 |
|
New approach to wound healing may be easy on skin, but hard on bacteria
August 19, 2009WASHINGTON, D.C. - In a presentation today (Aug. 19) to the American Chemical Society meeting, Ankit Agarwal, a postdoctoral researcher at the University of Wisconsin-Madison, described an experimental approach to wound healing that could take advantage of silver's anti-bacterial properties, while sidestepping the damage silver can cause to cells needed for healing.
Silver is widely used to prevent bacterial contamination in wound dressings, says Agarwal, "but these dressings deliver a very large load of silver, and that can kill a lot of cells in the wound."
Wound healing is a particular problem in diabetes, where poor blood supply that inhibits healing can require amputations, and also in burn wards. Agarwal says some burn surgeons avoid silver dressings despite their constant concern with infection.
Using a new approach, Agarwal has crafted an ultra-thin material carrying a precise dose of silver. One square inch contains just 0.4 percent of the silver that is found in the silver-treated antibacterial bandages now used in medicine.
In tests in lab dishes, the low concentration of silver killed 99.9999 percent of the bacteria but did not damage cells called fibroblasts that are needed to repair a wound.
Agarwal builds the experimental material from polyelectrolyte multilayers - a sandwich of ultra-thin polymers that adhere through electrical attraction. To make the sandwich, Agarwal alternately dips a glass plate in two solutions of oppositely charged polymers, and finally adds a precise dose of silver.
"This architecture is very easily tuned to different applications," Agarwal says, because it allows exact control of such factors as thickness, porosity and silver content. The final sandwich may range from a few nanometers to several hundred nanometers in thickness. (One nanometer is one-billionth of a meter; a human hair is about 60,000 nanometers in diameter.)
Nicholas Abbott, a professor of chemical and biological engineering who advises Agarwal, says during the past decade, "about a bazillion papers have been published on polyelectrolyte multilayers. It's been a tremendous investment by material scientists, and that investment is now ripe to be exploited."
The project was supported by seed funding from the Wisconsin Institutes of Discovery - a new unit devoted to advancing technology in five targeted areas, including tissue engineering - and benefited from contributions by Christopher Murphy, Jonathan McAnulty and Charles Czuprynski of UW-Madison's School of Veterinary Medicine; Ronald Raines of the Department of Biochemistry; and Michael Schurr, a burn surgeon at the School of Medicine and Public Health.
Although both mammalian cells and bacteria are sensitive to silver, bacteria are much more sensitive, leaving a sweet spot - a concentration of silver that can kill bacteria without harming cells needed for healing. In tests using mouse cells and sample bacteria, Agarwal has tuned the dose to find the sweet spot where the silver bullet destroys 99.9999 percent of the bacteria, but does not harm fibroblasts.
Indeed, the system is so sensitive that increasing the silver dose from 0.4 percent to 1 percent of the level used in a commercial dressing severely damaged the fibroblasts.
To kill bacteria, silver must take the form of charged particles, or ions, and the tiny silver nanoparticles that Agarwal embeds in the sandwich can be designed to release ions for days or weeks as needed. In contrast, Agarwal says, commercial wound dressings contain a large dose of silver ions, which are released faster and with less control.
The required dose of silver can also be reduced because the new material would be designed to stay in close contact with the wound, Abbott says. "In a commercial dressing, the silver is part of the bandage that is placed on the wound surface. We envision this material becoming incorporated into the wound; the cells will grow over it and it will eventually decay and be absorbed into the body, much like an absorbable suture."
Tests on animals will be needed to before the new material can be tested on humans, says Abbott. "A commercial dressing needs to have a large quantity of silver so it can diffuse to the wound bed, and that quantity turns out to be toxic to mammalian cells in lab dishes. We are putting the silver where we need it, so we can use a small loading of silver, which does not exhibit toxicity to mammalian cells because the silver is precisely targeted."
University of Wisconsin-Madison
Using a new approach, Agarwal has crafted an ultra-thin material carrying a precise dose of silver. One square inch contains just 0.4 percent of the silver that is found in the silver-treated antibacterial bandages now used in medicine.
