Faculty


 

Fidel Santamaria
Fidel Santamaria, Ph.D.
Associate Professor

Phone: (210) 458-6910
Email: fidel.santamaria@utsa.edu


Lab website

Areas of Specialization

» Computational neuroscience
» Experiments and modeling of cerebellar function
» Learning and memory
» Modeling power-law behavior from molecules to behavior


Brain Health Consortium
UTSA Neurosciences Institute

Education

Ph.D. in Neuroscience; California Institute of Technology
B.S. in Physics; National Autonomous University of Mexico

Research Interests

research image

Dr. Sanatmaria is a computational neuroscientist with two main lines of work. The first one is to understand how the cerebellum processes and stores information. In particular, he studies a really beautiful neuron called the Purkinje cell. His second line of research is very theoretical. Here his interest is to understand how the engram, the physical foundation of memory, is implemented by the interaction of processes spanning multiple scales of biological organization, from molecules to neuronal networks. For this he uses fractional order differential equations, a branch of mathematics that is the natural language to describe complex systems.

Dr. Sanatmaria's long term objective is to combine theory, modeling, and experiments to understand how the cerebellum computes information; develop closed-loop systems for neuronal control, particularly those associated with deep brain stimulation; and neuromorphic devices for the solution of real-time complex signal analysis for brain machine interfaces.

Training Opportunities

In Dr. Sanatmaria's lab, people can be trained in modeling, electrophysiology, and imaging. The modeling uses all available resources, from ready to use software to the lab's own algorithms. They run their simulations in local servers, computer clusters, super-computers, and even the cloud.

The experimental work that the lab performs requires performing intracellular recordings in live neurons in vitro. These recordings can be done also using fluorescent markers to then be visualized in a two-photon microscope. With this approach, the lab can control and monitor the electrical activity of the neuron while also visualizing biochemical signals in its complex dendrites. Ideally, all students in the lab should combine modeling and experimentation for their work.

Publications

Click here for a list of publications.