Skip to main content

Offline Learning of Closed-Loop Deep Brain Stimulation Controllers for Parkinson Disease Treatment.

Publication ,  Journal Article
Gao, Q; Schimdt, SL; Chowdhury, A; Feng, G; Peters, JJ; Genty, K; Grill, WM; Turner, DA; Pajic, M
Published in: ArXiv
March 16, 2023

Deep brain stimulation (DBS) has shown great promise toward treating motor symptoms caused by Parkinson's disease (PD), by delivering electrical pulses to the Basal Ganglia (BG) region of the brain. However, DBS devices approved by the U.S. Food and Drug Administration (FDA) can only deliver continuous DBS (cDBS) stimuli at a fixed amplitude; this energy inefficient operation reduces battery lifetime of the device, cannot adapt treatment dynamically for activity, and may cause significant side-effects (e.g., gait impairment). In this work, we introduce an offline reinforcement learning (RL) framework, allowing the use of past clinical data to train an RL policy to adjust the stimulation amplitude in real time, with the goal of reducing energy use while maintaining the same level of treatment (i.e., control) efficacy as cDBS. Moreover, clinical protocols require the safety and performance of such RL controllers to be demonstrated ahead of deployments in patients. Thus, we also introduce an offline policy evaluation (OPE) method to estimate the performance of RL policies using historical data, before deploying them on patients. We evaluated our framework on four PD patients equipped with the RC+S DBS system, employing the RL controllers during monthly clinical visits, with the overall control efficacy evaluated by severity of symptoms (i.e., bradykinesia and tremor), changes in PD biomakers (i.e., local field potentials), and patient ratings. The results from clinical experiments show that our RL-based controller maintains the same level of control efficacy as cDBS, but with significantly reduced stimulation energy. Further, the OPE method is shown effective in accurately estimating and ranking the expected returns of RL controllers.

Duke Scholars

Published In

ArXiv

EISSN

2331-8422

Publication Date

March 16, 2023

Location

United States
 

Citation

APA
Chicago
ICMJE
MLA
NLM
Gao, Q., Schimdt, S. L., Chowdhury, A., Feng, G., Peters, J. J., Genty, K., … Pajic, M. (2023). Offline Learning of Closed-Loop Deep Brain Stimulation Controllers for Parkinson Disease Treatment. ArXiv.
Gao, Qitong, Stephen L. Schimdt, Afsana Chowdhury, Guangyu Feng, Jennifer J. Peters, Katherine Genty, Warren M. Grill, Dennis A. Turner, and Miroslav Pajic. “Offline Learning of Closed-Loop Deep Brain Stimulation Controllers for Parkinson Disease Treatment.ArXiv, March 16, 2023.
Gao Q, Schimdt SL, Chowdhury A, Feng G, Peters JJ, Genty K, et al. Offline Learning of Closed-Loop Deep Brain Stimulation Controllers for Parkinson Disease Treatment. ArXiv. 2023 Mar 16;
Gao Q, Schimdt SL, Chowdhury A, Feng G, Peters JJ, Genty K, Grill WM, Turner DA, Pajic M. Offline Learning of Closed-Loop Deep Brain Stimulation Controllers for Parkinson Disease Treatment. ArXiv. 2023 Mar 16;

Published In

ArXiv

EISSN

2331-8422

Publication Date

March 16, 2023

Location

United States