Innovative Injectable Gel Accelerates Tissue Healing
By HospiMedica International staff writers Posted on 17 Jun 2015 |
Image: Tissue infiltrates the injectable MAP spheres gel fills, promoting regeneration (Photo courtesy of UCLA).
A new hydrogel creates an instant scaffold of microporous annealed particles (MAP) that allows tissue regeneration to form within its cavities.
Developed by researchers at the University of California, Los Angeles (UCLA; USA), the injected hydrogel—filled with the microscopic synthetic polymer MAP spheres, each about the width of a human hair—forms a packed cluster that completely fills the wound cavity. New tissue quickly grows into the voids between the microspheres; as the MAP spheres degrade into the body, a matrix of repair tissue is left where the wound once was. New tissue then continues to grow until the wound is completely healed.
The researchers succeeded in demonstrating that the MAP hydrogel can promote the growth of new cells and formation of networks of connected cells at previously unseen rates. During in vivo tests, the researchers observed significant tissue regeneration in the first 48 hours, with much more healing over five days compared to other materials in use today. According to the researchers, the combination of microporosity and injectability will enable novel routes to tissue regeneration. The study was published on June 2, 2015, in Nature Materials.
“The beauty of the MAP gel is that there are no other added growth factors that other technologies require to attract cells into the material,” said study coauthor Westbrook Weaver, PhD, of the UCLA Henry Samueli School of Engineering and Applied Science. “The geometry of the MAP gel networks entices cells to migrate into the gel without the need for anything other than a cell adhesive peptide, so that the cells can grab onto the gels.”
Related Links:
University of California Los Angeles
Developed by researchers at the University of California, Los Angeles (UCLA; USA), the injected hydrogel—filled with the microscopic synthetic polymer MAP spheres, each about the width of a human hair—forms a packed cluster that completely fills the wound cavity. New tissue quickly grows into the voids between the microspheres; as the MAP spheres degrade into the body, a matrix of repair tissue is left where the wound once was. New tissue then continues to grow until the wound is completely healed.
The researchers succeeded in demonstrating that the MAP hydrogel can promote the growth of new cells and formation of networks of connected cells at previously unseen rates. During in vivo tests, the researchers observed significant tissue regeneration in the first 48 hours, with much more healing over five days compared to other materials in use today. According to the researchers, the combination of microporosity and injectability will enable novel routes to tissue regeneration. The study was published on June 2, 2015, in Nature Materials.
“The beauty of the MAP gel is that there are no other added growth factors that other technologies require to attract cells into the material,” said study coauthor Westbrook Weaver, PhD, of the UCLA Henry Samueli School of Engineering and Applied Science. “The geometry of the MAP gel networks entices cells to migrate into the gel without the need for anything other than a cell adhesive peptide, so that the cells can grab onto the gels.”
Related Links:
University of California Los Angeles
Latest Critical Care News
- Stretchable Microneedles to Help In Accurate Tracking of Abnormalities and Identifying Rapid Treatment
- Machine Learning Tool Identifies Rare, Undiagnosed Immune Disorders from Patient EHRs
- On-Skin Wearable Bioelectronic Device Paves Way for Intelligent Implants
- First-Of-Its-Kind Dissolvable Stent to Improve Outcomes for Patients with Severe PAD
- AI Brain-Age Estimation Technology Uses EEG Scans to Screen for Degenerative Diseases
- Wheeze-Counting Wearable Device Monitors Patient's Breathing In Real Time
- Wearable Multiplex Biosensors Could Revolutionize COPD Management
- New Low-Energy Defibrillation Method Controls Cardiac Arrhythmias
- New Machine Learning Models Help Predict Heart Disease Risk in Women
- Deep-Learning Model Predicts Arrhythmia 30 Minutes before Onset
- Breakthrough Technology Combines Detection and Treatment of Nerve-Related Disorders in Single Procedure
- Plasma Irradiation Promotes Faster Bone Healing
- New Device Treats Acute Kidney Injury from Sepsis
- Study Confirms Safety of DCB-Only Strategy for Treating De Novo Left Main Coronary Artery Disease
- Revascularization Improves Quality of Life for Patients with Chronic Limb Threatening Ischemia
- AI-Driven Prediction Models Accurately Predict Critical Care Patient Deterioration