Intimal hyperplasia in balloon dilated coronary arteries is reduced by local delivery of the NO donor, SIN-1 via a cGMP-dependent pathway

3-morpholinosydnonimine (SIN-1)-induced oxidative stress leads to necrosis in hypertrophic chondrocytes in vitro

Chondrocyte is targeted for disruption in Osteoarthritis (OA) and Kashin-Beck Disease (KBD), and chondrocyte death in cartilage may contribute to the progression of OA and KBD. Oxidative stress leads to increased risk for OA. Previous work in our laboratory implicates oxidative stress as a potential mediator in children with KBD. While these studies suggest a role for oxidative stress in the modulation of OA and KBD, the direct effects of reactive oxygen species/reactive nitrogen species (ROS/RNS) on the stability of this domain remain unclear. Here, we demonstrate that oxidative stress, as induced through treatment with 3-morpholinosydnonimine (SIN-1), a spontaneous ROS/RNS generator, decreased the cell viability in hypertrophic chondrocytes in a dose- and time- dependent manner. SIN-1 induced necrosis in hypertrophic chondrocytes, whereas triggered apoptosis in non-hypertrophic cells of non-differentiated ATDC5 cells and C28/I2 cells. Ultrastructural analysis of hypertrophic chondrocyte treated with SIN-1 revealed morphological changes, such as plasma membrane breakdown, generalized swelling of the cytoplasm and organelles, even to disappearance. Moreover, SIN-1 induced chondronecrosis in the deep zone of engineered cartilage tissue, such as cell-free vacancy and "red ghost" cells. Overall, we demonstrate for the first time that oxidative stress, as induced through exogenous ROS/RNS, leads to necrosis in hypertrophic chondrocytes. Oxidative stress-mediated necrotic cell death contributes to chondronecrosis in the deep zone of cartilage in both OA and KBD.

Engineering Cardiovascular Implant Surfaces to Create a Vascular Endothelial Growth Microenvironment

Cardiovascular disease (CVD) is generally accepted as the leading cause of morbidity and mortality worldwide, and an increasing number of patients suffer from atherosclerosis and thrombosis annually. To treat these disorders and prolong the sufferers' life, several cardiovascular implants have been developed and applied clinically. Nevertheless, thrombosis and hyperplasia at the site of cardiovascular implants are recognized as long-term problems in the practice of interventional cardiology. Here, we start this review from the clinical requirement of the implants, such as anti-hyperplasia, anti-thrombosis, and pro-endothelialization, wherein particularly focus on the natural factors which influence functional endothelialization in situ, including the healthy smooth muscle cells (SMCs) environment, blood flow shear stress (BFSS), and the extracellular matrix (ECM) microenvironment. Then, the currently available strategies on surface modification of cardiovascular biomaterials to create vascular endothelial growth microenvironment are introduced as the main topic, e.g., BFSS effect simulation by surface micro-patterning, ECM rational construction and SMCs phenotype maintain. Finally, the prospects for extending use of the in situ construction of endothelial cells growth microenvironment are discussed and summarized in designing the next generation of vascular implants.

New approach to molsidomine active metabolites coming from the results of 2 models of experimental cardiology

Molsidomine is a well-known vasodilatating, antianginal drug. Despite earlier studies with its metabolites (3-morpholino-syndnonimine (SIN-1) and N-nitroso-N-morpholino-amino-acetonitrile (SIN-1A)), which indicated a potential favorable cardioprotective activity, a lot of controversy remains. The aim of our research was to compare molsidomine, SIN-1, SIN-1A, and lidocaine influence on arrhythmias and hemodynamic parameters in 2 experimental models in rats. In the Langendorff heart study, SIN-1A markedly elevated left ventricular systolic pressure, maximum rise and fall of the first pressure derivative, coronary flow, and myocardial oxygen consumption. In addition, SIN-1A more so than SIN-1 significantly lowered creatine kinase release. The antiarrhythmic action of SIN-1 was observed, while lidocaine significantly diminished ventricular arrhythmias duration in comparison with the control. In the ischemia-reperfusion-induced arrhythmias model, hypotensive action of molsidomine was observed as well as the reduction in pressure rate product. Molsidomine also prolonged ventricular tachycardia duration. On the other hand, no significant effects on hemodynamic parameters as well as on ventricular arrhythmias were found in any of the SIN-1 and SIN-1A groups. In conclusion, our research suggests a possible direct, cardioprotective action of SIN-1A. It seems worthwhile to further investigate molsidomine derivatives, especially SIN-1A, because of its potential use in invasive cardiology procedures such as percutaneous transluminal coronary angioplasty.

Nitric oxide delivery via a permeable balloon catheter inhibits neointimal growth after arterial injury

BACKGROUND

Neointimal hyperplasia limits the longevity of vascular interventions. Nitric oxide (NO) is well known to inhibit neointimal hyperplasia. However, delivery of NO to the vasculature is challenging. Our study aims to evaluate the efficacy of delivering NO to the site of injury using a permeable balloon catheter. Our hypothesis is that ultra-short duration NO delivery using a permeable balloon catheter will inhibit neointimal hyperplasia.

MATERIALS AND METHODS

Ten-week-old male Sprague-Dawley rats underwent carotid artery balloon injury. Groups included: (1) control, (2) injury, (3) injury + periadventitial NO, and (4) injury + endoluminal NO via permeable balloon catheter. The catheter was inflated to 5 atm pressure for 5 min. Arteries were harvested 2 wk following injury. Morphometric assessment for neointimal hyperplasia and immunohistochemical staining for inflammatory markers were performed.

RESULTS

Injury increased neointimal hyperplasia compared with control (intima/media area [I/M] ratio 1.07 versus 0.11, respectively, P < 0.001). Periadventitial delivery of NO reduced the I/M area ratio compared with injury alone (55% decrease, P < 0.001). Endoluminal delivery of NO also reduced the I/M area ratio compared with injury alone (65% decrease; P < 0.001). Both endoluminal and periadventitial NO affected the I/M ratio by reducing the intimal area (64% and 46%, respectively, P < 0.001) whereas neither affected the medial area. Periadventitial NO delivery increased lumen area (P < 0.05), whereas endoluminal NO delivery increased circumference (P < 0.05). Periadventitial NO delivery inhibited macrophage intimal infiltration compared with injury alone (P < 0.05).

CONCLUSIONS

These data demonstrate that short-duration endoluminal NO delivery via permeable balloon catheters inhibits neointimal hyperplasia following arterial interventions. Endoluminal delivery of NO could become a focus for future clinical interventions.

Nitric oxide and nitrite-based therapeutic opportunities in intimal hyperplasia

Vascular intimal hyperplasia (IH) limits the long term efficacy of current surgical and percutaneous therapies for atherosclerotic disease. There are extensive changes in gene expression and cell signaling in response to vascular therapies, including changes in nitric oxide (NO) signaling. NO is well recognized for its vasoregulatory properties and has been investigated as a therapeutic treatment for its vasoprotective abilities. The circulating molecules nitrite (NO(2)(-)) and nitrate (NO(3)(-)), once thought to be stable products of NO metabolism, are now recognized as important circulating reservoirs of NO and represent a complementary source of NO in contrast to the classic L-arginine-NO-synthase pathway. Here we review the background of IH, its relationship with the NO and nitrite/nitrate pathways, and current and future therapeutic opportunities for these molecules.