Myocardial dysfunction after resuscitation from cardiac arrest: an example of global myocardial stunning

Myocardial protection during ventricular fibrillation by inhibition of the sodium-hydrogen exchanger isoform-1

Activation of the sarcolemmal sodium-hydrogen exchanger isoform-1 (NHE-1) in response to the intense intracellular acidosis that develops during ischemia has been identified as an important mechanism of myocardial cell injury. NHE-1 inhibition in the quiescent (nonfibrillating) heart ameliorates functional manifestation of ischemia and reperfusion injury. We investigated in isolated heart and intact rat models of ventricular fibrillation whether NHE-1 inhibition, by using the selective inhibitor cariporide, could ameliorate myocardial abnormalities that develop during ventricular fibrillation and limit resuscitability and survival. In the isolated rat heart, cariporide significantly reduced the magnitude of ischemic contracture during ventricular fibrillation and the accompanying increases in coronary vascular resistance. Hearts that had received cariporide during ventricular fibrillation had no diastolic dysfunction after resuscitation and recovered their systolic function earlier. In intact rats, cariporide given immediately before starting chest compression allowed generation of a coronary perfusion pressure and end-tidal Pco2 comparable with control rats but with significantly less depth of compression. Cariporide had an unprecedented effect in this rat model, prompting spontaneous defibrillation after approximately 8 mins of chest compression. After resuscitation, rats treated with cariporide had significantly less ventricular ectopic activity, better hemodynamic function, and higher survival rates (22 of 24 [94%] vs. 15 of 24 [63%] in control rats, p <.05). We conclude that NHE-1 inhibition may represent a novel and highly effective form of treatment for resuscitation from ventricular fibrillation.

Pharmacologic defibrillation

Ventricular fibrillation (VF) is generally sustained. The mechanism is, at least in part, caused by progressive accumulation of intracellular sodium and calcium ions during untreated ventricular fibrillation, which subsequently increases defibrillation threshold. Cariporide, a potent and specific inhibitor of the sodium-hydrogen exchanger, has been shown to reduce intracellular sodium and calcium concentration in the setting of myocardial ischemia and reperfusion. We hypothesized that cariporide would facilitate defibrillation from prolonged ventricular fibrillation in a rodent model of cardiac arrest and resuscitation. Fifteen Sprague-Dawley rats were randomized to receive bolus injections of cariporide or placebo in a dose of 3 mg/kg into the right atrium either 5 mins before or at 8 mins after onset of ventricular fibrillation. Ventricular fibrillation was electrically induced and untreated for 8 mins. Precordial compression together with mechanical ventilation was then started and continued for an interval of 8 mins before attempted electrical defibrillation. All but one placebo-treated animal were successfully resuscitated. Spontaneous defibrillation with restoration of circulation was observed in both cariporide pretreatment and treatment groups but in none of the placebo-treated animals. The duration of postresuscitation survival was significantly increased in animals pretreated with cariporide. Therefore, sodium-hydrogen exchanger inhibitors may provide new options in settings of cardiopulmonary resuscitation to facilitate defibrillation.

Role of epinephrine in acute stress

This article presents the likely pathway of stimuli generated by the recognition of high-intensity stressors to ultimately produce a fight-or-flight response. A key element is the recognition that psychological stressors that do not directly alter the internal environment represent the most important etiology of a fight-or-flight response. Adrenomedullary secretion is a critical component of that response; impromptu stimulation of the adrenal medulla can produce plasma epinephrine concentrations greater than 10,000 pg/mL. When these plasma levels reach the hypothalamus to act on the CNS, the result is facilitation of the decision making, and decision execution processes (fight-or-flight), and perhaps further sympathetic stimulation and vasopressin release. Subjects with underlying cardiovascular and/or metabolic pathology may be particularly susceptible to potentially lethal reactions to this neuroendocrine response. Additionally, since this biological reaction may be triggered by sudden changes in the social environment, the coordinated actions of epinephrine, sympathetic stimulation and vasopressin must be directed at not only optimizing the chances for survival, but also at attaining maximal preservation of the individual environmental and social domains.

