Identifying which septic patients have increased mortality risk using severity scores: a cohort study

Ninewells Hospital is an 860-bedded, tertiary, teaching hospital serving the Scottish region of Tayside, which has a population of approximately 400,000. In this cohort study we retrospectively analysed data that had been collected prospectively. We identified patients who developed sepsis while inpatients in Ninewells Hospital in two cohorts, from September 2008 to February 2009 and October 2009 to March 2010, as part of a larger quality improvement project [18]. The study case definition was: an adult (≥18 years old) patient with sepsis occurring ≥24 h after admission to hospital, either as a first episode of sepsis or following a period of ≥24 h without meeting SIRS criteria. Patients with immune compromise due to chemotherapy or organ transplant were excluded. For the first cohort we screened patients who had blood cultures taken while in any hospital ward except paediatrics, obstetrics, haematology, oncology, acute admissions units, and the accident and emergency department, to identify patients meeting the study case definition. In pilot work, we demonstrated that screening patients who had blood cultures taken (regardless of whether positive or negative) had good performance characteristics for identifying patients with sepsis [18]. For the second cohort we restricted screening to general medical, general surgical, and orthopaedic wards (due to the design of the improvement project), which included 22 of the 30 wards screened for the first cohort.

The prospectively collected clinical data, which included the patient’s clinical measurements at sepsis onset, comorbidity, and demographics, were anonymised in a study database, with a Charlson Index of comorbidity [19] calculated for each patient. We linked these to routine data via the Health Informatics Centre (HIC), University of Dundee, using patients’ unique community health index (CHI) numbers. The Scottish Morbidity Record (SMR) databases accessed for this study were: SMR01 general acute inpatient and day case discharges, General Register Office for Scotland (GRO) death registrations, and the NHS Tayside Microbiology database. We obtained blood culture results and a Scottish Index of Multiple Deprivation (SIMD) quintile [20] for all patients and dates of all deaths up to 90 days after the end of data collection. Because the cohort included mainly older adults, we defined the age groups as <60 yrs, 60-69 yrs, 70-79 yrs and ≥80 yrs for analysis. We categorised blood culture results, from seven days before to seven days after sepsis onset, as positive, probable contaminant, or negative. The categorisation of isolated organisms was done by two Infectious Diseases physicians (CM and PD, authors) and a consultant microbiologist (GP, acknowledgements) (see Additional file 2: Table S2 for how we classified the isolated organisms). Patients were grouped according to their “most positive” blood culture result, so a patient with a positive culture and a probable contaminant was grouped as positive, and a patient with a probable contaminant and a negative culture was grouped as probable contaminant. In classifying sepsis severity, when the data item required for a severity criterion was not available we classified the patient as not meeting that criterion. This risked underestimating severity but reflected real-life performance of the criteria. For all definitions of severe sepsis, organ dysfunction must be new and distant from the site of infection, so we took comorbidity, previous blood results, and the site of infection into account when classifying severity criteria.

We calculated 30 and 90 day mortality and used binary logistic regression to examine associations with age, gender, SIMD quintile [20], Charlson Index of comorbidity [19], admission type, ward type at sepsis onset, length of inpatient stay prior to sepsis onset, blood culture result, and by sepsis severity according to each set of criteria, with results reported as odds ratios (OR) with 95% confidence intervals (CI). We then used multivariate regression to adjust for variables associated with mortality in univariate analysis (p < 0.10). Each set of severity criteria was analysed in a separate multivariate model due to overlaps in criteria.

For all data management and analysis we used Microsoft Access 2007 and SPSS Statistics 17.0.

The study was approved by the Tayside Medical Research Ethics Committee A, who deemed that informed consent was not required as data were observational, extracted from routine care records, and anonymised for analysis. The Caldicott Guardian for inpatients gave permission to access the data.

