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Objective: To describe the change in survival and factors associated with survival during a 20 year period among patients suffering from out of hospital cardiac arrest and being hospitalised alive.
Patients: All patients hospitalised alive in the community of Göteborg after out of hospital cardiac arrest between 1 October 1980 and 1 October 2000 were included.
Methods: Patient data were prospectively computerised with regard to factors at resuscitation. Data on medical history and hospitalisation were retrospectively recorded. Patients were divided into two groups (the first and second 10 year periods).
Setting: Community of Göteborg, Sweden.
Results: 5505 patients suffered from cardiac arrest during the time of the survey. Among them 1310 patients (24%) were hospitalised alive. Survival (discharged alive) was 37.5% during the first part and 35.1% during the second part (NS). The following were independent predictors of an increased chance of survival: ventricular fibrillation/tachycardia as the first recorded rhythm (odds ratio (OR) 3.46, 95% confidence interval (CI) 2.36 to 5.07); witnessed arrest (OR 2.50, 95% CI 1.52 to 4.10); bystander initiated cardiopulmonary resuscitation (OR 2.00, 95% CI 1.42 to 2.80); the patient being conscious on admission to hospital (OR 6.43, 95% CI 3.61 to 11.45); sinus rhythm on admission to hospital (OR 1.53, 95% CI 1.12 to 2.10); and treatment with lidocaine in the emergency department (OR 1.64, 95% CI 1.16 to 2.31). The following were independent predictors of a low chance of survival: age > 70 years (median) (OR 0.65, 95% CI 0.47 to 0.88); atropine required in the emergency department (OR 0.35, 95% CI 0.16 to 0.75); and chronic treatment with diuretics before hospital admission (OR 0.59, 95% CI 0.43 to 0.81).
Conclusion: There was no improvement in survival over time among initial survivors of out of hospital cardiac arrest during a 20 year period. Major indicators for an increased chance of survival were initial ventricular fibrillation/tachycardia, bystander cardiopulmonary resuscitation, arrest being witnessed, and the patient being conscious on admission. Major indicators for a lower chance were high age, requirement for atropine in the emergency department, and chronic treatment with diuretics before cardiac arrest.
A large proportion of patients who die from ischaemic heart disease die outside hospital in sudden death.1 Only a minority of patients are successfully resuscitated and can be discharged alive from hospital.2,3
To increase survival among these patients the concept of the chain of survival has emerged.4 However, this chain (early access, early bystander cardiopulmonary resuscitation, early defibrillation, and early advanced cardiac life support) does not include the hospital care of initial survivors. Not much has been written about this aspect of the handling of these patients. Taking into account the vast variations in reported hospital survival,5,6 we believe that more attention must be paid to the “fifth link” to view a complete chain from early access to hospital discharge.
This article describes experiences in the community of Göteborg over 20 years with regard to treatment, outcome, and predictors of outcome among patients hospitalised alive after out of hospital cardiac arrest. Our hypothesis was that among patients hospitalised alive after out of hospital cardiac arrest there would be an increase in survival to discharge over time and that factors associated with survival can be defined from history, factors at resuscitation, and status on admission to the emergency department. We have previously described this database in a preliminary report in 19947 and in a comparison of outcome between women and men in 1999.8
Since 1974, the municipality of Göteborg has had an area of 455 km2, excluding areas of water. The population increased from 427 644 to 457 400 between 1980 and 1996. Of the total population, 49% are men. The age distribution of the population is as follows: 0–4 years, 6.1%; 5–14 years, 10.6%; 15–24 years, 12.9%; 25–34 years 17.8%; 35–44 years, 13.5%; 45–54 years, 13.0%; 55–64 years, 8.8%; 65–74 years, 8.4%; 75–84 years, 67%; and > 85 years, 2.2% (1996 data).
In 1990, there were 5108 deaths in Göteborg, 1360 of which were attributable to ischaemic or coronary heart disease (International classification of diseases, injuries and causes of death codes 410–414).
All the ambulances were dispatched by one ambulance centre according to a two tier system—that is, for each call judged to be for a cardiac arrest, a mobile coronary care unit, if available, and the nearest standard ambulance were dispatched simultaneously. The proportion of patients reached by both tiers was similar during the two periods, nearly 100%. All patients suffering an out of hospital cardiac arrest arrived at one of the two city hospitals in Göteborg.