Postresuscitation myocardial dysfunction

Postresuscitation myocardial dysfunction is common after prolonged cardiac arrest and can have life-threatening consequences. Experimental data suggest that systolic and diastolic left ventricular function can be adversely effected following successful resuscitation. Such dysfunction can resolve and represents true global myocardial stunning. Identified factors contributing to postresuscitation myocardial dysfunction include prolonged CPR, use of vasoconstricting drugs, and high-energy defibrillation. Potential treatments include dobutamine, KATP channel activators, and 21-aminosteroids. In the author's efforts to improve long-term survival from cardiac arrest, more attention is needed to the postresuscitation period.

Postischemic inotropic support of the dysfunctional heart

OBJECTIVE

To determine relative adenine nucleotide regeneration and improvement in left ventricular (LV) function using three commonly used adrenergic agents--epinephrine, dobutamine, and phenylephrine---during reperfusion after a period of global ischemia. After initial resuscitation from cardiac arrest, adrenergic agents are frequently required to support postischemic LV dysfunction. However, the relative effectiveness and associated bioenergetic changes associated with these agents in the postischemic heart are unclear.

DESIGN

Prospective, controlled laboratory study.

SETTING

University research laboratory.

SUBJECTS

Isolated, perfused Sprague-Dawley rat hearts.

INTERVENTIONS

After 20 mins of global ischemia, isolated rat hearts were reperfused for 30 mins with Krebs-Henseleit solution alone (control, n = 8), or with the addition of equipotent doses of epinephrine 1 microM (n = 8), dobutamine 0.3 microM (n = 8), or phenylephrine 50 microM (n = 8). In a second experiment, an alpha-1 antagonist, prazosin was given with phenylephrine to block the presumed alpha-1 agonist effect of phenylephrine.

MEASUREMENTS AND MAIN RESULTS

A constant volume balloon was placed in the left ventricle to measure LV pressure and derived parameters of LV function. Adenine nucleotide concentrations were derived at various time points using high-performance liquid chromatography. During reperfusion, the phenylephrine group had significant improvement in LV function and cardiac efficiency in contrast to epinephrine and dobutamine. Total adenine nucleotides tended to be highest in the phenylephrine group with significant increases in adenosine diphosphate and adenosine monophosphate and no significant loss of adenosine triphosphate. The phenylephrine-induced increase in heart rate and developed pressure could be blocked with an alpha-1 antagonist, prazosin.

CONCLUSIONS

In the isolated reperfused heart, phenylephrine, mediated by alpha-1 agonism, significantly improves postischemic LV dysfunction without worsening the overall myocardial metabolic state.

Managing the post-resuscitation patient in the field

The principal goal after successful resuscitation of a cardiac arrest patient is to maintain the patient's pulse and avoid a pulseless state. Of equal importance in the post-resuscitation patient are efforts to prevent myocardial dysfunction and increase the likelihood of a good neurologic outcome. To optimize cardiac and hemodynamic resuscitation, paramedics should obtain good background information, which could provide clues to factors contributing to the cardiac arrest, such as the use of certain drugs or being overdue for dialysis, and could aid in customizing therapy for rhythm disturbances and hemodynamic aberrations. Treatment of rhythm disturbances depends on the type of arrhythmia identified, the history of present illness, and the resuscitation efforts provided. Common post-resuscitation dysrhythmias are wide-complex tachycardia, narrow-complex tachycardia, and bradycardia. Optimizing neurologic resuscitation is difficult, but evidence suggests that hypertensive reperfusion, hemodilution, and mild hypothermia may be of benefit in improving neurologic outcome after resuscitation. Unfortunately, to date, no proven therapies are available to improve neurologic outcome after resuscitation from cardiac arrest.

