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Journal of Science Education and Technology

Erschienen in:

23.01.2023

Online, Interactive Modules Improve Quantitative Skills in Community College Biology Students

verfasst von: Katerina V. Thompson, Kären C. Nelson, James Sniezek, Gili Marbach-Ad

Erschienen in: Journal of Science Education and Technology | Ausgabe 6/2023

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Abstract

Introductory courses in biology often lack sufficient emphasis on quantitative skills and interdisciplinary problem solving, leaving many students unprepared for more advanced biology coursework and hampering their ability to pursue biology research careers. MathBench Biology Modules were created to enhance the quantitative skills of biology students by leveraging the unique advantages of the online environment (e.g., self-pacing, opportunities for practice, and immediate, individualized feedback). Using a pre-/post-design, we tested the ability of MathBench modules to improve student quantitative skills and their attitudes towards the integration of math and biology in a community college introductory biology course, where instructors face multiple challenges to integrating quantitative content. Ten sections of the course incorporated MathBench into laboratory and lecture content (MathBench group, N = 124 students), while five sections covered the same laboratory and lecture content without MathBench (comparison group, N = 31 students). On average, students who used MathBench experienced gains in their quantitative skills, while those in the comparison group did not. For students with the lowest level of preparation in math, using MathBench was associated with improvements in quantitative skill only if they were concurrently enrolled in a math class. Neither group of students demonstrated changes over the semester in their attitudes towards the integration of math and biology. Qualitative data indicated that MathBench group students could identify multiple aspects of how MathBench contributed to their learning, including providing new content, alternative approaches to learning, and additional opportunities to practice new skills. Our work demonstrates how learner-centered technologies can be used effectively to supplement traditional instruction in the community college context.

Vorheriger Artikel Digital Curation as a Pedagogical Approach to Promote Critical Thinking

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Aikens, M. L., Eaton, C. D., & Hightower, H. C. (2021). The case for biocalculus: Improving student understanding of the utility value of mathematics and affect toward mathematics. CBE – Life Sciences Education, 20(1), 1–14.

American Association for the Advancement of Science. (2011). Vision and change in undergraduate biology education: A call to action. American Association for the Advancement of Science.

American Association for the Advancement of Science. (2015). Vision and change in undergraduate biology education: Chronicling change, inspiring the future. American Association for the Advancement of Science.

Andrews, S. E., & Aikens, M. L. (2018). Life science majors’ math-biology task values relate to student characteristics and predict the likelihood of taking quantitative biology courses. Journal of Microbiology & Biology Education, 19(2), 19–22.CrossRef

Ashcraft, M. H., & Krause, J. A. (2007). Working memory, math performance, and math anxiety. Psychonomic Bulletin & Review, 14(2), 243–248.CrossRef

Atkinson, R. K., Mayer, R. E., & Merrill, M. M. (2005). Fostering social agency in multimedia learning: Examining the impact of an animated agent’s voice. Contemporary Educational Psychology, 30(1), 117–139.CrossRef

Betz, N. E. (1978). Prevalence, distribution, and correlates of math anxiety in college students. Journal of Counseling Psychology, 25(5), 441.CrossRef

Boud, D., Lawson, R., & Thompson, D. G. (2013). Does student engagement in self-assessment calibrate their judgement over time? Assessment & Evaluation in Higher Education, 38(8), 941–956.CrossRef

Brasier, D. J., Melville, M., Hershock, C., & Rule, G. (2019). Pairing practice and feedback with animations optimizes student learning in online module. Journal of Computer Assisted Learning, 35(6), 782–793.CrossRef

Chen, X. (2016). Remedial coursetaking at U.S. public 2- and 4-year institutions: Scope, experiences, and outcomes (NCES 2016–405). National Center for Education Statistics.

Chen, M. M., Scott, S. M., & Stevens, J. D. (2018). Technology as a tool in teaching quantitative biology at the secondary and undergraduate levels: A review. Letters in Biomathematics, 5(1), 30.CrossRef

Clark, R. C., & Mayer, R. E. (2008). E-learning and the science of instruction (2nd ed.). Pfeiffer.

Corwin, L. A., Kiser, S., LoRe, S. M., Miller, J. M., & Aikens, M. L. (2019). Community college instructors’ perceptions of constraints and affordances related to teaching quantitative biology skills and concepts. CBE—Life Sciences Education, 18(4), ar64.

Dethier, L. E. (2014). Assessing the potential to improve the basic quantitative skills of undergraduate biology students (Unpublished master’s thesis). Western Washington University.

