Abstract
Acne vulgaris is a common chronic skin disease in young adults caused by infection of the pilosebaceous unit, resulting in pimples and possibly permanent scarring on the skin. Minocycline, a common antibiotic, has been widely utilized as a systemic antimicrobial treatment for acne via oral administration. Recently, a topical minocycline gel (BPX-01) was developed to directly deliver minocycline through the epidermis and into the pilosebaceous unit to achieve localized treatment with lower doses of drug. As the effectiveness of the drug is directly related to its successful delivery, there is a need to evaluate the pharmacokinetics at the cellular level within tissue. Advantageously, minocycline is naturally fluorescent and can be directly visualized using microscopy-based approaches. Due to high endogenous autofluorescence, however, imaging of weakly emitting fluorescent molecules such as minocycline in skin tissue can be challenging. Here, we demonstrate a method for the selective visualization of minocycline within human skin tissue by utilizing two-photon excitation fluorescence (TPEF) microscopy and fluorescence lifetime imaging microscopy (FLIM). To demonstrate the feasibility of this approach, ex vivo human facial skin samples treated with various concentrations of BPX-01 were investigated. From the TPEF analysis, we were able to visualize relatively high levels of drug uptake within facial skin. However, minocycline fluorescence could be overwhelmed by endogenous fluorescence that complicates TPEF quantitative analysis, making FLIM more advantageous for visualizing drug uptake. Importantly, we found a unique signature of minocycline uptake via FLIM analysis that enabled the successful differentiation of the drug and enabled the extraction of drug local distribution from the endogenous fluorescence using a non-Euclidean phasor analysis method. Based on these results, we believe that the drug local distribution visualization method using TPEF and FLIM with phasor analysis can play an important role in studying the pharmacokinetics and pharmacodynamics of a topically applicable drug.
Highlights
Minocycline is a tetracycline class antibiotic that is frequently used for the treatment of acne vulgaris [1, 2]
In order to characterize the fluorescent properties of the drug and sebaceous glands, the two-photon excitation fluorescence (TPEF) spectra of MNC-Mg2+ and a thin section of human facial sebaceous gland were measured while the ultrafast laser was continuously scanned over the field of view
We developed and demonstrated a method for the selective visualization of minocycline uptake within human skin using TPEF microscopy and fluorescence lifetime imaging microscopy (FLIM) combined with a non-Euclidean phasor analysis approach
Summary
Minocycline is a tetracycline class antibiotic that is frequently used for the treatment of acne vulgaris [1, 2]. Systemic oral administration of an antibiotic to address a cutaneous disease may not be efficient, with high doses of minocycline required to drive sufficient concentration of the drug to its intended target. This is problematic for patients as minocycline is associated with systemic side effects that include dizziness, nausea, joint and muscle pain, and skin discoloration [3,4,5]. Minocycline has a characteristic yellow-green fluorescence that becomes brighter when chelated to magnesium ions, and this fluorescence has been used in the past to detect minocycline within minocycline-induced skin hyperpigmentation using conventional fluorescence microscopy [4, 5]
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