Skip to main content

Development of educational materials for a bioengineering fundamentals course

Publication ,  Conference
Saterbak, A; San, KY; McIntire, L
Published in: ASEE Annual Conference and Exposition, Conference Proceedings
December 1, 2006

A significant effort has been made to develop educational materials for sophomore-level bioengineering and biomedical engineering students. The materials focus on the conservation laws and include: a textbook, a problem-based learning (PBL) module, a computer-based simulation, and a communications module. The textbook, Bioengineering Fundamentals, which covers the conservation laws with applications in biological and medical systems, has been written. Its publication by PearsonPrentice Hall is expected in 2006. The conservation laws of mass, energy, charge, and momentum form the foundation of engineering. Focusing on applications in biological systems to teach these conservation laws provides a new and unifying approach to the introductory, interdisciplinary fundamentals course in biomedical engineering departments. Chapter 1 begins with a basic review of engineering calculations with an emphasis on elaborating physical variables, which are introduced in the context of different biomedical technologies. The fundamental framework of the conservation laws is described in Chapter 2. Chapters 3-6 cover conservation of mass, energy, charge, and momentum in biomedical systems. Each chapter begins with a challenge problem that presents a current bioengineering design challenge. Within each chapter, the accounting and conservation equations are restated and explicitly formulated for the property of interest. The derivation of Kirchhoff s current and voltage laws, Newton's laws of motions, Bernoulli's equation, and others from the key accounting and conservation equations are also presented. The text includes ten or more worked examples per chapter that span physiology, kinematics, biomaterials, cellular engineering, instrumentation, imaging, and biotechnology. Each chapter has 25-40 homework problems. One unique feature of this textbook is the inclusion of three case studies in Chapter 7 that integrate the different conservation applications of mass, energy, charge, and momentum. The case studies include the heart, the lungs, and the kidneys. We developed a problem-based learning (PBL) module in conjunction with another university. We completed a computer simulation of the kidneys that supports the conservation concepts. Finally, we developed and implemented a communications module that improves students' communication skills, while simultaneously encouraging students to explore the emerging field of bioengineering. The effectiveness of the textbook and students' progress toward established educational goals have been assessed over two year in several bioengineering departments across the country where the manuscript is currently being used. Based on a course impact surveys and pre- and post-tests focused on the conservation equations, statistically significant gains in acquired knowledge and problem-solving skills development were seen. The NSF Division of Undergraduate Education Course, Curriculum, and Laboratory Instruction (CCLI) program (DUE-0231313) funded this work. © American Society for Engineering Education, 2006.

Duke Scholars

Published In

ASEE Annual Conference and Exposition, Conference Proceedings

Publication Date

December 1, 2006
 

Citation

APA
Chicago
ICMJE
MLA
NLM
Saterbak, A., San, K. Y., & McIntire, L. (2006). Development of educational materials for a bioengineering fundamentals course. In ASEE Annual Conference and Exposition, Conference Proceedings.
Saterbak, A., K. Y. San, and L. McIntire. “Development of educational materials for a bioengineering fundamentals course.” In ASEE Annual Conference and Exposition, Conference Proceedings, 2006.
Saterbak A, San KY, McIntire L. Development of educational materials for a bioengineering fundamentals course. In: ASEE Annual Conference and Exposition, Conference Proceedings. 2006.
Saterbak, A., et al. “Development of educational materials for a bioengineering fundamentals course.” ASEE Annual Conference and Exposition, Conference Proceedings, 2006.
Saterbak A, San KY, McIntire L. Development of educational materials for a bioengineering fundamentals course. ASEE Annual Conference and Exposition, Conference Proceedings. 2006.

Published In

ASEE Annual Conference and Exposition, Conference Proceedings

Publication Date

December 1, 2006