Bench to bedside: resuscitation from prolonged ventricular fibrillation

Ventricular fibrillation (VF) remains the most common cardiac arrest heart rhythm. Defibrillation is the primary treatment and is very effective if delivered early within a few minutes of onset of VF. However, successful treatment of VF becomes increasingly more difficult when the duration of VF exceeds 4 minutes. Classically, successful cardiac arrest resuscitation has been thought of as simply achieving restoration of spontaneous circulation (ROSC). However, this traditional approach fails to consider the high early post-cardiac arrest mortality and morbidity and ignores the reperfusion injuries, which are manifest in the heart and brain. More recently, resuscitation from cardiac arrest has been divided into two phases; phase I, achieving ROSC, and phase II, treatment of reperfusion injury. The focus in both phases of resuscitation remains the heart and brain, as prolonged VF remains primarily a two-organ disease. These two organs are most sensitive to oxygen and substrate deprivation and account for the vast majority of early post-resuscitation mortality and morbidity. This review focuses first on the initial resuscitation (achieving ROSC) and then on the reperfusion issues affecting the heart and brain.

Myocardial protection during ventricular fibrillation by reduction of proton-driven sarcolemmal sodium influx

Although the inhibition of proton-driven sarcolemmal sodium influx ameliorates ischemic injury in the quiescent myocardium, the effects when ventricular fibrillation is present are largely unknown. We used an isolated rat heart model to investigate whether inhibition of the sodium-hydrogen exchanger isoform-1 (with the benzoylguanidine derivatives HOE-694 and cariporide) with or without concomitant inhibition of the sodium-bicarbonate co-transporter (with perfusate buffered with N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid [HEPES]) during ischemia and ventricular fibrillation could ameliorate functional myocardial abnormalities presumed to limit cardiac resuscitability. Ischemic contracture, which typically develops during ventricular fibrillation, was ameliorated by HOE-694 when either a bicarbonate-buffered (20 +/- 7 mm Hg vs 15 +/- 5 mm Hg, P <.05) or a HEPES-buffered (14 +/- 5 mm Hg vs 10 +/- 3 mm Hg, P <.04) perfusate was used. Maximal amelioration occurred when cariporide and HEPES-buffered perfusate were used simultaneously (25 +/- 14 mm Hg vs 11 +/- 3 mm Hg, P <.01), and this was accompanied by lesser leftward shifts of the end-diastolic pressure-volume curves after defibrillation. Intramyocardial sodium increases of 76% during ischemia and ventricular fibrillation (P <.05) were ameliorated by the sodium-influx-limiting interventions. Thus interventions limiting sarcolemmal sodium influx during ischemia and ventricular fibrillation may facilitate successful resuscitation from ventricular fibrillation.

Effects of repetitive electrical shocks on postresuscitation myocardial function

Whereas myocardial cell injury can occur during electrical defibrillation proportional to the energy level of individual shocks, only minimal (or no) injury seems to develop when the energy is limited to the levels typically required to terminate ventricular fibrillation. During cardiac arrest, however, multiple shocks are often required to terminate ventricular fibrillation or to treat episodes that appear subsequently during the resuscitation effort or the postresuscitation interval. Concern exists because an inverse relationship has been reported between the number of electrical shocks delivered during cardiac resuscitation and both resuscitability and survival. Repetitive electrical shocks can alter diastolic function and prompt leftward shifts of the end-diastolic pressure-volume curves. Repetitive shocks may, therefore, contribute to the recently recognized phenomenon of postresuscitation myocardial dysfunction and hamper efforts to reestablish competent myocardial function after resuscitation. Thus, strategies aimed at limiting the number of electrical shocks during cardiopulmonary resuscitation are highly desirable. These may include real-time ventricular fibrillation waveform analysis to improve targeting of individual shocks and efforts (using mechanical and pharmacologic means) to render the myocardium more responsive to individual shocks and to promote greater electrical stability after successful defibrillation.

Transthoracic monophasic and biphasic defibrillation in a swine model: a comparison of efficacy, ST segment changes, and postshock hemodynamics

OBJECTIVE

Biphasic waveforms for transthoracic defibrillation (DF) have been tested extensively after brief (15 s) episodes of VF in animal models and in patients undergoing electrophysiologic testing. The purpose of this study was to compare the effects mono- and biphasic waveforms for DF on postdefibrillation ST segments and left ventricular pressure, markers of myocardial injury, after more extended periods of VF (30 and 90 s).

