In Vitro Evaluation of Percutaneous Absorption of an Acyclovir Product using Intact and Tape-stripped Human Skin

Manuscript received August 10th, 1998; Reviewed August 18th, 1998; Accepted October 23rd 1998.

Min Jiang, Saeed A. Qureshi¹
Therapeutic Products Directorate |(PL#2202C1), Health Canada, Ottawa, Ontario, Canada K1A 0L2

Kamal K. Midha
Drug Metabolism, Drug Disposition Research Group, College of Pharmacy and Nutrition, University of Saskatchewan, Saskatoon, Saskatchewan, Canada S7N 5C9

Jerome P. Skelly
Copley Pharmaceuticals, Inc., Canton, MA, USA 02021, presently with College of Pharmacy, University of Cincinnati, Cincinnati, Ohio, USA

Abstract

Purpose. To evaluate the use of a flow-through diffusion cell system to assess the absorption and penetration characteristics of drug (acyclovir) products.

Methods. In vitro studies were performed to assess the absorption/penetration of acyclovir using a flow-through diffusion cell system with human skin sections obtained from 19 healthy women following mammoplasty. The skin sections, 200-400 mm thick, were prepared using a dermatome. Acyclovir ointment (~10 mg) spiked with ³H-labelled acyclovir was applied onto the stratum corneum/epidermis side. The skin sections were continually perfused on the dermis side with sterilized culture medium, Buffered Hanks’ Balanced Salt Solution, saturated with a CO2/O2 (5/95%).

Results. After 24 hours, the percentages of acyclovir-derived radioactivity (based on dose applied) in different components were as follows: stratum corneum (SC), 0.20+0.28; viable skin (VS), 0.40+0.38; effluent fluid (EF), 0.25+0.53. A second set of experiments was performed using tape stripped (10X) skin sections. Levels of acyclovir-derived radioactivity were VS, 1.21+1.43 and EF, 2.65+2.61, which were threefold higher (p < 0.05) for VS and elevenfold higher (p < 0.05) for EF compared to the results obtained with the intact skin sections.

Conclusions. The SC is the main barrier layer for the penetration of acyclovir through human skin. The use of the flow-through diffusion cell system provides an appropriate in vitro model to assess the absorption/penetration of acyclovir through human skin layers and therefore can potentially be used for dermal formulation characterization and development.

Introduction

Acyclovir {9-[(2-hydroxyethoxy)methyl]guanine} is a synthetic purine nucleoside analog derived from guanine. It differs structurally from guanine by the presence of an acyclic side chain (1). The activity of acyclovir is directed primarily against the herpes group of DNA viruses (2-3). Susceptible members of the herpes virus family include herpes simplex virus 1 (HSV-1), herpes simplex virus 2 (HSV-2), varicella-zoster, Epstein-Barr virus, and murine cytomegalovirus (4-7). The unique feature of acyclovir is its selectivity as a substrate for virus-specified thymidine kinase (8-10). Since acyclovir is selectively converted to its active form in herpes virus-infected cells, it is not toxic to normal, uninfected cells (11-14). Acyclovir is indicated for the treatment of infections caused by the herpes virus and is considered the safest and most efficacious for this purpose.

Acyclovir can be administered orally or intravenously for treating herpes virus infections (15-16). Topical application of acyclovir in polyethylene glycol (PEG) is also a common practice, but has been shown to be less effective compared with oral or intravenous routes. Lack of effectiveness of topically applied acyclovir has been attributed to an inadequate delivery of the drug to the skin cells (17-19). Nevertheless, convincing evidence to conclude lack of absorption into the skin layer appears to be lacking.

This report describes an application of the flow-through diffusion system for the evaluation of absorption and penetration characteristics of acyclovir from an ointment product.

Material and Methods

Skin sections were prepared using an Electro-dermatome, model B purchased from Padgett Instruments, Missouri, USA. The percutaneous absorption experiments were conducted using a flow-through diffusion cell system (Crown Glass, Inc. PA, USA). A 5% acyclovir ointment, in a polyethylene glycol (Burroughs Wellcome Co., Research Triangle Park, N.C. USA) was obtained from a local market. [³H]-acyclovir (specific activity: 35 mCi/mmol and concentration: 1000 mCi/ml) was obtained from ICN, CA, USA. The Liquid Scintillation Counter, System 1400^TM was from Fisher Scientific, USA. All other chemicals and reagents were of analytical grade and were obtained from commercial sources.

Nineteen healthy women participated in the study by providing the skin tissue. All subjects gave written informed consent before participating in the trial. The subjects were 19 to 35 years of age (27 + 5.6) and were judged to be healthy based on medical history and physical evaluation.

The skin specimens were collected from the hospital after plastic breast reduction surgery. The skin tissue was transferred into a container with the sterilised (HEPES buffered Hanks' Balanced Salt Solution) to maintain the tissue viability. To minimize the loss of viability of the skin tissue, experiments were initiated within 4 hours after the surgery.

Set-Up Of Flow-Through Diffusion Cell System

Water, maintained at 35⁰, was circulated around the diffusion cell system to maintain a skin temperature of 32⁰. The system, including perfusion medium reservoir, flow-through cells and connected tubing, was sterilized using 75% ethanol/water solution. Following the sterilization step, the remaining 75% alcohol was flushed out with sterilized water which was then replaced with HHBSS perfusion media maintaining a flow rate of 2 mL/hour, as described by Bronaugh et al (20).

