12.02.22
Researchers at Stanford University report they have developed a wireless smart bandage that has shown promise in speeding up tissue repair in chronic wounds by monitoring the wound healing process and treating the wound simultaneously. In a paper published in Nature Biotechnology, the researchers say their device promotes faster closure of wounds, increases new blood flow to injured tissue, and enhances skin recovery by significantly reducing scar formation.
The smart bandage is composed of wireless circuitry that uses impedance/temperature sensors to monitor the progression of wound healing. If the wound is less healed or an infection is detected, the sensors inform a central processing unit to apply more electrical stimulation across the wound bed to accelerate tissue closure and reduce infection. The researchers were able to track the sensor data in real time on a smart phone, all without the need for wires.
The electronic layer, including a microcontroller unit (MCU), radio antenna, memory, electrical stimulator, biosensors, and other components, is just 100 microns thick—about the thickness of a single coat of latex paint. The circuitry rides atop a an engineered hydrogel that is integrated to both deliver healing electrical stimulation to the injured tissue and collect real-time biosensor data.
The polymer in the hydrogel is designed to adhere securely to the wound surface when needed, yet to pull away cleanly and gently without harm to the wound when warmed to just a few degrees above body temperature (40°C/104°F).
“In sealing the wound, the smart bandage protects as it heals,” said Yuanwen Jiang, co-first author of the study and a post-doctoral scholar in the lab of Zhenan Bao, the K.K. Lee Professor in Chemical Engineering in the Stanford School of Engineering. “But it is not a passive tool. It is an active healing device that could transform the standard of care in the treatment of chronic wounds.”
Electrical stimulation (galvanotaxis) has been previously reported to accelerate the migration of keratinocytes to the wound site, limit bacterial infections and prevent the development of biofilms on wound surfaces, to proactively promote tissue growth and help with tissue repair. The researchers were able to take this technology and integrate it with real-time biosensor data to provide a novel automated treatment modality that is informed by biosensors.
The smart bandage’s biosensing capabilities monitor biophysical changes in the local environment, providing a real-time, rapid, robust, and extremely accurate way to measure wound condition, said the study authors.
The researchers caution that the smart bandage is, as yet, a proof of concept, albeit a promising one. Many challenges remain, however. These include increasing the size of the device to human scale, reducing cost, and solving long-term data storage issues - all necessary to scale up to mass production should need and opportunity arise. Likewise, there are potentially new sensors not currently integrated that might be added, such as those that measure metabolites, biomarkers, and pH. And there are some potential roadblocks to clinical use, such as hydrogel rejection, in which the skin may react to the device and create a bad gel-to-skin combination, or biofouling of the sensors, which can cause irritation. The researchers are pushing ahead and remain optimistic about the potential of their smart bandage to provide hope for patients suffering with chronic wounds.
Stanford co-first authors are: Yuanwen Jiang, a postdoctoral fellow in the Bao Group; Artem Trotsyuk, a former graduate student in the Gurtner Lab; and Simiao Niu, a former postdoctoral scholar in the Bao Group.
The smart bandage is composed of wireless circuitry that uses impedance/temperature sensors to monitor the progression of wound healing. If the wound is less healed or an infection is detected, the sensors inform a central processing unit to apply more electrical stimulation across the wound bed to accelerate tissue closure and reduce infection. The researchers were able to track the sensor data in real time on a smart phone, all without the need for wires.
The electronic layer, including a microcontroller unit (MCU), radio antenna, memory, electrical stimulator, biosensors, and other components, is just 100 microns thick—about the thickness of a single coat of latex paint. The circuitry rides atop a an engineered hydrogel that is integrated to both deliver healing electrical stimulation to the injured tissue and collect real-time biosensor data.
The polymer in the hydrogel is designed to adhere securely to the wound surface when needed, yet to pull away cleanly and gently without harm to the wound when warmed to just a few degrees above body temperature (40°C/104°F).
“In sealing the wound, the smart bandage protects as it heals,” said Yuanwen Jiang, co-first author of the study and a post-doctoral scholar in the lab of Zhenan Bao, the K.K. Lee Professor in Chemical Engineering in the Stanford School of Engineering. “But it is not a passive tool. It is an active healing device that could transform the standard of care in the treatment of chronic wounds.”
Electrical stimulation (galvanotaxis) has been previously reported to accelerate the migration of keratinocytes to the wound site, limit bacterial infections and prevent the development of biofilms on wound surfaces, to proactively promote tissue growth and help with tissue repair. The researchers were able to take this technology and integrate it with real-time biosensor data to provide a novel automated treatment modality that is informed by biosensors.
The smart bandage’s biosensing capabilities monitor biophysical changes in the local environment, providing a real-time, rapid, robust, and extremely accurate way to measure wound condition, said the study authors.
Anti-Inflammatory Gene
The researchers took their study a step further, venturing to understand why and how electrical stimulation heals the wound faster. They now believe that electrical stimulation promotes the activation of pro-regenerative genes such as Selenop, an anti-inflammatory gene that has been found to help with pathogen clearance and wound repair, and Apoe, which has been shown to increase muscle and soft tissue growth. Likewise, electrical stimulation increased the amount of white blood cell populations, namely monocytes and macrophages, through the recruitment of greater amounts of M2 anti-inflammatory macrophages, which have been previously reported as pro-regenerative and playing a key role in the extracellular matrix formation that is required during the proliferative phases of wound healing.The researchers caution that the smart bandage is, as yet, a proof of concept, albeit a promising one. Many challenges remain, however. These include increasing the size of the device to human scale, reducing cost, and solving long-term data storage issues - all necessary to scale up to mass production should need and opportunity arise. Likewise, there are potentially new sensors not currently integrated that might be added, such as those that measure metabolites, biomarkers, and pH. And there are some potential roadblocks to clinical use, such as hydrogel rejection, in which the skin may react to the device and create a bad gel-to-skin combination, or biofouling of the sensors, which can cause irritation. The researchers are pushing ahead and remain optimistic about the potential of their smart bandage to provide hope for patients suffering with chronic wounds.
Stanford co-first authors are: Yuanwen Jiang, a postdoctoral fellow in the Bao Group; Artem Trotsyuk, a former graduate student in the Gurtner Lab; and Simiao Niu, a former postdoctoral scholar in the Bao Group.