Informed by mechanics and computation, flexible bioelectronics can better conform to a curvy body

Flexible bioelectronics have been gaining popularity in the medical field due to their ability to conform to the human body. However, one challenge that researchers have faced is creating bioelectronics that can conform to the curves of the body, such as the heart or brain.

Recent advancements in mechanics and computation have allowed researchers to create flexible bioelectronics that can better conform to a curvy body. By using computer simulations and 3D printing, researchers can design bioelectronics that are specifically tailored to the shape of the body part they will be attached to.

One example of this is the development of a flexible brain implant that can conform to the shape of the brain. The implant is made up of a thin, flexible material that can be printed with a 3D printer. The researchers used computer simulations to design the implant to fit the specific shape of the patient's brain, allowing for better contact between the implant and the brain tissue.

Another example is the development of a flexible heart monitor that can conform to the shape of the heart. The monitor is made up of a thin, flexible material that can be attached directly to the surface of the heart. The researchers used computer simulations to design the monitor to fit the specific shape of the patient's heart, allowing for more accurate monitoring of heart activity.

Overall, the use of mechanics and computation in the development of flexible bioelectronics has allowed for better conformity to the curves of the body. This has opened up new possibilities for medical treatments and monitoring, as well as improved patient comfort and safety.

https://www.lifetechnology.com/blogs/life-technology-technology-news/informed-by-mechanics-and-computation-flexible-bioelectronics-can-better-conform-to-a-curvy-body

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