Thousands of theragrippers can be endoscopically deployed in the GI tract. Once released, the machines migrate to the mucosal wall, where they release their medicine payloads gradually into the body. Image shows open and closed theragrippers.
Inspired by a parasitic worm that digs its sharp teeth into its host’s intestines, Johns Hopkins researchers have designed tiny, star-shaped microdevices that can latch onto intestinal mucosa and release drugs into the body.
David Gracias, a professor in the Johns Hopkins University Whiting School of Engineering, and gastroenterologist Florin Selaru, director of the Johns Hopkins Inflammatory Bowel Disease Center, led a team of researchers and biomedical engineers that designed and tested shape-changing machines that mimic the way the parasitic hookworm affixes itself to an organism’s intestines.
Made of metal and thin, shape-changing film and coated in a heat-sensitive paraffin wax, “theragrippers,” each roughly the size of a dust speck, potentially can carry any drug and release it gradually into the body.
“We’ve been working to develop small drug carriers that can autonomously latch onto the organ and keep the drug load inside the GI tract for a desired duration of time.” —Florin Selaru
The team published results of an animal study in October as the cover article in the journal Science Advances.
Selaru says that extended-release drugs often make their way entirely through the gastrointestinal tract before they’ve finished dispensing their medication.
“Normal constriction and relaxation of GI tract muscles make it impossible for extended-release drugs to stay in the intestine long enough for the patient to receive the full dose,” says Selaru, who has collaborated with Gracias for more than 10 years. “We’ve been working to solve this problem by designing these small drug carriers that can autonomously latch onto the intestinal mucosa and keep the drug load inside the GI tract for a desired duration of time.”
Thousands of theragrippers can be endoscopically deployed in the GI tract. Once released, the machines migrate to the mucosal wall. When the grippers’ wax coating reaches the temperature inside the body, the devices close autonomously and clamp onto the colonic lining. The closing action causes the tiny, six-pointed devices to dig into the mucosa and remain attached to the colon, where they release their medicine payloads gradually into the body. Within a day or two, the theragrippers lose their hold on the tissue and are cleared from the intestine via normal gastrointestinal muscular function.
“We have seen the introduction of dynamic, microfabricated smart devices that can be controlled by electrical or chemical signals,” Gracias says. “But these grippers are so small that batteries, antennas and other components will not fit on them.”
Theragrippers, he says, don’t rely on electricity, wireless signals or external controls. “Instead, they operate like small, compressed springs with a temperature-triggered coating that releases the stored energy autonomously at body temperature.”
The Johns Hopkins researchers fabricated the devices with about 6,000 theragrippers per 3-inch silicon wafer. In their animal experiments, they loaded a pain-relieving drug onto the grippers. The researchers’ studies found that the animals into which theragrippers were administered had higher concentrates of the pain reliever in their bloodstreams than did the control group. The drug stayed in the test subjects’ systems for nearly 12 hours versus two hours in the control group.