The impact on risk-factor analysis of different mortality outcomes in COPD patients

Study population

The study population was enrolled from the HDR and were residents of the Lazio region of Italy (∼5 million inhabitants) aged ≥35 yrs and hospitalised for COPD between January 1, 1998, and November 1, 2000. The subjects were identified by the primary diagnosis (International Classification of Diseases 9th revision (ICD-9) 490.X, 491.X, 492.X, 494.X and 496.X 8) according to the information reported in the HDR. When more than one hospitalisation occurred in the study period, the first was chosen as the index hospitalisation. The clinical history of each patient was reconstructed based on hospital diagnoses from the previous 2 yrs.

Follow-up and mortality estimates

Mortality rates were followed-up for 30 days after admission using both the regional CMR and the HDR by means of an individual record-linkage; deaths reported in the HDR were identified for the index or subsequent hospitalisations. Follow-up started on the first day of the index hospitalisation; when the patient was discharged from another hospital on the same or previous day with a diagnosis of COPD (primary or secondary), follow-up started on the first day of the previous hospitalisation. Patients not listed in the CMR or in the HDR were assumed to be alive at the end of the study period.

For residents of Rome (Italy), vital status from each register was validated through information from the municipality register. The characteristics and underlying causes of death of patients who died in hospital and those who died after discharge were compared. Mortality rates were calculated as the number of deaths within 30 days after admission reported in each register over 1,000 patient-days; 95% confidence intervals (CI) were calculated according to a binomial distribution.

Factors associated with 30-day mortality and data analysis

Age, sex, place of residence (Rome versus residence anywhere else in the region) and years of education were analysed. Information on smoking habits and occupation were not available.

The admission ward was selected as an indicator of care quality 3. The hospital ward was categorised as appropriate for COPD treatment (pneumology and intensive care units (ICU)), acceptable (general medicine, geriatrics and casualty) or unsatisfactory (all others).

To account for the severity of patients’ conditions at the time of hospitalisation, information about comorbidities was obtained from the previous 2 yrs’ hospital records for: lung cancer and pneumoconiosis (ICD-9: 162, 505–506) 9; chronic heart failure (ICD-9: 428) 1; bronchopneumonia (ICD-9: 480–486) 10, 11; pulmonary embolism (ICD-9: 415.1) 12; respiratory failure (ICD-9: 518.8, 518.5, 786.0); kidney failure (ICD-9: 585) 13; and all cancers apart from lung cancer (ICD-9: 585, 140–239). Arrhythmias were added as a possible complication of β-agonists in COPD treatment 11. The conditions tested that were associated with risk of death in COPD patients, such as vascular and heart disease other than AMI and heart failure (ICD-9: 390–459, excluding 410, 415 and 428), central nervous system diseases (ICD-9: 320–349), traumas (ICD-9: 800-829) and poisonings (ICD-9: 960–979), were included in the analysis. The methodological indications of Charlson et al. 14, as modified by Deyo et al. 15, were followed in the present analysis.

The number of comorbidities, the number of hospitalisations that occurred in the previous 2 yrs and those with a diagnosis of respiratory failure, were used as quantitative indicators of patient condition severity. These indicators were included in the multivariable analysis one at a time due to the high colinearity between them.

The count of person-days of observation started on the first day of hospitalisation and ended with death on the 30th day. Survival analysis was carried out. The follow-up time (days) was divided into four intervals; the grouping was the result of a segmental regression analysis 16 of the relationship between daily mortality and follow-up time that identified the lowest mortality level on day 7. Poisson regression analysis was conducted to estimate relative risk of dying and 95% CI in univariable, as well as in multivariable, analysis as mortality rates differed in the follow-up intervals.

30-day mortality

Among 26,039 patients aged ≥35 yrs who were hospitalised with COPD between 1998 and 2000, 925 deaths (3.6% (95% CI 3.3–3.8%)) occurred within 30 days after admission according to the CMR; the mortality rate was 1.21·1,000 patient-days⁻¹ (95% CI 1.14–1.29). The follow-up carried out with the HDR detected 812 deaths (3.1% (2.9–3.3%)); the mortality rate was 1.06·1,000 patient-days⁻¹ (0.98–1.13). Both total and in-hospital mortality showed a similar decreasing trend in the follow-up period, but rates decreased more rapidly in the HDR follow-up (fig. 1⇓). In total, 62 in-hospital deaths were not listed in the CMR, and 175 were deaths not reported in the HDR. Only 17% of patients were hospitalised more than once and 0.3% of them died.

• Download figure
• Open in new tab
• Download powerpoint

Fig. 1—

Cumulative mortality after 30-days follow-up. –––––: follow-up by cause mortality register; ··········: follow-up by hospital discharge register.

Information on vital status was validated for 11,433 patients who were confirmed residents of Rome. Vital status as reported in the CMR had a sensitivity of 93.5% and a specificity of 99.97%; 38 patients who died according to the municipal register were not reported in the CMR, while three patients who were listed as dead in the CMR were still alive 30 days after admission. Vital status from the HDR had a sensitivity of 72.8% and a specificity of 99.99%.