METHODS

21 anesthetized and instrumented swine were randomized to truncated exponential monophasic or biphasic waveform DF. VF was induced electrically and 30 s later, DF with the designated waveform was attempted with a shock dose of 200 J. If unsuccessful, 300 J and then 360 J were administered if necessary. Following return to control hemodynamic values and normalization of the surface ECG, VF was again induced and, after 90 s, DF was attempted as in the 30 s VF period. CPR was not performed during VF and each animal was countershocked with only one waveform for both VF episodes. Waveforms were compared for frequency of first shock defibrillation success, surface ECG indicators of myocardial injury (ST segment changes at 10, 20, and 30 s after countershock) and time to return to pre-VF hemodynamics after successful DF, an indicator of postshock ventricular function.

RESULTS

Successful first shock conversion rates at 30 and 90 s were 60 and 63% for monophasic and 64 and 82% for biphasic (NS). Biphasic DF after 30 s produced ST segment changes (measured 10 s after DF) in 1/10 animals while six of eight animals in the monophasic group showed ST segment changes (P=0.013). After 90 s of VF, ST segment changes were observed in 6/8 in the monophasic group and 2/10 in the biphasic group (P=0.054). Differences in the time to hemodynamic recovery (return to control peak left ventricular pressure) were not observed between biphasic and monophasic waveforms after 30 or 90 s of VF.

CONCLUSIONS

Monophasic and biphasic transthoracic defibrillation are equally effective in terminating VF of 30 and 90 s duration and restoring a perfusing rhythm. The biphasic waveform produced less ECG evidence of transient myocardial injury. However, there was no difference in the rate of return to control hemodynamics. ST segment changes following countershock of VF of brief duration are transient and of questionable significance.

Myocardial effects of repeated electrical defibrillations in the isolated fibrillating rat heart

OBJECTIVE

Although substantial myocardial cell injury has been reported after high-energy electrical defibrillation, only minimal injury with transient functional defects seems to develop at energy levels not exceeding those required to reverse ventricular fibrillation. Because multiple electrical shocks are often delivered in clinical settings during attempts to reverse ventricular fibrillation, we investigated the effects of repetitive shocks on postresuscitation myocardial dysfunction by using an isolated rat heart model of ventricular fibrillation.

DESIGN

Prospective and randomized.

SETTING

Cardiopulmonary resuscitation research laboratory.

SUBJECTS

Twenty-seven Sprague-Dawley rats.

INTERVENTIONS

Hearts were harvested and perfused at a constant flow of 10 mL/min by using a modified Krebs-Henseleit solution equilibrated with 95% oxygen and 5% CO2. Ventricular fibrillation (VF) was induced by a 0.05-mA current delivered to the right ventricular endocardium and the perfusate flow was stopped. After 10 mins, the perfusate flow was resumed at 20% of baseline flow and maintained for 15 additional minutes before returning to baseline flow after 25 mins of VF (VF25 mins). Twenty-seven hearts were randomized to receive from VF22 mins to VF25 mins either 0 epicardial shocks, 6 epicardial shocks, or 12 epicardial shocks.

MEASUREMENTS AND MAIN RESULTS

Isovolumic indices of left ventricular function were obtained by using a latex balloon advanced through the mitral valve into the ventricular cavity. After defibrillation, indices of contractile function rapidly returned to baseline without differences among groups. The isovolumic end-diastolic pressure, however, remained elevated throughout the postresuscitation interval. A left shift of the diastolic pressure-volume curves without changes in their slope was observed at 10 mins after resuscitation with partial return to baseline by 30 mins postresuscitation. The shifts were significantly greater in hearts that received 12 shocks.

CONCLUSIONS

These findings indicate that repetitive low-energy electrical shocks do not accentuate postischemic systolic dysfunction in the isolated fibrillating rat heart but adversely affect postischemic diastolic dysfunction by reducing the unstressed left ventricular end-diastolic volume.