There were 339 eligible patients in the first cohort and 302 in the second cohort. The two cohorts were the same in terms of age, gender, Charlson Index of comorbidity, and SIRS criteria (Chi-squared tests p > 0.2 for each comparison) so they were combined. Outcome data were missing for one patient, leaving 640 patients for analysis. Death within 30 days of sepsis onset occurred in 124/640 (19.4%, 95% CI 16.3-22.4%) patients. A further 56 patients died between 31 and 90 days, meaning 90 day mortality was 28.1% (180/640, 95% CI 24.6-31.6%). Mean survival among those who died within 90 days was 24.0 days (95% CI 20.8-27.2), and median survival 16.5 days (interquartile range (IQR) 7.0-36.0). Distribution of the cohort by demographic and clinical characteristics and six sets of severity criteria, along with the mortality in each variable category, are given in Table 2. The minimum number of SIRS criteria was two because of the sepsis case definition. Of note, in 24% (150/633) of cases blood cultures were positive, in 66% (418) they were negative and in the remaining 10% (65) a probable contaminant organism was isolated (Table 2 and Additional file 2: Table S2).

In univariate logistic regression analysis, increasing age and comorbidity were associated with increased mortality. Having been admitted as an emergency, longer stays in hospital prior to sepsis onset, and being in a medical ward, were also each associated with increased mortality, but blood culture results had little association. Higher scores against all six sets of severity criteria were associated with increased mortality, but the SEWS score was least, and CURB65 most, discriminant (Table 2).

Gender and SIMD were excluded from multivariate analysis due to lack of association in univariate analysis. Other variables were included in the adjusted models for the severity criteria, except age was excluded from the CURB65 model because age forms part of the score. Older age remained associated with increased mortality after adjustment in all other models. Associations between comorbidity and death were much weaker, and only significant for 90 day mortality with Charlson Index ≥3 in some models (OR 1.73-2.13, p 0.03-0.09, across all models). Having been admitted as an emergency remained associated with increased 30 day mortality (OR 3.82-4.35, p ≤ 0.02 in all models). Being in a surgical, or orthopaedic, ward at sepsis onset was associated with lower adjusted 30 day mortality compared to being in a medical ward (OR 0.44-0.49, and 0.17-0.26, respectively across all models, p < 0.01 in all instances). Having an inpatient stay of >21 days before sepsis onset was also still associated with increased 30 day mortality (OR 2.81-3.10, p < 0.01 in all models) (data not shown). Blood culture results had no association with mortality in the adjusted models.

All sets of severity criteria were significantly associated with mortality in adjusted models (Table 3). For SIRS criteria and SEWS scores, associations with mortality were only significant in the highest category, and only at 30 days. Each increase in CURB65 score had a stepwise increase in the adjusted odds of death, with scores of three or more having 12 times increased risk of death compared to a score of zero (Table 3). The other three sets of severity criteria all had significant associations with mortality (Table 3), with similar odds ratios to those in the univariate models (Table 2).

The performance characteristics for predicting 30 day mortality for each set of severity criteria are given in Table 4, including the mortality among those below the best cut-off value for each. SIRS criteria (cut-off of ≥3) had reasonable sensitivity, but had the lowest specificity of all criteria (Table 4). The SEWS score (cut-off ≥4) was more specific but at the expense of sensitivity. The CURB65 score (cut-off ≥2) performed best, with PPV almost as good as any other set of criteria and much stronger other performance characteristics (Table 4). CURB65 had the lowest mortality among patients below the cut-off, and the biggest difference between those above and below it (29% versus 8%). The other three sets of criteria had very similar performance characteristics, due to similar inclusion criteria (Table 4).

The AUROC with 95% CIs for each set of severity criteria, for 30 and 90 day mortality, are given in Table 4. The ROC curves for 30 day mortality are given in Figure 1 and Figure 2. CURB65 had the largest AUROC at 0.72 for both 30 and 90 day mortality. The other severity criteria had AUROC between 0.60 and 0.63 at 30 days, and 0.57 and 0.61 at 90 days (Table 4). Of the existing criteria, the CURB65 score performed best so we used it to test whether performance improved further with the addition of clinical variables that were significantly associated with mortality in the adjusted regression analysis. Thus, we allocated a point for each of: emergency admission; admitted ≥21 days prior to sepsis onset, and; medical ward at sepsis onset. Adding each of these points to the CURB65 score in different combinations resulted in small increases in AUROC (detailed in Additional file 3: Table S3). The addition of all three resulted in an AUC of 0.77 for both 30 and 90 day mortality (see Additional file 3: Table S3).