The next-generation prevention tool-microbicides (vaginally or rectally delivered topical products) - hold great promise as new HIV and STD prevention methods to be controlled by women. The microbicide research community has identified knowledge gaps in microbicide development which include a lack of knowledge in delivery vehicle design and a lack of efficacy predictors for decisions on which products to advance to Phase II/III trials. Our long-term goal is to identify structure-property-function relationships of topical epithelial drug delivery systems and to apply that knowledge to designing therapeutic/prophylactic agents and their delivery vehicles. The objective of this project is to demonstrate a method to design new microbicide delivery vehicles, specific to selected female populations, with simultaneously-optimized physicochemical properties, biocompatibility, and innate microbicidal activity. The overall hypothesis of this project is that biophysical measurements of in vivo tissue mechanics, vehicle properties, and vehicle performance can be used with mathematical and experimental tools to rationally design and optimize the efficacy of vaginally-delivered microbicides. The rationale for the proposed research is that, once the vaginal tissue properties and vehicle structure-property-function relationships are characterized and modeled, the delivery vehicle structure can be adjusted rationally to optimize microbicide efficacy, saving time and money. The overall objectives of the R21 Phase are to establish feasibility of a new in vivo instrument and create models (experimental and computational) of structure-property-function relationships. The 3 specific aims during the R21 phase are: 1. Characterize a new instrument and measure squeezing forces and elastic modulus of human vaginal tissue in vivo. 2. Determine the property-function relationship for polymeric delivery vehicles and identify target values of critical vehicle physicochemical properties. 3. Quantify relationships between molecular structure and measured physicochemical and microbicidal properties of polymeric delivery vehicles. The overall objectives of the R33 Phase are to show utility of the in vivo instrument and computational structure- property-function models of the R21 phase and expand the features of the instrument and models. Ultimately, the goal is to determine the efficacy of novel polymeric delivery vehicles to prevent Chlamydia trachomatis and Neisseria gonorrhea infections, while simultaneously exhibiting target physicochemical properties. Our contribution here is to demonstrate a new method to optimize polymeric delivery vehicles for a set of target properties, against two bacterial pathogens, and for specific groups of women. This contribution is significant because it will show that the methodologies of computational molecular design and biomechanical analysis are able to effectively develop novel polymer formulations for a delivery vehicle in an efficient and expedient manner.

Public Health Relevance

Relevance to Public Health The results of the proposed research will benefit public health because the outcomes are a necessary step to making tools to efficiently design and optimize vaginal delivery vehicles. New screening tools will reduce the time and cost of clinical trials, and help to bring urgently needed microbicides to women.

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Exploratory/Developmental Grants (R21)
Project #
5R21AI082697-02
Application #
7935367
Study Section
Special Emphasis Panel (ZAI1-RB-A (J1))
Program Officer
Turpin, Jim A
Project Start
2009-09-19
Project End
2011-08-31
Budget Start
2010-09-01
Budget End
2011-08-31
Support Year
2
Fiscal Year
2010
Total Cost
$216,693
Indirect Cost
Name
University of Kansas Lawrence
Department
Engineering (All Types)
Type
Schools of Engineering
DUNS #
076248616
City
Lawrence
State
KS
Country
United States
Zip Code
66045
Anwar, Md Rajib; Camarda, Kyle V; Kieweg, Sarah L (2015) Mathematical model of microbicidal flow dynamics and optimization of rheological properties for intra-vaginal drug delivery: Role of tissue mechanics and fluid rheology. J Biomech 48:1625-30
Hu, Bin; Kieweg, Sarah L (2015) Contact Line Instability of Gravity-Driven Flow of Power-Law Fluids. J Nonnewton Fluid Mech 225:62-69
Koppolu, Veerendra; Osaka, Ichie; Skredenske, Jeff M et al. (2013) Small-molecule inhibitor of the Shigella flexneri master virulence regulator VirF. Infect Immun 81:4220-31
Kheyfets, Vitaly O; Kieweg, Sarah L (2013) Gravity-Driven Thin Film Flow of an Ellis Fluid. J Nonnewton Fluid Mech 202:88-98
Osaka, Ichie; Hefty, P Scott (2013) Simple resazurin-based microplate assay for measuring Chlamydia infections. Antimicrob Agents Chemother 57:2838-40
Osaka, Ichie; Hills, Jeffrey M; Kieweg, Sarah L et al. (2012) An automated image-based method for rapid analysis of Chlamydia infection as a tool for screening antichlamydial agents. Antimicrob Agents Chemother 56:4184-8
Hu, Bin; Kieweg, Sarah L (2012) The Effect of Surface Tension on the Gravity-driven Thin Film Flow of Newtonian and Power-law Fluids. Comput Fluids 64:83-90