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https://www.eurekalert.org/news-releases/1116905
INTRO: As aging populations and rising diabetes rates drive an increase in chronic wounds, more patients face the risk of amputations. UC Riverside researchers have developed an oxygen-delivering gel capable of healing injuries that might otherwise progress to limb loss.
Injuries that fail to heal for more than a month are considered chronic wounds. They affect an estimated 12 million people annually worldwide, and around 4.5 million in the U.S. Of these, about one in five patients will ultimately require a life-altering amputation.
The new gel, tested in animal models, targets what researchers believe is a root cause of many chronic wounds: a lack of oxygen in the deepest layers of the damaged tissue. Without sufficient oxygen, wounds languish in a prolonged state of inflammation, allowing bacteria to flourish and tissue to deteriorate rather than regenerate.
“Chronic wounds don’t heal by themselves,” said Iman Noshadi, UCR associate professor of bioengineering who led the research team. “There are four stages to healing chronic wounds: inflammation, vascularization where tissue starts making blood vessels, remodeling, and regeneration or healing. In any of these stages, lack of a stable, consistent oxygen supply is a big problem,” he said.
When oxygen from the air or bloodstream cannot penetrate far enough into injured tissue the result is hypoxia, which derails normal healing. The researchers’ approach to preventing hypoxia with a gel is detailed in a paper published in Nature Communications Material.
The soft, flexible gel contains water as well as a choline-based liquid that is antibacterial, nontoxic, and biocompatible. When paired with a small battery similar to those used in hearing aids, the gel becomes a tiny electrochemical machine splitting water molecules to generate a slow, steady stream of oxygen.
Unlike treatments that deliver oxygen only at the surface, the gel conforms to the unique shape of each wound, filling crevices where oxygen levels are often lowest and infection risk is highest. Before it sets, the material molds precisely to the contours of the damaged tissue. Equally important, the oxygen delivery is continuous... (MORE - details, no ads)
INTRO: As aging populations and rising diabetes rates drive an increase in chronic wounds, more patients face the risk of amputations. UC Riverside researchers have developed an oxygen-delivering gel capable of healing injuries that might otherwise progress to limb loss.
Injuries that fail to heal for more than a month are considered chronic wounds. They affect an estimated 12 million people annually worldwide, and around 4.5 million in the U.S. Of these, about one in five patients will ultimately require a life-altering amputation.
The new gel, tested in animal models, targets what researchers believe is a root cause of many chronic wounds: a lack of oxygen in the deepest layers of the damaged tissue. Without sufficient oxygen, wounds languish in a prolonged state of inflammation, allowing bacteria to flourish and tissue to deteriorate rather than regenerate.
“Chronic wounds don’t heal by themselves,” said Iman Noshadi, UCR associate professor of bioengineering who led the research team. “There are four stages to healing chronic wounds: inflammation, vascularization where tissue starts making blood vessels, remodeling, and regeneration or healing. In any of these stages, lack of a stable, consistent oxygen supply is a big problem,” he said.
When oxygen from the air or bloodstream cannot penetrate far enough into injured tissue the result is hypoxia, which derails normal healing. The researchers’ approach to preventing hypoxia with a gel is detailed in a paper published in Nature Communications Material.
The soft, flexible gel contains water as well as a choline-based liquid that is antibacterial, nontoxic, and biocompatible. When paired with a small battery similar to those used in hearing aids, the gel becomes a tiny electrochemical machine splitting water molecules to generate a slow, steady stream of oxygen.
Unlike treatments that deliver oxygen only at the surface, the gel conforms to the unique shape of each wound, filling crevices where oxygen levels are often lowest and infection risk is highest. Before it sets, the material molds precisely to the contours of the damaged tissue. Equally important, the oxygen delivery is continuous... (MORE - details, no ads)
