N. Otberg

Porcine ear skin: an in vitro model for human skin

Background/purpose: Porcine ear skin is used in studies of percutaneous penetration as a substitute for human skin. The structure of this tissue, including hair follicles, was studied qualitatively and quantitatively in comparison with human skin.

Hair follicles - a long-term reservoir for drug delivery.

Nanoparticles represent an important drug carrier system. Recently, we have reported on the penetration and storage behavior of particular and non-particular substances revealing the superiority of particular substances in the range of 300–400 nm. In this regard, it was assumed that the rigid hair shaft acts as a geared pump, moving the particles deeper into the hair follicle. In the present investigation, the storage reservoir capacity of the stratum corneum and the hair follicle infundibulum and canal are compared. Interestingly, we could demonstrate a 10 times longer storage within the hair follicles. These results underscore the importance of the hair follicle for drug delivery purposes, mainly highlighting new possibilities for the future concerning retarded delivery, application frequency, and galenic design.

Application of optical non‐invasive methods in skin physiology: a comparison of laser scanning microscopy and optical coherent tomography with histological analysis

Background/purpose: Optical, non‐invasive methods, such as fluorescence laser scanning microscopy (LSM) and optical coherent tomography (OCT), have become efficient tools for the characterization of the skin structure in vivo, as well as real‐time investigation of distribution and penetration of topically applied substances.

Follicular Penetration: Development of a Method to Block the Follicles Selectively against the Penetration of Topically Applied Substances

Investigations into the penetration pathways of topically applied substances through the skin play an important role in dermatological science. Recently, the hair follicles have increasingly been recognized as an important pathway for percutaneous penetration, although the role of the follicles has still not been clarified in detail. Therefore, the aim of the present study was to develop an in vivo method for the analysis of the follicular rate of penetration processes. In order to reach this goal, the follicles were excluded from the penetration process of topically applied substances. Different study designs were evaluated, and we were able to show that the application of nail varnish to each follicular orifice represents an effective method of blocking the follicles selectively against the penetration of topically applied substances. In dermatological science, there is new information on the physiology of skin penetration processes, thus allowing examination of the follicular rate of penetration and improvement of the pharmacokinetics of topically applied substances.

Permeation of topically applied caffeine through human skin – a comparison of in vivo and in vitro data

AIMS Due to ethical reasons, in vivo penetration studies are not applicable at all stages of development of new substances. Therefore, the development of appropriate in vitro methods is essential, as well as the comparison of the obtained in vivo and in vitro data, in order to identify their transferability. The aim of the present study was to investigate the follicular penetration of caffeine in vitro and to compare the data with the in vivo results determined previously under similar conditions. METHODS The Follicular Closing Technique (FCT) represents a method to investigate the follicular penetration selectively. In the present study, FCT was combined with the Franz diffusion cell in order to differentiate between follicular and intercellular penetration of caffeine into the receptor medium in vitro. Subsequently, the results were compared with the data obtained in an earlier study investigating follicular and intercellular penetration of caffeine in vivo. RESULTS The comparison of the data revealed that the in vitro experiments were valuable for the investigation of the follicular penetration pathway, which contributed in vivo as well as in vitro to approximately 50% of the total penetration, whereas the kinetics of caffeine penetration were shown to be significantly different. CONCLUSIONS The combination of FCT with the Franz diffusion cell represents a valuable method to investigate follicular penetration in vitro. Nevertheless, in vivo experiments should not be abandoned as in vitro, structural changes of skin occur and blood flow and metabolism are absent, probably accounting for reduced penetration rates in vitro.

Follicular Penetration of Topically Applied Caffeine via a Shampoo Formulation

Aims: Follicular drug delivery is the prerequisite for an effective treatment of androgenetic alopecia or other reasons of premature hair loss. Methods: The follicular penetration of caffeine, applied topically in a shampoo formulation for 2 min, was measured with highly sensitive surface ionization in combination with mass spectroscopy, a selective method for the detection of very small quantities of transcutaneously absorbed substances in the blood. An experimental protocol, developed to selectively block the follicular pathway within the test area, was used. Based on this principle, a clear distinction between interfollicular and follicular penetration of topically applied caffeine was feasible. Results: After 2 min, caffeine penetrated via the hair follicles and stratum corneum. Conclusion: It was found that the penetration via hair follicles was faster and higher compared with the interfollicular route and that hair follicles are the only pathway for fast caffeine absorption during the first 20 min after application.

In vivo confocal scanning laser microscopy: comparison of the reflectance and fluorescence mode by imaging human skin

Optical, noninvasive methods have become efficient in vivo tools in dermatological diagnosis and research. From these promising imaging techniques, only the confocal scanning laser microscopy (CSLM) provides visualization of subsurface skin structures with resolutions similar to those of light microscopy. Skin annexes, as well as cutaneous cells from different epidermal layers, can be distinguished excellently. Currently, two forms of application have been established in dermatological practice: the reflectance mode, predominantly in the clinical field, and the fluorescence mode in dermatological research. Differences in both methods exist in the preparative protocol, in maximum imaging depth and, particularly, in the gain of contrast extraction. The reflectance mode demonstrates naturally occurring tissue components, whereas the fluorescent CSLM achieves contrast by administering fluorescence dye, representing the dynamic distribution pattern of the dyes fluorescent emission. Therefore, the reflectance and fluorescent modes highlight various skin microstructures, providing dissimilar in vivo confocal images of the skin. This permits different predications and information on the state of the tissue. We report the advantages and disadvantages of both optical imaging modes. The comparison was drawn by scanning human skin in vivo. Representative images in varying depths were obtained and analyzed; preparation procedures are shown and discussed.

