Use of intermittent dobutamine infusion in congestive heart failure

Dobutamine is a cardiac inotrope useful in the acute treatment of congestive heart failure. Dobutamine improves cardiac output, decreases pulmonary wedge pressure, and decreases total systemic vascular resistance with little effect on heart rate or systemic arterial pressure. Clinical benefit has been observed to continue for weeks to months following the discontinuation of dobutamine. In addition, tolerance to dobutamine has been observed when infusions last 72 hours or longer. This has led investigators to study the effectiveness of chronic intermittent infusions of dobutamine. Studies utilizing dobutamine doses ranging from 1.5 to 15 micrograms/kg/min for 4-48 h/wk have shown sustained clinical and hemodynamic improvement in patients suffering from congestive heart failure. The mechanism by which dobutamine creates this effect is not entirely known; however, studies suggest dobutamine exerts a physical conditioning effect similar to exercise. Dobutamine infusions have also been associated with morphological and metabolic changes in myocardial tissue consistent with improved myocardial structure and function. The intermittent use of dobutamine may be beneficial in the chronic treatment of congestive heart failure in patients who fail to respond to conventional therapy.     

The effects of dobutamine on renal sympathetic activity in human heart failure

The pathophysiology of the cardiorenal syndrome remains poorly understood. Renal sympathetic activity is increased in heart failure. It contributes to the sodium avid state, renal vasoconstriction, and reduced glomerular filtration rate that is characteristic of a large number of heart failure patients. Dobutamine is commonly used in the treatment of decompensated heart failure. We used the norepinephrine spillover technique to examine the effects of dobutamine on renal sympathetic activity in human heart failure. Dobutamine was titrated to increase the peak positive rate of change in left ventricular pressure by 25%. In 11 patients with heart failure, dobutamine infusion reduced efferent renal sympathetic activity by 50% (P < 0.003). This sympatholytic response was associated with an 11% increase in renal plasma flow (P < 0.03) and a 12% increase in glomerular filtration rate (P < 0.04). These findings suggest that dobutamine infusion is acutely associated with a beneficial effect on renal function. This observation is potentially related to a renal sympatholytic response to ventricular mechanoreceptor activation associated with the inotropic effects of beta-adrenergic receptor stimulation.     

Haemodynamic advantages of a combined inotropic/venodilator regimen over inotropic monotherapy in acute heart failure

The haemodynamic influence of positive inotropic therapy with dobutamine, both alone and when combined with isosorbide dinitrate, was evaluated in 10 consecutive patients admitted to Coronary Care with acute left ventricular failure (pulmonary artery occluded pressure greater than 20 mm Hg) complicating myocardial infarction. Dobutamine increased systemic arterial blood pressure and heart rate without reduction in the left heart filling pressure; cardiac index (+0.9 L/min/m2; p less than 0.01) was substantially increased. Thus, consequent on these effects, dobutamine could increase myocardial oxygen requirements. The addition of intravenous isosorbide dinitrate reduced systemic arterial pressure and left heart filling pressure; the augmented cardiac index following therapy with dobutamine alone was maintained. Combined dobutamine/nitrate therapy, therefore, appeared haemodynamically superior to dobutamine monotherapy, in that it improved cardiac stroke volume at a normalised left ventricular filling pressure. These data suggest that combined dobutamine/nitrate therapy may prove useful as an adjunct to the treatment of normotensive heart failure complicating acute myocardial infarction.     

Two weeks of intermittent dobutamine therapy restores cardiac performance and inotropic responsiveness in conscious rats with heart failure.

