For years, scientists have been trying to develop a topical vaginal microbicide for preventing transmission of HIV, the virus that causes AIDS. A safe and effective microbicide would help protect women in settings where male condoms are not used — a common situation in many cultures. The need for an HIV microbicide is especially urgent in Africa, where AIDS is the leading cause of death and where women account for six out of ten of those living with HIV.
Several microbicide gels have been assessed in clinical trials after passing laboratory and animal safety tests. But with just one exception, all the microbicides were found to be ineffective against HIV; and two of the gels — nonoxynol-9 and cellulose sulfate — actually increased the risk of HIV infection in women.
“Our goal was to develop assays that are predictive of safety before proceeding to clinical trials that typically cost millions of dollars, involve thousands of women, and take many years,” says study leader Betsy C. Herold, M.D., professor of pediatrics, of microbiology & immunology, and of obstetrics & gynecology and women’s health at Einstein.
In evaluating a microbicide’s safety, researchers look primarily for signs that the chemical inflames cells of the vaginal lining, or epithelium. That could cause more harm than good: When the epithelium becomes inflamed, T cells flock to the damaged area — which might actually encourage HIV infection, since T cells are the main targets of HIV.
Dr. Herold theorized that another mechanism may also compromise a microbicide’s safety. The cells of the vaginal epithelium normally are tightly packed together, forming an impermeable barrier to HIV. If a microbicide disrupts the barrier’s structural integrity, HIV would be able to slip through the gaps and infect circulating T cells.
To test this theory, Pedro Mesquita, a postdoctoral fellow in Dr. Herold’s lab, developed a model that mimicked the genital tract environment. It was composed of two chambers separated by a barrier of cultured human cells that form tight junctions. After treating the epithelial cells with different microbicides, the researchers tested the barrier’s permeability to HIV by placing HIV in the upper chamber, T cells in the lower chamber, and then monitoring the infection of the T cells over time.
When the epithelial barrier was treated with placebo, HIV was unable to pass through to the lower chamber, leaving the T cells uninfected. “But when we applied nonoxynol-9, the virus went right through the barrier and infected the T cells,” says Dr. Herold. This result was no surprise, since nonoxynol-9 is a detergent, a class of chemicals known to be disruptive to cells.
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Tight junctions between genital tract epithelial cells provide an anatomic barrier and prevent HIV from reaching submucosal targets. Microbicides that disrupt the barrier increase the risk for HIV infection. This assay accurately predicts the safety of microbicides.
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