The Minnesota Regional Peripheral Arterial Disease Screening Program: toward a definition of community standards of care.

The Minnesota Regional Peripheral Arterial Disease Screening Program was designed to define the efficacy of community PAD detection efforts, to assess the disease-specific and health-related morbidity, to assess PAD awareness rates, and to determine the magnitude of atherosclerosis disease risk factors and the intensity of their management. The target population was recruited via mass media efforts directed at individuals over 50 years of age and those with leg pain with ambulation. Screening sessions included assessments of the ankle-brachial index, blood pressure, fasting lipid profile, and use of validated tools to detect symptomatic claudication (by the Modified WHO-Edinburgh Claudication Questionnaire), walking impairment (Walking Impairment Questionnaire - WIQ), quality of life (MOS SF-36), PAD awareness, and the intensity of PAD medical therapeutic interventions. PAD was defined as any ankle-brachial index < or =0.85 or a history of lower extremity revascularization. The program evaluated 347 individuals and identified 92 subjects with PAD and 255 subjects without PAD, yielding a detection rate of 26.5%. Individuals with PAD were older, tended to have higher blood pressures, and had a significant walking impairment and an impaired health-related quality of life compared with the non-PAD subjects. Current rates of tobacco use were low. Lipid-lowering, estrogen replacement, anti-platelet, and antihypertensive medications and exercise therapies were underutilized in the PAD cohort. Peripheral arterial disease awareness was low in these community-identified patients. This Program demonstrated that individuals with PAD can be efficiently identified within the community, but that current standards of medical care are low. These data can assist in the future development of PAD awareness, education, and treatment programs.

Active renin and angiotensinogen in cardiac interstitial fluid after myocardial infarction.

The renin-angiotensin system promotes cardiac hypertrophy after myocardial infarction. The purpose of this study was to measure renin and angiotensinogen in plasma and myocardium 10 days after myocardial infarction. Infarction involving 45 +/- 4% of left ventricular circumference with accompanying hypertrophy was induced in rats (n = 14). Plasma and myocardial renin were increased after infarction compared with sham controls (n = 8) (27.4 +/- 3.2 vs. 7.5 +/- 1.8 ng ANG I. ml plasma. h-1, P < 0.0002; and 8.8 +/- 1.6 vs. 2. 5 +/- 0.1 ng ANG I. g myocardium-1. h-1, P < 0.008, respectively). After infarction, myocardial renin was correlated with infarct size (r = 0.62, P < 0.02) and plasma renin (r = 0.55, P < 0.04). Plasma angiotensinogen decreased in infarct animals, but myocardial angiotensinogen was not different from shams (1.1 +/- 0.08 vs. 2.03 +/- 0.06 nM/ml plasma, P < 0.002; and 0.081 +/- 0.008 vs. 0.070 +/- 0.004 nM/g myocardium, respectively). In conclusion, myocardial renin increased after infarction in proportion to plasma renin and infarct size, and myocardial angiotensinogen was maintained after infarction despite decreased plasma angiotensinogen and increased levels of myocardial renin.

Temporal induction of clusterin in the peri-infarct zone after experimental myocardial infarction in the rat.

Clusterin, a glycoprotein with potent cellular cohesive properties, is induced in many organs at times of tissue injury or remodeling. After renal infarction, for example, clusterin is localized to tubular epithelial cells in the peri-infarct zone. The purpose of this study was to examine the spatial and temporal expression of cardiac clusterin after myocardial infarction. Sprague-Dawley rats underwent permanent coronary ligation or sham operation. Hearts were harvested at 6 hours and at 2, 14, and 28 days after infarction. Cardiac clusterin expression was examined by immunohistochemistry and in situ hybridization. Left ventricular clusterin staining was evident at 6 hours and 2 days after myocardial infarction, although not at later time periods. Clusterin was localized to peri-infarct zone myocytes and endothelial cells of this region, and local synthesis of clusterin by myocytes was confirmed by in situ hybridization. Clusterin was not present in inflammatory cells or in left ventricular tissue distant from the infarct. The distribution of clusterin was different from the membrane attack complex of complement (C5b-9), with the latter being present diffusely throughout the infarct zone. Although the role of cardiac clusterin is not known, we speculate that clusterin's cohesive properties serve to promote myocyte interactions that are perturbed in the peri-infarct zone after myocardial infarction.

Effect of bilateral nephrectomy on active renin, angiotensinogen, and renin glycoforms in plasma and myocardium.

In an attempt to clarify the relationship of the circulating and myocardial renin-angiotensin systems, active renin concentration, its constituent major glycoforms (active renin glycoforms I through V), and angiotensinogen were measured in plasma and left ventricular homogenates from sodium-depleted rats under control conditions or 2 minutes, 3 hours, 6 hours, and 48 hours after bilateral nephrectomy (BNX). Control myocardial renin concentration was 1.4+/-0.1 ng angiotensin I (Ang I) per gram myocardium per hour and plasma renin concentration was 6.7+/-1.1 ng Ang I per milliliter plasma per hour. Control myocardial angiotensinogen was 0.042+/-0.004 micromol/kg myocardium and plasma angiotensinogen was 1.5 micromol/L plasma. Two minutes after BNX and corresponding stimulation of renin secretion by anesthesia and surgery, plasma renin concentration was increased disproportionately compared with myocardial renin. Three, 6, and 48 hours after BNX, renin decay occurred significantly faster from the plasma than from the myocardium. Forty-eight hours after BNX, myocardial renin concentrations had fallen to 15% of control values, while myocardial angiotensinogen concentrations had increased 12-fold and plasma angiotensinogen concentrations had increased by only 3.5-fold. Myocardial renin glycoform proportions were identical in myocardial homogenates and plasma in control animals. At 6 hours BNX, the proportions of plasma active renin glycoforms I+II fell, while those in the myocardium significantly increased. We conclude that in control rats, active renin and active renin glycoforms are distributed as if in diffusion equilibrium between plasma and the myocardial interstitial space. After BNX, myocardial renin concentration falls dramatically, suggesting that most cardiac renin is derived from plasma renin of renal origin. After BNX, renin glycoforms I+II are preferentially cleared from the plasma but preferentially retained by the myocardium. Control myocardial angiotensinogen concentrations are too low to result from simple diffusion equilibrium between plasma and the myocardial interstitium.