Browsing by Subject "nitric oxide"
Now showing 1 - 4 of 4
- Results Per Page
- Sort Options
Item Novel Thiol Containing Hybrid Antioxidant-Nitric Oxide Donor Small Molecules for Treatment of Glaucoma(MDPI, 2021-04-08) Amankwa, Charles E.; Gondi, Sudershan R.; Dibas, Adnan Dibas; Weston, Courtney; Funk, Arlene; Nguyen, Tam; Nguyen, Kytai T.; Ellis, Dorette Z.; Acharya, SuchismitaOxidative stress induced death and dysregulation of trabecular meshwork (TM) cells contribute to the increased intraocular pressure (IOP) in primary open angle (POAG) glaucoma patients. POAG is one of the major causes of irreversible vision loss worldwide. Nitric oxide (NO), a small gas molecule, has demonstrated IOP lowering activity in glaucoma by increasing aqueous humor outflow and relaxing TM. Glaucomatous pathology is associated with decreased antioxidant enzyme levels in ocular tissues causing increased reactive oxygen species (ROS) production that reduce the bioavailability of NO. Here, we designed, synthesized, and conducted in vitro studies of novel second-generation sulfur containing hybrid NO donor-antioxidants SA-9 and its active metabolite SA-10 to scavenge broad-spectrum ROS as well as provide efficient protection from t-butyl hydrogen peroxide (TBHP) induced oxidative stress while maintaining NO bioavailability in TM cells. To allow a better drug delivery, a slow release nanosuspension SA-9 nanoparticles (SA-9 NPs) was prepared, characterized, and tested in dexamethasone induced ocular hypertensive (OHT) mice model for IOP lowering activity. A single topical eye drop of SA-9 NPs significantly lowered IOP (61%) at 3 h post-dose, with the effect lasting up to 72 h. This class of molecule has high potential to be useful for treatment of glaucoma.Item Opioid and Nitric Oxide Interaction in the Control of Heart Rate(2002-12-01) Farias III, Martin; James Caffrey; Fred H. Downey; Patricia GwirtzFarias III, Martin, Opioid and Nitric Oxide Interaction in the Control of Heart Rate. Doctor of Philosophy (Biomedical Sciences), December 2002, 130 pp, 2 tables, 30 figures. Understanding of the role endogenous opioids play as modulators of parasympathetic function has increased. The endogenous opioid, methionine-enkephalin arginine phenylalanine (MEAP) attenuates vagal control of heart rate when delivered by microdialysis directly in the canine sinoatrial node. This effect was mimicked by the δ-2 agonist, deltorphin-II indicating involvement by a δ-opioid receptor. The nodal delivery of the δ-antagonist naltrindole abolished the effect of deltorphin-II, further supporting the delta character of the receptor. Although the findings suggested that the opioid receptor mediating vagolysis was delta in character, the exact subtype of δ-receptor remained in question. Selective agonist and antagonists for δ-1 and δ-2 opioid receptors were employed to determine which subtype of δ-receptor mediated MEAP vagolysis. In these experiments, vagolysis produced by the nodal delivery of MEAP was unaltered by the highly selective δ-1 antagonist BNTX but abolished by the δ-2 antagonist, naltriben. Nodal delivery of deltorphin-II attenuated vagal bradycardia similar to MEAP while δ-1 agonists, DPDPE and TAN-67 failed to interrupt vagal bradycardia. TAN-67 actually improved vagal transmission and this effect was reversed by BNTX. These data indicate that δ-2 opioid receptors in the sinoatrial node and vagolytic and support the presence of vagotonic δ-1-opioid receptors in the same location. Nitric Oxide/Opioid Interaction. The hypothesis that intranodal nitric oxide synthase (NOS) modulates vagal transmission and that MEAP attenuates vagal bradycardia via the interruption of the NOS-cGMP pathway was tested. The general (L-NAME) and neuronal (7-nitroindazole) NOS inhibitors each attenuated vagal bradycardia and both effects were reversed by adding excess of the NOS substrate, L-arginine. These findings suggested that nNOS was a necessary component of vagal bradycardia in the canine sinoatrial node. Various probes of the NOS-cGMP pathway (L-arginine, SNAP, cGMP, and IBMX) were employed to determine if MEAP interrupted this pathway to produce vagolysis. The delivery of MEAP into the sinoatrial node for sixty minutes exerted a consistent vagolytic effect during vagal simulations. When MEAP was combined with a NOS pathway components, the vagolytic effect was reversed after 15-45 minutes of treatment. These findings suggested that MEAP exerted its effect by interacting with the NOW-cGMP system. The site of convergence maybe cAMP since the phosphodiesterase inhibitor, IBMX (by allowing the accumulation of cAMP) reversed the vagolytic effect of MEAP. To rule out a postjunctional effect, MEAP and the NOS inhibitors were combined with the direct acting muscarinic agonist, methacholine. The bradycardia produced by methacholine was unaltered by MEAP or nNOS inhibitors. This suggested that the effect of NOS inhibitors and MEAP were prejunctional. In summary, the cumulative findings suggest that MEAP, by activating δ-2-opioid receptors, attenuated vagal bradycardia prejunctionally, through modulating the cAMP component of the NOS-cGMP pathway in the canine sinoatrial node.Item The Role of Mechanosensory TRPV4 Channels and Nitric Oxide Signaling