Low-Frequency Dual Target Deep Brain Stimulation May Relieve Parkinsonian Symptoms

Rocio Rodriguez Capilla
Aislinn M. Hurley
Karthik Kumaravelu
Jennifer J. Peters
Hui-Jie Lee
Dennis A. Turner
Warren M. Grill
Stephen L. Schmidt

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Abstract

Background

Deep brain stimulation (DBS) reduces the motor symptoms of Parkinson’s disease. The two most common targets are the subthalamic nucleus and the globus pallidus. Dual target deep brain stimulation may better reduce symptoms and minimize side effects, but the optimal parameters of dual target deep brain stimulation and their potential interactions are unknown.

Objective

Our purpose was to quantify the frequency response of dual target DBS on bradykinesia and beta oscillations in participants with Parkinson’s disease, and to explore intrahemispheric pulse delays as a means to reduce total energy delivered.

Methods

We applied dual target DBS using the Summit RC+S in six participants, varying deep brain stimulation frequency.

Results

Dual target DBS at 50 Hz was effective at reducing bradykinesia, whereas increasing deep brain stimulation frequency up to 125 Hz also significantly reduced beta power. This frequency effect on beta power was replicated in a biophysical model. The model suggested that 22 Hz dual target deep brain stimulation, with an intrahemispheric delay of 40 ms, can reduce beta power by 87%.

Conclusion

We conclude that dual target DBS at 125 Hz best reduced bradykinesia. However, low frequency DBS with an appropriate intrahemispheric delay could improve symptom relief.

Version published to 10.1101/2025.03.25.25324612v1 on medRxiv
Mar 25, 2025

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Abstract

Background

Objective

Methods

Results

Conclusion

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