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Wearable Ultrasound Patch Redefining Health Monitoring

This method might also be used to monitor different organs within the body by relocating the ultrasonic array and adjusting the frequency of the signal. Such gadgets may be able to detect tumors that originate deep within the body, such as

, early.

“This technology is versatile and can be used not only on the bladder but any deep tissue of the body. It’s a novel platform that can do identification and characterization of many of the diseases that we carry in our body,” says Canan Dagdeviren, an associate professor in MIT’s Media Lab and the senior author of the study.

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Lin Zhang, an MIT research scientist; Colin Marcus, an MIT graduate student in electrical engineering and computer science; and Dabin Lin, a professor at Xi’an Technological University, are the paper’s lead authors.

Wearable Monitoring Devices that Take Ultrasound Images of Internal Organs

Dagdeviren’s lab, which specializes in the development of flexible, wearable electronic devices, recently created an ultrasound monitor that can be put into a bra and used to screen for breast cancer. The scientists utilized a similar strategy in the latest work to construct a wearable patch that can attach to the skin and take ultrasound images of organs situated within the body.

The researchers decided to focus on the bladder for their first demonstration, partially motivated by Dagdeviren’s younger brother, who was diagnosed with kidney cancer a few years ago. He had difficulties completely emptying his bladder after having one of his kidneys surgically removed. Dagdeviren wondered if an ultrasound device that shows how full the bladder is could help patients like her brother or others with bladder or kidney problems.

“Millions of people are suffering from bladder dysfunction and related diseases, and not surprisingly, bladder volume monitoring is an effective way to assess your kidney health and wellness,” she says.

Currently, the only technique to estimate bladder volume is to visit a medical facility and use a standard, cumbersome ultrasonography probe. Dagdeviren and her colleagues aimed to create a wearable option for patients to use at home.

To accomplish this, the researchers produced a flexible patch of silicone rubber embedded with five ultrasonic arrays made from a novel piezoelectric material designed specifically for this device. The arrays are arranged in the shape of a cross, allowing the patch to scan the entire bladder, which measures approximately 12 by 8 centimeters when full.

The patch’s polymer is naturally adhesive and attaches gently to the skin, making it simple to attach and detach. When applied to the skin, underwear or leggings might assist in keeping it in place.

Novel Patch that Can Help Determine Bladder Capacity Using Ultrasound Technology

The researchers demonstrated that the new patch could capture images comparable to those taken with a traditional ultrasound probe in a study conducted with collaborators from the Center for Ultrasound Research and Translation and the Department of Radiology at Massachusetts General Hospital and that these images could be used to track changes in bladder volume.

The researchers recruited 20 patients with varying BMIs for the study. The subjects were photographed with a full bladder, then a partially empty bladder, and finally an empty bladder. The novel patch produced images of comparable quality to standard ultrasonography, and the ultrasound arrays operated on all participants regardless of body mass index.

Because the field of vision is big enough to encompass the entire bladder, no ultrasound gel or pressure is required while using this patch, as with a standard ultrasound probe.

The researchers connected their ultrasound arrays to the same type of ultrasound machine used in medical imaging centers to view the images. The MIT team is now developing a portable device the size of a smartphone that might be used to see the photographs.

“In this work, we have further developed a path toward clinical translation of conformable ultrasonic biosensors that yield valuable information about vital physiologic parameters. Our group hopes to build on this and develop a suite of devices that will ultimately bridge the information gap between clinicians and patients,” says Anthony E. Samir, director of the MGH Center for Ultrasound Research and Translation and Associate Chair of Imaging Sciences at MGH Radiology, who is also an author of the study.

The MIT team also intends to create ultrasound devices that can image other organs in the body, such as the pancreas, liver, or ovaries. The frequency of the ultrasound signal must be adjusted based on the location and depth of each organ, which necessitates the development of new piezoelectric materials. For some of these deep-seated organs, the device may be more effective as an implant rather than a patch.

“For whatever organ that we need to visualize, we go back to the first step, select the right materials, come up with the right device design and then fabricate everything accordingly,” before testing the device and performing clinical trials, Dagdeviren says. “This work could develop into a central area of focus in ultrasound research, motivate a new approach to future medical device designs, and lay the groundwork for many more fruitful collaborations between materials scientists, electrical engineers, and biomedical researchers,” says Anantha Chandrakasan, dean of MIT’s School of Engineering, the Vannevar Bush Professor of Electrical Engineering and Computer Science, and an author of the paper.

Reference :

  1. A conformable phased-array ultrasound patch for bladder volume monitoring – (https:www.nature.com/articles/s41928-023-01068-x)

Source: Medindia

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