in Intraocular Pressure Homeostasis and its Impairment in Glaucoma(2020-08) Patel, Pinkal D.; Zode, Gulab S.; Clark, Abbot F.; Pang, Iok-Hou; Krishnamoorthy, Raghu R.; Rickards, Caroline A.Several population-based studies have identified elevated intraocular pressure (IOP) as a major causative risk factor associated with primary open angle glaucoma (POAG), the most common form of glaucoma that affects millions of people worldwide. Moreover, multi-ethnic clinical trials in several different countries over the last few decades have provided overwhelming evidence showing correlation between lowering of IOP and reduced progression of vision loss. As a result, IOP reducing therapeutic interventions are the gold standard in glaucoma therapy. Although the role of IOP is evident in pathology of POAG, very few studies have delved into the complex physiological mechanisms that regulate IOP homeostasis. From continuous telemetry recordings in nonhuman primates, we now know that IOP is a dynamic variable that fluctuates throughout the day. However, despite the fluctuations, the mean IOP is still maintained within a narrow physiological range. The level of IOP elevation at any given time depends on the resistance to aqueous humor outflow encountered in the conventional outflow pathway consisting of the trabecular meshwork (TM), Schlemm's canal (SC), and the distal episcleral vessels. Recent studies have suggested that the cells of the outflow pathway have intrinsic ability to detect biomechanical stimuli in their environment (like shear stress) and convert these stimuli into biochemical signals to elicit specific cellular responses. Although mechanotransduction at the TM is deemed critical for IOP homeostasis, we are yet to conclusively identify the exact signaling pathway involved. In this study, we identify the role of transient receptor potential vanilloid IV channels (TRPV4) in sensing mechanical stress on the TM. We show that shear stress activates TRPV4 channels in human primary TM cells, which leads to endothelial nitric oxide synthase (eNOS)-dependent nitric oxide (NO) production. NO, itself has been identified as a key regulator of IOP. Exogenous NO delivery to the eye has been shown to reduce IOP in humans. However, the underlying mechanism that regulates endogenous levels of NO still remains unknown. To this end, we demonstrate that TRPV4 channels regulate eNOS-dependent NO production in primary human TM cells and ex vivo cultured human TM tissues. We show that TRPV4 activation by mechanical shear leads to activation of eNOS signaling and NO production. Furthermore, pharmacological activation of TRPV4 channels via a selective agonist GSK1016790A (GSK101) leads to eNOS phosphorylation and NO production. In animal models, we demonstrate a role of TRPV4 channels in regulating physiological IOP. Treatment of C57BL/6J mouse eyes with TRPV4 agonist GSK101 leads to reduction in baseline night-time IOP and nominal improvement in outflow facility. We also show that conditional knockout of TRPV4 channels in Ad5-Cre injected TRPV4f/f mice leads to increase in IOP. We use the NOS3-/- (eNOS) to further show that TRPV4 mediated lowering of IOP is eNOS dependent. Dysregulation of the TM cells leads to increase in resistance and IOP elevation. Furthermore, glaucomatous human TM cells show impaired activity of TRPV4 channels and disrupted TRPV4-eNOS signaling. Flow/shear stress activation of TRPV4 channels and subsequent NO release were also impaired in glaucomatous primary human TM cells. Together, our studies demonstrate a central role for TRPV4-eNOS signaling in lowering the resting IOP. Our results also provide evidence that impaired TRPV4 channel activity in TM cells contributes to TM dysfunction and elevated IOP in glaucoma.Item Therapeutic Potential of Antioxidants and Hybrid TEMPOL Derivatives in Ocular Neurodegenerative Diseases: A Glimpse into the Future(MDPI, 2023-11-25) Amankwa, Charles E.; Kodati, Bindu; Donkor, Nina; Acharya, SuchismitaReactive oxygen species play a significant role in the pathogenesis of various ocular neurodegenerative diseases especially glaucoma, age-related macular degeneration (AMD), and ocular ischemic stroke. Increased oxidative stress and the accumulation of ROS have been implicated in the progression of these diseases. As a result, there has been growing interest in exploring potential therapeutic and prophylactic strategies involving exogenous antioxidants. In recent years, there have been significant advancements in the development of synthetic therapeutic antioxidants for targeting reactive oxygen species (ROS) in neurodegenerative diseases. One area of focus has been the development of hybrid TEMPOL derivatives. In the context of ocular diseases, the application of next-generation hybrid TEMPOL antioxidants may offer new avenues for neuroprotection. By targeting ROS and reducing oxidative stress in the retina and optic nerve, these compounds have the potential to preserve retinal ganglion cells and trabecular meshwork and protect against optic nerve damage, mitigating irreversible blindness associated with these diseases. This review seeks to highlight the potential impact of hybrid TEMPOL antioxidants and their derivatives on ocular neurodegenerative disorders.