Endothelin-1 vasoconstriction during swine cardiopulmonary resuscitation improves coronary perfusion pressures but worsens postresuscitation outcome

BACKGROUND

Vasoconstriction during cardiopulmonary resuscitation (CPR) improves coronary perfusion pressure (CPP) and thereby outcome. The combination of endothelin-1 (ET-1) plus epinephrine improved CPP during CPR compared with epinephrine alone in a canine cardiac arrest model. The effect of the combination on outcome variables, such as successful resuscitation and survival, has not been investigated.

METHODS AND RESULTS

Twenty-seven swine were randomly provided with 1 mg epinephrine (Epi group) or 1 mg epinephrine plus 0.1 mg ET-1 (ET-1 group) during a prolonged ventricular fibrillatory cardiac arrest. ET-1 resulted in substantially superior aortic relaxation pressure and CPP during CPR. These hemodynamic improvements tended to increase initial rates of restoration of spontaneous circulation (8 of 10 versus 8 of 17, P=0.12). However, continued intense vasoconstriction from ET-1 led to higher aortic diastolic pressure and very narrow pulse pressure after resuscitation. The mean pulse pressure 1 hour after resuscitation was 7+/-8 mm Hg with ET-1 versus 24+/-1 mm Hg with Epi, P<0.01. Most importantly, the postresuscitation mortality was dramatically higher in the ET-1 group (6 of 8 versus 0 of 8 in the Epi group, P<0.01).

CONCLUSIONS

These data establish that administration of ET-1 during CPR can result in worse postresuscitation outcome. The intense vasoconstriction from ET-1 improved CPP during CPR but had detrimental effects in the postresuscitation period.

The effects of biphasic and conventional monophasic defibrillation on postresuscitation myocardial function

OBJECTIVES

The purpose of this study was to compare the effects of biphasic defibrillation waveforms and conventional monophasic defibrillation waveforms on the success of initial defibrillation, postresuscitation myocardial function and duration of survival after prolonged ventricular fibrillation (VF).

BACKGROUND

We have recently demonstrated that the severity of postresuscitation myocardial dysfunction was closely related to the magnitude of the electrical energy of the delivered defibrillation shock. In the present study, the effects of fixed 150-J low-energy biphasic waveform shocks were compared with conventional monophasic waveform shocks after prolonged VF.

METHODS

Twenty anesthetized, mechanically ventilated domestic pigs were investigated. VF was induced with an AC current delivered to the right ventricular endocardium. After either 4 or 7 min of untreated ventricular fibrillation (VF), the animals were randomized for attempted defibrillation with up to three 150-J biphasic waveform shocks or conventional sequence of 200-, 300- or 360-J monophasic waveform shocks. If VF was not reversed, a 1-min interval of precordial compression preceded a second sequence of up to three shocks. The protocol was repeated until spontaneous circulation was restored or for a total of 15 min.

RESULTS

Monophasic waveform defibrillation after 4 or 7 min of untreated VF resuscitated eight of 10 pigs. All 10 pigs treated with biphasic waveform defibrillation were successfully resuscitated. Transesophageal echo-Doppler, arterial pressure and heart rate measurements demonstrated significantly less impairment of cardiovascular function after biphasic defibrillation.

CONCLUSIONS

Lower-energy biphasic waveform shocks were as effective as conventional higher energy monophasic waveform shocks for restoration of spontaneous circulation after 4 and 7 min of untreated VF. Significantly better postresuscitation myocardial function was observed after biphasic waveform defibrillation.

Myocardial effects of ventricular fibrillation in the isolated rat heart

OBJECTIVE

Ventricular fibrillation (VF) is known to increase myocardial oxygen requirements and to alter coronary vascular physiology. However, the significance of these effects during cardiac arrest and resuscitation is not well understood. A model was developed in the isolated rat heart to investigate the myocardial effects of VF during a simulated episode of cardiac arrest and resuscitation. We hypothesized that VF would intensify the severity of myocardial ischemia and consequently accentuate postischemic myocardial dysfunction.

DESIGN

Prospective and randomized.

SETTING

Research laboratory.

SUBJECTS

Twenty Sprague-Dawley rats.

