Heart output

It seems inevitable in view of our discussion on variations of anatomy and of heart outputs that normal individuals should have circulatory peculiarities. An extreme case of what may be a circulatory peculiarity has been called to my attention. This individual continually has a problem of cold feet he uses a heating pad under his working desk, carries one around with him and on social occasions sits near an electric outlet, plugs it in, and attempts to be comfortable. It seems likely that this individual suffers because of unrecognized... 

Though only about 1% of body mass, the kidney receives about one fourth of the heart output of blood. This high level of blood combined with the kidney s ability to concentrate substances in the kidney tubular fluid, from which most of the water and sodium removed by the kidney are returned to the blood, often means that the kidney is exposed to especially high levels of toxicants. Such concentrations have been known to cause deposition of substances such as sulfonamides and oxalates in the kidney, resulting in cell necrosis. Fortunately, the kidney has a good ability to compensate for damage. 

Nasal mucus increased Saliva produced Breathing slow Heart rate slow Heart output decreased Surface blood vessels dilated Skin hairs normal Dry skin... 

The normal cardiovascular response (a compensatory increased heart output and rate) that should follow the first-dose hypotensive reaction to alpha blockers is apparently eompromised by the presence of a beta bloeker. The problem is usually only short-lasting because some physiological compensation oeeurs within hours or days, and this allows the blood pressure to be lowered without falling preeipitously. Tamsulosin possibly has less effeet on blood pressure sinee it has some selectivity for alpha receptors in the prostate (see Alpha bloekers , (p.83)). 

Cardiac defibrillators are electronic devices that have been used for decades to provide a strong electrical shock to a patient in an attempt to convert a very rapid (and often chaotic), ineffective heart rhythm to a slower, coordinated, and more effective rhythm. When used to treat ventricular fibrillation (VF) or very rapid ventricular tachycardia the shock may be lifesaving because the heart output is nil or is too low to sustain life. Occurrence of VF is a medical emergency and rapid treatment (within seconds to minutes) is essential for survival. 

Organ Total Blood Flow (ml/min) Organ Mass (% of body weight) Percent of Heart Output Relative Blood Flow (ml/min/lOOg) Percent Lipid Relative DDT Concentration (mg/kg)< ... 

Isoflurane is a respiratory depressant (71). At concentrations which are associated with surgical levels of anesthesia, there is Htde or no depression of myocardial function. In experimental animals, isoflurane is the safest of the oral clinical agents (72). Cardiac output is maintained despite a decrease in stroke volume. This is usually because of an increase in heart rate. The decrease in blood pressure can be used to produce "deHberate hypotension" necessary for some intracranial procedures (73). This agent produces less sensitization of the human heart to epinephrine relative to the other inhaled anesthetics. Isoflurane potentiates the action of neuromuscular blockers and when used alone can produce sufficient muscle relaxation (74). Of all the inhaled agents currently in use, isoflurane is metabolized to the least extent (75). Unlike halothane, isoflurane does not appear to produce Hver injury and unlike methoxyflurane, isoflurane is not associated with renal toxicity. 

Desflurane is less potent than the other fluorinated anesthetics having MAC values of 5.7 to 8.9% in animals (76,85), and 6% to 7.25% in surgical patients. The respiratory effects are similar to isoflurane. Heart rate is somewhat increased and blood pressure decreased with increasing concentrations. Cardiac output remains fairly stable. Desflurane does not sensitize the myocardium to epinephrine relative to isoflurane (86). EEG effects are similar to isoflurane and muscle relaxation is satisfactory (87). Desflurane is not metabolized to any significant extent (88,89) as levels of fluoride ion in the semm and urine are not increased even after prolonged exposure. Desflurane appears to offer advantages over sevoflurane and other inhaled anesthetics because of its limited solubiHty in blood and other tissues. It is the least metabolized of current agents. 

Some P-adrenoceptor blockers have intrinsic sympathomimetic activity (ISA) or partial agonist activity (PAA). They activate P-adrenoceptors before blocking them. Theoretically, patients taking P-adrenoceptor blockers with ISA should not have cold extremities because the dmg produces minimal decreases in peripheral blood flow (smaller increases in resistance). In addition, these agents should produce minimal depression of heart rate and cardiac output, either at rest or during exercise (36). 

