USA: Wireless Computer Chip Research

A team of researchers from Columbia University in New York City have developed a tiny, wireless computer chip that can be implanted into body parts and uses ultrasound for monitoring body temperature, and has the potential to measure more.

According to the study, published in the journal Science Advances, the computer chip which is the size of a dust mite may be the future of monitoring the human body and can be injected into the body to monitor processes in real-time. The implant acts as a probe for real-time temperature sensing, including the monitoring of body temperature and temperature changes resulting from the therapeutic application of ultrasound.

There has been increasing interest in wireless, miniaturized implantable medical devices for in vivo and in situ physiological monitoring.

Chen Shi, Department of Electrical Engineering, Columbia University, New York, NY, USA, and colleagues aimed to develop chips that can be injected into the body with a hypodermic needle and then communicate back out of the body using ultrasound, providing information about body characteristics they measure locally.

"We are working on ideas that allow devices like these to augment ultrasound by providing information within an ultrasound image that cannot be conveyed endogenously, like pH, temperature, identification and quantitation of small molecules and proteins," said senior author Kenneth Shepard.

The sub–0.1-mm³, sub–1-nW device, referred to as a mote, achieves aggressive miniaturization through the monolithic integration of a custom low-power temperature sensor chip with a microscale piezoelectric transducer fabricated on top of the chip. The small displaced volume of these motes allows them to be implanted or injected using minimally invasive techniques with improved biocompatibility.

"We demonstrate their sensing functionality in vivo for an ultrasound neurostimulation procedure in mice," wrote the authors. "Our motes have the potential to be adapted to the distributed and localized sensing of other clinically relevant physiological parameters."

"Functionality at greater tissue depths could be achieved with further reduction in the device power consumption, a reduction in the ultrasound operating frequency, and the application of two-dimensional ultrasound imaging array for more effective focusing of ultrasound energy to the implanted motes and more effective capture of the backscattered signals," the team wrote.

The authors are calling this the world's smallest single-chip system that is a complete functioning electronic circuit.

Reference

The study titled, "Application of a sub–0.1-mm³ implantable mote for in vivo real-time wireless temperature sensing," is published in the journal Science Advances.

DOI: https://advances.sciencemag.org/content/7/19/eabf6312