In tests in lab dishes, the low concentration of silver killed 99.9999 percent of the bacteria but did not damage cells called fibroblasts that are needed to repair a wound.
Agarwal builds the experimental material from polyelectrolyte multilayers - a sandwich of ultra-thin polymers that adhere through electrical attraction. To make the sandwich, Agarwal alternately dips a glass plate in two solutions of oppositely charged polymers, and finally adds a precise dose of silver.
"This architecture is very easily tuned to different applications," Agarwal says, because it allows exact control of such factors as thickness, porosity and silver content. The final sandwich may range from a few nanometers to several hundred nanometers in thickness. (One nanometer is one-billionth of a meter; a human hair is about 60,000 nanometers in diameter.)
Nicholas Abbott, a professor of chemical and biological engineering who advises Agarwal, says during the past decade, "about a bazillion papers have been published on polyelectrolyte multilayers. It's been a tremendous investment by material scientists, and that investment is now ripe to be exploited."
The project was supported by seed funding from the Wisconsin Institutes of Discovery - a new unit devoted to advancing technology in five targeted areas, including tissue engineering - and benefited from contributions by Christopher Murphy, Jonathan McAnulty and Charles Czuprynski of UW-Madison's School of Veterinary Medicine; Ronald Raines of the Department of Biochemistry; and Michael Schurr, a burn surgeon at the School of Medicine and Public Health.
Although both mammalian cells and bacteria are sensitive to silver, bacteria are much more sensitive, leaving a sweet spot - a concentration of silver that can kill bacteria without harming cells needed for healing. In tests using mouse cells and sample bacteria, Agarwal has tuned the dose to find the sweet spot where the silver bullet destroys 99.9999 percent of the bacteria, but does not harm fibroblasts.
Indeed, the system is so sensitive that increasing the silver dose from 0.4 percent to 1 percent of the level used in a commercial dressing severely damaged the fibroblasts.
To kill bacteria, silver must take the form of charged particles, or ions, and the tiny silver nanoparticles that Agarwal embeds in the sandwich can be designed to release ions for days or weeks as needed. In contrast, Agarwal says, commercial wound dressings contain a large dose of silver ions, which are released faster and with less control.
The required dose of silver can also be reduced because the new material would be designed to stay in close contact with the wound, Abbott says. "In a commercial dressing, the silver is part of the bandage that is placed on the wound surface. We envision this material becoming incorporated into the wound; the cells will grow over it and it will eventually decay and be absorbed into the body, much like an absorbable suture."
Tests on animals will be needed to before the new material can be tested on humans, says Abbott. "A commercial dressing needs to have a large quantity of silver so it can diffuse to the wound bed, and that quantity turns out to be toxic to mammalian cells in lab dishes. We are putting the silver where we need it, so we can use a small loading of silver, which does not exhibit toxicity to mammalian cells because the silver is precisely targeted."
University of Wisconsin-Madison
Wound Healing Current Events and Wound Healing News RSS1930s drug slows tumor growth
Drugs sometimes have beneficial side effects. A glaucoma treatment causes luscious eyelashes. A blood pressure drug also aids those with a rare genetic disease.
Probiotic Found to Be Effective Treatment for Colitis In Mice
The probiotic, Bacillus polyfermenticus, can help mice recover from colitis, a new study has found.
Aggressive microdermabrasion induces wound-healing response in aging skin
Microdermabrasion using a coarse diamond-studded instrument appears to induce molecular changes in the skin of older adults that mimic the way skin is remodeled during the wound healing process.
Super sticky barnacle glue cures like blood clots
Barnacles are a big problem for boats. Adhering to the undersides of vessels, carpets of the crustaceans can increase fuel consumption by as much as 25%.
'Spaghetti' scaffolding could help grow skin in labs
Scientists are developing new scaffolding technology which could be used to grow tissues such as skin, nerves and cartilage using 3D spaghetti-like structures.