Dobutamine is frequently used for acute therapy in heart failure. In the present study, the hemodynamic effects of long-term intermittent dobutamine therapy were investigated in conscious rats with heart failure. Rats with healed myocardial infarctions received two i.p. injections of dobutamine per day for 2 weeks. Hemodynamic measurements were performed 90-180 min after the last injection. Two weeks of intermittent dobutamine significantly restored all hemodynamic changes induced by infarction. The maximal cardiac output during volume loading was depressed due to infarction and dose-dependently restored by 2 weeks of intermittent dobutamine. An increased stroke volume accounted for this improvement since the heart rate was not altered. In order to investigate changes in adrenergic responsiveness, the effects of acute dobutamine in nontreated and 2 weeks of dobutamine-treated infarcted rats were compared to those in control rats. Whereas chronotropic responses to acute dobutamine were comparable for all experimental groups, the inotropic response was reduced in nontreated infarcted rats but dose-dependently restored after 2 weeks of intermittent dobutamine therapy. From the data, we conclude that 2 weeks of intermittent dobutamine therapy in conscious rats with healed myocardial infarcts improved cardiac performance and restored the inotropic response to acute dobutamine administration. Data indicate that dobutamine has a long-term effect on cardiac function, which differs from the acute inotropic effect.     

Dopamine and dobutamine in pediatric therapy

Dopamine hydrochloride is widely used to increase blood pressure, cardiac output, urine output, and peripheral perfusion in neonates, infants, and older children with shock and cardiac failure. Its pharmacologic effects are dose dependent, and at low, intermediate, and high dosages include dilation of renal, mesenteric, and cerebral vasculature; inotropic response in the myocardium; and increases in peripheral and renal vascular resistance, respectively. The inotropic response is diminished in neonates compared with older children and adults due to maturational differences in norepinephrine stores. The clearance of dopamine varies widely in the pediatric population, depending on age. Its elimination half-life is approximately 2 minutes in full-term neonates and older children, and may be as long as 4-5 minutes in preterm infants. Due to immaturity of the autonomic nervous system, the drug may produce some adverse respiratory responses at high dose in neonates, the most common being tachycardia and cardiac arrhythmias. Dobutamine resembles dopamine chemically and is an analog of isoproterenol. It is relatively cardioselective at dosages used in clinical practice, with its main action being on beta 1-adrenergic receptors. Unlike dopamine, it does not have any effect on specific dopaminergic receptors. Dobutamine is used to increase cardiac output in infants and children with circulatory failure. Its elimination half-life is about 2 minutes in adults and older children. No information is available about its pharmacokinetics in neonates and infants. Adverse effects such as an increase in heart rate usually occur at high dosages.     

Levosimendan: a review of its use in the management of acute decompensated heart failure

Levosimendan (Simdax) is a calcium-sensitising drug that stabilises the troponin molecule in cardiac muscle, thus prolonging its effects on contractile proteins, with concomitant vasodilating properties. Intravenous levosimendan (12-24 microg/kg loading dose followed by 0.1-0.2 microg/kg/min for 24 hours, adjusted for response and tolerability) is approved for the short-term treatment of acute severe decompensated heart failure. Cardiac output increased by about 30% and pulmonary capillary wedge pressure and systemic vascular resistance decreased by about 17-29% in patients with decompensated heart failure receiving intravenous levosimendan. In large, well controlled trials in patients with decompensated heart failure, intravenous levosimendan was significantly more effective than placebo or dobutamine for overall haemodynamic response rate (primary endpoint). Significant benefits were also seen for mortality (versus placebo or dobutamine) and for the combined risk of worsening heart failure or death (versus dobutamine). Improvements in key symptoms (dyspnoea and fatigue) have not been consistently demonstrated. Hospitalisation costs were similar for levosimendan and dobutamine; the total incremental (hospitalisation plus drug) cost per life-year saved (extrapolated to 3 years) for levosimendan relative to dobutamine was estimated at Euro 3205 (year of costing 2000). Levosimendan is generally well tolerated, with an adverse event profile at recommended dosages similar to that in patients receiving placebo. Cardiac rate/rhythm disorders and headache were the most common events. At higher dosages, patients receiving levosimendan had higher rates of sinus tachycardia than those in placebo recipients. More patients receiving dobutamine than those receiving levosimendan experienced angina pectoris/chest pain/myocardial ischaemia or rate/rhythm disorders. CONCLUSION: Intravenous levosimendan is an effective calcium-sensitising drug with vasodilatory and inotropic effects, and superior efficacy/tolerability to those of intravenous dobutamine in patients with acute decompensated heart failure. It may be associated with reduced mortality compared with both placebo and dobutamine. Levosimendan is generally well tolerated and may have less potential for cardiac rate/rhythm disorders than dobutamine. While evidence from well designed trials confirming the improved mortality over dobutamine and investigating haemodynamic efficacy and mortality versus other positive inotropes is required, intravenous levosimendan appears to be a useful addition to the treatment options for acute decompensated heart failure in patients with low cardiac output.     

