sepharose and Myocardial-Ischemia

Animal models are indispensable in order to investigate the mechanism of various diseases and to explore the counter measures for those disease states. Although there are several animal models of ischemic heart diseases, surgical interventions required to create myocardial ischemia sometimes give rise to a problem in the yield of model. This study describes a new technique for inducing myocardial ischemia in rats.. A 0.014-inch guidewire was introduced via the carotid artery and selectively advanced into the coronary arteries under fluoroscopy. Transmural myocardial ischemia was confirmed by ST-segment elevation and by the appearance of left ventricular wall motion abnormalities on the echocardiogram. Reversibility of the wire-induced myocardial ischemia was demonstrated by complete resolution of both ST-segment elevation and wall motion abnormalities after removing the wire.. Wire-induced myocardial ischemia was reproducible and is less invasive than conventional ischemic models in rats. This method is a powerful and useful tool for the investigation of ischemic heart disease in small animals.

Topics: Animals; Cardiac Catheterization; Coronary Disease; Electrocardiography; Embolism; Male; Microspheres; Models, Animal; Myocardial Ischemia; Rats; Rats, Wistar; Reproducibility of Results; Sepharose; Ultrasonography

The Ca(2+)-binding protein S100A1 displays a tissue-specific expression pattern with highest levels in myocardium and has been shown to interact with SR-proteins regulating the Ca(2+)-induced Ca(2+)-release. We, therefore, hypothesized that changes in S100A1 gene expression might correlate with the pathognomonic finding of altered SR Ca(2+)-transients in human end stage heart failure. To test this hypothesis, we established a specific and sensitive method to analyse S100A1 expression in cardiac tissues by employing hydrophobic interaction-chromatography and reversed-phase high performance liquid chromatography (RP-HPLC) coupled with Electron-Ionisation-Mass-Spectrometry (ESI-MS). Porcine myocardium showed a differential expression of S100A1 with relative protein concentrations of 62 +/- 8% in the right ventricle (RV), 57 +/- 9% in the right atrium (RA), and 25 +/- 15% in the left atrium (LA) as compared to the left ventricle (LV) (100 +/- 10%; P < 0.001). Northern blot analyses confirmed a likewise distribution of porcine S100A1 mRNA implying a regulation on the transcriptional level. Analyses of left ventricular specimen of patients with end stage heart failure (CHF, n = 6; CHD, n = 6) revealed significantly reduced S100A1 protein levels, while integration of S100A1 peaks after RP-HPLC yielded two groups of patients with < 76% (69 +/- 7%, n = 6) and < 35% (23 +/- 12%, n = 6) respectively as compared to controls (100 +/- 8%, n = 3). These data demonstrate for the first time that S100A1 is differentially expressed in myocardium and that in human cardiomyopathy a reduced expression of S100A1 may contribute to a compromised contractility.

Topics: Animals; Calcium-Binding Proteins; Calmodulin; Cardiomyopathies; Gene Expression Regulation; Heart Atria; Heart Ventricles; Humans; Molecular Sequence Data; Molecular Weight; Myocardial Ischemia; Myocardium; RNA, Messenger; S100 Proteins; Sepharose; Swine