Platelet-rich plasma: Does it work?
Platelet -rich plasma (PRP) is currently used as an alternative treatment method for several common orthopaedic-related sports medicine conditions.
Diabetes weakens your bones
Current research suggests that the inflammatory molecule TNF-α may contribute to delayed bone fracture healing in diabetics.
UT scientists discover link between protein and lung disease
In a development that could lead to a novel approach to the treatment of a devastating lung disease, biochemists at The University of Texas Health Science Center at Houston report they are the first to link the osteopontin (OPN) protein to chronic obstructive pulmonary disease (COPD).
How stem cells make skin
Stem cells have a unique ability: when they divide, they can either give rise to more stem cells, or to a variety of specialised cell types.
Plastic surgeons should be part of disaster relief planning, response
When a terrorist bomb explodes, a tornado rips through a town, a hurricane devastates a region, or wildfires ravage homes and businesses, plastic surgeons are not typically atop the list of emergency responders.
More Wound Healing Current Events and Wound Healing News Articles
 |
Wound Healing (Basic and Clinical Dermatology) by Anna Falabella (Editor), Robert Kirsner (Editor) Offering a comprehensive review of the field from basic scientific concepts to assessment and treatment strategies, this reference provides an excellent understanding of the epidemiology, diagnosis, and prevention of acute and chronic wounds-analyzing the latest research from some of the most experienced clinicians and scientists in the field, as well as promising therapies for wound evaluation and care. The editors provide a complete understanding of the process of wound healing and cover the latest practices in wound management and care. They discuss the pathophysiologic processes that lead to chronic wound formation, common factors, possible complications, and the most recent developments. |
 |
WOUND-BE-GONE Healing Gel (5g) by Wake Pharma US Wound-Be-GoneĀ® is the only Over-the-Counter product Clinically Proven to accelerate healing, decrease inflammation, reduce pain, and prevent scar formation with both ACUTE and CHRONIC wounds. Wound-Be-Gone is a breakthrough technology, the active ingredient in Wound-Be-GoneĀ® binds and deactivates Oxygen Free Radicals, which are toxic substances known to cause inflammation and delay wound |
 |
ABC of Wound Healing (ABC Series) by Joseph E. Grey (Editor), Keith G. Harding (Editor) This brand new title in the ABC series looks at the treatment and management of wounds and healing procedure - it's the perfect aid for students, nursing staff, hospital doctors and GPs. Covers the assessment, diagnosis and management of all wounds - from traumatic to chronic. Giving practical advice on dressings and devices used in the management of wounds. |
|
Bulletin - European Tissue Repair Society by Wound Healing Institute | |
 |
Healing the Wounds by The Crusaders |
 |
The Uncanny X-Men Sabretooth I Action Figure With HIdden wounds and Glow In The Dark Features! Self Healing Wounds! Marvel ToyBiz by Toy Biz Marvel The Uncanny X-Men Sabretooth I Action Figure With HIdden wounds and Glow In The Dark Features! Self Healing Wounds! Marvel ToyBiz |
 |
J&J Red Cross Ultraheal Multi-Day Pads, 4 1/3-Inches X 4 1/3-Inches, 3-Count Boxes by J&J Red Cross |
 |
Healing The Wounds The Crusaders (Primary Contributor) |
 |
Zoo Med Repti Wound-Healing Aid 1 fl. oz. by Zoo Med 1 oz. Topical antiseptic with jojoba oil and tea tree oil helps heal cuts, burns, and abrasions on reptiles. Can also be used to help heal topical infections of toads. Use as a topical antiseptic to help heal cuts, burns, and abrasions on reptiles.Can also be used to help heal topical infections of toads. reptile health care |
 |
Saviours' Day 2002 - Healing the Wounds to Bring About a Universal Family Also With: Louis Farrakhan (Primary Contributor) Saviours' Day - February 17, 2002, Los Angeles, California. "Healing the Wounds to Bring About a Universal Family." |
| © 2009 BrightSurf.com |