The use of levosimendan in comparison and in combination with dobutamine in the treatment of decompensated heart failure

Levosimendan is a new calcium sensitizer with inotropic and vasodilatory actions mediated by the sensitization of contractile proteins to calcium, opening of potassium channels and inhibition of phosphodiesterase-3. Its alternative mechanisms of action to those of other traditional inotropes provide a new approach in the management of decompensated heart failure. In contrast to dobutamine, levosimendan does not increase myocardial oxygen demand and, therefore, it is thought to have a lower potential to induce increases in myocardial ischemia and cardiac arrhythmias. The commonly used inotropic agent dobutamine increases myocardial contractility at the expense of increased myocardial oxygen consumption and, therefore, it can result in poor outcomes. Although dobutamine may also have favorable hemodynamic and symptomatic effects, levosimendan has been shown to be superior to dobutamine in increasing cardiac output and decreasing pulmonary capillary wedge pressure in patients with decompensated heart failure. In the presence of concomitant β-blocker therapy, these favorable effects were present or even more pronounced during treatment with levosimendan, but not dobutamine. However, the mortality benefit of levosimendan observed in earlier trials has not been confirmed in recent, larger clinical trials. A distinct advantage of levosimendan over dobutamine is its prolonged hemodynamic effects, which last for up to 7 – 9 days. There are more data on the safety of levosimendan in ischemic patients than with any other inotropic drug and, therefore, levosimendan seems to be safe and effective in patients with ischemic heart disease when used at the recommended doses. Despite advances in heart failure therapy, many patients experience clinical deterioration, or do not respond to a single inotropic drug. Increasing evidence suggests the use of levosimendan in combination with dobutamine in patients with decompensated heart failure that is refractory to dobutamine alone.     

The use of levosimendan in comparison and in combination with dobutamine in the treatment of decompensated heart failure

Levosimendan is a new calcium sensitizer with inotropic and vasodilatory actions mediated by the sensitization of contractile proteins to calcium, opening of potassium channels and inhibition of phosphodiesterase-3. Its alternative mechanisms of action to those of other traditional inotropes provide a new approach in the management of decompensated heart failure. In contrast to dobutamine, levosimendan does not increase myocardial oxygen demand and, therefore, it is thought to have a lower potential to induce increases in myocardial ischemia and cardiac arrhythmias. The commonly used inotropic agent dobutamine increases myocardial contractility at the expense of increased myocardial oxygen consumption and, therefore, it can result in poor outcomes. Although dobutamine may also have favorable hemodynamic and symptomatic effects, levosimendan has been shown to be superior to dobutamine in increasing cardiac output and decreasing pulmonary capillary wedge pressure in patients with decompensated heart failure. In the presence of concomitant beta-blocker therapy, these favorable effects were present or even more pronounced during treatment with levosimendan, but not dobutamine. However, the mortality benefit of levosimendan observed in earlier trials has not been confirmed in recent, larger clinical trials. A distinct advantage of levosimendan over dobutamine is its prolonged hemodynamic effects, which last for up to 7-9 days. There are more data on the safety of levosimendan in ischemic patients than with any other inotropic drug and, therefore, levosimendan seems to be safe and effective in patients with ischemic heart disease when used at the recommended doses. Despite advances in heart failure therapy, many patients experience clinical deterioration, or do not respond to a single inotropic drug. Increasing evidence suggests the use of levosimendan in combination with dobutamine in patients with decompensated heart failure that is refractory to dobutamine alone.     