INTERVENTIONS

Hearts were harvested and perfused at a constant flow rate of 10 mL/min using a modified Krebs-Henseleit solution equilibrated with 95% oxygen and 5% CO2. In five hearts, VF was induced by a 0.05-mA current delivered to the right ventricular endocardium. The perfusate flow was then stopped for a 10-min interval and resumed at 20% of baseline flow for another 10 mins. After 20 mins of VF, the perfusate flow was returned to baseline and a sinus rhythm reestablished by epicardial electrical shocks. The studies were randomized and included three additional groups to control for the effects of ischemia without VF (n = 5), the effects of VF without ischemia (n = 5), and the stability of the preparation (n = 5).

MEASUREMENTS AND MAIN RESULTS

Isovolumic indices of left ventricular function were obtained using a latex balloon advanced through the mitral valve and distended to an end-diastolic pressure of 10 mm Hg. The coronary effluent was collected from the right ventricular cavity. VF during myocardial ischemia was associated with a higher coronary effluent PCO2, increased coronary vascular resistance, and development of ischemic contracture as indicated by increases in left ventricular pressure from 9+/-3 to 33+/-6 mm Hg (p < .05). After defibrillation, contractility and relaxation rapidly returned to baseline values, whereas the isovolumic end-diastolic pressure remained elevated for 20 mins. These changes were much less prominent when ischemia was not accompanied by VF.

CONCLUSIONS

These findings indicate that VF may adversely affect myocardial ischemia by hastening the development of ischemic contracture, increasing coronary vascular resistance, and favoring the development of diastolic pump failure early after resuscitation from cardiac arrest.

Vasopressin versus epinephrine during cardiopulmonary resuscitation: a randomized swine outcome study

In animal models, vasopressin improves short-term outcome after cardiopulmonary resuscitation (CPR) for ventricular fibrillation compared to placebo, and improves myocardial and cerebral hemodynamics during CPR compared to epinephrine. This study was designed to test the hypothesis that vasopressin would improve 24-h neurologically intact survival compared to epinephrine. After a 2-min untreated ventricular fibrillation interval followed by 6 min of simulated bystander CPR, 35 domestic swine (weight, 25+/-1 kg) were randomly provided with a single dose of vasopressin (20 U or approximately 0.8 U kg(-1) intravenously) or with epinephrine (0.02 mg kg(-1) intravenously every 5 min). Ten minutes after initial medication administration (18 min after induction of ventricular fibrillation), standard advanced life support was provided, starting with defibrillation. Animals that were successfully resuscitated received 1 h of intensive care support and were observed for 24 h. Coronary perfusion pressures were higher in the vasopressin group 2 and 4 min after vasopressin administration (28+/-2 versus 18+/-1 mm Hg, P<0.01, and 26+/-3 versus 18+/-2 mm Hg, P<0.05, respectively). The vasopressin group tended to be successfully defibrillated on the first attempt more frequently (8/18 versus 3/17, P = 0.15). Return of spontaneous circulation (ROSC) was attained in 12/18 (67%) vasopressin-treated pigs versus 8/17 (47%) epinephrine-treated pigs, P = 0.24. Twenty-four hour neurologically normal survival occurred in 11/18 (61%) versus 7/17 (41%), respectively, P = 0.24. In conclusion, vasopressin administration during CPR improved coronary perfusion pressure, but did not result in statistically significant outcome improvement.

Experimental model of cardiovascular post-resuscitation syndrome--no effect of platelet activating factor antagonism

The cardiovascular instability seen in the reperfusion phase after resuscitation from cardiac arrest may contribute to secondary brain injury. The aim of the present study was to characterise post-resuscitation cardiovascular instability in an experimental model of cardiac arrest and to test if cardiovascular stability could be improved by pre-treatment with the platelet activating factor (PAF) antagonist BN52021. Ten anaesthetised pigs received pre-treatment with BN52021 before induction of ventricular fibrillation (arrest/BN52021 group), while ten animals received only the vehicle (arrest/vehicle group). After a non-intervention interval of 9 min, resuscitation was attempted. Resuscitated animals were observed for 5 h and compared to a sham arrest group of seven animals. The haemodynamic situation after resuscitation was characterised by a low cardiac output that was inadequate in relation to the oxygen demand, as reflected by a low mixed venous oxygen saturation. The arterial blood pressure was to some extent reduced and the filling pressures in both the right and left heart were increased, but urinary output was not reduced. The severe haemodynamic compromise was not adequately reflected by standard monitoring variables such as arterial blood pressure and urinary output. Pre-treatment with BN52021 was unable to improve any aspect of short-term survival or haemodynamic stability.