Clinical applicability of in vivo fluorescence confocal microscopy for noninvasive diagnosis and therapeutic monitoring of nonmelanoma skin cancer.

Excisional biopsies and routine histology remains the gold standard for the histomorphologic evaluation of normal and diseased skin. However, there is increasing interest in the development of noninvasive optical technologies for evaluation, diagnosis, and monitoring of skin disease in vivo. Fluorescent confocal microscopy is an innovative optical technology that has previously been used for morphologic evaluation of live human tissue. We evaluate the clinical applicability of a fluorescent confocal laser scanning microscope (FLSM) for a systematic evaluation of normal and diseased skin in vivo and in correlation with routine histology. A total of 40 patients were recruited to participate in the study. Skin sites of 10 participants with no prior history of skin disease served as controls and to evaluate topographic variations of normal skin in vivo. Thirty patients with a suspected diagnosis of nonmelanoma skin cancer were evaluated, whereby FLSM features of actinic keratoses (AK) and basal cell carcinoma (BCC) were recorded in an observational analysis. Selected BCCs were monitored for their skin response to topical therapy using Imiquimod as an immune-response modifier. A commercially available fluorescence microscope (OptiScan Ltd., Melbourne, Australia) was used to carry out all FLSM evaluations. Common FLSM features to AK and BCC included nuclear pleomorphism at the level of the granular and spinous layer and increased vascularity in the superficial dermal compartment. Even though the presence of superficial disruption and mere atypia of epidermal keratinocytes was more indicative of AK, the nesting of atypical basal cells, increased blood vessel tortuosity, and nuclear polarization were more typical for BCC. All diagnoses were confirmed by histology. FLSM allowed a monitoring of the local immune response following therapy with Imiquimod and demonstrated a continuous normalization of diseased skin on repeated evaluations over time. This study illustrates potential applications of FLSM in clinical dermatology for the evaluation of dynamic skin conditions and monitoring of cutaneous response to noninvasive therapies. The findings are of preliminary nature and warrant further investigations in the future.

Ethnic Variation in Vellus Hair Follicle Size and Distribution

It is a given fact that hair follicles play an important role in the penetration process of topically applied drugs and cosmetics. Since exact knowledge of the potential follicular reservoir is essential for understanding and calculating the penetration process, this knowledge may indeed help to optimize the development of topically applied drugs and cosmetic products. We know that variability in skin properties exists among the human population, but it is the deciphering and quantification of these differences that may help to explain racial disparities in dermatological disorders and provide a basic approach for treatment and prevention. Data pertaining to structural and functional differences within ethnic skin types (reviewed in this paper) support the assumption that hair follicles in the various skin types are not equal. Thus, the need to investigate follicular morphology in non-Caucasian skin types becomes more than apparent. The aim of the present study was to determine the potential reservoir of vellus hair follicles in non-Caucasian skin types in order to estimate their contribution to the penetration of topically applied substances. Cyanoacrylate skin surface biopsies were taken from seven body sites of Asians and African-Americans. To determine the follicular reservoir, the samples were evaluated under the light microscope. Follicular parameters were measured with the help of a digital imaging software program. In the evaluation and comparison of the results with those of Caucasians, significant differences were detected. Compared with Whites, follicular density on the forehead is significantly lower in Asians and African-Americans. Smaller values were detected for volume, surface, follicular orifice and hair shaft diameter on the thigh and in calf regions in Asians and African-Americans. Furthermore, the follicular reservoir, characterized by follicular volume, is generally higher in Caucasians. In comparison to African-Americans, larger follicular volumes on the forehead, back and on the upper arm were determined in Asians. The fairly similar density in these sites revealed that Asians have a higher follicular reservoir in these sites. Due to significant ethnic differences in the follicular reservoir, particularly on the calf and forehead, prospective skin absorption experiments need to be performed on different skin types in order to be representative. Likewise, the development of topically applied drugs should take place under adequate consideration of ethnic differences in skin physiology.

Penetration of microparticles into human skin

The efficacy of the penetration of microparticles into the human skin depends on the size and the type of the formulation with which they are topically applied. Microparticles with a diameter of >1 microm barely penetrate into the human skin. They are located on the skin surface and form a film which, for instance, can be used for camouflage or protection against UV radiation in sunscreens. While the penetration of the microparticles in the lipid layers of the stratum corneum is limited, they penetrate efficiently into the hair follicles up to a depth >2 mm, providing their diameter is <1.5 microm. Thus, microparticles can be used for drug delivery into the hair follicles.