<p>Inside the biomedical electronics lab at General Electric (GE) Global Research in Niskayuna, New York, Jeff Ashe, a principal engineer, holds up a mechanical pencil and points to its thin graphite point. <br /><br />That, he says, is the size of the new wireless brain implants GE is developing. <br /><br />The hope is that smaller, more biocompatible implants will help the paralysed walk and provide a more effective way to treat diseases that affect the brain.<br /><br />Neuroscientists have implanted such devices in the brains of several paralysed patients. But today’s implants are not practical solutions. <br /><br />They capture only a crude picture of activity inside the brain. </p>.<p>Also, they invariably begin to fail after a year or two, in large part because brain tissue begins encapsulating them in scar tissue. <br /><br />Not much of evolution<br /><br />The software that interprets signals from the implants has gotten much better in recent years, but the implants themselves have changed little.<br /><br />Some of the implants under development at GE should be about the same size as the neurons they’re measuring. According to Andrew Schwartz, a professor of neurobiology at the University of Pittsburgh, there is good evidence that making them so small will minimise the scarring. <br /><br />The implants are also being designed to have 10 times as many electrodes, so they will be able to record from thousands of neurons instead of just a couple of hundred. <br /><br />They should be wireless, too, eliminating the hardwired electrical connections that often fail and can cause infection.<br /><br />GE is testing a variety of approaches for growing very thin electrodes on top of microchips, using its expertise in fabricating microelectromechanical devices (MEMs).<br /><br /> The company thinks its experience with wireless medical devices and electronics could also help. <br /><br />Materials for coating the devices, which could help them last longer in the brain, are being tested now.<br />Existing implants, about the size of a thumbtack, have allowed a dozen or so patients to control a cursor or a robot arm just by thinking about it. <br /><br />This week, researchers at Ohio State University reported that an implant that detects electrical activity in neurons, paired with a device that conveys electrical signals to a paralysed arm, allowed a patient to move his hand by the power of thought.<br /><br />GE is collaborating with John Donoghue, a neuroscientist at Brown University who is pioneering the use of implants as aids to paralysed patients.<br /><br /> The medical-device maker Medtronic and a few startups are working on better implants as well.<br /><br /></p>
<p>Inside the biomedical electronics lab at General Electric (GE) Global Research in Niskayuna, New York, Jeff Ashe, a principal engineer, holds up a mechanical pencil and points to its thin graphite point. <br /><br />That, he says, is the size of the new wireless brain implants GE is developing. <br /><br />The hope is that smaller, more biocompatible implants will help the paralysed walk and provide a more effective way to treat diseases that affect the brain.<br /><br />Neuroscientists have implanted such devices in the brains of several paralysed patients. But today’s implants are not practical solutions. <br /><br />They capture only a crude picture of activity inside the brain. </p>.<p>Also, they invariably begin to fail after a year or two, in large part because brain tissue begins encapsulating them in scar tissue. <br /><br />Not much of evolution<br /><br />The software that interprets signals from the implants has gotten much better in recent years, but the implants themselves have changed little.<br /><br />Some of the implants under development at GE should be about the same size as the neurons they’re measuring. According to Andrew Schwartz, a professor of neurobiology at the University of Pittsburgh, there is good evidence that making them so small will minimise the scarring. <br /><br />The implants are also being designed to have 10 times as many electrodes, so they will be able to record from thousands of neurons instead of just a couple of hundred. <br /><br />They should be wireless, too, eliminating the hardwired electrical connections that often fail and can cause infection.<br /><br />GE is testing a variety of approaches for growing very thin electrodes on top of microchips, using its expertise in fabricating microelectromechanical devices (MEMs).<br /><br /> The company thinks its experience with wireless medical devices and electronics could also help. <br /><br />Materials for coating the devices, which could help them last longer in the brain, are being tested now.<br />Existing implants, about the size of a thumbtack, have allowed a dozen or so patients to control a cursor or a robot arm just by thinking about it. <br /><br />This week, researchers at Ohio State University reported that an implant that detects electrical activity in neurons, paired with a device that conveys electrical signals to a paralysed arm, allowed a patient to move his hand by the power of thought.<br /><br />GE is collaborating with John Donoghue, a neuroscientist at Brown University who is pioneering the use of implants as aids to paralysed patients.<br /><br /> The medical-device maker Medtronic and a few startups are working on better implants as well.<br /><br /></p>