News | Stents | May 13, 2022

Georgia Tech Researchers Develop Wireless Implantable Vascular Monitoring System

Woon-Hong Yeo has developed a smarter stent. Georgia Tech Photo

May 13, 2022 — Vascular diseases are public enemy number one: the leading killers worldwide, accounting for nearly a third of all human deaths on the planet.

Continuous monitoring of hemodynamics – blood flow through the vascular system – can improve treatments and patient outcomes. But deadly conditions like hypertension and atherosclerosis occur in long and twisting vascular system with arteries of varying diameter and curvature, and existing clinical devices are limited by their bulk, rigidity, and utility.

Georgia Institute of Technology researcher Woon-Hong Yeo and his collaborators are trying to improve the odds for patients with development of an implantable soft electronic monitoring system. Their new device, consisting of a smart stent and printed soft sensors, is capable of wireless real-time monitoring of hemodynamics without batteries or circuits.

“This electronic system is designed to wirelessly deliver hemodynamic data, including arterial pressure, pulse, and flow, to an external data acquisition system, and it is super small and thin, which is why we can use a catheter to deliver it, anywhere inside the body,” said Yeo, whose team released its study this week in the journal Science Advances.

Yeo added, smiling, “It’s like a stent with multiple tricks up its sleeve.”

For example, when this device is installed in a patient with atherosclerosis, in addition to expanding and preventing the artery from narrowing, like a traditional stent, restoring normal blood flow, it will also provide a constant flow of data.

“Now, once you have deployed a stent, you’re not sure if the problem was resolved and patients may come back with the same issue,” Yeo said. “It can be a defect of the stent, or an issue with stent deployment, or perhaps a problem with the patient’s blood flow.”

And the current standard way to monitor all of that is with an angiogram. That can be expensive and in rare instances, particularly with patients also struggling with diabetes, the dyes and radiation used in angiogram imaging can cause cancer. Yeo’s system seeks to circumvent the need for an angiogram or other imaging requirements.

His wireless smart stent platform, integrated with soft sensors, is operated by inductive coupling to offer wireless real-time monitoring that can detect a wide range of vascular conditions. Inductive coupling uses magnetic fields for wireless energy transfer. It’s similar to what’s happening when you use a wireless charger for your phone, smartwatch, or other devices – they are gaining energy from the magnetic field created by the charger.

“Basically, you can put this sensor system anywhere inside the body,” Yeo explained. “The other thing about this technology platform is, in addition to being an implantable sensor system, it can be used as a wearable system. Think about a smartwatch and how much of its bulk is taken up by circuits or batteries. If you remove all of that, you have a device that is thinner than a typical Band-Aid, an almost invisible health monitor that you can wear anywhere.”

That’s the long-range goal, anyway. So far, they’ve tested their wireless implantable system on animal models. However, there is still plenty of work to do. And Yeo also has the backing of the National Science Foundation to advance the technology. He recently received a 3-year, $400,000 grant from NSF focused on his printed nanomembrane sensors and bioelectronics for wireless and continuous monitoring of vascular health.

“We believe that the mechanical, material, and electrical design principles we develop, and the engineering and biosensing framework that results from this work, will advance the field of implantable electronics and biomedical systems,” Yeo said. “And the insights and knowledge we gain will be applicable for other physiological processes and challenges in biomedical science and engineering.”

For more information: https://www.gatech.edu/


Related Content

News | Hemodynamic Support Devices

October 23, 2023 — Supira Medical, Inc., a Shifamed portfolio company, announced that the company's percutaneous ...

Home October 23, 2023
Home
News | Hemodynamic Support Devices

November 1, 2022 — Abiomed announced that Impella RP Flex with SmartAssist has received U.S. Food and Drug ...

Home November 01, 2022
Home
News | Hemodynamic Support Devices

September 17, 2022 — Results of a new per-protocol analysis of the ST-segment Elevation Myocardial Infarction Door-To ...

Home September 17, 2022
Home
News | Hemodynamic Support Devices

November 12, 2020 — Abiomed recently announced new PROTECT III study data that demonstrates reduced rates of MACCE ...

Home November 12, 2020
Home
Videos | Hemodynamic Support Devices

Chuck Simonton, M.D., chief medical officer at Abiomed, discusses some of the new technologies and clinical trials the ...

Home October 20, 2020
Home
News | Hemodynamic Support Devices

October 16, 2020 — The Restore EF Study demonstrates the use of contemporary best practices, including attempting a more ...

Home October 16, 2020
Home
News | Hemodynamic Support Devices

July 16, 2020 – The U.S. Food and Drug Administration (FDA) approved one-way digital data streaming during patient ...

Home July 16, 2020
Home
News | Hemodynamic Support Devices

June 5, 2020 — Abiomed announced the U.S. Food and Drug Administration (FDA) has approved the company's investigational ...

Home June 05, 2020
Home
Videos | Hemodynamic Support Devices

This is a quick animation demonstrating how the new 9 French Abiomed Impella ECP expands to approximately 18 French and ...

Home June 05, 2020
Home
Subscribe Now