Interdisciplinarity: The Right People, a Supportive Place, and a Program Emerges (original) (raw)
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Cell Biology Education, 2004
Too often, biology has been considered by both students and faculty as the ideal major for the scientifically inclined but mathematically challenged, even though the advantage of quantitative approaches in biology has always been apparent. Increasingly, biologists are utilizing mathematical skills to create simulations or manage and query large data sets. The need for basic mathematical and computer science (CS) literacy among biologists has never been greater. But does this require a fundamental change in the organization of the undergraduate biology curriculum? What is the utility of math/CS in different areas of biology? How can we best provide math/CS instruction to biologists so that the utility is appreciated? Do all biology students require a stronger math/CS foundation, or only those interested in research careers? Given the speed at which technology changes, what is the best preparation? Three different points of view are offered below. Dr. Roger Brent, President and Director of the Molecular Sciences Institute, reflects on the "innumeracy" common among biologists and argues that significant insights into biological problems may be gained from better mathematical intuition.
CBE life sciences education, 2010
Inspired by BIO2010 and leveraging institutional and external funding, Truman State University built an undergraduate program in mathematical biology with high-quality, faculty-mentored interdisciplinary research experiences at its core. These experiences taught faculty and students to bridge the epistemological gap between the mathematical and life sciences. Together they created the infrastructure that currently supports several interdisciplinary courses, an innovative minor degree, and long-term interdepartmental research collaborations. This article describes how the program was built with support from the National Science Foundation's Interdisciplinary Training for Undergraduates in Biology and Mathematics program, and it shares lessons learned that will help other undergraduate institutions build their own program.
Creating an Interdisciplinary Research Course in Mathematical Biology
Undergraduate Mathematics for the Life Sciences, 2009
Size about 24,000 students Institution Type large state university with PhD program Student recent high school graduates with high potential Demogaphic and interests in mathematics and biology Department Mathematics and Biology are individual Structure departments in the College of Arts and Sciences An integrated interdisciplinary research course in biology and mathematics is useful for recruiting studeots tu interdisciplinary research careers, but there are difficulties involved in creating and implemeoting it. We describe the genesis, objectives, design policies, and structure of the Research Skills in Theoretical Ecology course at the University of Nebraska-Lincoln and discuss the difficulties that can arise in designing and implemeoting interdisciplinary courses. Course Structure • Weeks per term: 5-week summer session • Classes per week/type/leogth: five I-hour lecture periods each week • Labs per week/leogth: five I-hour laboratory periods each week • Average class size: 8-14 students in one section • Enrollment reqniremeots: For high school students and university freslnnen. Studeots must apply for the program and get a recommendation from a teacher. • Faculty/dept per class, TAs: Team-taught by one mathematics instructor and one biology instructor, with the mathematics instructor doing the quantitative lecture portion of the lecture. • Next course: The purpose of the course is to teach research skills. There are no related courses, but many of the studeots will do research projects later in their programs. Some students may choose to take additional courses in mathematics and/or biology, including interdisciplinary courses.
We describe a unique Research Experience for Undergraduates and Research Experience for Veterinary students summer program at the National Institute for Mathematical and Biological Synthesis on the campus of the University of Tennessee, Knoxville. The program focused on interdisciplinary research at the interface of biology and mathematics. Participants were selected to work on projects with a biology mentor and a mathematics mentor in an environment that promoted collaboration outside of the students' respective disciplines. There were four research projects with teams of four participants and two faculty mentors. The participants consisted of a mixture of 10 undergraduates in biology-and mathematics-related disciplines, four veterinary students, and two high-school teachers. The activities included lectures on both the biological and mathematical backgrounds of the projects, tutorials for software, and sessions on ethics, graduate school, and possible career paths for individuals interested in biology and mathematics. The program was designed to give students the ability to actively participate in the scientific research process by working on a project, writing up their results in a final report, and presenting their work orally. We report on the results of our evaluation surveys of the participants.
CBE life sciences education, 2016
Western science has grown increasingly reductionistic and, in parallel, the undergraduate life sciences curriculum has become disciplinarily fragmented. While reductionistic approaches have led to landmark discoveries, many of the most exciting scientific advances in the late 20th century have occurred at disciplinary interfaces; work at these interfaces is necessary to manage the world's looming problems, particularly those that are rooted in cellular-level processes but have ecosystem- and even global-scale ramifications (e.g., nonsustainable agriculture, emerging infectious diseases). Managing such problems requires comprehending whole scenarios and their emergent properties as sums of their multiple facets and complex interrelationships, which usually integrate several disciplines across multiple scales (e.g., time, organization, space). This essay discusses bringing interdisciplinarity into undergraduate cellular biology courses through the use of multiscalar topics. Discus...
Cell Biology Education, 2010
Funded by innovative programs at the National Science Foundation and the Howard Hughes Medical Institute, University of Richmond faculty in biology, chemistry, mathematics, physics, and computer science teamed up to offer first-and second-year students the opportunity to contribute to vibrant, interdisciplinary research projects. The result was not only good science but also good science that motivated and informed course development. Here, we describe four recent undergraduate research projects involving students and faculty in biology, physics, mathematics, and computer science and how each contributed in significant ways to the conception and implementation of our new Integrated Quantitative Science course, a course for first-year students that integrates the material in the first course of the major in each of biology, chemistry, mathematics, computer science, and physics.
Cell Biology Education, 2010
Modern biological sciences require practitioners to have increasing levels of knowledge, competence, and skills in mathematics and programming. A recent review of the science curriculum at the University of Queensland, a large, research-intensive institution in Australia, resulted in the development of a more quantitatively rigorous undergraduate program. Inspired by the National Research Council's BIO2010 report, a new interdisciplinary first-year course (SCIE1000) was created, incorporating mathematics and computer programming in the context of modern science. In this study, the perceptions of biological science students enrolled in SCIE1000 in 2008 and 2009 are measured. Analysis indicates that, as a result of taking SCIE1000, biological science students gained a positive appreciation of the importance of mathematics in their discipline. However, the data revealed that SCIE1000 did not contribute positively to gains in appreciation for computing and only slightly influenced s...
Integration of Physics and Biology: Synergistic Undergraduate Education for the 21st Century
Cell Biology Education, 2013
This is an exciting time to be a biologist. The advances in our field and the many opportunities to expand our horizons through interaction with other disciplines are intellectually stimulating. This is as true for people tasked with helping the field move forward through support of research and education projects that serve the nation's needs as for those carrying out that research and educating the next generation of biologists. So, it is a pleasure to contribute to this edition of CBE—Life Sciences Education. This column will cover three aspects of the interactions of physics and biology as seen from the viewpoint of four members of the Division of Undergraduate Education of the National Science Foundation. The first section places the material to follow in context. The second reviews some of the many interdisciplinary physics–biology projects we support. The third highlights mechanisms available for supporting new physics–biology undergraduate education projects based on ide...