Preparation Of Skin Tissues

The skin tissues for diffusion experiments were prepared by removing any muscle and fat tissues. The tissues were pinned to the surface of a styrofoam block (with stratum corneum side up) and a layer of 200 - 400 mm thickness was removed using a dermatome. The thin layered skin section was then cut into pieces of about 1.8-cm diameter using a cork-borer, which were then mounted onto the cells (with stratum corneum or epidermis exposed to environment). The lower chamber of flow-cell apparatus, which had a volume of approximately 150 mL, was continually replenished with sterilized perfusion medium (HHBSS), saturated with a CO₂/O₂ (5/95%) to perfuse the skin sections and to remove the penetrated drug. For the assessment of drug absorption with tape-stripped sections, prior to mounting the skin sections onto the cells, SC layers were removed by repeated (10X) tape stripping the sections.

Sample Application and Quantitation: Prior to each experiment sufficient quantity of acyclovir ointment was spiked with [³H]-acyclovir and thoroughly mixed at room temperature. Consistency in mixing of the labelled compound was established by obtaining consistent radioactivity readings of serial samples.

An aliquot of acyclovir ointment (~10 mg) spiked with [³H]-acyclovir (1.00 mCi/mL), resulting in ~5 X 10 5 counts (DPM), were applied on the stratum corneum/epidermis side of the skin sections. The tissues were perfused for 24 and the perfusion medium was collected in four fractions of six–hour each.

To solubilize the viable skin sections, i.e. sections without SC, for determining the radioactivity, the tissue was mixed with 3 mL of tissue solubilizing solution (Soluene 350, Packard, USA) and was kept at room temperature for 24 hr. The mixture was then neutralized by adding 180 mL of acetic acid followed by mixing with 7 mL of LSC-Cocktail, which was used for scintillation counting to determine the amount of acyclovir in the tissue.

The results were analyzed using the Student t-test (SAS software, SAS Institute, Cary, NC). In the description of results, "N" represents the numbers of human volunteers, and "n" represents the numbers of experimental repeats. A difference in results with a p value less than 0.05 was considered significant. Data are presented as mean +SD.

Results

To minimize the variability in results due to tissue sites, only skin specimens from breast tissues were employed.

At the end of the experiments 60 to 85% of the total applied radioactivity was accounted for, however, only 0.85% of the applied dose was absorbed or penetrated through the skin. The distribution of absorbed acyclovir into different skin layers and the receptor fluid is given in Table 1.

These results are in agreement with the reported limited absorption characteristics of acyclovir both in human and animal studies (10, 19). Compared to intact skin section taped stripped sections resulted in higher (p < 0.05) drug levels in viable skin tissue (threefold) and into perfusion medium (elevenfold).

Table 1: Percent distribution of acyclovir, based on radioactivity levels, in different components of skin tissue and the perfusion medium

	Intact Skin (N=9, n = 32)	Tape-Stripped Skin (N=10, n=19)
Stratum Corneum	0.20 ± 0.28	N/A
Viable skin	0.40 ± 0.38	1.21 ± 1.43*
Perfusion Medium (Effluent)	0.25 ± 0.53	2.65 ± 2.61*

Values are the mean ± SD and are expressed as percentage of total applied acyclovir. All comparisons are based on t-test. "N" and "n" represents number of volunteers and repeats using tissue from the same volunteer, respectively.

*These values are significantly different at p < 0.05 when compared between groups (intact skin vs tape-stripped skin)

Discussion

The topical application of acyclovir for the treatment of HSV skin infections has a long history. However, the topical application of acyclovir has proven clinically disappointing in the therapy of HSV skin infections compared with oral or intravenous administration. Many authors have speculated that the failure of topical acyclovir therapy is due to the inadequate drug delivery to the target site, that is, basal epidermis (18-19). Adequate amounts of drug delivery to skin basal epidermis are necessary for the treatment of HSV skin infections because major virus-induced epidermal pathology occurs in the basal epidermis (21). Previous studies have also demonstrated that a positive correlation exists between drug dose and antiviral efficacy of acyclovir in HSV diseases (21-22). The results of our study support such a hypothesis, since only minimal amounts of acyclovir were absorbed and penetrated through the skin layers following topical application of the drug to intact skin (10, 19). Therefore, it is reasonable to conclude that the limited efficiency of topical acyclovir therapy is due, at least in part, to the inability of acyclovir to penetrate through the stratum corneum barrier layer of the skin and a lack of its reach at the target site the, basal epidermis.

In order to determine the mechanism of transdermal drug delivery and develop the optimal drug formulation, an adequate methodology for evaluating the percutaneous absorption of chemicals/drugs is needed. A wide variety of in vivo and in vitro methods for measuring percutaneous absorption are available. In vitro results from this study, with respect to the absorption and penetration of acyclovir, appear to be in good agreement with those in vivo and in vitro methods reported previously in the literature (18, 19, 27). Thus, the flow-through diffusion cell system provides an appropriate alternative approach for the direct measurement of skin absorption under controlled conditions and is relatively simple to study the extent of absorption and penetration of drugs, in particular acyclovir, at a relatively low cost.

Acknowledgement

We thank Michael S.G. Bell, M.D., Ms. Linda Charbonneau, R.N. and other nursing staff working at the Day Surgery, Ottawa Civic Hospital, for collecting and supplying samples. This project was partly funded by the University of Saskatchewan, Saskatoon, Canada.

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Corresponding author: Saeed A. Qureshi, Therapeutic Products Directorate (PL#2202C1), Health Canada, Ottawa, Ontario, Canada K1A 0L2 email:Saeed_qureshi@hc-sc.gc.ca

Keywords: Acyclovir, human skin, percutaneous absorption, in vitro method.

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