Eccles, J., Adler, T. F., Futterman, R., Goff, S. B., Kaczala, C. M., Meece, J. L., & Midgley, C. (1983). Expectancies, values, and academic behaviors. In J. T. Spence (Ed.), Achievement and achievement approaches (pp. 74–146). Freeman.

Flanagan, K. M., & Einarson, J. (2017). Gender, math confidence, and grit: Relationships with quantitative skills and performance in an undergraduate biology course. CBE—Life Sciences Education, 16(3), ar47.

Feser, J., Vasaly, H., & Herrera, J. (2013). On the edge of mathematics and biology integration: improving quantitative skills in undergraduate biology education. CBE—Life Sciences Education, 12(2), 124–128.

Goff, E. E., Reindl, K. M., Johnson, C., McClean, P., Offerdahl, E. G., Schroeder, N. L., & White, A. R. (2017). Efficacy of a meiosis learning module developed for the virtual cell animation collection. CBE—Life Sciences Education, 16(1), ar9.

Goff, E. E., Reindl, K. M., Johnson, C., McClean, P., Offerdahl, E. G., Schroeder, N. L., & White, A. R. (2018). Investigation of a stand-alone online learning module for cellular respiration instruction. Journal of Microbiology & Biology Education, 19(2), 19–22.CrossRef

Gross, L. (2000). Education for a bio-complex future. Science, 28, 807.CrossRef

Gross, L. J. (2004). Interdisciplinarity and the undergraduate biology curriculum: Finding a balance. Cell Biology Education, 3, 85–87.CrossRef

Gyamfi, G., Hanna, B. E., & Khosravi, H. (2022). The effects of rubrics on evaluative judgement: A randomised controlled experiment. Assessment & Evaluation in Higher Education, 47(1), 126–143.CrossRef

Hart Research Associates. (2015). Falling short? Association of American Colleges and Universities.

Hester, S., Buxner, S., Elfring, L., & Nagy, L. (2014). Integrating quantitative thinking into an introductory biology course improves students’ mathematical reasoning in biological contexts. CBE—Life Sciences Education, 13(1), 54–64.

Holmberg, T. J., Gusky, S., Kiser, S., Karpakakunjaram, V., Seitz, H., Fletcher, L., Fields, L., Nenortas, A., Corless, A., & Marcos, K. (2021). Biology educators, professional societies, and practitioner networks within community colleges. New Dir for Community Coll., 2021, 15–28.CrossRef

Hoy, R. (2004). New math for biology is the old new math. Cell Biology Education, 3, 90–92.CrossRef

Indorf, J. L., Benabentos, R., Daubenmire, P., Murasko, D., Hazari, Z., Potvin, G., & Stanford, J. S. (2021). Distinct factors predict use of active learning techniques by pre-tenure and tenured STEM faculty. Journal of Geoscience Education, 69(4), 357–372.CrossRef

Jameson, M. M., & Fusco, B. R. (2014). Math anxiety, math self-concept, and math self-efficacy in adult learners compared to traditional undergraduate students. Adult Education Quarterly, 64(4), 306–322.CrossRef

Karsai, I., Thompson, K. V., & Nelson, K. C. (2015). Modeling and simulation: Helping students acquire this skill using Stock and Flow approach with MathBench. Letters in Biomathematics, 2(1), 1–12.CrossRef

Koenig, J. (2011). A survey of the mathematics landscape within biosciences undergraduate and postgraduate UK higher education. UK Center for Bioscience.

LeBard, R. J., Thompson, R., & Quinnell, R. (2014). Quantitative skills and complexity: How can we combat these challenges and equip undergraduate students to think and practice as biologists? International Journal of Innovation in Science and Mathematics Education, 22(3), 1–14.

Llamas, A., Vila, F., & Sanz, A. (2012). Mathematical skills in undergraduate students. A ten-year survey of a plant physiology course. Biosci Educ, 19, 1–10.CrossRef

Lyons, I. M., & Beilock, S. L. (2012b). When math hurts: Math anxiety predicts pain network activation in anticipation of doing math. PLoS ONE, 7(10). https://doi.org/10.1371/journal.pone.0048076

Marsteller, P., de Pillis, L., Findley, A., Joplin, K., Pelesko, J., Nelson, K., & Watkins, J. (2010). Toward integration: From quantitative biology to math bio-biomath? CBE—Life Sciences Education, 9(3), 165–171.

Matthews, K. E., Hodgson, Y., & Varsavsky, C. (2013). Factors influencing students’ perceptions of their quantitative skills. International Journal of Mathematical Education in Science and Technology, 44(6), 782–795.CrossRef

Mayer, R. E. (2008). Learning and instruction (2nd ed.). Upper Saddle River, NJ.

