This Tiny Submarine Cruises Inside A Stomach To Deliver Drugs
A tiny self-propelled drug-delivery device might someday make taking antibiotics safer and more efficient. Think of it as a tiny submarine scooting around inside your stomach, fueled by the acid there.
Oral antibiotics are commonly prescribed life-saving drugs. Once an antibiotic is swallowed, it takes a trip to the stomach, where there's lots of acid. That stomach acid can break chemical bonds in the antibiotic and deactivate it.
To keep that from happening, doctors often prescribe acid-reducing medications like Prilosec or Prevacid. But they can cause side effects such as headache, diarrhea and fatigue.
Source: Angewandte Chemie International Edition
So scientists at the University of California, San Diego, came up with a device designed to both reduce stomach acid and deliver medication without the side effects.
The swallowable device reacts with stomach acid release of tiny hydrogen bubbles. The bubbles scoot it around the stomach, and a magnesium core reduces acidity as it goes. The tiny device is covered by a special polymer, like a jacket, that is sensitive to changes in the acidity. Once the acid in the stomach is neutralized, the polymer dissolves and the submarines unload their antibiotic payload.
The micro submarine is only 20 microns across, about one-fifth the width of a human hair.
It might sound like an episode of The Magic School Bus, the cartoon series that miniaturized children so they could explore inside the body, but the authors think it could be a big improvement in drug delivery.
The study was led by Joseph Wang, the chair of nanoengineering at the University of California, San Diego. He says that the way that the scooting submarine delivers the drug actually helps the drug work better. "This active movement of the carrier improved the therapeutic efficiency in addition to the neutralization of the stomach [acid)."
The device isn't ready for use in humans yet, but preliminary testing in mice shows that it's safe and effective, at least there. The study was published Jan. 20 in Angewandte Chemie International Edition.