Now, a brain-recording device that melts into place
April 19th, 2010 - 5:26 pm ICT by ANILondon, Apr 19 (ANI): A newly developed brain implant can essentially melt into place, snugly fitting to the brain’s surface.
The technology could pave the way for better devices to monitor and control seizures, and to transmit signals from the brain past damaged parts of the spinal cord.
“These implants have the potential to maximize the contact between electrodes and brain tissue, while minimizing damage to the brain. They could provide a platform for a range of devices with applications in epilepsy, spinal cord injuries and other neurological disorders,” Nature quoted Dr. Walter Koroshetz, deputy director of the National Institute of Neurological Disorders and Stroke (NINDS), as saying.
The study shows that the ultrathin flexible implants, made partly from silk, can record brain activity more faithfully than thicker implants embedded with similar electronics.
The simplest devices for recording from the brain are needle-like electrodes that can penetrate deep into brain tissue.
More state-of-the-art devices, called micro-electrode arrays, consist of dozens of semi-flexible wire electrodes, usually fixed to rigid silicon grids that do not conform to the brain’s shape.
In people with epilepsy, the arrays could be used to detect when seizures first begin, and deliver pulses to shut the seizures down.
In people with spinal cord injuries, the technology has promise for reading complex signals in the brain that direct movement, and routing those signals to healthy muscles or prosthetic devices.
“The focus of our study was to make ultrathin arrays that conform to the complex shape of the brain, and limit the amount of tissue damage and inflammation,” said Dr. Brian Litt, M.D., an author on the study.
The silk-based implants can hug the brain like shrink wrap, collapsing into its grooves and stretching over its rounded surfaces.
The implants contain metal electrodes that are 500 microns thick, or about five times the thickness of a human hair.
The absence of sharp electrodes and rigid surfaces should improve safety, with less damage to brain tissue.
Also, the implants’ ability to mould to the brain’s surface could provide better stability; the brain sometimes shifts in the skull and the implant could move with it.
Finally, by spreading across the brain, the implants have the potential to capture the activity of large networks of brain cells, said Litt.
In the future, the researchers hope to design implants that are more densely packed with electrodes to achieve higher resolution recordings.
The study has been published in Nature Materials. (ANI)
- New implant to ease seizures fits snugly into brain - Apr 19, 2010
- Diamond-studded electrode could cure paralysis - Oct 06, 2010
- Neurons play distinct roles at different stages of epileptic seizures - Mar 28, 2011
- New treatment to heal spinal injuries - Nov 17, 2011
- New treatment could help minimize nerve damage in spinal cord injuries - May 04, 2011
- Study shows brain waves can 'write' on a computer - Dec 07, 2009
- Researchers take first steps towards mind-machine interface - Dec 07, 2009
- Brain's 'radio stations' have a lot to tell scientists - Feb 09, 2011
- Scientists find extensive natural recovery after spinal cord injury - Nov 15, 2010
- Soon, brain chip that could herald the end of paralysis - Jul 05, 2010
- Stem cells can fix damaged spinal cord tissue - Oct 09, 2010
- Heating up pelvic nerves could halt premature ejaculation - Mar 16, 2011
- Scientists translate brain signals into words - Sep 07, 2010
- Soon, flexible retinal implants to restore vision - Dec 15, 2009
- Tiny smart chip to combat chronic pain - Dec 17, 2010
Tags: art devices, brain activity, brain implant, brain tissue, dr brian, dr walter, flexible wire, metal electrodes, micro electrode, microns, national institute of neurological disorders, ninds, other neurological disorders, parts of the spinal cord, prosthetic devices, seizures, spinal cord, spinal cord injuries, tissue damage, wire electrodes