Closed-Loop Neurostimulation for Biomarker-Driven, Personalized Treatment of Major Depressive Disorder

Summary

Deep brain stimulation triggered by a patient-specific neural biomarker of a high-symptom state may better control symptoms of major depressive disorder compared to continuous, open-loop stimulation. This protocol provides a workflow for identifying a patient-specific neural biomarker and controlling the delivery of therapeutic stimulation based on the identified biomarker.

Abstract

Deep brain stimulation involves the administration of electrical stimulation to targeted brain regions for therapeutic benefit. In the context of major depressive disorder (MDD), most studies to date have administered continuous or open-loop stimulation with promising but mixed results. One factor contributing to these mixed results may stem from when the stimulation is applied. Stimulation administration specific to high-symptom states in a personalized and responsive manner may be more effective at reducing symptoms compared to continuous stimulation and may avoid diminished therapeutic effects related to habituation. Additionally, a lower total duration of stimulation per day is advantageous for reducing device energy consumption. This protocol describes an experimental workflow using a chronically implanted neurostimulation device to achieve closed-loop stimulation for individuals with treatment-refractory MDD. This paradigm hinges on determining a patient-specific neural biomarker that is related to states of high symptoms and programming the device detectors, such that stimulation is triggered by this read-out of symptom state. The described procedures include how to obtain neural recordings concurrent with patient symptom reports, how to use these data in a state-space model approach to differentiate low- and high-symptom states and corresponding neural features, and how to subsequently program and tune the device to deliver closed-loop stimulation therapy.

Introduction

Major depressive disorder (MDD) is a neuropsychiatric disease characterized by network-level aberrant activity and connectivity¹. The disease manifests a variety of symptoms that vary across individuals, fluctuate over time, and may stem from different neural circuits^2,3. Approximately 30% of individuals with MDD are refractory to standard-of-care treatments⁴, highlighting a need for new approaches.

Deep brain stimulation (DBS) is a form of neuromodulation in which electrical current is delivered to targeted areas of the brain with the....

Protocol

This protocol has been reviewed and approved by the University of California, San Francisco Institutional Review Board.

1. Device setup for patient at-home recordings

1. Work with a representative from the device company to set four configured channels for acquisition, two from each implanted lead.
   NOTE: Each channel records a bipolar recording. Configured channels may use adjacent (e.g., 1-2, 3-4) or interleaved (e.g., 1-3, 2-4) electrode contacts. When leads .......

Discussion

Deep brain stimulation has become an established therapy for Parkinson's disease, essential tremor, dystonia, and epilepsy, and is actively being investigated in numerous other neuropsychiatric conditions^26,27,28,29. The vast majority of DBS is delivered in open-loop mode, in which stimulation is delivered continuously. For symptoms which are paroxysmal in nature, continuous stimulation may.......

Materials

Name	Company	Catalog Number	Comments
Depth Lead	Neuropace	DL-330-3.5	30 cm length, 3.5 mm contact spacing
Depth Lead	Neuropace	DL-330-10	30 cm length, 10 mm contact spacing
Depth Lead	Neuropace	DL-344-3.5	44 cm length, 3.5 mm contact spacing
Depth Lead	Neuropace	DL-344-10	44 cm length, 10 mm contact spacing
Hat with velcro	Self-assembled	NA	Optional
Jupyter Notebook	Project Jupyter	NA
Magnet	Neuropace	M-01
Programmer	Neuropace	PGM-300	Clinician tablet
Python 3.10	Python	NA
Remote Monitor	Neuropace	5000	Patient laptop
Responsive Neurostimulation System (RNS)	Neuropace	RNS-320
Wand	Neuropace	W-02