Thoracoscore fails to predict complications following elective lung resection

RESULTS

A total of 703 patients who underwent surgery in a single institution were analysed. The median (IQR) age was 68 (14–89) yrs and 57% were male. The following procedures were performed: lobectomies (n=385, 55%), wedge excisions (n=158, 22%), pneumonectomies (n=67, 10%), segmentectomies (n=42, 6%), explorations (n=31, 4%) and sleeve resections (n=20, 3%). 641 (91%) patients underwent surgery for primary lung cancer. The median (IQR) FEV₁ was 2.00 (0.40–4.65) and FVC was 3.09 (0.48–6.05). Patients’ characteristics are presented in table 2.

There were 16 (2%) in-hospital deaths and all but two were secondary to pulmonary complications. A total of 128 (18%) patients experienced PPCs and had a longer length of stay (11 (8–23) days) compared to patients who did not develop a PPC (5 (4–7) days). Patients who developed a PPC also had a higher rate of ITU admission: 14% versus 2%.

The median (IQR) predicted in-hospital mortality based on the Thoracoscore for those patients who died was 4.1 (2.3–5.7)% and for the remaining patients was 2.3 (1.3–4.1)%. The predicted risk of mortality from the Thoracoscore was considerably higher than the observed mortality within each Thoracoscore risk group (table 3). The Thoracoscore was not a significant predictor of mortality in a logistic regression analysis (OR 1.07, 95% CI 0.99–1.17; p=0.11). The area under the ROC curve for the Thoracoscore in this population was 0.68 (95% CI 0.56–0.80) for predicting mortality, indicating limited discriminative ability. The Hosmer and Lemeshow goodness of fit test was not statistically significant (Chi-squared=11.32, degrees of freedom (df)=8, p=0.18), suggesting there may be adequate calibration but the R² measure of goodness of fit of 0.0028 indicates poor predictive ability. The predicted risk of mortality increases with increasing Thoracoscore risk group (table). The factors showing disparity between the patients who died and those who were alive were sex (p=0.003), chronic obstructive pulmonary disease (COPD) (p=0.03) and type of operation (p=0.06) (table 2). The number of events was too small to perform a reliable multivariate analysis.

The median (IQR) predicted mortality rate based on the Thoracoscore was higher for those patients who had a PPC (3.2 (2.0–4.8)%) than for patients without PPCs (2.3 (1.2–4.1)%). The Thoracoscore was a significant predictor of PPCs in a logistic regression analysis (OR 1.08, 95% CI 1.03–1.13; p=0.002). However, the area under the ROC curve for the Thoracoscore in this population was 0.64 (95% CI 0.59–0.69) for predicting PPCs, indicating unsatisfactory discriminative ability. The Hosmer and Lemeshow goodness of fit test was statistically significant (Chi-squared=17.78, df=8, p=0.02), suggesting poor calibration and an R² measure of goodness of fit of 0.013 indicates relative poor predictive ability. The predicted risk of PPCs from the logistic regression analysis is higher in the high-risk group based on the Thoracoscore (table 4).

The median (IQR) predicted in-hospital mortality based on the ESOS score for those patients who died was 3.4 (2.6–4.2)% and for the remaining patients was 1.9 (1.2–3.1)%. The predicted risk of mortality is similar to the observed mortality and was highest for the patients in the high-risk group based on the ESOS score (table 3). The ESOS score was predictive of mortality in a logistic regression analysis (OR 1.43, 95% CI 1.11–1.83; p=0.006). It had good discriminative ability (area under the ROC curve 0.73, 95% CI 0.62–0.85) and adequate calibration (Hosmer and Lemeshow goodness of fit test Chi-squared=8.37, df=8, p=0.40), but poor predictive ability (R²=0.009).

