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Repurposing Pyrvinium as an Inhalation Therapy for Idiopathic Pulmonary Fibrosis

$309,418R41FY2025HLNIH

Oleolive, Inc., Shreveport LA

Investigators

Abstract

SUMMARY Idiopathic pulmonary fibrosis (IPF) is a fibrosing interstitial lung disease that is characterized by progressive decline in lung function due to inflammatory and fibrotic changes of the lung parenchyma. The average life expectancy for patients is only 3-5 years, resulting in the deaths of 40,000 patients each year in the US. There are only two FDA-approved drugs for IPF that slow disease progression but do not prevent or reverse symptoms or pathology, and they exhibit significant side effects in many patients. Promising drugs are in development, but recent clinical trial failures emphasize the need for additional therapeutic approaches. IPF begins following an insult to the tissue microenvironment, resulting in a loss of alveolar cells, growth of activated fibroblasts (myofibroblasts), and increased deposition of extracellular matrix proteins, like collagen, leading to scarring, increased tissue stiffness, and the inability to breathe followed by death. Many cell signaling pathways contribute to this pathology, including TGFβ signaling. A high content imaging screen was used to discover that the FDA- approved pinworm drug pyrvinium (pyr) blocks TGFβ-induced fibrosis. Subsequent studies showed pyr activated casein kinase 1α and downregulated the YAP/TAZ signaling pathway. Pyr appeared efficacious in a variety of in vitro assays and in vivo studies (intraperitoneal route), but bioavailability problems presented a challenge for oral administration. Inhalation dosing allows for direct drug delivery to the site of action and may reduce the possibility of off-target organ toxicity. In preliminary acute toxicity studies, pyr was well-tolerated when administered as a nebulized aqueous solution to mice, but efficacy was not tested. Therefore, the following aims are proposed to further develop pyr as an experimental IPF therapeutic designed for inhaled administration. In Aim 1, pyr will be administered by oropharyngeal aspiration beginning after administration of bleomycin, a treatment resulting in progressive fibrosis over 3 months. A second animal model will involve administration to lungs of an adenovirus expressing TGFβ to induce fibrosis. Lungs will be analyzed by histopathological and biochemical approaches to measure extracellular matrix remodeling, fibrosis, cell proliferation and measures of toxicity. This study will determine if pyr is safe and effective in two relevant mouse models when administered via inhalation. Aim 2 will test the ability of pyr to repress fibrosis in ex vivo human precision-cut lung slice tissue from healthy and IPF patient donors. Assays will include a hydroxyproline assay for collagen, immunoblotting, and qRT-PCR analysis to measure activity of fibrosis-associated signaling pathways, automated imaging to quantify alveolar and fibroblast cell density, and histological staining to score changes in cell morphology and tissue architecture. This study will reveal if pyr can inhibit and reverse fibrosis in a human ex vivo model, adding relevance to outcomes of the mouse studies, and will be used to test the proposed mechanisms of action for pyr. These data will also inform the design of IND-enabling safety and pharmacology studies in preparation for a Phase 1 clinical trial.

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