Major Findings: Seizures declined by a mean of 29% during active stimulation with the device over the first 12 weeks, compared with a 14% reduction during sham activation.
Source of Data: Multicenter, randomized, sham-controlled clinical trial of 191 patients with medically intractable partial onset seizures.
Disclosures: Dr. Morrell is the chief medical officer of NeuroPace, which developed the system and funded the trial.
BOSTON – Patients with treatment-resistant epilepsy can significantly reduce their frequency of seizures with the use of an implantable device that detects preseizure electrical activity and preemptively aborts seizures.
In 191 patients with medically intractable partial onset seizures who were implanted with the neurostimulator, seizures declined by a mean of 29% during active stimulation with the device, compared with a 14% reduction during sham activation, Dr. Martha J. Morrell reported at the annual meeting of the American Epilepsy Society.
In the later, open-label phase of the study in which all of the patients received the active stimulation, nearly half of the 171 patients for whom 12 weeks of data were available experienced at least a 50% reduction in seizure frequency relative to baseline, said Dr. Morrell, clinical professor of neurology at Stanford (Calif.) University and chief medical officer of NeuroPace, developer of the Responsive NeuroStimulator System (RNS).
The cranially implanted RNS device differs from conventional, “open loop” brain stimulation technologies that involve the scheduled delivery of electrical stimulation to specific brain regions independent of brain activity.
“The RNS delivers stimulation in response to a detected event,” said Dr. Morrell, noting that the treatment is “individualized and dynamic” in that it uses computer technology to recognize and respond to patterns of brain activity specific to individual patients' seizure patterns.
The RNS comprises electrodes that are surgically implanted in epileptic regions of the brain and connected to the computerized, battery-powered neurostimulator, which is embedded in the patient's skull. The device, which continuously monitors the electrical activity of the patient's brain, is programmed by a neurologist to detect and disrupt significant electrical events. “The programming is done wirelessly via a laptop computer,” Dr. Morrell said. “It's highly modifiable in that the physician can view the patient's electrocorticographic activity in real time and change the [signal-detection] criteria at any time based on individual patient characteristics.”
Up to two leads, each containing four electrodes, can be connected to the neurostimulator, so the system can monitor and deliver responsive stimulation to two distinct epileptogenic zones independently, she noted.
Because the neurostimulation occurs in response to aberrant electrical activity in the brain, fewer electrical impulses are being delivered to the brain than would occur with continuous stimulation. This in turn diminishes the possibility of treatment-related adverse events.
In an initial feasibility study of 65 patients, the responsive neurostimulation system demonstrated excellent safety, tolerability, and preliminary evidence of efficacy, Dr. Morrell said. “There were no serious device-related adverse events, and stimulation-related symptoms experienced by several subjects were addressed by adjusting the stimulation settings.”
The preliminary efficacy evidence from that study showed that a minimum 50% reduction in seizure frequency was experienced by 43% of the patients with complex partial seizures and 35% of those with total disabling seizures (Neurotherapeutics 2008;5:68–74).
In the double-blind pivotal trial, the 191 patients were randomized to active or sham therapy. The patients were between 18 and 70 years of age (median age 35 years), and all had partial onset epilepsy localized to one or two foci and had failed at least two antiepileptic medications.
The patients were taking an average of three antiepileptic medications to attempt seizure control, and about 34% of the patients had been treated previously with vagus nerve stimulation, 33% had prior surgical resection, and 16% had been treated with both.
“These patients tended to be very ill. Most of them had epilepsy for more than 20 years, and many were having at least three seizures per 28-day period–often many more than that,” Dr. Morrell said.
Of the 191 patients implanted with the device, 50% had mesial temporal seizure onset, 42% had neocortical seizure onset, and 8% had both, Dr. Morrell said in a press briefing at the meeting.
The trial consisted of an initial, 12-week period prior to system implantation during which baseline seizure activity was collected, followed by a 12-week blinded period when participants were randomly assigned to have the responsive stimulation activated or left inactive, she said.
At each of the 31 trial sites, the patients and one neurologist were blinded to the stimulation status, while a separate neurologist programmed the devices in order to maintain the study blinding. The responsive stimulation was optimized in the treatment over the next four weeks, followed by 84 days of data collection. At the end of the blinded efficacy period, stimulation was activated for all of the study participants for two years post-implantation, Dr. Morrell said.