Program Information
Neuroscience Curriculum
Understanding nervous system functions and disorders from
molecules to mind is one of the greatest challenges facing the
biomedical sciences. A multidisciplinary enterprise and one of the
fastest advancing domains of science and technology, Neuroscience
addresses questions fundamental to human nature. How does brain activity
lead to perception, cognition, emotion, and other behaviors? How do
genes and experience ("nature and nurture") shape our brains, our minds,
and who we are? How can we protect, restore and enhance brain and other
nervous system functions? Resolution of these grand challenges can do
more to explain and predict the human condition than any other realm of
science.
Objective and Scope of the Training Program
The Neuroscience Graduate Program (NGP) at UTMB established in 1981 was the first PhD program in neuroscience in Texas. The rich interdisciplinary program of course work and research provides an internationally competitive education that enhances a trainee's
ability to become a scholarly and productive contributor to our knowledge of nervous system function and disease mechanisms.
It is anticipated that our graduates will become researchers and/or teachers in the field of neuroscience in academic institutions, industry, biotechnology or government. The program is designed to be rigorous but flexible and is explicitly multidisciplinary.
Research can be done in areas ranging from molecules to excitable membranes to behavior, using preparations ranging from cell cultures to isolated ganglia to brain slices to intact nervous systems of invertebrates and vertebrates.
Students are exposed to a broad, integrated foundation of courses in the biomedical sciences and to fundamental neurobiological concepts. They also gain exposure to modern experimental techniques: immunocytochemistry, live cell imaging, electron and confocal
microscopy, nuclear magnetic resonance-based imaging; electrophysiological methods of extracellular recording and patch clamping; molecular, biochemical and pharmacological methods for identifying and characterizing drugs and drug targets, neurotransmitters,
peptides, growth factors, receptors, chaperones andother intracellular signaling molecules; immunological, cell culture, and a multitude of behavioral assays. Major areas of research strength in the program include: neuroplasticity, learning and memory;
pain mechanisms, neural injury and brain trauma; drug abuse and addiction; neurodegenerative disorders (Alzheimer's, Parkinson's, ALS); other conditions and disorders affecting the nervous system.
Our goal is to graduate neuroscientists who have a broad base of experience with modern experimental skills and comprehensive knowledge background of the organization, structure and functions of nervous systems and who will seek to explore cellular and
molecular mechanisms of important nervous system functions and disorders.