Time-course quantitative mapping of caffeine within the epidermis, using high-contrast pump-probe stimulated Raman scattering microscopy.

BACKGROUND: An assessment of the drug penetration and distribution profiles within the skin is essential in dermatology and cosmetology. Recent advances in label-free imaging technologies have facilitated the direct detection of unlabeled compounds in tissues, with high resolution. However, it remains challenging to provide quantitative time-course distribution maps of drugs within the complex skin tissue. The present study aims at acquiring the real-time quantitative skin penetration profiles of topically applied caffeine, by means of a combination of pump-probe phase-modulated stimulated Raman scattering (PM-SRS) and confocal reflection microscopy. The recently developed PM-SRS microscopy is a unique imaging tool that can minimize strong background signals through a pulse-shaping technique, while providing high-contrast images of small molecules in tissues. MATERIALS AND METHODS: Reconstructed human skin epidermis models were used in order to analyze caffeine penetration in tissues. The penetration profiles of caffeine in an aqueous solution, an oil-in-water gel, and a water-in-oil gel were examined by combining PM-SRS and confocal reflection microscopy. RESULTS: The characteristic Raman signal of caffeine was directly detected in the skin model using PM-SRS. Integrating PM-SRS and confocal reflection microscopy allowed real-time concentration maps of caffeine to be obtained from formulation samples, within the skin model. Compared with the conventional Raman detection method, PM-SRS lowered the background tissue-oriented signals and supplied high-contrast images of caffeine. CONCLUSION: We successfully established real-time skin penetration profiles of caffeine from different formulations. PM-SRS microscopy proved to be a powerful, non-invasive, and real-time depth-profile imaging technique for use in quantitative studies of topically applied drugs.

Label-free skin penetration analysis using time-resolved, phase-modulated stimulated Raman scattering microscopy.

Skin penetration analysis of topically applied drugs or active compounds is essential in biomedical applications. Stimulated Raman scattering (SRS) microscopy is a promising label-free skin penetration analysis tool. However, conventional SRS microcopy suffers from limited signal contrast owing to strong background signals, which prevents its use in low-concentration drug imaging. Here, we present a skin penetration analysis method of topical agents using recently developed phase-modulated SRS (PM-SRS) microscopy. PM-SRS uses phase modulation and time-resolved signal detection to suppress both nonlinear background signals and Raman background signals from a tissue. A proof-of-concept experiment with a topically applied skin moisturizing agent (ectoine) in an in vitro skin tissue model revealed that PM-SRS with 1.7-ps probe delay yields a signal contrast 40 times higher than that of conventional amplitude-modulated SRS (AM-SRS). Skin penetration measurement of a topical therapeutic drug (loxoprofen sodium) showed that the mean drug concentration at the tissue surface layer after 240 min was 47.3 ± 4.8 mM. The proposed PM-SRS microscopy can be employed to monitor the spatial and temporal pharmacokinetics of small molecules in the millimolar concentration regime.

Assay of photoinhibition of photosystem II and protease activity.

Under light-stress conditions, the photosystem (PS)II reaction center D1 protein is photo-damaged. The damage to the D1 protein is induced by singlet oxygen molecules and endogenous free radicals generated by the photochemical reactions of PSII. To maintain PSII activity, the oxidatively damaged D1 protein is replaced by a newly synthesized protein. Thus, degradation and removal of the photodamaged D1 protein in PSII are essential steps for maintaining the viability of PSII. In the present chapter, we describe the method to induce photoinhibition of PSII both in vitro and in vivo, and also the method to assay the processes closely related to the photoinhibition, including degradation of the damaged D1 protein and its crosslinking with the neighboring polypeptides. The method to analyze the protease activity in the stroma that recognizes and digests the crosslinked products of the D1 protein generated by the light stress is also described.