|
|
|
|
|
|
|
Course Criteria
Add courses to your favorites to save, share, and find your best transfer school.
-
4.00 Credits
Lecture/discussion-4 hours. Prerequisite: Biological Sciences 2A; Physics 9B; Mathematics 22B; Chemistry 8B. Use of engineering principles to understand fundamental cell biology. Emphasis on physical concepts underlying cellular processes including protein trafficking, cell motility, cell division and cell adhesion. Current topics including cell biology of cancer and stem cells will be discussed. Only two units of credit for students who have previously taken Biological Sciences 104 or Molecular and Cellular Biology 143.-I. (I.) Yamada
-
4.00 Credits
Lecture-3 hours; discussion-1 hour. Prerequisite:Mathematics 21D; upper division. Concepts of probability, random variables and processes, and statistical analysis with applications to engineering problems in biomedical sciences. Contents include discrete and continuous random variables, probability distributions and models, hypothesis testing, statistical inference and stochastic processes. Emphasis on BME applications. Limited to upper division standing.-I. (I.) Saiz
-
4.00 Credits
Lecture-4 hours. Prerequisite: Neurobiology, Physiology, and Behavior 101 or equivalent, Physics 9B, Mathematics 22B. Principles of heat and mass transfer with applications to biomedical systems; emphasis on mass transfer across cell membranes and the design and analysis of artificial human organs, and basic fluid transport.-II. (II.)
-
4.00 Credits
Lecture-3 hours; discussion-1 hour. Prerequisite:Mathematics 22A and 22B. Restricted to upper division engineering. Essential mathematical and numerical techniques for engineering problems in medicine and biology. Contents include matrix algebra, linear transforms, ordinary and partial differential equations, probability and stochastic processes, and an introduction to Monte Carlo and molecular dynamics simulations.-II. (II.) Raychaudhuri
-
4.00 Credits
Lecture-4 hours. Prerequisite: Mathematics 22B; Engineering 100 (may be taken concurrently). Restricted to upper division Engineering students. Systems and control theory applied to biomedical engineering problems. Time-domain and frequencydomain analyses of signals and systems, convolution, Laplace and Fourier transforms, transfer function, dynamic behavior of first and second order processes, and design of feedback control systems for biomedical applications. No credit for students who have taken Electrical and Computer Engineering 150A; 2 units of credit for students who have taken Mechanical Engineering 171.-III. (III.) Qi
-
4.00 Credits
Lecture-3 hours; discussion-1 hour. Prerequisite:course 106. Mechanical and chemical properties of metallic, ceramic, and polymeric implant materials. Properties of bones, joints, and blood vessels. Cellular response to implants, including inflammation, blood coagulation, and wound and fracture healing. Biocompatibility of orthopaedic and cardiovascular materials.-III. (III.) Revzin
-
2.00 Credits
Laboratory-3 hours; lecture/discussion-1 hour.Prerequisite: courses 107, 108, 109. Application of bioengineering theory and experimental analysis culminating in the design of a unique solution to a problem. The design may be geared towards current applications in applied biomechanics, biotechnology or medical technology. (Deferred grading only, pending completion of sequence.)-II, III. (II, III.)
-
6.00 Credits
Lecture-4 hours; laboratory-6 hours. Prerequisite:courses 107 and 108; Statistics 120, 131A, or equivalent; Engineering 100; Neurology, Physiology, & Behavior 101. Basic biomedical signals and sensors. Topics include analog and digital records using electronic, hydrodynamic, and optical sensors, and measurements made at cellular, tissue and whole organism level. Limited to upper division Biomedical Engineering majors-II. (II.) Marcu, Pan
-
5.00 Credits
Lecture-2 hours; practice-3 hours; extensive writing.Prerequisite: Biological Sciences 1A; Mathematics 22B; Physics 9C. Introduction to the engineering research and design process as applied to biomedical devices and therapeutics. Small group design projects and presentations in interdisciplinary topics relating biomedical engineering to biology and medicine. GE Credit: Wrt.-I. (I.) Louie
-
4.00 Credits
Lecture-3 hours; discussion-1 hour. Prerequisite:Biological Sciences 1A and Mathematics 22B. Network themes in biology, emphasizing metabolic, genetic, and developmental networks. Mathematical and computational methods for analysis of such networks. Elucidation of design principles in natural networks. Engineering and ethical issues in the design of synthetic networks.-III. (III.) Savageau
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Privacy Statement
|
Terms of Use
|
Institutional Membership Information
|
About AcademyOne
Copyright 2006 - 2024 AcademyOne, Inc.
|
|
|