Description

Objective: The objective of the proposed research is to test the ability of theta stimulation of the STN to modulate cognitive processing in PD patients by directly targeting associative STN circuitry.

Hypothesis: The hypothesis is that theta stimulation of associative STN circuitry will improve performance on cognitive tasks compared to a control condition, where stimulation is targeting a sensorimotor STN circuit.

Methods: Power analysis - with previously reported moderate effect sizes (Cohen's d=0.57), the investigators anticipate the need to recruit 27 subjects for a within-subject design with a power of 0.8 and an alpha level of 0.05.

Subjects: Patients with deep brain stimulation systems will be recruited from the Vancouver General Hospital DBS clinic. Subjects will be included if they have STN DBS, pre- and post-operative imaging (to allow electrode reconstruction), and are at least three months post-operative. Subjects will be excluded if they are unable to complete the cognitive task (due to language barriers or dementia) or if they have significant DBS related complications.

Study design: This is a double blind, randomized, cross-over within-subject repeated measure design assessing the interaction between stimulation location and behavioural modification. Subjects will be blinded to stimulation condition, and the individual administering the working memory task will also be blinded, as a neutral third party will program the DBS settings for each condition.

Identification of associative STN network and optimal electrode configuration: Before the subject arrives for stimulation, the location of the electrode will be reconstructed using the pipeline in LeadDBS. Briefly, a pre-operative MRI and a post-operative CT scan will be co-registered and subsequently non-linearly normalized into standard space. Electrodes will be identified and reconstructed using the PaCER algorithm as implemented in LeadDBS. Using each subject's individualized electrode reconstruction, we will calculate the volume of tissue activated (VTA) to optimally engage either the associative or sensorimotor STN networks. Multiple VTA configurations will be evaluated to achieve this goal. VTAs targeting the associative STN network will be defined by maximizing structural and functional connectivity to the dorsolateral prefrontal cortex (DLPFC) while minimizing connectivity to the primary motor cortex (M1) and supplementary motor area (SMA) among the viable configurations for the individual electrode. Conversely, VTAs designed to engage the sensorimotor STN network are defined by maximizing connectivity to M1 and SMA and minimizing connectivity to the DLPFC.

Structural and functional connectivity will be quantified as follows: Percent overlap of the individual VTA with the associative and sensorimotor STN regions will be calculated using MATLAB, employing the DISTAL Atlas to delineate each STN region. Structural connectivity will be estimated by computing the total number of streamlines connected to the VTA that pass through the specified region-of-interest (ROI), based on structural normative connectomes. Functional connectivity will be assessed by calculating the Pearson's correlation coefficient between the VTA and the ROI, using resting-state functional normative connectomes.

If it is not feasible to differentially activate the associative or sensorimotor STN networks using these criteria, simplified VTAs will be employed: a ventral VTA and a dorsal VTA. This may be the case due to the anatomical location of the electrode or the electrode model (ring-mode or directional).

Baseline cognitive assessment: Each subject will undergo a baseline cognitive screening examination (Montreal Cognitive Assessment, MOCA), that will be used as a covariate in future analysis. This will be done as part of their routine screening prior to DBS surgery.

Theta DBS: Subjects will come into the clinic in the OFF-medication state, to help control for the known non-linear contribution of dopamine to working memory. They will undergo a computerized working memory task while being stimulated in each of four following conditions:

1. OFF
2. Target condition: Theta (6 Hz) stimulation of the associative STN. If differential activation of the associative and sensorimotor STN networks is not feasible, ventral VTA is used.
3. Anatomical control condition: Theta stimulation of the sensorimotor STN. If differential activation is not feasible, dorsal VTA is used
4. Frequency control condition: High-frequency (135 Hz) stimulation of the associative STN. If differential activation is not feasible, ventral VTA is used.

These conditions will be randomized within each subject by creating a random integer (1-4) with no repeats. The amplitude and pulse width will remain constant (2.5 mA, 60us). After changing the stimulation setting, there will be a wait period of 5-10 minutes prior to commencement of the working memory task. The subject will be asked if there is any unwanted stimulation side-effect (for example paresthesia). If the subject has paraesthesia or otherwise complains about the stimulation, the amplitude will be reduced by 0.5mA. If stimulation is not possible, the patient will be excluded from the study. Immediately before the working memory task commences, subjects will undergo a brief motor examination, consisting of items from the Unified Parkinson's Disease Rating Scale III. At the end of the session, the subjects will be placed back on their clinically optimized program and will take their medication according to their normal schedule.

Working Memory Task: A modified Sternberg task will be presented using a laptop computer.

Statistical analysis: The primary outcome will be working memory performance during each stimulation condition as assessed by a linear mixed effect model. The model will be specified as working memory performance ~ age + MoCA + stimulation condition + baseline cognition*stimulation condition + stimulation order + (1|subject). The hypothesis is that there will be a main effect of stimulation condition on working memory performance, with post-hoc one sample t-tests demonstrating an improvement in the theta associative STN condition relative to the other conditions. An interaction effect of baseline cognition with stimulation condition is also expected to be observed. Based on previous literature, it is hypothesized that subjects with lower baseline cognition will have more improvement during associative STN region stimulation.

To further understand the impact of differential network activation, a secondary analysis will categorize subjects into two groups: 1) those where differential activation of the associative and sensorimotor STN networks was achieved and 2) those where differential targeting of these networks was not possible based on the imaging criteria. We will repeat the linear mixed effect model, adding an interaction term between stimulation condition and group. The hypothesis is that there will be a significant interaction effect between stimulation condition and group, with higher working memory performance observed during theta stimulation of the associative STN in the group where differential targeting of the associative STN network was achieved. This will enable the assessment of whether precise STN network targeting influences working memory outcomes and to evaluate the impact of direct network engagement on cognitive effects.

By including the stimulation order variable, the investigators will adjust for the possibility that subjects performance will decline over time (due to fatigue) irrespective of the stimulation condition. Supplementary analysis will assess for motor performance during each stimulation condition, with the hypothesis that high frequency stimulation will have a reduction in motor scores compared to low frequency stimulation. Post-hoc analysis will also be performed to assess the relationship between task performance and functional and structural connectivity between the STN and associative networks, assuming there is some variability in individual connectivity strengths.