RCN-UBE) program was held January 14–16, 2016, in Washington, DC. Sixty-five scientists and science educators from 38 of the 41 Incubator and Full RCN-UBE awards discussed the value and contributions of RCNs to the national biology education reform effort. The summit illustrated the progress of this innovative UBE track, first awarded in 2009. Participants shared experiences regarding network development and growth, identified best practices and challenges faced in network management, and discussed work accomplished. We report here on key aspects of network evaluation, characteristics of successful networks, and how to sustain and broaden participation in networks. Evidence from successful networks indicates that 5 years (the length of a Full RCN-UBE) may be insufficient time to produce a cohesive and effective network. While online communication promotes the activities of a network and disseminates effective practices, face-to-face meetings are critical for establishing ties between network participants. Creation of these National Science Foundation–funded networks may be particularly useful for consortia of faculty working to address problems or exchange novel solutions discovered while introducing active-learning methods and/or course-based research into their curricula.

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Mixed Student Ideas about Mechanisms of Human Weight Loss

CBE—Life Sciences Education ◽

10.1187/cbe.18-11-0227 ◽

2019 ◽

Vol 18 (3) ◽

pp. ar37 ◽

Cited By ~ 4

Author(s):

Kamali N. Sripathi ◽

Rosa A. Moscarella ◽

Rachel Yoho ◽

Hye Sun You ◽

Mark Urban-Lurain ◽

...

Keyword(s):

College Students ◽

Weight Loss ◽

Education Reform ◽

Biology Education ◽

Student Thinking ◽

Biological Processes ◽

Learning Gains ◽

Student Responses ◽

College Biology ◽

Descriptive Models

Recent calls for college biology education reform have identified “pathways and transformations of matter and energy” as a big idea in biology crucial for students to learn. Previous work has been conducted on how college students think about such matter-transforming processes; however, little research has investigated how students connect these ideas. Here, we probe student thinking about matter transformations in the familiar context of human weight loss. Our analysis of 1192 student constructed responses revealed three scientific (which we label “Normative”) and five less scientific (which we label “Developing”) ideas that students use to explain weight loss. Additionally, students combine these ideas in their responses, with an average number of 2.19 ± 1.07 ideas per response, and 74.4% of responses containing two or more ideas. These results highlight the extent to which students hold multiple (both correct and incorrect) ideas about complex biological processes. We described student responses as conforming to either Scientific, Mixed, or Developing descriptive models, which had an average of 1.9 ± 0.6, 3.1 ± 0.9, and 1.7 ± 0.8 ideas per response, respectively. Such heterogeneous student thinking is characteristic of difficulties in both conceptual change and early expertise development and will require careful instructional intervention for lasting learning gains.

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Preservice biology teachers’ knowledge and usage level regarding lab equipment and materials

Journal of Education and Learning (EduLearn) ◽

10.11591/edulearn.v15i3.20018 ◽

2021 ◽

Vol 15 (3) ◽

pp. 397-405

Author(s):

Ahmet Gökmen ◽

Burak Gürkan ◽

Hikmet Türk Katırcıoğlu

Keyword(s):

Preservice Teachers ◽

Correct Answer ◽

Descriptive Analysis ◽

Biology Education ◽

Application Process ◽

Education Department ◽

Biology Teachers ◽

Usage Level ◽

Biology Curriculum ◽

Descriptive Survey

Laboratories are an indispensable part of the fundamental sciences. Laboratories are important learning environments that enable students to relate events to daily life as well as being places where theoretical knowledge is implemented. The present study investigated the knowledge and usage level of preservice biology teachers regarding lab equipment and materials. The study utilized a descriptive survey. A total of 61 preservice biology teachers from the Biology Education Department of a public university in Turkey constituted the participants. Lab Equipment and Materials Recognition Form that is developed by the researcher of the present study was used to collect data. In the design of this form, the 9–12 grade biology curriculum was first analyzed, and a list of frequently-used equipment and materials of biology laboratories was created in line with the opinions of field experts. The form included 40 laboratories equipment and materials and questions regarding the recognition of these items, their functions, and their application processes. The preservice teachers’ answers to these questions were graded as: zero points for each incorrect answer, one point for each partially correct answer, and two points for each correct answer. The data obtained were analyzed using cluster analysis, descriptive analysis, one-way analysis of variance, and independent samples T-test in SPSS27 software, and the Polycoric correlation coefficient in Factor Analysis software. The results revealed that the preservice teachers mainly recognize the biology laboratories equipment and materials but generally lack information regarding the application process of laboratories equipment and materials.

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