Selection for admission to one or the other hospital was based purely on geographical criteria.
Patients suffering an out of hospital cardiac arrest between 1 October 1980 and 1 October 2000 were included in the survey, regardless of the cause of the arrest and the patient’s age. Data on the entire cardiac arrest cohort were obtained from the Göteborg emergency medical service. Patients were excluded if the emergency medical service did not attempt resuscitation. Further medical data on patients admitted to hospital were obtained from hospital records and general practitioners’ records. Information was gathered similarly for the two hospitals and for the two time periods. All the patients admitted alive to hospital were identified. The patients were recruited from the same municipality and resuscitated by the same emergency medical service but they were taken to one of the two city hospitals in the municipality of Göteborg: Sahlgrenska Hospital or Östra Hospital.
Being hospitalised alive was defined according to the Utstein criteria—that is, the patient had to be alive when admitted to a hospital ward.
There were no guidelines for treatments and investigations in any of the two hospitals.
Rules for starting resuscitation and stopping resuscitation in the field did not change over time. The ambulance staff were only allowed to stop resuscitation after continuous asystole for 30 minutes with no sign of respiration or circulation.
In the correlation analyses Pitman’s test was used.9 All the analyses were performed using the Statistical Analysis System (SAS Institute Inc, Cary, North Carolina, USA). For comparison of dichotomous variables between groups Fisher’s exact test was used, which is a special form of Pitman’s test. For multivariate analysis, a stepwise logistic regression procedure was used. In the multivariate analysis of factors up to and including hospital admission, only those for which information was missing for < 15% of patients were included in the model. Thus, the following were excluded from the multivariate analysis: history of smoking and interval between collapse and arrival of an ambulance.
All significance tests were two tailed. Because of the large number of p values calculated no formal significance level is stated. In the tables only p < 0.05 is denoted. To compare differences in outcome over time, patients were divided into groups with an equal time of inclusion—that is, two 10 year periods. Thus, the cut off date was 31 October 1990, which means that the first time interval was 31 October 1980 to 31 October 1990 and the second time interval was 31 October 1990 to 31 October 2000.
In all, 1310 patients (24%) of 5505 patients suffering from out of hospital cardiac arrest were admitted alive to hospital during the time of the survey. During period 1, there were 670 admittances and during period 2 there were 639. Among all 5505 patients the mean (SD) age during period 1 was 65 (17) years compared with 68 (16) years during period 2 (p < 0.0001). During period 1 the response time—that is, the time between cardiac arrest and arrival of the ambulance—was 6.4 (5.5) minutes compared with 6.3 (4.9) minutes during period 2 (NS). During period 1 the mean interval between cardiac arrest and defibrillation was 9.4 (5.4) minutes compared with 6.7 (4.2) minutes during period 2 (p < 0.0001). The remaining part of the survey included only patients hospitalised alive.
Patients during the second period were older but had a lower prevalence of previous acute myocardial infarction, angina pectoris, congestive heart failure, and smoking (table 11).
There was a decrease in the proportion of patients chronically treated with digitalis and diuretics and an increase in the proportion chronically treatment with aspirin and angiotensin converting enzyme inhibitors (table 22).
During the second period fewer patients were found in ventricular fibrillation/tachycardia (table 33).
There was a slight decrease in the proportion of patients requiring assisted breathing (table 44).). Ongoing cardiopulmonary resuscitation was used less frequently during the second study interval. Defibrillation and treatment with various medications were also required less frequently.
Despite these changes over time in the characteristics of patients being admitted alive to hospital after out of hospital cardiac arrest, the proportion of initial survivors who were discharged from hospital did not change (37.5% during period 1 and 34.5% during period 2).
There were pronounced changes in the use of various investigational procedures and treatments (table 55).). Thus, there was an increase in the use of echocardiography, thrombolysis, percutaneous transluminal coronary angioplasty, and implantable cardioverter defibrillators. On the other hand, there was a decrease in the use of exercise test, electrophysiological testing, and Holter monitoring.
As table 66 shows, a large number of factors (age, previous history, chronic medication before cardiac arrest, events at resuscitation, and status on admission to hospital) were associated with the chance of surviving to hospital discharge.
