Biomedical Engineering Course
Descriptions
BMEN 6341 Biostatistics (3 semester hours) Introduction to probability; joint, marginal and
conditional distributions; entropy and relative entropy (Kullback-Leibler
divergence); Markov processes and hidden Markov models; applications to
specific problems such as sequence alignment, analysis of gene expression data
and protein classification. (3-0) T
BMEN 6351 Biomedical Microdevices (3 semester hours)
Introduction to concepts of medical microdevices; design methodology and
its applications for diagnostics and therapeutics. (3 -0)Y
BMEN 6355 (MSEN 6355) Nanotechnology and Sensors (3 semester hours) Introduction
to the concept of nanotechnology, in context toward designing
sensors/diagnostic devices. Identifying
the impact of nanotechnology in designing "state-of-the art" sensors
for healthcare applications. Topics
include: nanotechnology and nanomaterials, principles of sensing and
transduction and heterogeneous integration toward sensor design. (3-0) Y
BMEN 6372 (MECH 6314, SYSM 6306) Engineering Systems: Modeling & Simulation (3 semester hours) This course will present principles of
computational modeling and simulation of systems. General topics covered
include: parametric and non-parametric modeling; system simulation; parameter
estimation, linear regression and least squares; model structure and model
validation through simulation; and, numerical issues in systems theory.
Techniques covered include methods from numerical linear algebra, nonlinear
programming and Monte Carlo simulation, with applications to general
engineering systems. Modeling and simulation software is utilized
(MATLAB/SIMULINK). (3-0) Y
BMEN 6373 (EEBM 6373) Anatomy and Human Physiology for
Engineers (3 semester hours) This
course provides an introduction to anatomy and human physiology for engineers
and other non-life scientists. Topics include nervous system, muscle and
cardiac function, digestive system, and immune system. (3-0) Y
BMEN 6374 (EEBM 6374) Molecular and Cell Biology for Engineers (3 semester hours) An introduction to principles of modern
molecular and cellular biology for engineers and other non-life-scientists.
Topics include genes, protein structure and function, organization of cells and
cellular trafficking. (3-0) Y
BMEN 6375 Techniques in Cell and Molecular Biology (3 semester hours) Introduction to cell and molecular
laboratory techniques including DNA recombinant technology, protein
biochemistry, structural biology, and molecular biology. Intended for engineers
and other non-life-scientists. Prerequisite: BMEN 6374 or instructor
permission. (3-0) Y
BMEN 6376 (EEBM 6376) Lecture Course in Biomedical
Applications of Electrical Engineering
(3 semester hours) This course provides an introduction to different areas of
biomedical applications of electrical engineering. A special emphasis will be
placed on research topics that are actively pursued at UTD. (3-0) Y
BMEN 6377 Introduction to Protein Engineering (3 semester hours) Development of proteins with practical
utility will be discussed, using examples and case studies taken from the
current literature. Prerequisites: BMEN 6374 or by instructor permission. (3-0)
Y
BMEN 6380 (EEBM 6380) Introduction to Cellular Microscopy (3 semester hours) Image formation, diffraction, labeling
techniques, fluorescence and image processing techniques will be introduced.
(3-0) Y
BMEN 6381 (EEBM 6381) Advanced Concepts in Microscopy (3 semester hours) Continuation of BMEN 6380, with emphasis
on advanced approaches such as vectorial diffraction, stochastic aspects of
image formation and analysis. Prerequisites: BMEN/EEBM 6380 or by instructor
permission. (3-0) Y
BMEN 6382 Systems Biology (3 semester hours) An interdisciplinary approach to biology. It explores
experimental, theoretical, and computational approaches from mathematics,
physics, and engineering for the understanding and analysis of biological
problems. Prerequisites: BMEN 6374 or instructor permission. (3-0) Y
BMEN 6385 Biomedical Signals and Systems (3 semester hours) Time and Frequency domain analysis;
continuous-time and discrete-time signals, linear-time invariant (LTI) systems
and their properties. Frequency analysis of: LTI systems, continuous-time
signals (Fourier series and Fourier transform) and discrete time signals
[discrete Fourier series and discrete-time Fourier transform (DTFT)]. Sampling
and signal reconstruction. Discrete Fourier transform (DFT) and fast Fourier
transform (FFT). Filter design. MATLAB-based tutorials. Prerequisites: ENGR 2300
and EE 4310. (3-0) Y
BMEN 6386 Biological Processes: Modeling and Simulation (3 semester hours) Introduces fundamental principles to
develop and simulate mathematical and computer models of biological systems.
