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Electric fields weaker in slow-healing diabetic wounds

Date:
June 16, 2016
Source:
University of California - Davis
Summary:
People with diabetes often suffer from wounds that are slow to heal and can lead to ulcers, gangrene and amputation. New research from an international group shows that, in mouse models of diabetes, slow healing is associated with weaker electrical currents in wounds. The results could ultimately open up new approaches for managing diabetic patients.
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People with diabetes often suffer from wounds that are slow to heal and can lead to ulcers, gangrene and amputation. New research from an international group led by Min Zhao, professor of ophthalmology and of dermatology at the University of California, Davis, shows that, in animal models of diabetes, slow healing is associated with weaker electrical currents in wounds. The results could ultimately open up new approaches for managing diabetic patients.

"This is the first demonstration, in diabetic wounds or any chronic wounds, that the naturally occurring electrical signal is impaired and correlated with delayed healing," Zhao said. "Correcting this defect offers a totally new approach for chronic and nonhealing wounds in diabetes."

It has been estimated that as much as $25 billion a year is spent on treating chronic ulcers and wounds related to diabetes, Zhao said.

Electric fields and wound healing

Electric fields are associated with living tissue. Previous work by Zhao and Brian Reid, project scientist at the UC Davis Department of Dermatology, showed that electric fields are associated with healing damage to the cornea, the transparent outer layer of the eye.

In the new work, published June 10 in the journal Scientific Reports, Zhao, Reid and colleagues used a highly sensitive probe to measure electrical fields in the corneas of isolated eyes from three different lab mouse models with different types of diabetes: genetic, drug-induced and in mice fed a high-fat diet.

In a healthy eye, there is an electrical potential across the thickness of the cornea. Removing a small piece of cornea collapses this potential and creates electric currents, especially at the edges of the wound. Cells migrate along the electric currents, closing the scratch wound in about 48 hours.

The researchers found that these electric currents were much weaker in eyes from all three strains of diabetic mice than in healthy mice. Delayed wound healing was correlated with weaker electric currents.

"We saw similar results with all three models," Reid said.

The researchers also found that human corneal cells exposed to high levels of glucose showed less response to an electric field. Diabetics have high levels of glucose in their tears, Reid noted.

Unique facility

The UC Davis bioelectricity laboratory is one of a very few able to make such sensitive measurements of electric fields in living tissue.

"We might be the only lab in the country that is able to do this," Reid said. They are collaborating with a number of laboratories worldwide and across the country, as well as several other UC Davis departments.


Story Source:

Materials provided by University of California - Davis. Note: Content may be edited for style and length.


Journal Reference:

  1. Yunyun Shen, Trisha Pfluger, Fernando Ferreira, Jiebing Liang, Manuel F. Navedo, Qunli Zeng, Brian Reid, Min Zhao. Diabetic cornea wounds produce significantly weaker electric signals that may contribute to impaired healing. Scientific Reports, 2016; 6: 26525 DOI: 10.1038/srep26525

Cite This Page:

University of California - Davis. "Electric fields weaker in slow-healing diabetic wounds." ScienceDaily. ScienceDaily, 16 June 2016. <www.sciencedaily.com/releases/2016/06/160616165941.htm>.
University of California - Davis. (2016, June 16). Electric fields weaker in slow-healing diabetic wounds. ScienceDaily. Retrieved November 22, 2024 from www.sciencedaily.com/releases/2016/06/160616165941.htm
University of California - Davis. "Electric fields weaker in slow-healing diabetic wounds." ScienceDaily. www.sciencedaily.com/releases/2016/06/160616165941.htm (accessed November 22, 2024).

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