Hemodynamic effects of dobutamine in patients with an exacerbation of chronic systolic heart failure treated with low doses of carvedilol

Although most patients in Europe with systolic heart failure (SHF) are treated with I(2)-blocking agents at doses significantly lower than the recommended dose, there is limited information available regarding the hemodynamic effects of dobutamine in this patient population. Therefore, a study was carried out in patients (n=31) admitted to the University Hospital, Larissa, Greece with an acute exacerbation of chronic SHF (25 men and 6 women, mean age 58 years, range 32 a 80 years, left ventricular (LV) ejection fraction 相似文献   

Review of Intermittent Dobutamine Infusions for Congestive Cardiomyopathy

Dobutamine is a potent inotropic agent traditionally used for treatment of acute cardiac decompensation of congestive heart failure (CHF). It acts primarily by increasing myocardial contractility and cardiac output. It has a rapid onset of action, a half-life of 2 minutes, and a duration of action of 10 minutes. Recently, the therapeutic effect of dobutamine was noted to be prolonged beyond the discontinuation of an infusion, persisting for 4–10 weeks after infusion of 48–72 hours. Because of this prolonged effect, dobutamine infusions were evaluated in outpatients with intractable CHF and were effective in improving their functional status. No effect on survival rates may be expected, but this form of therapy may improve the patient's lifestyle. Although several factors may limit the application of dobutamine infusion to outpatients, it offers an effective alternative to traditional therapy for select patients.     

Comparative hemodynamic effects of intravenous dobutamine and dibutyryl cyclic AMP, a new inotropic agent, in severe congestive heart failure.

In nine patients with chronic congestive heart failure, the acute hemodynamic response to intravenous (i.v.) dibutyryl cyclic AMP (DBcyclicAMP) administration was compared with i.v. dobutamine administration. Both agents led to a significant and similar increase in cardiac index. Dobutamine caused a significant increase in mean arterial pressure but did not produce a significant change in pulmonary capillary wedge, mean pulmonary artery, or mean right atrial pressures. In contrast, DBcyclicAMP caused a significant decrease in mean arterial, mean pulmonary capillary wedge, mean pulmonary artery, and mean right atrial pressures, reflecting vasodilator activity. The fall in systemic vascular resistance was larger after DBcyclicAMP than after dobutamine. DBcyclicAMP achieves an optimal improvement in cardiovascular hemodynamics in concert with substantial vasodilating effect. This pharmacologic action constitutes the mainstay of i.v. therapy for severe congestive heart failure (CHF).     

Comparative effects of dobutamine and corwin, a beta 1-adrenergic partial agonist, in experimental left ventricular failure

Corwin is a new, long-acting beta 1-adrenergic partial agonist for oral and intravenous (i.v.) use. The effects of corwin were compared with those of dobutamine in acute ischemic left ventricular failure in dogs. Failure was produced by embolization of the left main coronary artery with 50 micron plastic microspheres. This induced severe depression in left ventricular function, as evidenced by a marked increase in left ventricular end-diastolic pressure, reduction in left ventricular dP/dtmax, and cardiac output. After 45 min was allowed for stabilization, the 27 dogs were randomly assigned to three groups: control (n = 9), dobutamine-treated (5-10 micrograms/kg/min i.v., n = 9), and corwin-treated (0.025-0.10 mg/kg i.v., n = 9). The doses of dobutamine and corwin were adjusted to give an increase in left ventricular dP/dtmax of 50%. Both drugs similarly increased cardiac output (p less than 0.01), lowered left ventricular end-diastolic pressure (p less than 0.01) and total peripheral vascular resistance (p less than 0.01), but did not affect the heart rate. Only dobutamine increased the mean arterial pressure (p less than 0.01). Both drugs also increased the arterial concentrations and myocardial uptake of fatty acids (p less than 0.05) but caused only a small and nonsignificant increase in myocardial oxygen consumption. Our findings indicate that the hemodynamic and metabolic profiles of corwin and dobutamine are similar, and both drugs should be of special value in the treatment of congestive heart failure. Since corwin can be given orally and has a longer duration of action, it is potentially useful in the long-term treatment of heart failure.     

