Monday, March 20, 2023

New biobatteries power ingestible cameras in the small intestine

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Ingestible electronics enable the transient and non-invasive implantation of sensors inside the body. Functioning ingestible capsules offer tremendous promise for use in the healthcare industry for disease diagnostics and monitoring. However, the absence of realistic and practical power solutions has greatly hindered the development of ingestible electronics.

Binghamton University biobattery researchers think they have a solution for the hard-to-reach small intestine, which winds around the human gut for an average of 22 feet.

“There are some regions in the small intestine that are not reachable, and that is why ingestible cameras have been developed to solve this issue,” said Professor Seokheun “Sean” Choi, a faculty member in the Department of Electrical and Computer Engineering at the Thomas J. Watson College of Engineering and Applied Science, and who led the team. “They can do many things, such as imaging and physical sensing, even drug delivery. The problem is power. So far, the electronics are using primary batteries that have a finite energy budget and cannot function for the long term.”

The team’s solution builds on findings that Choi has made over the past decade about utilizing bacteria to create low levels of electricity that can power sensors and Wi-Fi connections as part of the Internet of Things (IoT).

However, other options inside the small intense are less viable. Traditional batteries are potentially harmful, wireless power transfer from outside the body is inefficient, temperature differences aren’t enough to harness thermal energy, and intestinal movement is too slow for mechanical energy. So, Choi’s capsule-sized biobatteries utilize microbial fuel cells with spore-forming Bacillus subtilis bacteria that remain inert until they reach the small intestine.

By using a pH sensitive membrane, the ingestible biobattery would not begin producing power until it reached the small intestine.
By using a pH-sensitive membrane, the ingestible biobattery would not begin producing power until it reached the small intestine. Credit: Binghamton University

“How do you make your micro-fuel cell selectively work in the small intestine? We use a pH-sensitive membrane that requires certain conditions to activate,” Choi said. “When you look at our gastrointestinal tract, the esophagus has a neutral pH, the same as the small intestine, but the transit time is only 10 seconds. It will not activate in this area, and it will never work in the stomach because the stomach has a very low pH. It only works in the small intestine.”

Some people might balk at ingesting bacteria. To those, Choi says our bodies are filled with nontoxic microbes that help with digestion and other functions. “We use these spores as a dormant, storable biocatalyst,” he said. “The spores can be germinated when the nutrients are available, and they can resume vegetative life and generate the power.”

Choi and the team are already looking ahead to improving the capsule-sized biobatteries. Once the fuel cell reaches the small intestine, it takes up to an hour to germinate completely – faster would be better. In addition, the cell generates around 100 microwatts per square centimeter of power density – enough for wireless transmission, but ten times more would offer many more options for use. The batteries also would require animal and human testing as well as biocompatibility studies.

Choi envisions several uses that low-level microbial fuel cells could power, including biological and chemical sensors, drug-delivery systems, and electrical stimulation devices.

Journal reference:

  1. Maryam Rezaie, Zahra Rafiee, and Seokheun Choi. A Biobattery Capsule for Ingestible Electronics in the Small Intestine: Biopower Production from Intestinal Fluids Activated Germination of Exoelectrogenic Bacterial Endospores. Advanced Energy Materials, 2022; DOI: 10.1002/aenm.202202581
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