- Presents the first comprehensive textbook on biofluid dynamics, placing the concepts in a bioengineering context
- Provides extensive worked examples, homework problems, and illustrations including a 16-page full-color insert
- Contains project assignments to stimulate critical thinking and build students' problem-solving skills
- Develops the necessary tools for solving basic biofluid problems analytically, approximately, and numerically
- Offers computer simulations of biofluid dynamics processes and medical device operations
Solutions manual available with qualifying course adoption
Requiring only an introductory background in continuum mechanics, including thermodynamics, fluid mechanics, and solid mechanics, Biofluid Dynamics: Principles and Selected Applications contains review, methodology, and application chapters to build a solid understanding of medical implants and devices. For additional assistance, it includes a glossary of biological terms, many figures illustrating theoretical concepts, numerous solved sample problems, and mathematical appendices. The text is geared toward seniors and first-year graduate students in engineering and physics as well as professionals in medicine and medical implant/device industries. It can be used as a primary selection for a comprehensive course or for a two-course sequence.
The book has two main parts: theory, comprising the first two chapters; and applications, constituting the remainder of the book. Specifically, the author reviews the fundamentals of physical and related biological transport phenomena, such as mass, momentum, and heat transfer in biomedical systems, and highlights complementary topics such as two-phase flow, biomechanics, and fluid-structure interaction. Two appendices summarize needed elements of engineering mathematics and CFD software applications, and these are also found in the fifth chapter. The application part, in form of project analyses, focuses on the cardiovascular system with common arterial diseases, organ systems, targeted drug delivery, and stent-graft implants.
Armed with Biofluid Dynamics, students will be ready to solve basic biofluids-related problems, gain new physical insight, and analyze biofluid dynamics aspects of biomedical systems.