Factors associated with 30-day mortality

When factors associated with total 30-day mortality in 925 subjects were analysed, age > 64 yrs, male sex, residency in Rome, being admitted to a ward other than pneumology or ICU, having at least one comorbidity or having been hospitalised at least twice in the previous 2 yrs were all associated with increased mortality (table 1⇓). The two quantitative indicators of patient severity predicted an increased risk of death proportional to the number of comorbidities and previous hospitalisations. (table 1⇓). The most frequent comorbidities reported in previous hospitalisations were chronic heart failure (7%), respiratory failure (9%), and vascular and heart diseases other than AMI and chronic heart failure (27%); however, lung cancer (odds ratio 2.17 (95% CI 1.25–3.75)), central nervous system diseases (2.06 (1.55–2.74)) and renal failure (1.98 (1.29–3.04)) were the strongest predictors of short-term mortality.

The multivariable analysis confirmed these results. However, the strength of the association was higher for sex and previous hospitalisation for respiratory failure, but weaker for age and comorbidities (table 2⇓).

The factors associated with in-hospital mortality were very similar to those observed for total short-term mortality, but a few differences were evident in terms of effect estimates for age, sex, education, residence and previous hospitalisations. A statistically significant association was not identified for sex, while the role of comorbidities became much more important in patients with more than two comorbidities and the risk of dying for residents in Rome increased. The mortality rate was the highest for the most poorly educated patients in total short-term mortality analysis and was the lowest based on HDR data (tables 1⇑ and 2⇑).

Characteristics of patients who died

Table 3⇓ shows the characteristics of the 750 patients who died in hospital and the 125 who died after hospital discharge; the 68 patients reported as dead by HDR only were not included in the comparison. Male patients, those who resided outside Rome, patients with the lowest education and those who had more than one hospitalisation in the previous 2 yrs were more likely to die after discharge than when hospitalised. In contrast, patients living in Rome, those who were well educated and those who had been not hospitalised in the previous 2 yrs were more likely to die in hospital than after discharge. No differences were observed for age, admission ward and comorbidities (table 3⇓).

Several differences were found in the underlying causes of death for patients who died when hospitalised and those who died after discharge (table 4⇓). COPD and all respiratory diseases were the most frequent causes of deaths for the former group of patients, while the most frequent causes of deaths were heart diseases, cancer and other vascular diseases for the latter group. Cerebrovascular diseases followed as the most frequent cause of death in both groups.

Factors associated with short-term mortality

Among the factors found to be associated with total 30-day mortality in COPD patients, being >64 yrs of age and male have already been reported 20, as has the presence of concomitant diseases 9–13. The increasing risk proportional to the number of comorbidities and to the number of previous hospitalisations has been less frequently reported; however, the exposure–effect relationship observed in the current study indicates, with some confidence, that these severity indicators are true risk factors for 30-day mortality. The higher risk for residents of Rome, a large city (2.5 million inhabitants) with significant air pollution problems, suggests a role of air pollution in increasing the risk of short-term mortality in COPD patients, as previously reported 21. The accuracy of the mortality data may be different in Rome with respect to other areas.

With regard to the indicators of care quality, in the absence of data about hospital organisation, the present authors can only hypothesise that the higher risk of death associated with wards other than pneumology, ICU and general medicine, are explained by the therapeutic protocols or the availability of adequate treatment. Comparing mortality between patients who died in hospital with those who died at home in different periods of the follow-up, the most relevant results are the higher mortality rate observed for patients who were hospitalised for only 1 week regardless of the place of death, and the higher proportion of patients who died at home than in hospital in week 2 of the follow-up. These results suggest a different risk profile for the two groups of patients; those who died in hospital in the first week were possibly too seriously ill to benefit from hospital treatment, while those who died at home in week 2 of follow-up possibly incurred treatment side-effects or complications not recognised during admission.

Other studies have pointed to different factors influencing mortality, including the volume of procedures 22. The current authors did not conduct this analysis because there was not enough evidence for an association between the number of patients and the outcomes for COPD 23.

Impact of using different short-term mortality measures on risk-factor analysis

The factors associated with in-hospital mortality were very similar to those observed for total short-term mortality, with a few important differences.

A selection of patients discharged before 30 days is the most probable explanation of most differences. The consequences of this selection are missing important associations, such as the increased risk for males, exaggerating the risk for residents of Rome and lowering the risk for having comorbidities and for having been hospitalised in the previous 2 yrs for conditions other than respiratory diseases.

Study limitations

The lack of information on other determinants of mortality in COPD patients, such as occupational exposure 24 and smoking 25, could have affected the accuracy of the present study. The lack of information regarding ventilation and the date the complications began enabled the current authors to analyse the role of these factors as possible risk factors in a prospective approach for the mortality observed later. Another problem is related to the method used to assess comorbidities. Although the method is widely employed, evaluating patient history for only 2 previous years may have misclassified patients with chronic underlying diseases.

Conclusion

In conclusion, in-hospital 30-day mortality is an underestimate of total 30-day mortality. It includes only 86.5% of all deaths and causes a selection of patients for sex, education level, residency and underlying condition severity. It was found that admission to wards that are not appropriate to treat respiratory diseases is the most important factor related to care management that is associated with 30-day mortality for chronic obstructive pulmonary disease patients. Older age, male sex and condition severity are the strongest risk factors among the individual characteristics. The present authors believe that it is vital to check for possible selection of discharged patients when in-hospital 30-day mortality is used as the preferred outcome in evaluating the quality of hospital care.