From the 63rd International Symposium and Exhibition of AVS

Using Plasma to Make Skin “Thin” Researchers in Japan use microplasma to reduce skin’s barrier in drug delivery

EMBARGOED for release until 8:00a.m. Eastern Time on November 08, 2016For More Information:AIP Media Line[email protected]301-209-3090

Newswise — Washington, D. C., November 08, 2016— Delivering drugs through needles presents risks of infection to patients, not to mention causing pain and discomfort. Oral delivery of drugs, on the other hand, can prove toxic for some in digestible form and can be less effective than more direct methods unless higher does are administered. Transdermal delivery, where the drug is absorbed into the blood stream through the skin, provides an ideal solution, offering painless and effective delivery.

Only a fraction of drugs currently on the market can be administered this way because skin, by its very nature, is difficult to permeate -- a characteristic measured by its barrier function. More universal use of transdermal drug delivery demands a mechanism to reduce this barrier function, improving its permeability to drugs.

A research team from Shizuoka University in Japan has explored the permeability of skin and will present their work during the AVS 63rd International Symposium and Exhibition being held November 6-11, 2016, in Nashville, Tennessee. As a means to interact with skin, the team used plasma, a state of matter where electrons have dissociated from their corresponding ions and exhibit more collective behavior. Using plasma, which conducts electricity, they successfully decreased its barrier function for transdermal drug delivery.

The team of researchers at Shizuoka University built upon this prior work proving that plasma can interact with skin in the desired way. Using both a plasma jet and a microplasma discharge method researchers investigated the barrier function of the stratum corneum, or outermost skin layer, of Yucatan micropig skin, chosen because of its similarities to human skin. The physical changes in the pig skin were studied microscopically. Specifically, they studied changes in the outer skin layer using Attenuated Total Reflectance – Fourier Transform InfraRed (ATR-FTIR) spectroscopy. ATR-FTIR spectra provide precise information about water, the lipid (fat) bilayer and proteins in the outermost layer of the skin, all factors directly related to its permeability.

The team found microplasma to be a good potential method for transdermal applications. “We compared the effects of plasma on conductive and non-conductive material,” explained M. Blajan, an applied physicist from Shizuoka University in Japan. "Placement of skin on the conductive material caused burned spots on the skin by the plasma jet, while treatment of the skin by microplasma showed little physical damage.” This work could be instrumental in developing a more effective means of drug delivery.

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Presentation PB+BI+PS-TuM2, "Spectroscopic Study of Permeability of Stratum Corneum by Plasma Treatment for Transdermal Drug Delivery," is at 8:20 a.m. CDT, November 8, 2016 in Room 101A

MORE ABOUT THE AVS 63rd INTERNATIONAL SYMPOSIUM & EXHIBITIONThe symposium is being held November 6-11, 2016, in Nashville, Tennessee

USEFUL LINKSMain symposium website: https://www.avs.org/SymposiumTechnical Program: http://www.avssymposium.orgMedia Center: https://www.avs.org/About/Press-Media-Center

PRESSROOMTo request free press registration, please contact Della Miller at [email protected].

ABOUT AVS As an interdisciplinary, professional Society, AVS supports networking among academic, industrial, government, and consulting professionals involved in a variety of disciplines - chemistry, physics, biology, mathematics, all engineering disciplines, business, sales, etc. through common interests related to the basic science, technology development, and commercialization of materials, interfaces, and processing area.

Founded in 1953, AVS is organized into technical divisions and technical groups that encompass a range of established as well as emerging science and technology areas. There are also regional chapters, international chapters and affiliates, and student chapters that promote communication and networking for professionals and students within a geographical region. AVS is comprised of approximately 4,500 members worldwide.

AVS is a member society of the American Institute of Physics with additional benefits for our members. For more information about AVS, visit our website at http://www.avs.org