Implantable device cuts obstructive sleep apnea symptoms
News Jun 10, 2016
Device offers promise for patients unable to tolerate CPAP, study says -
Since the 1980s, continuous positive airway pressure (CPAP), in which positive pressure is pushed through the nasal airways to help users breathe while sleeping, has been by far the most widely used treatment for obstructive sleep apnea (OSA). With more than 18 million people experiencing OSA, a number expected to rise, new results from a University of Pennsylvania (Penn) case study of a new device implanted in the chest called hypoglossal nerve stimulation (HGNS) offers promise for patients with moderate to severe OSA who cannot tolerate CPAP. Researchers at the Perelman School of Medicine at the University of Pennsylvania will present data on their outcomes with hypoglossal nerve stimulation for the treatment of patients with sleep apnea at SLEEP 2016, the 30th annual meeting of the Associated Professional Sleep Societies LLC.
The device is a pacemaker with a tiny generator and a sensing lead, but instead of using electrical pulses to control abnormal heart rate, the device uses two wires to stimulate the tongue. Patients use a remote control to turn on the device before going to sleep and turn it off upon waking up. A delay allows the user to fall asleep before the pulse generator begins stimulation. After detecting the user's breathing pattern, the machine stimulates the hypoglossal nerve (the nerve that controls tongue motion) which enlarges the upper airway.
In the current Penn case study, 20 implants were completed at the University of Pennsylvania between January 2015 and March 2016. All patients had information from a baseline polysomnography (PSG) recording prior to HGNS implant, as well as a post PSG approximately two months after HGNS, to assess the severity of their apnea and any change after treatment. Those who received the implant were typically overweight, middle aged, and had severe OSA.
Total apnea-hypopnea index (AHI)—which measures severity of sleep apnea by counting the number of pauses in breathing during sleep—for all patients significantly decreased an average of 35 events per hour after the device was planted, which corresponds to an average reduction of 84 percent. Additionally, the lowest oxygen level measured in the blood during the night significantly increased by 11 percent, from 79 percent to 90 percent.
In the previous STAR clinical trial, NCT01161420, which led to the device's FDA approval in April 2014 for patients unable to tolerate CPAP, patients implanted with the Inspire Upper Airway Stimulation device showed a 78 percent reduction in AHI and 80 percent fewer oxygen desaturation events (number of times the oxygen levels in the blood were low). These results were sustained three years after the device was implanted.
The STAR trial was conducted under controlled conditions, while the Penn study takes the next step by looking at outcomes in post-approval clinical use of the device. By replicating the success of the clinical trial, the findings show that the device is as successful in the general clinical population as it was in participants that met the previous clinical trial criteria.
"Considering that sleep apnea can lead to high blood pressure, heart attack, stroke, and other serious health problems, it is critically important that we study devices that may serve as another option instead of CPAP to treat patients with sleep apnea," said lead author Richard Schwab, MD, co-medical director of the Penn Sleep Center. "There is no perfect treatment option for obstructive sleep apnea, but our preliminary data suggest that hypoglossal nerve stimulation can effectively treat patients with sleep apnea who are unable to tolerate CPAP."
Note: Material may have been edited for length and content. For further information, please contact the cited source.
SLEEP 2016 - 30th annual meeting of the Associated Professional Sleep Societies LLC
Abstract 0378: Schwab R et al. Hypoglossal Nerve Stimulation for Obstructive Sleep Apnea: Initial results at the University of Pennsylvania.
Biomaterial Helps Brain Tissue Regrow After StrokeNews
A new stroke-healing gel created by UCLA researchers helped regrow neurons and blood vessels in mice whose brains had been damaged by strokes.READ MORE
Ataxin Links Long Term-Memory and NeurodegenerationNews
Scientists have just discovered that a small region of a cellular protein that helps long-term memories form also drives the neurodegeneration seen in motor neuron disease (MND)READ MORE
New Inherited Neurodevelopmental Disease DiscoveredNews
Researchers have identified a new inherited neurodevelopmental disease that causes slow growth, seizures and learning difficulties in humans.READ MORE