Levosimendan: a new inodilatory drug for the treatment of decompensated heart failure

Levosimendan is a new calcium sensitizer developed for the treatment of congestive heart failure. Experimental studies indicate that levosimendan increases myocardial contractility and dilates both the peripheral and coronary vessels. Its positive inotropic effect is based on calcium-dependent binding of the drug to cardiac troponin C. It also acts as an opener of ATP-dependent potassium channels in vascular smooth muscle, thus inducing vasodilation. Although levosimendan acts preferentially as a calcium sensitizer it has also demonstrated selective phosphodiesterase III inhibitory effects in vitro. However, this selective inhibition does not seem to contribute to the positive action at pharmacologically relevant concentrations. Levosimendan has an active metabolite, OR-1896. Similarly to levosimendan, the metabolite exerts its positive inotropic and vasodilatory effects on myocardium and vasculature. The elimination half-life of levosimendan is about 1 hour. Thus, with intravenous administration, the parent drug rapidly disappears from the circulation after the infusion is stopped. The active metabolite, however, has a half-life of approximately 80 hours, and can be detected in circulation up to 2 weeks after stopping a 24-hour infusion of levosimendan. The intravenous formulation of levosimendan has been studied in several randomized comparative studies in patients with decompensated heart failure. Both patients with ischemic and non-ischemic etiology have participated in the studies. Levosimendan produces significant, dose-dependent increases in cardiac output, stroke volume and heart rate, and decreases in PCWP, mean blood pressure, mean pulmonary artery pressure, mean right atrial pressure and total peripheral resistance. With a loading dose, the effects on PCWP and cardiac ouput are seen within few minutes. There is no sign of development of tolerance even with a prolonged infusion up to 48 hours. Cardiac performance is improved with no significant increases in oxygen consumption or potentially malignant rhythm disorders. Due to the formation of an active metabolite, the hemodynamic effects are maintained up to several days after stopping levosimendan infusion. Compared to dobutamine, levosimendan produces similar increase in cardiac output but profoundly greater decrease in pulmonary capillary wedge pressure. On the contrary to dobutamine, the hemodynamic effects are not attenuated with concomitant beta-blocker use. Levosimendan has been shown to have favourable effects on symptoms of heart failure superior to placebo and at least comparable to dobutamine. Mortality and morbidity in levosimendan treated patients has been shown to be significantly lower when compared to dobutamine or placebo treated patients. The most common adverse events associated with levosimendan treatment are headache and hypotension, as a likely consequence of the vasodilating properties of the compound. In conclusion, levosimendan offers a new effective option for the treatment of acutely decompensated heart failure. Unlike traditional inotropes, levosimendan seems also to be safe in terms of morbidity and mortality.     

Acute hemodynamic and neuroendocrine effects of dopexamine, a new vasodilator for the treatment of heart failure: comparison with dobutamine, captopril, and nitrate

Dopexamine (FPL 60278) is a new vasodilator possessing both postjunctional dopaminergic and beta 2-adrenoceptor agonist actions. Its acute haemodynamic effects were compared in a cross-over study with those of dobutamine, captopril, and glyceryl trinitrate (GTN) in eight adult patients with chronic heart failure. Dopexamine, 1 microgram/kg/min intravenously (i.v.) for 10 min, increased cardiac index, systolic blood pressure, and heart rate while reducing systemic vascular resistance. Pulmonary artery end-diastolic pressure was unchanged. Plasma norepinephrine (NE) increased during dopexamine infusion. No arrhythmias occurred. Dobutamine, 5 micrograms/kg/min i.v. for 10 min, increased cardiac index and systolic blood pressure similarly but did not increase heart rate or reduce vascular resistance. Captopril, 25 mg orally, did not alter cardiac index at 1 h, but reduced heart rate, blood pressure, pulmonary diastolic pressure, and vascular resistance. GTN, 100 micrograms sublingually, reduced pulmonary diastolic pressure but did not affect other variables at 5 min. Dopexamine, because it combines some of the properties of dopamine and salbutamol, may have a role in the management of severe low output cardiac failure.     

