T. I. Musch

Delayed reversal of impaired vasodilation in congestive heart failure after heart transplantation.

The effects of changes in central cardiovascular function on peripheral vasodilation were investigated. Strain gauge plethysmography was used to measure the maximal blood flow response following release of forearm arterial occlusion and the peak reactive hyperemic blood flow response (ml/min.100 ml) before and twice after orthotopic heart transplantation in 10 subjects with severe congestive heart failure. The 2 posttransplantation studies were done before hospital discharge (mean 18 days after transplantation) and again after discharge (mean 114 days after transplantation). Transplantation led to a significant but delayed increase in maximal vasodilation (reactive hyperemic blood flow: pretransplant 21 +/- 3; predischarge 25 +/- 2; postdischarge 43 +/- 5) and a concurrent significant reduction in minimal forearm resistance. Although the improvement in peripheral vasodilator function may be linked to improvement in cardiac function, this linkage is not direct, nor is it immediate. If the normalization of maximal metabolic blood flow is related to resumption of normal physical activity postdischarge, then much of the basic abnormality in vasodilator capacity in congestive heart failure may be related to physical deconditioning.

Endurance training in rats with chronic heart failure induced by myocardial infarction.

The response to exercise was investigated in trained and sedentary rats with moderate compensated heart failure produced by myocardial infarction (MI) and in rats that underwent sham operations. Trained rats ran on a treadmill (10% grade at 20 m/min) for 60 min/day, 5 days/week for 10 to 12 weeks, whereas sedentary rats had only limited activity. Maximal oxygen consumption normalized for body weight (ml kg-1 min-1) was determined for each rat and found to be (1) greater in trained rats when compared with sedentary rats and (2) greater in sham-operated rats when compared with their counterparts that suffered infarction. In addition, skeletal muscle succinate dehydrogenase activities were greater and the blood lactic acid response to submaximal exercise was lower in trained rats compared with sedentary rats. Left ventricular infarct size for sedentary and trained rats with infarction was 36 +/- 3% and 34 +/- 3% of the total endocardial circumference, respectively, and resulted in (1) elevated left ventricular end-diastolic pressures at rest and during exercise, (2) lower mean arterial pressures at rest, and (3) lower maximal heart rates when compared with those in their sham-operated counterparts. However, normalization of mean arterial pressures during submaximal and maximal exercise was found along with a trend toward normalization of maximal heart rate when trained rats with infarction were compared with their sedentary counterparts. Blood flows to the kidneys, organs of the gut, and skeletal muscle during both submaximal and maximal exercise were unaffected by either myocardial infarction or training; no differences between sedentary and trained rats with infarction and sedentary and trained sham-operated rats were found. These results demonstrate that an exercise training program of moderate intensity produces beneficial hemodynamic and metabolic effects in rats with moderate compensated heart failure.

Enhanced metabolic vasodilation secondary to diuretic therapy in decompensated congestive heart failure secondary to coronary artery disease

Since sodium and water retention have been implicated as major factors limiting maximal metabolic vasodilation in congestive heart failure (CHF), the effect of rigorous diuresis on maximal vasodilatory capacity was studied systematically in 9 subjects hospitalized with decompensated CHF. Peak reactive hyperemic blood flow, measured by strain-gauge plethysmography, was used as an index of maximal vasodilatory capacity. After 24 hours of diuresis and a 2.2-kg weight loss, maximal flow increased from 19.9 to 26.1 ml/min X 100 ml (p less than 0.05). Despite a further 1.4-kg weight loss between 24 and 48 hours, maximal blood flow increased no more (26.1 to 25.8 ml/min X 100 ml). Since blood pressure did not change significantly, minimal forearm resistance and maximal conductance showed similar improvements. It is unlikely that vasoconstrictor hormone changes could account for this effect since a marked decrease in plasma norepinephrine occurred in only 2 of 8 subjects and plasma renin activity decreased in only 1 subject. As a group there was no significant change in norepinephrine level, which remained substantially above normal (1,525 to 1,148 pg/ml), or in plasma renin activity (12.3 to 18.9 ng/ml/hour). Because the improvement in vasodilator capacity reached a plateau by 24 hours despite continued diuresis, and because peak reactive hyperemic blood flow was still 32% below normal, it is suggested that a second mechanism besides sodium and water retention is responsible for a significant portion of the impaired peripheral vasodilation in CHF.

Regional blood flow in congestive heart failure: Concept of compensatory mechanisms with short and long time constants

With physiologic stress to the cardiovascular system, some circulatory compensatory mechanisms are designed to restore homeostasis quickly (e.g., sympathetic nervous system activation and the Frank-Starling mechanism). These compensatory mechanisms are not nearly as effective when there is a chronic pathologic stress such as congestive heart failure (CHF). In this circumstance, other mechanisms that operate with longer time constants come into play (e.g., activation of the renin-angiotensin-aldosterone system, myocardial hypertrophy and deconditioning). The most successful chronic drug therapies of CHF are those that are designed to reverse the latter group of compensatory mechanisms, a process that is slow. It takes especially long to reverse those CHF-induced changes in blood vessels and skeletal muscle metabolism that are activated to cope with inadequate delivery of oxygenated blood to working muscles. The concept that compensatory mechanisms have either short or long time constants for activation, effectiveness and reversal may help explain why the improvement in exercise tolerance with effective heart failure therapy lags behind hemodynamic improvement.

Effects of dynamic exercise training on the metabolic and cardiocirculatory responses to exercise in the rat model of myocardial infarction and heart failure

In an effort to produce significant systemic circulatory training effects, including adaptations of the heart, myocardial infarcted (MI) rats were subjected to 2 training regimens: low-intensity endurance training (LIET) and high-intensity endurance training (HIET). When compared with sedentary controls, the MI rats subjected to LIET had small but significant beneficial systemic circulatory training effects exclusive of any training effects on the heart. MI rats subjected to HIET had similar but more extensive and quantitatively greater circulatory adaptations than those found in MI rats subjected to LIET. Unlike LIET MI rats, the HIET MI rats had an increase in maximal heart rate when compared with sedentary MI rats. However, despite the reversal of this chronotropic incompetence, the HIET MI rats did not have significant increases in parameters indicative of increased left ventricular pump function (maximal cardiac output) and maximal stroke volume. To further study the effect of incrementally increasing exercise intensity, a high-intensity sprint training (HIST) regimen was developed and studied in normal rats. In response to HIST, normal rats had central myocardial adaptations (increases in maximal cardiac output and stroke volume) in response to training that were not found in the MI rats subjected to LIET and HIET. Although the effects of HIST in normal rats is now known, the question of whether a training paradigm consisting of HIET and HIST will produce increases in maximal cardiac output and stroke volume in the MI rat has yet to be determined.