Photo of a water-powered, electronics-free dressing (WPED) for electrical stimulation of wounds. (Credit: Rajaram Kaveti)
In a nutshell
- A new water-activated bandage generates healing electrical fields without any electronics, costing just $1 to produce compared to current treatments that can cost up to $20,000
- In testing with diabetic mice, 75% of wounds treated with the electrical bandage healed completely by day 11, versus 0% with standard bandages
- The technology allows patients to receive advanced wound treatment at home without visiting clinics or using bulky equipment, potentially improving treatment compliance
RALEIGH, N.C. — A drop of water might be all it takes to revolutionize wound healing. Researchers have developed a $1 bandage that, when activated with water, generates its own electrical field to speed healing. This could transform treatment for the millions of Americans who struggle with chronic wounds.
About 2% of Americans suffer from chronic wounds, which are injuries that stubbornly refuse to heal normally. These persistent wounds, like diabetic foot ulcers, often recur after treatment and significantly increase the risk of amputation and death. Current treatments range from basic bandages to advanced biological therapies, but they’re either minimally effective or prohibitively expensive, with some treatments costing upwards of $20,000 per wound.
The study, published in Science Advances, reveals a treatment alternative that could make chronic wound care accessible and affordable. An American research team created a water-powered, electronics-free dressing (WPED) that costs approximately $1 to produce. The smart bandage uses a combination of magnesium and silver/silver chloride to generate a healing electrical field when activated with water.
“Our goal here was to develop a far less expensive technology that accelerates healing in patients with chronic wounds,” says co-author Amay Bandodkar, assistant professor at North Carolina State University, in a statement. “We also wanted to make sure that the technology is easy enough for people to use at home, rather than something that patients can only receive in clinical settings.”
Photo of WPED applied to a dummy wound on a human foot. (Credit: Rajaram Kaveti)
The dressing’s secret lies in its unique battery design. When water is added to a special inlet pad, it activates a flexible, biocompatible battery. This creates a gentle electrical field that helps stimulate the wound bed. A built-in “check pad” changes color to show when the separator is fully hydrated and the battery is working. The entire system weighs just 290 milligrams, only about 20% more than a standard bandage. Using specially designed electrodes, the bandage can conform to irregular wound surfaces.
“This ability to conform is critical because we want the electric field to be directed from the periphery of the wound toward the wound’s center,” says co-first author Rajaram Kaveti from North Carolina State University. “In order to focus the electric field effectively, you want electrodes to be in contact with the patient at both the periphery and center of the wound itself.”
Unlike existing electrical wound therapies that require bulky external equipment, this dressing works independently. After activation with water, it provides electrical stimulation for varying periods from 30 minutes to over 7 hours, depending on factors like wound characteristics and environmental conditions.
Laboratory testing revealed impressive resilience across temperatures and pressures. The dressing maintained function across a wide temperature range, though higher temperatures reduced duration due to faster water evaporation. It continued working under pressures similar to those experienced by heel wounds during walking.
Photo of researcher Rajaram Kaveti holding the water-powered, electronics-free dressing (WPED) for electrical stimulation of wounds. (Credit: Gurudatt Nanjanagudu Ganesh)
In carefully controlled trials with diabetic mice, the results showed significant promise. By day 11, 75% of wounds treated with the electrical dressing had fully closed, compared to 12.5% in the non-powered group and none in the control group. By day 13, healing rates reached 88% for the electrical dressing group.
“We found that the electrical stimulation from the device sped up the rate of wound closure, promoted new blood vessel formation, and reduced inflammation, all of which point to overall improved wound healing,” says co-first author Maggie Jakus, a graduate student at Columbia University.
“Diabetic foot ulceration is a serious problem that can lead to lower extremity amputations,” says co-author Aristidis Veves, professor of surgery at Beth Israel Deaconess Center. “There is urgent need for new therapeutic approaches, as the last one that was approved by the Food and Drug Administration was developed more than 25 years ago.”
While the researchers continue refining the technology for eventual clinical trials, their work highlights an important principle in medical innovation: sometimes the most impactful solutions aren’t the most complicated ones. By harnessing simple chemistry to replicate the body’s natural healing mechanisms, they’ve created a technology that could help millions access better wound care without breaking the bank.