The study describes research conducted on mice and pigs. The research team, led by Zhen Gu, PhD, professor of bioengineering at the UCLA Samueli School of Engineering, is applying for FDA approval of clinical trials in humans. Gu and colleagues conducted the initial successful tests of the smart insulin patch in mice in 2015 in North Carolina. “Our main goal is to enhance health and improve the quality of life for people who have diabetes,” said Gu, a former professor in the UNC/NCSU Joint Department of Biomedical Engineering. “This smart patch takes away the need to constantly check one’s blood sugar and then inject insulin if and when it’s needed. It mimics the regulatory function of the pancreas but in a way that’s easy to use.”
The adhesive patch monitors blood sugar, or glucose. It has doses of insulin pre-loaded in very tiny microneedles, less than one-millimeter in length that deliver medicine quickly when the blood sugar levels reach a certain threshold. When blood sugar returns to normal, the patch’s insulin delivery also slows down. The researchers said the advantage is that it can help prevent overdosing of insulin, which can lead to hypoglycemia, seizures, coma or even death. “It has always been a dream to achieve insulin-delivery in a smart and convenient manner,” said study co-author John Buse, MD, PhD, director of the UNC Diabetes Center and the North Carolina Translational and Clinical Sciences (NC TraCS) Institute at the University of North Carolina at Chapel Hill School of Medicine. “This smart insulin patch, if proven safe and effective in human trials, would revolutionize the patient experience of diabetes care.”
Insulin is a hormone naturally produced in the pancreas helps the body regulate glucose, which comes from food-consumption and provides the body with energy. Insulin is the molecular key that helps move glucose from the bloodstream to the cells for energy and storage. Type 1 diabetes occurs when a person’s body does not naturally produce insulin. Type 2 diabetes occurs when the body does not efficiently use the insulin that is produced. In either case, a regular dosage of insulin is prescribed to manage the disease, which affects more than 400 million people worldwide.
The treatment for the disease hasn’t changed much in decades in most of the world. Patients with diabetes draw their blood using a device that measures glucose levels. They then self-administer a necessary dose of insulin. The insulin can be injected with a needle and syringe, a pen-like device, or delivered by an insulin pump, which is a portable cellphone-sized instrument attached to the body through a tube with a needle on the end. A smart insulin patch would sense the need for insulin and deliver it.
The microneedles used in the patch are made with a glucose-sensing polymer that’s encapsulated with insulin. Once applied on the skin, the microneedles penetrate under the skin and can sense blood sugar levels. If glucose levels go up, the polymer is triggered to release the insulin. Each microneedle is smaller than a regular needle used to draw blood and do not reach as deeply, so the patch is less painful than a pin prick. Each microneedle penetrates about a half millimeter below the skin, which is sufficient to deliver insulin into the body.
In the experiments, one quarter-sized patch successfully controlled glucose levels in pigs with type I diabetes for about 20 hours. The pigs weighed about 55 pounds on average. “I am glad the team could bring this smart insulin patch one more step close to reality, and we look forward to hopefully seeing it move forward to someday help people with diabetes,” said Robert Langer, ScD, the David H. Koch Institute Professor at MIT and one of the paper’s co-authors.