3-O-methyldobutamine, a major metabolite of dobutamine in humans.

Dobutamine is a synthetic ionotropic catecholamine commonly used to treat heart failure and shock. The catabolic fate of dobutamine in humans has yet to be reported, although formation of 3-O-methyldobutamine represents the principal pathway of dobutamine disposition in the dog. Herein, we describe the isolation and identification of 3-O-methyldobutamine in the urine of children receiving infusions of racemic dobutamine. In a 9-year-old child with heart failure approximately 80% of dobutamine administered intravenously at steady state was detected in the urine. Forty-seven percent of infused dobutamine was identified as 3-O-methyldobutamine and its acid-hydrolyzed derivatives, the latter mostly conjugated with sulfate (33%). Thirty-two percent consisted of acid-hydrolyzed dobutamine metabolites, primarily conjugated with sulfate (16%). Sonicates of human blood mononuclear cells catalyzed the formation of 3-O-methyldobutamine from dobutamine and S-adenosylmethionine in vitro. These findings indicate that formation of 3-O-methyldobutamine constitutes a major pathway of dobutamine metabolism in humans.     

Author's reply: Managing the combination of non-alcoholic fatty liver disease and metabolic syndrome

In heart failure, positive inotropes that increase the heart’s energy requirements (digoxin, phosphodiesterase inhibitors and β-adrenoceptor agonists) either have no effect or increase mortality. Calcium sensitisers, including levosimendan, have minimal effects on myocardial energy requirements. In deteriorating severe heart failure, intravenous levosimendan and dobutamine (a β-adrenoceptor agonist) were compared and haemodynamic improvement (≥ 30% increase in cardiac output and ≥ 25% decrease in pulmonary-capillary wedge pressure) was more common with levosimendan than dobutamine. The effectiveness of dobutamine in some patients was probably limited by concurrent treatment with β-blockers. In the patients who were not receiving a β-blocker, 19 of 70 patients in the levosimendan group and 11 of 71 patients in the dobutamine group had haemodynamic improvement. Levosimendan may be more appropriate than dobutamine for the treatment of decompensated heart failure, especially given the growing use of β-blockers that may limit the effectiveness of dobutamine.     

Effects of dobutamine on coronary circulation and cardiac metabolism of the dog

Effects of (+/-)-4-[2-(3-p-hydroxyphenyl-1-methyl-amino)ethyl]pyrocatechol (dobutamine) on coronary circulation and cardiac metabolism were investigated using the heart in vivo and the isolated perfused heart of dogs. In the heart in vivo dobutamine 1--30 microgram/kg i.v. and 1--100 microgram i.c. produced dose-dependent increases in coronary perfusion pressure, coronary blood flow, heart rate and left intraventricular pressure. In the perfused heart dobutamine 10 microgram i.c. increased coronary flow, heart rate, cardiac contractility and myocardial oxygen consumption. Delta redox potentials decreased but did not show negative values. Propranolol 0.1 mg/kg i.v. and 0.1 mg i.c. inhibited these effects of dobutamine. Dobutamine shows basically the same actions as isoproterenol, but does not reduce the coronary perfusion pressure by the relatively high dose applied. The results suggest that dobutamine may have a selective adrenergic beta 1 receptor stimulating action on the heart and have a merit in maintaining the coronary perfusion pressure.     

Effects of milrinone on systemic hemodynamics and regional circulations in dogs with congestive heart failure: comparison with dobutamine

