Two-Photon Microscopy Reveals Skin-Allergen Connection
GOTHENBURG, Sweden, Dec. 30, 2011 — Two-photon microscopy has shown that the skin absorbs various substances differently, depending on what they are mixed with. These differences may determine whether a substance causes contact allergy.
“We have also been able to identify specific cells and proteins in the skin with which a contact allergen interacts,” said Carl Simonsson of the University of Gothenburg, where the skin research that formed his thesis took place. “The results increase our understanding of the mechanisms behind contact allergy.”
Skin photographed in the two-photon microscope, showing epidermal cells and the collagen present in the dermis. (Photo: Carl Simonsson)
The skin is the largest organ in the human body and plays many vital roles, one of which is to prevent harmful microorganisms from invading the body. The principal barrier is the stratum corneum — a layer of skin cells about a few microns thick. Despite being so thin, this layer effectively protects us from bacteria and viruses.
The skin, however, is not adapted to deal with and prevent absorption of many of the chemicals that we are exposed to today. This may lead to various types of diseases, such as contact allergy, which affects approximately 20 percent of people in Sweden.
Carl Simonsson, whose thesis showed the utility of two-photon microscopy in the exploration of contact allergens in the skin. (Photo: University of Gothenburg)
Two-photon microscopy makes it possible to follow substances as they are absorbed into the skin. The method is unique in that it allows researchers not only to see how well a substance is absorbed, but also what happens to it, and to find the location in the skin where the substance eventually arrives.
In addition, the skin barrier and the way in which various substances are absorbed are highly significant for the development of new drugs. Creams and ointments are for many reasons an interesting alternative to tablets, which must be taken orally. The barrier properties of the skin may present, in this case, an obstacle to drug absorption, making it difficult for sufficient amounts of the drug to penetrate the skin to give a clinical effect.
“We have used two-photon microscopy to study a new type of ointment that it may be possible to use to improve the absorption, and thus the clinical effect, of certain drugs that are used on the skin,” Simonsson said.
For more information, visit: hdl.handle.net/2077/27832
MORE FROM PHOTONICS MEDIA