In a study published in the journal Science Advances, researchers from Peking University have unveiled a miniaturized implantable sensor capable of health monitoring without the need of transcutaneous wires, integrated circuit chips, or bulky readout equipment, thereby reducing infection risks, improving biocompatibility, and enhancing portability. The study is titled “Millimeter-scale magnetic implants paired with a fully integrated wearable device for wireless biophysical and biochemical sensing.”
Han Mengdi from Peking University, the lead researcher of this project, said, “Our miniaturized system presents exciting possibilities for advancing health monitoring. By inserting a tiny magnetic implant into the body, it can provide a rich set of real-time data related to your health status. We aim to use such magnetic implants to enhance the way we monitor and manage health.”
In experiments conducted on rat models, the system showed promising capabilities in measuring critical parameters, such as cerebrospinal fluid viscosity, intracranial pressure, and glucose levels. This compact system holds potential for continuous, wireless monitoring of a wide range of biophysical and biochemical conditions within living organisms.
“Beyond monitoring signals in the brain, the versatility of our system can be further extended,” said Wan Ji, a Ph.D. Student in Han lab and co-first author on the paper. “It can be deployed to monitor a wide array of vital signs and parameters across various body regions, from cardiovascular indicators like blood pressure and viscosity to dental and orthopedic forces, abdominal pressure, and even molecular and cellular distributions within the body.”
This opens up unprecedented possibilities for diagnosing, treating, and managing a plethora of acute and chronic diseases.
“This system comprises millimeter-scale, chip-less, and battery-less magnetic implants paired with a seamlessly integrated wearable device. Unlike traditional methods, the wearable device has the capability to initiate a damped vibration in the magnetic implants, subsequently capturing their ensuing vibration motions wirelessly,” said Nie Zhongyi, a Ph.D. Student in Han lab and co-first author on the paper.
“These motions serve as precise indicators of the biophysical conditions surrounding the implants and the concentration of specific biochemicals, depending on surface modifications.”
“While the tiny magnetic implants show advanced capabilities in wireless biosensing, challenges lie ahead,” Han Mengdi said. “Long-term stability and biocompatibility of the magnetic implants require further investigation and improvement. Nevertheless, with ongoing advancements in technology and deeper exploration of research, these challenges are expected to be addressed effectively.”
These tiny magnetic implants not only advance the development of health monitoring technology, but also signify a potential transformation in the medical field. With further development, this technology could potentially contribute to an enhanced standard of health care, empowering individuals to more proactively manage their well-being with greater ease and accuracy.
More information:
Ji Wan et al, Millimeter-scale magnetic implants paired with a fully integrated wearable device for wireless biophysical and biochemical sensing, Science Advances (2024). DOI: 10.1126/sciadv.adm9314. www.science.org/doi/10.1126/sciadv.adm9314. On bioRxiv: DOI: 10.1101/2023.11.23.568392
Citation:
Tiny magnetic implants enable wireless health monitoring when paired with wearable device (2024, March 20)