Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0851184 (thinning)
 11,252 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The natural history of the disease of the dilated strain Bio TO-2 of cardiomyopathic hamsters (CMH) is not totally characterized. We investigated its hemodynamic and histomorphometric characteristics at 140, 180, 220, 260, and 300 days of age. Forty CMH and 40 controls were investigated (8 at each stage). Mean arterial pressure (MAP, carotid artery catheter) and cardiac output and femoral blood flow (CO, FBF, transit time method) were measured in anesthetized animals. Systemic (SVR) and femoral (FVR) vascular resistances were calculated. Atria, left and right ventricles (LV, RV), lungs, and liver were weighed. LV cavity area, LV and RV wall thicknesses and collagen densities were determined (computer-assisted image analyzer). Pulmonary and hepatic congestion were assessed (arbitrary scales). Compared with controls, MAP, CO and FBF were significantly lower in CMH throughout the study (on average: -22%, -34%, -33%, respectively), FVR was significantly increased (+15%), but SVR was not significantly modified. Concerning histomorphometric characteristics, differences between groups significantly increased with age for most variables: at 300 days, atria (+292%), RV (+13%), lungs (+44%), and liver (+23%) weights, LV cavity area (+130%), LV (+364%) and RV (+181%) collagen densities were significantly increased in CMH vs controls, whereas LV (-40%) and RV (-23%) wall thicknesses were significantly decreased. At 260 and 300 days, CMH showed significant pulmonary congestion without hepatic alteration. Bio TO-2 CMH progressively develop an alteration of cardiac function leading to decreased MAP and musculo-cutaneous blood flow associated with cardiac remodeling including atria hypertrophy and LV dilation, wall thinning and a rise in collagen density.
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PMID:Hemodynamic and histomorphometric characteristics of dilated cardiomyopathy of Syrian hamsters (Bio TO-2 strain). 1133 10

Because echocardiographic studies on infants with chronic lung disease (CLD) suggest that pulmonary hypertension (PH) may contribute to its severity, we studied acinar arterial walls in the following surfactant-era infants: controls (n=38): 22-41 weeks of gestational age (GA), exposed briefly to oxygen and positive pressure ventilation, died within 48 hr of birth; prolonged rupture of fetal membranes (PROM) and persistent pulmonary hypertension (PPHN) (n=17); and SCORE (integrated area under curve of average daily FiO2 x average daily MAP) groups (<20, 20-69, and 70-500; mild, moderate, and severe clinical lung disease, respectively, n=35): 23-30 weeks GA, lived 7-79 days. Lungs were stained for elastic tissue and smooth muscle actin. Vessels were assessed for percent of vessel circumference with smooth muscle, extent of elastic laminae in the walls, and percent arterial wall thickness (%AWT) at three levels: terminal to respiratory bronchiole transition (TRB), alveolar duct, and saccule. At the alveolar ductal and saccular levels, percent arterial wall thickness (%AWT) in mild CLD (SCORE < 20) was less than controls (P < 0.05) and those with more severe CLD (SCORE 70-500), indicating that normal postnatal arterial wall thinning may be delayed, or there is remodeling associated with increased %AWT. Severe CLD infants also had a significantly higher percent of circumferential actin than those with milder disease (SCORE < or = 69) and controls. In moderate and severe CLD, there was an increase in extent of the elastic laminae compared to controls and mild CLD. These changes were also significantly greater in PROM and PPHN infants compared to even severe CLD. We conclude that PH is a real possibility in severe CLD infants after discharge at 36 weeks. Grading the severity of CLD at discharge, and echocardiographic studies, may guide subsequent oxygen therapy.
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PMID:Acinar arterial changes with chronic lung disease of prematurity in the surfactant era. 1461 39

Intrauterine growth restriction in animal models reduces heart size and cardiomyocyte number at birth. Such incomplete cardiomyocyte endowment is believed to increase susceptibility toward cardiovascular disease in adulthood, a phenomenon referred to as developmental programming. We have previously described a mouse model of impaired myocardial development leading to a 25% reduction of cardiomyocyte number in neonates. This study investigated the response of these hypoplastic hearts to pressure overload in adulthood, applied by abdominal aortic constriction (AAC). Echocardiography revealed a similar hypertrophic response in hypoplastic hearts compared with controls over the first 2 weeks. Subsequently, control mice develop mild left ventricular (LV) dilation, wall thinning and contractile dysfunction 4 weeks after AAC, whereas hypoplastic hearts fully maintain LV dimensions, wall thickness and contractility. At the cellular level, controls exhibit increased cardiomyocyte cross-sectional area after 4 weeks pressure overload compared with sham operated animals, but this hypertrophic response is markedly attenuated in hypoplastic hearts. AAC mediated induction of fibrosis, apoptosis or cell cycle activity was not different between groups. Expression of fetal genes, indicative of pathological conditions, was similar in hypoplastic and control hearts after AAC. Among various signaling pathways involved in cardiac hypertrophy, pressure overload induces p38 MAP-kinase activity in hypoplastic hearts but not controls compared with the respective sham operated animals. In summary, based on the mouse model used in this study, our data indicates that adult hearts after neonatal cardiac hypoplasia show an altered growth response to pressure overload, eventually resulting in better functional outcome compared with controls.
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PMID:Preserved heart function after left ventricular pressure overload in adult mice subjected to neonatal cardiac hypoplasia. 2873 22