Topics include modeling principles [continuous (differential equation models),
discrete (Boolean network and Markov model), probabilistic (Bayesian network)
and stochastic models] and model optimization. Methods to simulate mathematical
biological models using computer programming (software: MATLAB) will be
introduced. Prerequisites: MATH 2419 or equivalent. (3-1) Y
BMEN 6387 (BIOL 5376) Applied Bioinformatics (3 semester hours) Genomic information content; data
searches and multiple sequence alignment; mutations and distance-based
phylogenetic analysis; genomics and gene recognition; polymorphisms and
forensic applications; nucleic-acid and protein array analysis; structure
prediction of biological macromolecules.
Prerequisites: STAT 1342 (introductory statistics) and MATH 1325 and
MATH 1326 (2 semesters of calculus). (3-0) T.
BMEN 6388 Nonlinear Dynamics and Control (3 semester hours) Introduction to analysis and control
methods for nonlinear dynamical systems, with application to representative
biological and engineering systems. Topics include local linearization and
stability analysis, phase space analysis, bifurcation analysis, chaos and
feedback linearization. Prerequisites:
BMEN 6385 Biomedical Signals & Systems. (3-0) Y
BMEN 6389 (BIOL 6385) Computational Biology (3 semester hours) Using computational and statistical
methods to analyze biological data, and perform mathematical modeling and
computational simulation techniques to understand the biological systems. The
course introduces methods in DNA/protein motif discovery, gene prediction, high-throughput
sequencing and microarray data analysis, computational modeling gene expression
regulation, and biological pathway and network analysis. Prerequisite: (BMEN
6374 and BMEN 6387) or BIOL 5376 or instructor permission. (3-0) Y
BMEN 6390 (BIOL 6390) Metabolic Pathways for Translational
Medicine (3 semester hours) This
course will provide extensive discussion of major metabolic pathways in human
and other experimental models of human diseases with emphasis on biochemical
understanding, roles and effects of the pathways in the entire cellular
network, and potential application to medicine. Prerequisites: BMEN 6389 or
BIOL 6385 or instructor permission. (3-0) T
BMEN 6391 (BIOL 6373) Proteomics (3 semester hours) Protein identification, sequencing, and analysis
of post-translational modifications by liquid chromatography/tandem mass
spectrometry; determination of protein three dimensional structure by x-ray
crystallography; its use in drug design; understanding protein interactions and
function using protein chip microarrays. Prerequisite: Undergraduate or
graduate biochemistry. (3-0) T
BMEN 6392 Bioinstrumentation and Systems (3 semester hours) Introduction to bioinstrumentation,
biomedical signal acquisition, isolation, amplification, and conditioning, biopotential
electrodes and amplifiers for ECG, EEG, ENG and EMG. Vascular system dynamics.
Transmission and propagation of EM and RF signals around tissue. Biomedical
applications. Prerequisites: BMEN 6385 Biomedical Signals and Systems. (3-0) Y.
BMEN 6V40 Individual Instruction in Biomedical Engineering (1-9 semester hours) (May be repeated for credit). ([1-9]-0)
R
BMEN 6V70 Research in Biomedical Engineering (3-9 semester hours) (May be repeated for credit). For
pass/fail credit only. ([3-9]-0) R
BMEN 6V71 Seminars in Biomedical Engineering (1-9 semester hours) (May be repeated for credit). For
pass/fail credit only. ([1-9]-0) R
BMEN 6V87 Special Topics in Biomedical Engineering (1-9 semester hours) (May be repeated for credit). ([1-9]-0)
S
BMEN 6V98 Thesis
(3-9 semester hours) (May be repeated for credit). For pass/fail credit only.
([3-9]-0) S
BMEN 7V87 Special Topics in Biomedical Engineering (1-9 semester hours) (May be repeated for credit). ([1-9]-0)
S
BMEN 7V88 Seminars in Biomedical Engineering (1-9 semester hours) (May be repeated for credit). ([1-9]-0)
R
BMEN 8V40 Individual Instruction in Biomedical Engineering (1-9 semester hours) (May be repeated for credit). ([1-9]-0)
R
BMEN 8V70 Research In Biomedical Engineering (3-9 semester hours) (May be repeated for credit). For
pass/fail credit only. ([3-9]-0) R
BMEN 8V99 Dissertation
(3-9 semester hours) (May be repeated for credit.) For pass/fail credit only.
([3-9]-0) S