Milrinone is a new bipyridine inotropic agent with direct vasodilator properties. To determine the role of the vasodilator action in mediating systemic and regional hemodynamic responses to milrinone, we administered two equipotent inotropic doses of either milrinone or dobutamine to dogs with chronic congestive right heart failure produced by tricuspid avulsion and pulmonary artery stenosis. Similar increases in cardiac output, right and left ventricular dP/dt, and left ventricular dP/dt/P were produced by milrinone and dobutamine; however, heart rate increased and mean aortic pressure decreased only with milrinone infusion. In addition, while total peripheral vascular resistance decreased with both agents, the decrease was greater with milrinone. Regional blood flows were measured by a radioactive microsphere method. Milrinone and dobutamine produced similar increases in myocardial blood flow and left ventricular oxygen consumption. Dobutamine infusion decreased quadriceps muscle vascular resistance and had no effect on renal and splanchnic circulations. In contrast, milrinone infusion increased vascular resistance in quadriceps muscle and decreased it in renal and splanchnic beds. Thus, when milrinone was used in inotropic doses similar to those of dobutamine, the responses in systemic and regional hemodynamics in congestive heart failure differed. Milrinone produced a greater decline in total peripheral, renal, and splanchnic vascular resistances, probably resulting from its direct vasodilator action.     

Pharmacokinetic-pharmacodynamic relationship of dobutamine and heart rate, stroke volume and cardiac output in healthy volunteers

BACKGROUND AND OBJECTIVE: Dobutamine causes an increase in cardiac output (CO) by augmenting stroke volume (SV) through enhanced left ventricular contractility and by decreasing systemic vascular resistance. However, in some patients, the dominant mechanism by which dobutamine improves left ventricular performance is an increase in the subject's heart rate (HR). We therefore decided to evaluate the pharmacokinetic-pharmacodynamic relationship of dobutamine plasma concentrations and heart rate, SV and CO in healthy volunteers. METHODS: We enrolled 23 subjects who received dobutamine at a dose of 2.5, 5 and 10 microg/kg/min for three consecutive periods of 60 minutes each. Dobutamine plasma concentrations were determined from 22 blood samples drawn during each study session. Echocardiography was used to measure CO before administration of dobutamine and once during each infusion period. RESULTS: There was a clear linear relationship between dobutamine plasma concentrations and CO (r(2) = 0.628; p < 0.001). In most subjects, HR remained stable at dobutamine plasma concentrations produced by the lowest infusion rate but increased markedly thereafter so that overall there was a linear relationship between dobutamine plasma concentrations and HR (r(2) = 0.540; p < 0.001). However, SV increased significantly at the dobutamine plasma concentrations produced by the lowest infusion rate but remained mostly stable or even decreased thereafter. Although clinically slight, the overall increase in SV was statistically significant (r(2) = 0.062; p < 0.05). CONCLUSION: Low plasma concentrations of dobutamine resulted in an increase in CO almost solely due to improved left ventricular contractility. However, at higher plasma concentrations of dobutamine, SV remained stable or even decreased, and the linear increase in CO was entirely based on increased HR.     

Comparative haemodynamic dose-response effects of dobutamine and amrinone in left ventricular failure complicating acute myocardial infarction

The comparative haemodynamic dose-response effects of intravenous (i.v.) amrinone and dobutamine were evaluated in 20 male patients with haemodynamic (pulmonary artery occluded pressure (PAOP) greater than 20 mm Hg) and radiographic left heart failure following a recent myocardial infarction. Following a 1-h control period, 10 patients were each randomised to amrinone (800, 1,600, or 3,200 micrograms/kg/h) or dobutamine (200, 400, or 800 micrograms/kg/h) sequentially infused for 30 min at each dose level; haemodynamic parameters were recorded at the end of each infusion period. Amrinone reduced systemic arterial blood pressure and vascular resistance index with a moderately increased heart rate; PAOP (-10 mm Hg; p less than 0.01) fell substantially without change in cardiac or stroke work indices. Dobutamine increased systemic arterial blood pressure, heart rate, and stroke work index at an unchanged PAOP; cardiac index (+0.7 L/min/m2; 25%; p less than 0.01) increased. Systemic vascular resistance index was significantly reduced by both drugs. Thus, dobutamine increased cardiac index at an unchanged PAOP; myocardial stroke work increased. Amrinone had lesser effect on cardiac pumping but reduced PAOP (preload) at an unchanged stroke work. The implications of these differential actions for the clinical therapy of myocardial infarction deserves further evaluation.