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Course Criteria
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3.00 Credits
Biomaterial interactions with the human body, biomaterial degradation, surface properties of biomaterials, acute inflammation, wound healing, implantation issues, and the immune system. PREREQ: Knowledge of basic biology, general chemistry, and calculus.
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3.00 Credits
How our senses, central nervous system, and muscles interact to produce movement. Fundamental principles, theories, computational models, and emerging technological applications of neuromechanics.
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3.00 Credits
Introduce the fundamentals of cell engineering including intracellular signaling events that regulate cell fate, current fabrication strategies to engineer a cell's environment, and current results in the literature.
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3.00 Credits
Describes how to use the engineering design process to create, characterize, and evaluate nanoscale structures for biotechnological applications, with an emphasis on noble metal nanoparticles. Topics include understanding and exploiting the physical properties that emerge at the nanoscale; precisely engineering the architecture and properties of noble metal nanoparticles; and rationally designing experiments to evaluate nanomaterials in biological/biomedical settings. PREREQ: BMEG301 or equivalent. RESTRICTIONS: Open to BME students; other students may take the course with the instructor's permission.
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3.00 Credits
Covers topics of mechanosensation and mechanotransduction in biological systems. Includes the principles and evolution of mechanosensory/mechanostransduction systems, their cellular machinery and mechanisms, and their role in health, disease and the engineering of tissues. PREREQ: BMEG401 or equivalent and BMEG301 or equivalent. RESTRICTIONS: Open to BME students; ENGG students may take it with the instructor's permission.
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3.00 Credits
Introduction to fundamental laws and material models used to describe the mechanical behavior of biological tissues. Application of these models to musculoskeletal tissues. Introduction to numerical methods used to simulate the response of these tissue to physiological loading. PREREQ: BMEG310 or equivalent (statics, strength of materials); MATH305 or equivalent (first order ODE, second order linear ODE, Laplace transform, partial differential equations, use of Matlab as a computational tool). RESTRICTIONS: Open to BME student; other students may take it with the instructor's permission.
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1.00 - 12.00 Credits
No course description available.
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1.00 - 12.00 Credits
No course description available.
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3.00 Credits
Mathematical methods in Human Physiology, covering cellular, tissue, organ, and integrated systems. Dynamic modeling of homeostasis, endocrine regulatory systems, immune response dynamics, mutation and selection. Mathematical methods covered include linear and nonlinear differential equations, Lyapunov analysis, mass action, Hamming spaces, reaction-diffusion equations, and simulation. RESTRICTIONS: Seniors, graduate students only.
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3.00 Credits
Physics, instrumentation, system design, and image reconstruction algorithms will be covered for the following modalities: radiography, x-ray computed tomography (CT), single photon emission computed tomography (SPECT), positron emission tomography (PET), magnetic resonance imaging (MRI), and real-time ultrasound. PREREQ: Requires permission of instructor.
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