Research
Goal
Goal
To create and continually enhance accurate, adaptive, and comprehensive mathematical models of control and atypical brain architecture, morphology, and wiring.
To create and continually enhance accurate, adaptive, and comprehensive mathematical models of control and atypical brain architecture, morphology, and wiring.
In general, I aim to better understand the topological and connective character of the brain, including both the steady state control construction as well as changes witnessed throughout prolonged duress. The goals of creating personalized patient care and improving prognosis, as well as my personal academic passions, shape these interests. I predominantly utilize various tools from Computational Anatomy, including Geometric Measure Theory and Pattern Theory, as well as connectomics.
In general, I aim to better understand the topological and connective character of the brain, including both the steady state control construction as well as changes witnessed throughout prolonged duress. The goals of creating personalized patient care and improving prognosis, as well as my personal academic passions, shape these interests. I predominantly utilize various tools from Computational Anatomy, including Geometric Measure Theory and Pattern Theory, as well as connectomics.
I previously worked on analyzing connectivity changes in a transgenic mouse model of Alzheimer's and in individuals who have suffered a Subarachnoid Hemorrhage.
I previously worked on analyzing connectivity changes in a transgenic mouse model of Alzheimer's and in individuals who have suffered a Subarachnoid Hemorrhage.
I currently hold membership in the Miller Lab at Johns Hopkins University and the Laboratory for Computational Intensive Care Medicine (LCICM) at Johns Hopkins Hospital.
I currently hold membership in the Miller Lab at Johns Hopkins University and the Laboratory for Computational Intensive Care Medicine (LCICM) at Johns Hopkins Hospital.
Full CV
Full CV
CV_latest.pdf