The following were independent predictors of an increased chance of survival: chronic treatment with diuretics and antidiabetics before hospital admission, initial ventricular fibrillation/tachycardia, bystander cardiopulmonary resuscitation, witnessed cardiac arrest, consciousness on admission to hospital, sinus rhythm on admission to hospital, and requirement for atropine and lidocaine in the emergency department (table 77).
A separate analysis of the interval between cardiac arrest and arrival of an ambulance found that a prolonged interval (defined as > 5 minutes) was inversely related to survival (odds ratio (OR) 0.85, 95% confidence interval (CI) 0.80 to 0.91, p < 0.0001).
In a further separate analysis treatment with thrombolysis was included in the model. Such treatment was an independent predictor of increased survival (OR 4.26, 95% CI 1.49 to 12.13, p = 0.007).
This is the largest sample published so far of patients who were hospitalised alive after out of hospital cardiac arrest from a well defined area. We found that among patients who were hospitalised alive after out of hospital cardiac arrest, a little more than one third were discharged alive. Previous studies indicate that this figure varies between 12–68%.5,10–15 Today we do not know anything about why survival rates differ between hospitals. In a paper from Scotland15 evaluating patients admitted to two different hospitals, the short term outcome was better among patients admitted to one of the hospitals. Witnessed arrest, bystander cardiopulmonary resuscitation, and shorter ambulance response times were assumed to contribute to the prognosis. There have been some indications from our own group that a more ambitious evaluation of these patients while in hospital may be associated with an increased survival.16
Very few studies have determined whether characteristics of this patient population change over time. In a paper on patients with out of hospital ventricular fibrillation, Cobb and colleagues17 also noted an increase in mean age over time among hospital survivors. Hospital survival did not change over time. We found that in the latter part of the survey patients were older and less frequently had ventricular fibrillation/tachycardia as the initial rhythm. Although this is in agreement with the overall finding of our patients suffering from out of hospital cardiac arrest and where cardiopulmonary resuscitation efforts were attempted,18 the finding of a greatly reduced proportion over time of patients with ventricular fibrillation as the first noted arrhythmia is somewhat puzzling under these circumstances. Changes in comorbidity favour period 2, and there are no significant differences in ambulance activation times, in proportions of bystander cardiopulmonary resuscitation, or in shares of witnessed arrests. One may speculate about the effect of age on initial arrhythmia in our population. Despite these observations we did not find any indication that the patients in the second part of the survey had more risk indicators in terms of medical history. With regard to status on admission to hospital we found that ongoing cardiopulmonary resuscitation was less frequent in the second part of the survey.
In terms of treatment and investigational procedures we found an increased rate of echocardiography, thrombolysis, percutaneous transluminal coronary angioplasty, and implantable cardioverter defibrillator implantation during the second part of the survey. This was an expected finding. However, as previously reported, there was a discrepancy between the two hospitals: more investigations were carried out in one of the hospitals than in the other.16 There was no indication of an increased survival during the hospital phase during the second part of the survey. This was a disappointing finding. The increase in various interventions may have been too small to have any major impact on survival. However, one can assume that, to have a major impact on survival in hospital, the intervention must take place very soon after admission to hospital. Although thrombolysis and the majority of percutaneous transluminal coronary angioplasty procedures were used early, internal defibrillators were implanted later in the course of hospitalisation.
Therefore, the variables in table 55 were not included in the multivariate analysis. In a separate analysis that included thrombolysis in the multivariate model, such treatment was associated with an increase in survival. However, one must take care in interpreting these data because of the low number of patients receiving the treatment and because we do not know whether all patients received the treatment immediately after admission to hospital. However, our data indicate that an increased use of thrombolysis may increase survival among patients hospitalised after out of hospital cardiac arrest.
We found nine major contributors to an increased or decreased chance of survival:
We found one further factor indicating an adverse outcome with borderline significance in multivariate analysis:
The data collected during the two time periods were of uniform quality. Discrepancies in the number of patients with missing information is a result of variability in data availability in the medical journals.
Analysis of the initial survivors of out of hospital cardiac arrest over 20 years found no improvement in survival over time. Major indicators of an increased chance of survival were initial ventricular fibrillation/tachycardia, bystander cardiopulmonary resuscitation, witnessed arrest, and consciousness on admission. Major indicators of a lower chance of survival were advanced age and requirement of atropine in the emergency department and chronic treatment with diuretics before the cardiac arrest.
This study was supported by grants from the Swedish Heart and Lung Foundation, Stockholm, Sweden.