GGrantIndex
← Search

Targeting GI Epithelial Integrity to Improve Arterial Inflammation in HIV

$822,455R01FY2017HLNIH

Massachusetts General Hospital, Boston MA

Investigators

Linked publications & trials

Abstract

DESCRIPTION (provided by applicant): Cardiovascular disease is highly prevalent among HIV-infected patients, however the distinct mechanisms of atherosclerotic disease development in HIV-infected patients are yet unknown. Chronic HIV infection is associated with loss of gastrointestinal mucosal epithelial integrity and loss of CD4+ T-cells in the intestinal lamina propria, leading to increased microbial translocation across the gastrointestinal tract. The key hypothesis of this grant application is that microbial translocation causes activation of the innat immune system which can induce inflammatory damage in the vasculature, leading to cardiovascular disease. Aim 1 seeks to study the relationships of intestinal epithelial integrity and microbial translocation to monocyte and macrophage activation and to cardiovascular risk measured by arterial inflammation via FDG-PET (to assess arterial macrophage activity) and coronary cardiac computed tomography angiography (to assess coronary atherosclerotic plaque quantitatively and qualitatively). Transcriptomic analyses in monocytes are proposed to identify novel biological pathways of atherogenesis in HIV-infected patients. To further test the central hypothesis, an interventional study is proposed in Aim 2 to improve the gut epithelial integrity and reduce microbial translocation in order to test effects of such an intervention on cardiovascular inflammation and monocyte function. The intervention of teduglutide, a glucagon-like peptide 2 analog with known trophic and anti-inflammatory effects on the intestinal epithelium, will be investigated in a randomized, double-blind placebo-controlled proof of concept trial in HIV-infected individuals. The hypothesis to be tested is that improvement of gut epithelial integrity will decrease intestinal permeability to microbial products, thus decreasing te stimulus for monocyte and macrophage activation, and therefore decrease macrophage activity in the arterial wall measured by FDG-PET and reduce overall cardiovascular risk.

View original record on NIH RePORTER →