2013 — 2017 |
Leventhal, Daniel K |
K08Activity Code Description: To provide the opportunity for promising medical scientists with demonstrated aptitude to develop into independent investigators, or for faculty members to pursue research aspects of categorical areas applicable to the awarding unit, and aid in filling the academic faculty gap in these shortage areas within health profession's institutions of the country. |
Neuronal Oscillations and Dysregulated Motor Learning in Parkinsonian Rats
DESCRIPTION (provided by applicant): Dr. Leventhal recently completed a clinical and research fellowship in Movement Disorders at the University of Michigan, where he also did his Neurology residency. He holds the M.D. and Ph.D. (Biomedical Engineering) degrees from Case Western Reserve University. His background in Engineering, Neuroscience, and clinical Neurology will allow him to establish a distinctive research program centered on in vivo electrophysiology in animal models of Movement Disorders, coupled with complementary recordings in human subjects. To achieve this long-term goal, a career development plan is proposed that includes continued training in in vivo electrophysiological and ontogenetic techniques, coursework, conference attendance, and limited clinical and teaching responsibilities. By the end of the award period, his goal is to have established an independent laboratory focused on in vivo animal electrophysiology, be performing complementary electrophysiological experiments in human subjects, and have clinical duties in the Movement Disorders and DBS programs. The research plan focuses on important questions regarding the systems-wide electrophysiological changes observed in Parkinson Disease (PD). Synchronized neuronal beta (~15 - 30 Hz) oscillations are tightly correlated with motor impairment, but it remains an open question whether this aberrant neural activity causes clinical symptoms. This is an important issue because therapeutic deep brain stimulation (DBS) is believed to work by disrupting pathologic beta oscillations. These experiments will address several critical gaps in the literature. First, are enhanced beta oscillations linked to dopamine loss or motor impairment? Second, what is the role of the thalamus in generating beta rhythms? Finally, how are dopamine, beta rhythms, and fine motor control related? To address these questions, Dr. Leventhal will use innovative behavioral, electrophysiological, and ontogenetic techniques in awake, behaving rats. It is hypothesized that thalamic firing patterns drive beta oscillations, which cause the bradykinesia and rigidity of PD. At the end of the award period, Dr. Leventhal will be poised to establish a sustainable research program based upon the results of these studies and his ability to perform complementary electrophysiological experiments in animals and humans.
|
0.943 |