MADRID – Deep brain stimulation shows considerable promise for reducing intractable seizures in patients who are not candidates for epilepsy surgery, even though there have been few large-scale controlled trials to back up the practice.
“We have no idea what the best stimulation parameters are, we don't know whether to stimulate in response to epileptiform activity or continuously, and, of course, the search for the optimal target is ongoing,” Dr. Paul Boon said at the annual congress of the European Federation of Neurological Societies.
“Most of our information has come from uncontrolled studies and case reports, which included about 115 people worldwide.”
Now, data from three new or upcoming studies might help shed light on some of these questions, said Dr. Boon of University Hospital Ghent (Belgium), where he and his colleagues are leaders in researching an epilepsy application for DBS.
Some of the earliest studies, in the 1980s and early 1990s, used the electrodes in the brain's cerebellar regions, but with very little effect, so the cerebellum is no longer considered a target. The caudate nucleus and centromedial nucleus of the thalamus have also been examined as possible targets, but in very small numbers of patients and with varying results, said Dr. Boon.
The most promising approach to date is bilateral stimulation of the anterior thalamic nucleus, he said. Early uncontrolled studies of this application had small patient numbers, but their success led to the Stimulation of the Anterior Nucleus of the Thalamus for Epilepsy trial of 110 patients with medically refractory partial-onset seizures.
All of the patients received the implants; for the first 3 months, only half of the patient had their stimulators turned on. After this blinded treatment phase, all of the patients received neurostimulation. By way of detailing his financial conflicts of interest, Dr. Boon said in an interview that Medtronic Inc., the company that makes DBS hardware, has been and is providing devices and electrodes in support of the pilot trial, and has provided an educational grant.
The medial temporal lobe and the hippocampus are other potential targets. Last year, Dr. Boon and his colleagues published a study of 12 patients with refractory temporal lobe epilepsy, who were also candidates for surgery. Instead of implanting recording electrodes during the presurgical period, they implanted DBS electrodes in the medial temporal lobe.
“We aimed to adjust the simulation parameters to get a 50% reduction in spikes for 7 consecutive days,” he said. “If the patient achieved that, then we went to chronic stimulation, and if they did not achieve that, then we adjusted the parameters until we met those criteria. If the patient still didn't achieve the reduction, then we removed the electrodes and proceeded to surgery.”
Of the 12 patients, 10 underwent long-term DBS and 2 had the resection. After a mean follow-up of 31 months, both of the surgical patients were seizure free. One of the DBS patients had a seizure reduction of more than 90%; five had a reduction of at least 50%, and two had a reduction of 30%–40% (Epilepsia 2007;48:1551–60).
“We got a 70% response rate, with no significant adverse events or changes in memory,” he said. “This shows that DBS of the medial temporal lobe is safe, feasible, and effective.”
Dr. Boon and his group are also seeking to recruit 45 patients for a study comparing DBS of the hippocampus with medial temporal lobe resection or with hippocampal DBS delayed for 6 months after implantation. The 1-year trial will also be sponsored by Medtronic.
Researchers believe that DBS controls seizures by desynchronizing synchronized high-voltage cortical discharges. During chronic DBS, the stimulation is applied constantly to the epileptogenic focus, regardless of the area's own discharge.
However, there is some evidence that stimulation only in response to epileptiform activity might be more effective. This “closed-loop” stimulation would require a device that could read and analyze brain waves and then “decide” what type of stimulation to deliver.
Early external devices were tested in small numbers of patients in the late 1990s and early 2000s. More recently, a California-based company, NeuroPace Inc., has developed the RNS System, which includes fully implantable intracranial components as well as external products, Dr. Boon said.
The device consists of an implanted neurostimulator with one or two strip leads that can be placed in different areas of the brain to allow activity to be monitored and controlled.
An external programming device allows the stimulator to detect predetermined electrographic patterns; the physician can also program the type of response that the device delivers.