Design of tenofovir-UC781 combination microbicide vaginal gels

Patrick F. Kiser; Alamelu Mahalingam; Judit Fabian; Eric Smith; Festo R. Damian; Jennifer J. Peters; David F. Katz; Hoda Elgendy; Meredith R. Clark; David R. Friend

doi:10.1002/jps.23089

Design of tenofovir-UC781 combination microbicide vaginal gels

Patrick F. Kiser, Alamelu Mahalingam, Judit Fabian, Eric Smith, Festo R. Damian, Jennifer J. Peters, David F. Katz, Hoda Elgendy, Meredith R. Clark, David R. Friend^*

^*Corresponding author for this work

Biomedical Engineering

Research output: Contribution to journal › Article › peer-review

29 Scopus citations

Abstract

Tenofovir (TFV) is a proven microbicide when administered topically as a vaginal gel. To improve its efficacy, TFV was combined with the nonnucleoside reverse-transcriptase inhibitor UC781 in a vaginal gel. Mixture design of experiments theory was used to define a range of gel compositions with varying rheological properties and to assess in vitro drug release and tissue retention. Experiments and computations led to the specification of three different gels referred to as a spreading gel (SG), an intermediate spreading gel (ISG), and a bolus gel (BG). These three gels, all containing 1.0% TFV and 0.1% micronized UC781, were evaluated for in vitro release, in vitro tissue retention and safety, and in vivo pharmacokinetics in the rabbit. There were some differences in in vitro release rates of UC781 (the higher the gel viscosity, the slower the release rate) across gels, while release of TFV was independent of gel type. In an organotypic human vaginal-ectocervical (VEC) tissue model, the amounts of tissue-associated TFV and UC781 were several orders of magnitude higher than their in vitro half-maximal inhibitory concentration. There were no differences in VEC tissue concentrations of TFV or UC781 between the SG, ISG, and BG. All three gels were well tolerated in the VEC model as assessed by tissue viability, electrical resistance, histology, and cytokine (interleukin-8 and interleukin-1 beta) release. The local vaginal tissue concentrations in rabbits following a single dose or seven once-daily doses were variable and generally lower than those found in the VEC tissue model. The approach described herein provides a rational schema to design and evaluate vaginal gels for use as microbicides.

Original language	English (US)
Pages (from-to)	1852-1864
Number of pages	13
Journal	Journal of Pharmaceutical Sciences
Volume	101
Issue number	5
DOIs	https://doi.org/10.1002/jps.23089
State	Published - May 2012

Funding

The support of Missy Peet and Devon Kyle of MPI in coordination of the rabbit studies and sample bioanalysis is gratefully acknowledged. The contributions of Seyoum Ayehunie of MatTek, Inc. and Qing Wang at Absorption Systems, Inc. are also acknowledged. The editorial assistance of Jennifer Hurlburt of Contraceptive Research and Development is gratefully acknowledged. This work was funded by the United States Agency for International Development (USAID) under Cooperative Agreement GPO-A-00-08-00005-00. The views expressed by the authors do not necessarily reflect those of USAID.

Keywords

Absorption
Formulation
Permeability
Pharmacokinetics
Rheology
Semi-solids
Tenofovir
UC781
Vaginal gel
in vitro safety

ASJC Scopus subject areas

Pharmaceutical Science

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10.1002/jps.23089

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title = "Design of tenofovir-UC781 combination microbicide vaginal gels",

abstract = "Tenofovir (TFV) is a proven microbicide when administered topically as a vaginal gel. To improve its efficacy, TFV was combined with the nonnucleoside reverse-transcriptase inhibitor UC781 in a vaginal gel. Mixture design of experiments theory was used to define a range of gel compositions with varying rheological properties and to assess in vitro drug release and tissue retention. Experiments and computations led to the specification of three different gels referred to as a spreading gel (SG), an intermediate spreading gel (ISG), and a bolus gel (BG). These three gels, all containing 1.0% TFV and 0.1% micronized UC781, were evaluated for in vitro release, in vitro tissue retention and safety, and in vivo pharmacokinetics in the rabbit. There were some differences in in vitro release rates of UC781 (the higher the gel viscosity, the slower the release rate) across gels, while release of TFV was independent of gel type. In an organotypic human vaginal-ectocervical (VEC) tissue model, the amounts of tissue-associated TFV and UC781 were several orders of magnitude higher than their in vitro half-maximal inhibitory concentration. There were no differences in VEC tissue concentrations of TFV or UC781 between the SG, ISG, and BG. All three gels were well tolerated in the VEC model as assessed by tissue viability, electrical resistance, histology, and cytokine (interleukin-8 and interleukin-1 beta) release. The local vaginal tissue concentrations in rabbits following a single dose or seven once-daily doses were variable and generally lower than those found in the VEC tissue model. The approach described herein provides a rational schema to design and evaluate vaginal gels for use as microbicides.",

