Tiny robots crawl through mouse’s stomach to heal ulcers

SHORT SHARP SCIENCE 16 August 2017

Tiny robots can heal him.  Mark Bowler/Nature Picture Library/Getty

Tiny robotic drug deliveries could soon be treating diseases inside your body. For the first time, micromotors – autonomous vehicles the width of a human hair – have cured bacterial infections in the stomachs of mice, using bubbles to power the transport of antibiotics.

“The movement itself improves the retention of antibiotics on the stomach lining where the bacteria are concentrated,” says Joseph Wang at the University of California San Diego, who led the research with Liangfang Zhang.

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In mice with bacterial stomach infections, the team used the micromotors to administer a dose of antibiotics daily for five days. At the end of the treatment, they found their approach was more effective than regular doses of medicine.

The tiny vehicles consist of a spherical magnesium core coated with several different layers that offer protection, treatment, and the ability to stick to stomach walls. After they are swallowed, the magnesium cores react with gastric acid to produce a stream of hydrogen bubbles that propel the motors around. This process briefly reduces acidity in the stomach. The antibiotic layer of the micromotor is sensitive to the surrounding acidity, and when this is lowered, the antibiotics are released.

Suppress stomach acid

Without this reduction, antibiotics and protein-based pharmaceuticals can be destroyed before they do any good. This mechanism means that drugs normally used to treat bacterial infections, such as ulcers, normally have to be taken alongside proton pump inhibitors that suppress gastric acid production. Long-term use of proton pump inhibitors can lead to some nasty side effects including headaches, diarrhoea, fatigue and even anxiety or depression. So being able to use tiny vehicles instead is a big step forward.

After 24 hours, the stomach acid of the mice returned to normal levels, and as the micromotors are mostly made of biodegradable materials, they were dissolved by the stomach, leaving no harmful residues.

“It’s a really nifty and impressive application. Micromotors are still new, but their impact will be big,” says Thomas Mallouk at Pennsylvania State University.

Samuel Sanchez at Max Planck Institute for Intelligent Systems says the new work is “pushing the field of micro-motors forward” and shows the benefits of using micromotors over traditional approaches.

The next steps are to look at a larger animal study, followed by eventual trials in humans. “There is still a long way to go, but we are on a fantastic voyage,” says Wang.

Journal reference: Nature CommunicationsDOI: 10.1038/s41467-017-00309-w

Medical microbots

Micromotors have huge promise in many different areas. Earlier this month, for example, researchers demonstrated that they could be used to propel drugs through the blood-brain barrier. Most drugs never make it from the bloodstream into the brain – the blood-brain barrier is just too good at its job. However, by using micromotors fuelled by glucose, the team increased penetration by 400 per cent. This could have big implications for treating diseases like Parkinson’s or Alzheimer’s.

The tiny vehicles also look like they will be effective for neutralising biological and chemical weapons like sarin gas. Normally, large machinery is required to help mix the neutralising compounds in a way that renders the weapons useless, but this machinery is often not available in the field. Wang found that using around 1.5 million micromotors – about 15 millilitres’ worth, was as effective as using a clunky mechanical mixer.

Source:Tiny robots crawl through mouse’s stomach to heal ulcers