Compatibility of Standard Vagus Nerve Stimulation and Investigational Microburst Vagus Nerve Stimulation Therapy with fMRI

MATERIALS AND METHODS

This prospective, interventional, unblinded multicenter study (NCT03446664) designed to collect data from patients with drug-resistant epilepsy (DRE) 12 years of age and older with an implanted investigational VNS (Model 1000C µB SenTiva VNS Therapy System; LivaNova USA) was conducted between February 1, 2018, and October 7, 2021.⁸ The study was in accordance with the ethical principles of the Declaration of Helsinki consistent with Good Clinical Practice described in ISO 14155 (https://en.wikipedia.org/wiki/ISO_14155) and the applicable regulatory requirements. All study participants provided informed consent, and study sites adhered to the institutional review board/ethics committee (https://clinicaltrials.gov/study/NCT03446664).

The investigational VNS device, Model 1000C, is physically identical to the conditionally approved Model 1000 (SenTiva VNS Therapy System) except for markings and firmware changes (Online Supplemental Data). Testing for the Model 1000 followed the requirements of ISO 14708–3, which indicates ISO/TS 10974 as the proper methodology for MR conditional assessments of active implantable medical devices. Modifications of the Model 1000 for the investigational Model 1000C included configuration to deliver either commercially available standard VNS or investigational µVNS. The investigational VNS device is also configured with the ability to disregard the reed switch response under the presence of a magnetic field, removing the necessity for any careful alignment with respect to the B₀ field. Additional testing was performed on the Model 1000C, the investigational VNS device, to monitor stimulation output during MR imaging (normally off) and was submitted as part of the investigational device exemption submission. No additional MR imaging device interaction risk was created by adding the stimulation output.

We studied 2 groups: 1) those with FOS and, 2) those with electroencephalogram-verified primary generalized tonic-clonic seizures (PGTC). Participants were neuromodulation-naïve, and additional investigational devices and/or investigational drugs were not permitted.

Participants underwent sequential fMRI at 2 weeks and 1-, 3-, and 6-month visits.³ They were placed in the 3T MR imaging scanner and had a series of 3 fMRI scans per visit with VNS “on” and a minimum scan time of 30 minutes (6 levels, 5 minutes per level) per day. There was an additional scanning time with the VNS “off,” which could add 10–15 minutes per session, which included structural MR imaging and resting-state fMRI. The time for patient positioning in the magnet varied with an additional 5–10 minutes per session. Participants were instructed to inform the physician, radiologist, and/or MR imaging technologist overseeing the procedure if they experienced any adverse effects during their scans. Inquiries were also made by the study investigator of the participant during each visit.

A single-channel transmit/receive head coil was used for data-acquisition. Recent regulatory approval under “group A” scan conditions permits the use of the body-transmit coil. However, those parameters are more stringent than the transmit/receive head coil, and using the body coil would have necessitated modifications to the proposed study protocol versus the initial pilot study. Each scan included acquisition of a localizer scan and an isotropic 3D T1-weighted anatomic sequence followed by fMRI during active stimulation of the VNS device (either standard or microburst).³ Functional data were acquired using gradient-echo EPI with the following parameters: TR/TE = 3000/25 ms, flip angle = 84°, voxel size = 3 mm isotropic, FOV = 256 mm, whole-brain coverage, 603 measurements, and a partial Fourier factor = 6/8. fMRI scans were obtained in a dose-dependent manner, leveraging a block design with 30 seconds of stimulation (on time) followed by 30 seconds of no stimulation (off time). Each on/off cycle was repeated 5 times for a total of 5 minutes before the parameter was changed for the next 5 minutes. Six 5-minute cycles were used for the fMRI scanning time of 30 minutes. During the fMRI study procedures, the parameter sweep feature on the investigational device was used and the reed switch (used to either inhibit or stimulate in Magnet mode) was disregarded.³

The study design required participants to have the device stimulated during the parameter sweep phase while undergoing the fMRI, so the fMRI results could further guide therapeutic adjustments. Following completion of a parameter sweep, the reed switch response was re-enabled and functioned as intended for normal use of the stimulator. Participants were continuously monitored by the MR imaging technologist and the LivaNova (device manufacturer) field engineers during and between scans.

Statistical analysis was not conducted to compare the demographics or outcomes of the study groups; therefore, no formal sample size calculation was provided.⁸ The number of subjects per cohort was deemed sufficient to provide initial information on the safety of the device. The final analysis was conducted when all participants completed the study at month 12.