Measurement of myocardial contractility following successful resuscitation: quantitated left ventricular systolic function utilising non-invasive wall stress analysis

After successful resuscitation from cardiac arrest, prolonged contractile failure has been demonstrated in animal experiments. No systematic evaluation of myocardial contractility following successful resuscitation after human cardiac arrest exists. The aim of this study was to assess left ventricular contractility following human cardiac arrest with successful resuscitation. In 20 adult patients after cardiac arrest and in four control patients, the relation between meridional wall stress (MWS) and rate-corrected mean velocity of circumferential fibre shortening (Vcf(c)), a load independent and rate corrected index of left ventricular contractility was measured within 4 h after return of spontaneous circulation and after 24 h by means of transoesophageal echocardiography. As the normal values of Vcf(c) depend on MWS, a normal deviate (z) was calculated. A normal z-score is defined as 0+/-2, < -2 indicates reduced contractility, > + 2 increased contractility. Data are presented as median and the interquartile range (IQR). For the comparison of related samples the Wilcoxon sign test was used. In most patients after cardiac arrest contractility was severely impaired within 4 h after successful resuscitation [z - 7.0 (IQR - 8.9 - (-2.5))]. Contractility did not significantly improve within the observational period [z after 24 h - 3.7 (IQR - 7.9 - (-1.8))] (P = 0.3). The four control patients had normal left ventricular contractility on arrival (z 0.0, range - 0.9-0.8) and after 24 h (z 0.7, range - 1.5-2.7). In conclusion non-invasive wall stress analysis can be applied to quantitate systolic left ventricular function, which was severely compromised in most patients within the first 24 h after successful resuscitation. Whether depression of left ventricular function is caused by cardiac arrest itself or by the underlying disease remains speculative.

Postresuscitation left ventricular systolic and diastolic dysfunction. Treatment with dobutamine

BACKGROUND

Global left ventricular dysfunction after successful resuscitation is well documented and appears to be a major contributing factor in limiting long-term survival after initial recovery from out-of-hospital sudden cardiac death. Treatment of such postresuscitation myocardial dysfunction has not been examined previously.

METHODS AND RESULTS

Systolic and diastolic parameters of left ventricular function were measured in 27 swine before and after successful resuscitation from prolonged ventricular fibrillation cardiac arrest. Dobutamine infusions (10 micrograms.kg-1.min-1 in 14 animals or 5 micrograms.kg-1.min-1 in 5 animals) begun 15 minutes after resuscitation were compared with controls receiving no treatment (8 animals). The marked deterioration in systolic and diastolic left ventricular function seen in the control group after resuscitation was ameliorated in the dobutamine-treated animals. Left ventricular ejection fraction fell from a prearrest 58 +/- 3% to 25 +/- 3% at 5 hours after resuscitation in the control group but remained unchanged in the dobutamine (10 micrograms.kg-1.min-1) group (52 +/- 1% prearrest and 55 +/- 3% at 5 hours after resuscitation). Measurement of the constant of isovolumic relaxation of the left ventricle (tau) demonstrated a similar benefit of the dobutamine infusion for overcoming postresuscitation diastolic dysfunction. The tau rose in the controls from 28 +/- 1 milliseconds (ms) prearrest to 41 +/- 3 ms at 5 hours after resuscitation whereas it remained constant in the dobutamine-treated animals (31 +/- 1 ms prearrest and 31 +/- 5 ms at 5 hours after resuscitation).

CONCLUSIONS

Dobutamine begun within 15 minutes of successful resuscitation can successfully overcome the global systolic and diastolic left ventricular dysfunction resulting from prolonged cardiac arrest and cardiopulmonary resuscitation.