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71 - 80 of 102 results for: BIOE

BIOE 313: Neuromorphics: Brains in Silicon (EE 207)

(Formerly EE 304) Neuromorphic systems run perceptual, cognitive and motor tasks in real-time on a network of highly interconnected nonlinear units. To maximize density and minimize energy, these units--like the brain's neurons--are heterogeneous and stochastic. The first half of the course covers learning algorithms that automatically synthesize network configurations to perform a desired computation on a given heterogeneous neural substrate. The second half of the course surveys system-on-a-chip architectures that efficiently realize highly interconnected networks and mixed analog-digital circuit designs that implement area and energy-efficient nonlinear units. Prerequisites: EE102A is required.
Terms: Spr | Units: 3

BIOE 326A: In Vivo MR: SpinPhysics and Spectroscopy (RAD 226A)

Collections of independent identical nuclear spins are well described by the classical vector model of magnetic resonance imaging, however, interaction among spins, as occur in many in vivo processes, require a more complete description. This course develops the basic physics and engineering principles of these interactions with emphasis on current research questions and clinical spectroscopy applications. Prerequisite: EE396b; familiarity with MRI, linear algebra recommended.
Terms: Win | Units: 3 | Repeatable for credit
Instructors: Spielman, D. (PI)

BIOE 326B: In Vivo MR: Relaxation Theory and Contrast Mechanisms (RAD 226B)

Principles of nuclear magnetic resonance relaxation theory as applicable to in vivo processes with an emphasis on medical imaging. Topics: physics and mathematics of relaxation, relaxation times in normal and diseased tissues, magnetization transfer contrast, chemical exchange saturation transfer, MRI contrast agents, and hyperpolarized 13C. Prerequisites: BIOE 22A
Terms: Spr | Units: 3
Instructors: Spielman, D. (PI)

BIOE 331: Protein Engineering (BIOE 231)

The design and engineering of biomolecules emphasizing proteins, antibodies, and enzymes. Combinatorial and rational methodologies, protein structure and function, and biophysical analyses of modified biomolecules. Clinically relevant examples from the literature and biotech industry. Prerequisite: basic biochemistry. Winter, Cochran
Last offered: Spring 2015

BIOE 333: Interfacial Phenomena and Bionanotechnology

Control over and understanding of interfacial phenomena and colloidal science are the essential foundation of bionanotechnology. Key mathematical relationships derived by Laplace, Gibbs, Kelvin and Young are derived and explained, along with the thermodynamics of systems of large interfacial area. Forces controlling surface and interfacial phenomena and surfactant and biomacromolecule self-assembly are discussed. Protein folding/unfolding and aggregation, and nano- and microfluidics are elucidated in these terms. Students will gain insight into the interplay between physical and chemical properties of biomolecules. Spring, (Barron, A.)
Last offered: Spring 2010

BIOE 334: Engineering Principles in Molecular Biology

The achievements and difficulties that exemplify the interface of theory and quantitative experiment. Topics include: bistability, cooperativity, robust adaptation, kinetic proofreading, analysis of fluctuations, sequence analysis, clustering, phylogenetics, maximum likelihood methods, and information theory. Sources include classic papers.
Last offered: Winter 2016

BIOE 335: Molecular Motors I

Physical mechanisms of mechanochemical coupling in biological molecular motors, using F1 ATPase as the major model system. Applications of biochemistry, structure determination, single molecule tracking and manipulation, protein engineering, and computational techniques to the study of molecular motors.
Last offered: Spring 2016

BIOE 337: Organismic Biophysics and Living Soft-matter

Integrated physical biology; from molecules to organisms. Tree of life, diversity of life forms. Multi-scale/hierarchical systems in biophysics, Hierarchical self-organization. Basic theory of squishy materials, colloidal physics. Phase transitions in living soft-matter. Experimental techniques in soft-matter physics. Active fluid models for living matter. Design of self-assembling and self-organizing, biomimetic supramolecular systems.
Terms: Win | Units: 3

BIOE 355: Advanced Biochemical Engineering (CHEMENG 355)

Combines biological knowledge and methods with quantitative engineering principles. Quantitative review of biochemistry and metabolism; recombinant DNA technology and synthetic biology (metabolic engineering). The production of protein pharaceuticals as a paradigm for the application of chemical engineering principles to advanced process development within the framework of current business and regulatory requirements. Prerequisite: CHEMENG 181 (formerly 188) or BIOSCI 41, or equivalent.
Terms: Spr | Units: 3

BIOE 361: Biomaterials in Regenerative Medicine (MATSCI 381)

Materials design and engineering for regenerative medicine. How materials interact with cells through their micro- and nanostructure, mechanical properties, degradation characteristics, surface chemistry, and biochemistry. Examples include novel materials for drug and gene delivery, materials for stem cell proliferation and differentiation, and tissue engineering scaffolds. Prerequisites: undergraduate chemistry, and cell/molecular biology or biochemistry.
Terms: Spr | Units: 3
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