McLeod, D. B. (1992). Research on affect in mathematics education: A reconceptualization. In D. A. Grouws (Ed.), Handbook of research on mathematics teaching and learning: A project of the National Council of Teachers of Mathematics (pp. 575–596). Macmillan Publishing Co Inc.

Moreno, R., & Mayer, R. E. (2000). Engaging students in active learning: The case for personalized multimedia messages. Journal of Educational Psychology, 92(4), 724.CrossRef

National Research Council. (2003). BIO2010: Transforming undergraduate education for future research biologists.

National Research Council. (2009). A new biology for the 21st century.

Nelson, K. C., Marbach-Ad, G., Schneider, K., Thompson, K. V., Shields, P. A., & Fagan, W. F. (2009). MathBench biology modules. Journal of College Science Teaching, 38, 34–39.

Öhrstedt, M. (2018). First-semester students’ capacity to predict academic achievement as related to approaches to learning. Journal of Further and Higher Education, 43(2), 1–13.

Pajares, F., & Miller, M. D. (1994). Role of self-efficacy and self-concept beliefs in mathematical problem solving: A path analysis. Journal of Educational Psychology, 86(2), 193.CrossRef

Quinnell, R., Thompson, R., & LeBard, R. (2012). Academic numeracy in life science learning: Challenging perceptions. In Inaugural STEM Annual Conference; April 12–13; Imperial College. London: The UK Higher Education Academy.

Reed, S. K. (1985). Effect of computer graphics on improving estimates to algebra word problems. Journal of Educational Psychology, 77(3), 285.CrossRef

Sadler, P. M., & Tai, R. H. (2007). The two high-school pillars supporting college science. Science, 317(5837), 457–458.CrossRef

Saldaña, J. (2015). The coding manual for qualitative researchers. Sage.

Scott, F. J. (2016). An investigation into students’ difficulties in numerical problem solving questions in high school biology using a numeracy framework. European Journal of Science and Mathematics Education, 4(2), 115–128.CrossRef

Tariq, F. N. (2005). Introduction and Evaluation of peer-assisted learning in first-year undergraduate bioscience. Bioscience Education, 6(1), 1–19.

Thompson, K. V., Cooke, T. J., Fagan, W. F., Gulick, D., Levy, D., Nelson, K. C., & Presson, J. (2013). Infusing quantitative approaches throughout the biological sciences curriculum. International Journal of Mathematical Education in Science and Technology, 44(6), 817–833.CrossRef

Thompson, K. V., Nelson, K. C., Marbach-Ad, G., Keller, M., & Fagan, W. F. (2010). Online interactive teaching modules enhance quantitative proficiency of introductory biology students. CBE—Life Sciences Education, 9(3), 277–283.

Tversky, B., Morrison, J. B., & Betrancourt, M. (2002). Animation: Can it facilitate? International Journal of Human-Computer Studies, 57(4), 247–262.CrossRef

Wachsmuth, L. P., Runyon, C. R., Drake, J. M., & Dolan, E. L. (2017). Do biology students really hate math? Empirical insights into undergraduate life science majors’ emotions about mathematics. CBE—Life Sciences Education, 16(3), ar49.

Wender, K. F., & Muehlboeck, J. (2003). Animated diagrams in teaching statistics. Behavior Research Methods, Instruments, & Computers, 35(2), 255–258.CrossRef

Williams, K. R., Wasson, S. R., Barrett, A., Greenall, R. F., Jones, S. R., & Bailey, E. G. (2021). Teaching Hardy-Weinberg equilibrium using population-level Punnett squares: Facilitating calculation for students with math anxiety. CBE—Life Sciences Education, 20(2), ar22.

Wolff, B. G., Wood-Kustanowitz, A. M., & Ashkenazi, J. M. (2014). Student performance at a community college: Mode of delivery, employment, and academic skills as predictors of success. Journal of Online Learning and Teaching, 10(2).

Yang, S., Hazlehurst, J., & Taniguchi, D. A. A. (2021). Cats teach stats: An interactive module to help reduce anxiety when learning statistics in biology. The American Biology Teacher, 83(8), 542–544.CrossRef

Titel: Online, Interactive Modules Improve Quantitative Skills in Community College Biology Students
verfasst von: Katerina V. Thompson
Kären C. Nelson
James Sniezek
Gili Marbach-Ad
Publikationsdatum: 23.01.2023
Verlag: Springer Netherlands
Erschienen in: Journal of Science Education and Technology / Ausgabe 6/2023
Print ISSN: 1059-0145
Elektronische ISSN: 1573-1839
DOI: https://doi.org/10.1007/s10956-022-10020-1

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