The heart, a four-chambered muscular pump has as its primary purpose the propelling of blood throughout the cardiovascular system. The left ventricle is the principal pumping chamber and is therefore the largest of the four chambers in terms of muscle mass. The efficiency of the heart as a pump can be assessed by measuring cardiac output, left ventricular pressure, and the amount of work requHed to accomplish any requHed amount of pumping. 

Moreover, digitahs has indirect effects on the circulation, which in normal hearts results in a small increase in arterial pressure, peripheral resistance, and cardiac output (114). The effects of digitahs on the circulation of an individual experiencing congestive heart failure are much more dramatic, however. The increased cardiac output, for example, increases renal blood flow which can reheve in part the edema of CHF associated with salt and water retention (114). 

ACE inhibitors lower the elevated blood pressure in humans with a concomitant decrease in total peripheral resistance. Cardiac output is increased or unchanged heart rate is unchanged urinary sodium excretion is unchanged and potassium excretion is decreased. ACE inhibitors promote reduction of left ventricular hypertrophy. 

P-Adrenoceptor Blockers. There is no satisfactory mechanism to explain the antihypertensive activity of P-adrenoceptor blockers (see Table 1) in humans particularly after chronic treatment (228,231—233). Reductions in heart rate correlate well with decreases in blood pressure and this may be an important mechanism. Other proposed mechanisms include reduction in PRA, reduction in cardiac output, and a central action. However, pindolol produces an antihypertensive effect without lowering PRA. In long-term treatment, the cardiac output is restored despite the decrease in arterial blood pressure and total peripheral resistance. Atenolol (Table 1), which does not penetrate into the brain is an efficacious antihypertensive agent. In short-term treatment, the blood flow to most organs (except the brain) is reduced and the total peripheral resistance may increase. 

Methyldopa. Methyldopa reduces arterial blood pressure by decreasing adrenergic outflow and decreasing total peripheral resistance and heart rate having no change in cardiac output. Blood flow to the kidneys is not changed and that to the heart is increased. It causes regression of myocardial hypertrophy. 

Glonidine. Clonidine decreases blood pressure, heart rate, cardiac output, stroke volume, and total peripheral resistance. It activates central a2 adrenoceptors ia the brainstem vasomotor center and produces a prolonged hypotensive response. Clonidine, most efficaciously used concomitantly with a diuretic in long-term treatment, decreases renin and aldosterone secretion. 

All power supplies work under the same basie prineiple, whether the supply is a linear or a more eomplieated switehing supply. All power supplies have at their heart a elosed negative feedbaek loop. This feedbaek loop does nothing more than hold the output voltage at a eonstant value. Figure 2-1 shows the major parts of a series-pass linear regulator. 

Mean arterial pressure and cardiac output, an expression of the amount of blood that the heart pumps each minute, are the key Indicators of the normal functioning of the cardiovascular system. Mean arterial pressure is strictly controlled, but by changing the cardiac output, a person can adapt, e.g., to increased oxygen requirement due to increased workload. Blood flow in vital organs may vary for many reasons, but is usually due to decreased cardiac output. However, there can be very dramatic changes in blood pressure, e.g., blood pressure plummets during an anaphylactic allergic reaction. Also cytotoxic chemicals, such as heavy metals, may decrease the blood pressure. 

Although blood pressure control follows Ohm s law and seems to be simple, it underlies a complex circuit of interrelated systems. Hence, numerous physiologic systems that have pleiotropic effects and interact in complex fashion have been found to modulate blood pressure. Because of their number and complexity it is beyond the scope of the current account to cover all mechanisms and feedback circuits involved in blood pressure control. Rather, an overview of the clinically most relevant ones is presented. These systems include the heart, the blood vessels, the extracellular volume, the kidneys, the nervous system, a variety of humoral factors, and molecular events at the cellular level. They are intertwined to maintain adequate tissue perfusion and nutrition. Normal blood pressure control can be related to cardiac output and the total peripheral resistance. The stroke volume and the heart rate determine cardiac output. Each cycle of cardiac contraction propels a bolus of about 70 ml blood into the systemic arterial system. As one example of the interaction of these multiple systems, the stroke volume is dependent in part on intravascular volume regulated by the kidneys as well as on myocardial contractility. The latter is, in turn, a complex function involving sympathetic and parasympathetic control of heart rate intrinsic activity of the cardiac conduction system complex membrane transport and cellular events requiring influx of calcium, which lead to myocardial fibre shortening and relaxation and affects the humoral substances (e.g., catecholamines) in stimulation heart rate and myocardial fibre tension. 

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