Maastricht Economic and social Research and  training centre on Innovation and Technology

Devil in the Data
When it comes to fully understanding intra-European mobility, we still have a surprisingly long way to go…

Subscribe and receive
I&T Weekly by email
email address


Please type the above code:
All headlines
  • Facebook to exclude billions from European privacy laws
  • Plastic-eating enzyme holds promise in fighting pollution
  • New oil spill clean-up 'sponge' created from waste
  • Japan's rare-earth mineral deposit can supply the world for centuries
  • Cutting-edge microscope spies on living cells inside the body
  • How to bend and stretch a diamond
  • Hearing implant uses lasers to shoot sound into your ear
    A new implantable device uses pulses of light to stimulate auditory nerves, offering an improvement on existing cochlear implants.

    Traditional implants rely on a series of electrodes that lie directly against the membrane of the inner ear, and use electrical signals to stimulate the auditory nerves lying beneath. However, implanting them can further damage hearing, and electrical currents can spread easily through the neural tissue to stimulate nearby cells, which the patient hears as noise.

    The new work, coordinated by the Swiss Center for Electronics and Microtechnology in Alpnach, Switzerland, builds on the recent discovery of the 'optoacoustic effect' - namely, that cells can be stimulated by pulses of infrared light. But exactly how this happens is unclear.

    One theory suggests that it works because rapidly heating nerve cells with light pulses causes them depolarise, triggering an action potential. A competing theory has it that the laser pulses rapidly heat water molecules in the inner ear, causing tiny shockwaves that vibrate the hairs in the same way sound waves normally do.

    Now, researchers from the Laser Zentrum Hannover in Germany have found evidence for the latter: their system did not work in guinea pigs which had intact auditory nerves but were missing their hair cells. This supports the optoacoustic stimulation theory, they say, and they aim use this refinement of the optoacoustic effect to develop a new generation of cochlear implants.

    Their next focus will be to make the system more energy efficient so that the battery lasts longer. Rather than replace existing cochlear implants, it's likely that the two technologies will be combined, to give patients a system with greater flexibility that can adapt to their needs over time.

    New Scientist    November 24, 2017