24-7 Blood Pressure Monitoring Without the Cuff

Outcome/Accomplishment

Hypertension (high blood pressure) is a serious health challenge costing billions of dollars a year in medical costs. New methods aim to detect problems before they require medical intervention. One approach created by researchers is a new kind of wearable patch that can continuously measure blood pressure without a cuff. The patch tracks blood pressure 24 hours a day so that problems are caught early, enabling speedy treatment and better outcomes. This work is supported by the National Science Foundation (NSF)-funded Precise Advanced Technologies and Health Systems for Underserved Populations (NSF PATHS-UP) Engineering Research Center (ERC), headquartered at Texas A&M University (TAMU), as part of its mission to improve healthcare for communities that need it most. (See figure 1 and 2.) 

Impact/Benefits

The patch uses a tiny sensor system that can directly measure pressure in the arteries while automatically adjusting for things like skin movement or outside forces. A plus is that it avoids the strong compression used in regular blood pressure cuffs. Additional testing is underway, with all indications that this breakthrough could make real-time, non-invasive blood pressure tracking possible not just in clinics but also in daily life. 

Explanation/Background

The device was carefully tested by volunteers who wore it in daily trials. Ten people participated in activities such as using a leg press machine to safely raise and lower blood pressure so test the sensor’s accuracy. These results were compared with those produced by similar, highly rated medical technology for continuous non-invasive blood pressure measurement, confirming particularly good accuracy.

The patch uses a strain gauge-based dual transducer system within a compact patch form factor. The strain gauge is a full Wheatstone bridge circuit and directly quantifies arterial pressure while compensating for tissue deformation and external forces.

This work has led to six patent applications, the launch of a new company, and a paper in Nature Communications, a multidisciplinary, open-access journal that covers all the natural sciences.

Figure 1. The photo depicts: (a) a cuffless blood pressure monitor placed on the wrist with either transducer on or near the artery, and (b) a diagram showing placement of transducers along with relative alignment.
Figure 2. Sensor system architecture and hardware design for wearable application on the wrist to measure pulsatile waveforms. (A) System block diagram showing the 3 separate PCB designs. (B) Illustration of the sensor interface on the radial artery of the wrist to capture pulse propagation (Created with BioRender.com). (C) A top-view image showing the wearable device on the wrist with the 3D printed enclosure. (D) A bottom- view image showing the 63 mm separation from PPG1 to PPG2 and 18 mm separation from

Location

College Station, Texas

e-mail

teesweb@tamu.edu

website

https://pathsup.org/

Start Year

Biotechnology and Healthcare

Biotechnology and Health Care Icon
Biotechnology and Health Care Icon

Biotechnology and Healthcare

Lead Institution

Texas A&M University

Core Partners

University of California at Los Angeles, Rice University , Florida International University

Fact Sheet

PATHS-UP Fact Sheet.pdf
Figure 1. The photo depicts: (a) a cuffless blood pressure monitor placed on the wrist with either transducer on or near the artery, and (b) a diagram showing placement of transducers along with relative alignment.
Figure 2. Sensor system architecture and hardware design for wearable application on the wrist to measure pulsatile waveforms. (A) System block diagram showing the 3 separate PCB designs. (B) Illustration of the sensor interface on the radial artery of the wrist to capture pulse propagation (Created with BioRender.com). (C) A top-view image showing the wearable device on the wrist with the 3D printed enclosure. (D) A bottom- view image showing the 63 mm separation from PPG1 to PPG2 and 18 mm separation from

Outcome/Accomplishment

Hypertension (high blood pressure) is a serious health challenge costing billions of dollars a year in medical costs. New methods aim to detect problems before they require medical intervention. One approach created by researchers is a new kind of wearable patch that can continuously measure blood pressure without a cuff. The patch tracks blood pressure 24 hours a day so that problems are caught early, enabling speedy treatment and better outcomes. This work is supported by the National Science Foundation (NSF)-funded Precise Advanced Technologies and Health Systems for Underserved Populations (NSF PATHS-UP) Engineering Research Center (ERC), headquartered at Texas A&M University (TAMU), as part of its mission to improve healthcare for communities that need it most. (See figure 1 and 2.) 

Location

College Station, Texas

e-mail

teesweb@tamu.edu

website

https://pathsup.org/

Start Year

Biotechnology and Healthcare

Biotechnology and Health Care Icon
Biotechnology and Health Care Icon

Biotechnology and Healthcare

Lead Institution

Texas A&M University

Core Partners

University of California at Los Angeles, Rice University , Florida International University

Fact Sheet

PATHS-UP Fact Sheet.pdf

Impact/benefits

The patch uses a tiny sensor system that can directly measure pressure in the arteries while automatically adjusting for things like skin movement or outside forces. A plus is that it avoids the strong compression used in regular blood pressure cuffs. Additional testing is underway, with all indications that this breakthrough could make real-time, non-invasive blood pressure tracking possible not just in clinics but also in daily life. 

Explanation/Background

The device was carefully tested by volunteers who wore it in daily trials. Ten people participated in activities such as using a leg press machine to safely raise and lower blood pressure so test the sensor’s accuracy. These results were compared with those produced by similar, highly rated medical technology for continuous non-invasive blood pressure measurement, confirming particularly good accuracy.

The patch uses a strain gauge-based dual transducer system within a compact patch form factor. The strain gauge is a full Wheatstone bridge circuit and directly quantifies arterial pressure while compensating for tissue deformation and external forces.

This work has led to six patent applications, the launch of a new company, and a paper in Nature Communications, a multidisciplinary, open-access journal that covers all the natural sciences.