Abstract
The search for new formulations for transdermal drug delivery (TDD) is an important field in medicine and cosmetology. Molecules with specific physicochemical properties which can increase the permeability of active ingredients across the stratum corneum (SC) are called chemical penetration enhancers (CPEs), and it was shown that some CPEs can act synergistically. In this study, we performed coarse-grained (CG) molecular dynamics (MD) simulations of the lidocaine delivery facilitated by two CPEs—linoleic acid (LA) and ethanol—through the SC model membrane containing cholesterol, N-Stearoylsphingosine (DCPE), and behenic acid. In our simulations, we probed the effects of individual CPEs as well as their combination on various properties of the SC membrane and the lidocaine penetration across it. We demonstrated that the addition of both CPEs decreases the membrane thickness and the order parameters of the DPCE hydrocarbon chains. Moreover, LA also enhances diffusion of the SC membrane components, especially cholesterol. The estimated potential of mean force (PMF) profiles for the lidocaine translocation across SC in the presence/absence of two individual CPEs and their combination demonstrated that while ethanol lowers the free energy barrier for lidocaine to enter SC, LA decreases the depth of the free energy minima for lidocaine inside SC. These two effects supposedly result in synergistic penetration enhancement of drugs. Altogether, the present simulations provide a detailed molecular picture of CPEs’ action and their synergistic effect on the penetration of small molecular weight therapeutics that can be beneficial for the design of novel drug and cosmetics formulations.
Highlights
Transdermal drug delivery (TDD) is a method of delivering drugs systemically by applying a drug formulation onto intact and healthy skin [1]
We have further analyzed the properties of the lipid bilayers and the effects of chemical penetration enhancers (CPEs) on them based on the equilibrium 1-μs long simulations: density of individual Stratum corneum (SC)
Membrane components, membrane thickness, and diffusion coefficients of lipids and fatty acids. As it was previously shown in the works of [69,70], fatty acids tended to be partitioned into the lipid bilayer
Summary
Transdermal drug delivery (TDD) is a method of delivering drugs systemically by applying a drug formulation onto intact and healthy skin [1]. Stratum corneum (SC) serves as a rate-limiting lipophilic barrier against the uptake of chemical and biological toxins as well as transepidermal water loss [2]. A minority of molecules with specific physico-chemical properties can cross the skin sufficiently, and in the case of drugs with the blood circulation target subdermal tissue [4]. There are different approaches which are used in TDD to overcome the skin barrier: physical (e.g., iontophoresis, sonophoresis, electroporation, microfabricated microneedles, local temperature increase) [5], chemical (use of penetration enhancers) [6], and the use of carriers (vesicles and micro/nanoparticles) [7].
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