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World's Smallest Implantable Device to Control Brain Patterns


Scientists have developed the world's smallest implantable device - no bigger than the width of a coin - that can be used to control brain patterns.

The device converts infrared light into blue light to control neural activity and is both the smallest and lightest wireless optical biodevice to be reported.

For centuries, it has been known that chemicals can change neural behaviour. The field of optogenetics proved that neural behaviour can also be changed with mere light.

It is now known that light can activate certain proteins in the brain to change brain patterns. Accordingly, scientists have implanted optical devices to successfully control the behaviour of rodents using nothing more than light of specific wavelengths as the stimulus.

However, the devices are often bulky, akin to wearing a football helmet or something heavier, and cause discomfort and distress to the animals.

Takashi Tokuda, an associate professor at the Nara Institute of Science and Technology (NAIST) in Japan, has been investigating ways to miniaturise implantable optical devices.

Size is always the challenge. No one likes having large implants, he said.

The miniaturisation of implantable devices has been hindered by a dependency on electromagnetic. In such devices, both the voltage and the current decrease with a reduction in size, thus limiting the power.

On the other hand, in devices that depend on photovoltaics, the voltage remains unchanged as size is reduced.

The new device made by Tokuda's research team uses a complementary metal-oxide semiconductor that controls photovoltaic power.

We integrated two sets of photovoltaic cells onto semiconductor chips. Ten cells were integrated for powering, and seven cells for biasing, he said.

The device includes an InGaN LED chip, which causes the device to emit blue light. A more distinguishing feature of the device, however, is that it can be activated with infrared light.

Infrared is used in many light therapies because it can penetrate deep in the body, whereas blue light cannot go much deeper than the surface. Therefore, the device can be implanted several centimetres into the body.

At just one cubic millimetre and 2.3 milligrammes, the volume and weight of the device are almost one order of magnitude than any other reported device, leading Tokuda to call it "the world's smallest wireless optical neural stimulator." At the same time, Tokuda acknowledges that the device needs modifications before reaching its fullest potential.

"The device can be applied only for pulse stimulations and requires a charge time for each stimulation. Most optogenetics uses multiple pulses. We need to improve the power receiving and conversion efficiency," he said.
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