Browsing by Subject "Griseofulvin"

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    Long-Acting Microparticle Formulation of Griseofulvin for Ocular Neovascularization Therapy
    (Wiley, 2024) Chobisa, Dhawal; Muniyandi, Anbukkarasi; Sishtla, Kamakshi; Corson, Timothy W.; Yeo, Yoon; Pharmacology and Toxicology, School of Medicine
    Neovascular age-related macular degeneration (nAMD) is a leading cause of vision loss in older adults. nAMD is treated with biologics targeting vascular endothelial growth factor; however, many patients do not respond to the current therapy. Here, a small molecule drug, griseofulvin (GRF), is used due to its inhibitory effect on ferrochelatase, an enzyme important for choroidal neovascularization (CNV). For local and sustained delivery to the eyes, GRF is encapsulated in microparticles based on poly(lactide-co-glycolide) (PLGA), a biodegradable polymer with a track record in long-acting formulations. The GRF-loaded PLGA microparticles (GRF MPs) are designed for intravitreal application, considering constraints in size, drug loading content, and drug release kinetics. Magnesium hydroxide is co-encapsulated to enable sustained GRF release over >30 days in phosphate-buffered saline with Tween 80. Incubated in cell culture medium over 30 days, the GRF MPs and the released drug show antiangiogenic effects in retinal endothelial cells. A single intravitreal injection of MPs containing 0.18 µg GRF releases the drug over 6 weeks in vivo to inhibit the progression of laser-induced CNV in mice with no abnormality in the fundus and retina. Intravitreally administered GRF MPs prove effective in preventing CNV, providing proof-of-concept toward a novel, cost-effective nAMD therapy.
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    The molecular mechanism of action of the antiangiogenic natural product, cremastranone
    (2016-07) Basavarajappa, Halesha Dhurvigere; Corson, Timothy W.; Grant, Maria B.; Hurley, Thomas D.; Quilliam, Lawrence A.; Chan, Rebecca
    Prevention of pathological angiogenesis is a key strategy for treatment of common blinding ocular diseases such as retinopathy of prematurity, proliferative diabetic retinopathy, and wet age-related macular degeneration. The current treatment strategies are associated with partial vision loss and are ineffective in a significant patient population. Hence novel drugs as well as new ways to target ocular angiogenesis are needed for treating these diseases. I pursued a natural antiangiogenic compound, cremastranone, to develop novel drug leads and to find new targets. The objective of my doctoral thesis project was to elucidate cremastranone’s molecular mechanism of action and optimize its structureactivity relationship (SAR). In order to achieve this goal, with the help of chemistry collaborators cremastranone was synthesized for the first time. I showed that cremastranone has 50-fold more potency against endothelial cells as compared to nonendothelial cells, and also tested a novel active isomer, SH-11052. By SAR studies I identified a potent molecule, SH-11037, that has 10-fold more selectivity against retinal endothelial cells as compared to macrovascular endothelial cells. I then elucidated cremastranone’s molecular mechanism using a chemical proteomic approach. I identified ferrochelatase (FECH) as a specific interacting protein partner of cremastranone using photoaffinity chromatography. Hence, I hypothesized that cremastranone exerts its antiangiogenic activities through modulation of the functions of FECH. Cremastranone inhibited the enzymatic activity FECH in endothelial cells. Therefore, I investigated the role of FECH in ocular angiogenesis. Partial loss of FECH, using a siRNA-based knock down approach, decreased retinal angiogenesis both in vitro and in vivo in mouse models. Knock down of FECH decreased the expression levels of key proangiogenic proteins HIF-1α, eNOS, and VEGFR2. This work suggests that ferrochelatase plays an important, previously undocumented role in angiogenesis and that targeting of this enzyme by cremastranone might be exploited to inhibit pathological angiogenesis in ocular diseases.