keywords = "Absorption, Formulation, Permeability, Pharmacokinetics, Rheology, Semi-solids, Tenofovir, UC781, Vaginal gel, in vitro safety",

author = "Kiser, {Patrick F.} and Alamelu Mahalingam and Judit Fabian and Eric Smith and Damian, {Festo R.} and Peters, {Jennifer J.} and Katz, {David F.} and Hoda Elgendy and Clark, {Meredith R.} and Friend, {David R.}",

note = "Funding Information: The support of Missy Peet and Devon Kyle of MPI in coordination of the rabbit studies and sample bioanalysis is gratefully acknowledged. The contributions of Seyoum Ayehunie of MatTek, Inc. and Qing Wang at Absorption Systems, Inc. are also acknowledged. The editorial assistance of Jennifer Hurlburt of Contraceptive Research and Development is gratefully acknowledged. This work was funded by the United States Agency for International Development (USAID) under Cooperative Agreement GPO-A-00-08-00005-00. The views expressed by the authors do not necessarily reflect those of USAID.",

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AU - Mahalingam, Alamelu

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AU - Smith, Eric

AU - Damian, Festo R.

AU - Peters, Jennifer J.

AU - Katz, David F.

AU - Elgendy, Hoda

AU - Clark, Meredith R.

AU - Friend, David R.

N1 - Funding Information: The support of Missy Peet and Devon Kyle of MPI in coordination of the rabbit studies and sample bioanalysis is gratefully acknowledged. The contributions of Seyoum Ayehunie of MatTek, Inc. and Qing Wang at Absorption Systems, Inc. are also acknowledged. The editorial assistance of Jennifer Hurlburt of Contraceptive Research and Development is gratefully acknowledged. This work was funded by the United States Agency for International Development (USAID) under Cooperative Agreement GPO-A-00-08-00005-00. The views expressed by the authors do not necessarily reflect those of USAID.

PY - 2012/5

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N2 - Tenofovir (TFV) is a proven microbicide when administered topically as a vaginal gel. To improve its efficacy, TFV was combined with the nonnucleoside reverse-transcriptase inhibitor UC781 in a vaginal gel. Mixture design of experiments theory was used to define a range of gel compositions with varying rheological properties and to assess in vitro drug release and tissue retention. Experiments and computations led to the specification of three different gels referred to as a spreading gel (SG), an intermediate spreading gel (ISG), and a bolus gel (BG). These three gels, all containing 1.0% TFV and 0.1% micronized UC781, were evaluated for in vitro release, in vitro tissue retention and safety, and in vivo pharmacokinetics in the rabbit. There were some differences in in vitro release rates of UC781 (the higher the gel viscosity, the slower the release rate) across gels, while release of TFV was independent of gel type. In an organotypic human vaginal-ectocervical (VEC) tissue model, the amounts of tissue-associated TFV and UC781 were several orders of magnitude higher than their in vitro half-maximal inhibitory concentration. There were no differences in VEC tissue concentrations of TFV or UC781 between the SG, ISG, and BG. All three gels were well tolerated in the VEC model as assessed by tissue viability, electrical resistance, histology, and cytokine (interleukin-8 and interleukin-1 beta) release. The local vaginal tissue concentrations in rabbits following a single dose or seven once-daily doses were variable and generally lower than those found in the VEC tissue model. The approach described herein provides a rational schema to design and evaluate vaginal gels for use as microbicides.

AB - Tenofovir (TFV) is a proven microbicide when administered topically as a vaginal gel. To improve its efficacy, TFV was combined with the nonnucleoside reverse-transcriptase inhibitor UC781 in a vaginal gel. Mixture design of experiments theory was used to define a range of gel compositions with varying rheological properties and to assess in vitro drug release and tissue retention. Experiments and computations led to the specification of three different gels referred to as a spreading gel (SG), an intermediate spreading gel (ISG), and a bolus gel (BG). These three gels, all containing 1.0% TFV and 0.1% micronized UC781, were evaluated for in vitro release, in vitro tissue retention and safety, and in vivo pharmacokinetics in the rabbit. There were some differences in in vitro release rates of UC781 (the higher the gel viscosity, the slower the release rate) across gels, while release of TFV was independent of gel type. In an organotypic human vaginal-ectocervical (VEC) tissue model, the amounts of tissue-associated TFV and UC781 were several orders of magnitude higher than their in vitro half-maximal inhibitory concentration. There were no differences in VEC tissue concentrations of TFV or UC781 between the SG, ISG, and BG. All three gels were well tolerated in the VEC model as assessed by tissue viability, electrical resistance, histology, and cytokine (interleukin-8 and interleukin-1 beta) release. The local vaginal tissue concentrations in rabbits following a single dose or seven once-daily doses were variable and generally lower than those found in the VEC tissue model. The approach described herein provides a rational schema to design and evaluate vaginal gels for use as microbicides.

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KW - Formulation

KW - Permeability

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Design of tenofovir-UC781 combination microbicide vaginal gels

Abstract

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Keywords

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