The median predictive mortality rate based on the ESOS score for those patients who had a PPC was 3.1 (7–4.0)% and for the patients without a PPC was 1.8 (1.1–2.2)%. The ESOS score was a significant predictor of PPCs in a logistic regression analysis (OR 1.48, 95% CI 1.30–1.68; p<0.0001). However, it had limited discriminative ability (area under the ROC curve 0.68, 95% CI 0.63–0.73), poor calibration (Hosmer and Lemeshow goodness of fit test Chi-squared=15.75, df=8, p=0.05) and limited predictive ability (R²=0.05). The predicted risk of PPCs from the logistic regression analysis is higher in the ESOS high-risk group than the other risk groups but differed from the observed PPC rates (table 3).

Univariate analysis of factors in patients with PPCs compared with those without PPCs are shown in table 5. Fitting a stepwise multivariate logistic regression identified that having COPD (p<0.0001), an ASA score of 3 or 4 (p=0.002), a dyspnoea score of 3 (p=0.004), high creatinine levels (>2 mg·dL⁻¹; p=0.002) and smoking (p=0.02) as the most important independent factors for predicting PPCs in this dataset (table 6). The area under the ROC curve was 0.74 (95% CI 0.69–0.79), suggesting good discriminatory ability. The Hosmer and Lemeshow goodness of fit test was not statistically significant (Chi-squared=3.37, df=6, p=0.76), indicating good calibration and an R² of 0.11 indicates reasonable predictive ability. Physical activity was not significant after fitting COPD, ASA, creatinine and dyspnoea into the model. Sensitivity analysis was performed to assess the impact of the missing physical activity data on the logistic regression model and results were such that after multiple imputation physical activity was not an independent predictor of PPCs.

DISCUSSION

Thoracoscore is a model with good accuracy to predict in-hospital and mid-term mortality after all types of general thoracic surgery [1, 4]. The new BTS guidelines have incorporated Thoracoscore into the selection for elective surgery for lung cancer [3]. Its applicability in this situation is uncertain. For example, it bundles together a minimally invasive keyhole procedure (removing <1% of lung function) with the same risk as a bilobectomy open surgery (removing one-third of lung function). Similarly the number of patients with poor performance status and/or breathlessness who would be selected for elective lung resection is very small, but these are important factors defining risk in the original cohort. In this study, Thoracoscore has limited discriminative and poor predictive ability for mortality following elective lung resection. There is a trend for Thoracoscore to underestimate risk in low-risk cases and overestimate risk in high-risk cases.

The ESOS score is a model developed to identify pre-operative risk factors associated with mortality after lung resection surgery [2]. The score is defined by age and post-operative predictive FEV₁. Interestingly this factor was not a significant risk factor but the authors chose to use this measure as it could be clearly defined. It is difficult to define how well the objective model performed in the defining cohort because no solid data is presented on this in the original publication. The ESOS, in contrast to Thoracoscore, in our population was a more significant predictor of mortality and had better discriminative, but still poor, predictive ability.

The variation of expected and observed mortality in both ESOS and Thoracoscore might not be considered relevant clinically. This raises the issue of the importance to the patient of such defined mortality values. These numbers might be of use in research and outcome assessment, but quoting a range of risk to patients might be more appropriate and easier to comprehend.

The risk of in-hospital mortality is a rare occurrence; perhaps what is of more relevance to patients is the development of more common complications such as PPCs. Both the Thoracoscore and ESOS had limited discriminative and predictive ability and poor calibration, providing predictions for PPC that were too low following elective lung resection. At first glance, observed PPC rates appear misleadingly similar to rates predicted using the Thoracoscore or ESOS. However, the patients who actually develop PPCs are not the ones predicted to do so by these scores. The poor model performance of these scores may be a consequence of their development for predicting mortality and not PPCs.

Factors identified as independently associated with a risk of developing PPCs were COPD, ASA, smoking, high dyspnoea score and pre-operative blood creatinine. Pre-operative self-reported exercise capacity (unavailable in 26%) was found not to be a significant predictor of PPCs once other factors were included in the multivariate logistic regression model sensitivity analysis. Using these significant factors in a regression model resulted in good predictive and discriminatory ability. PPCs are associated with patient morbidity and prolonged length of hospital stay. Thus, a predictive model that could identify those at high risk of PPCs would help to target preventative strategies, such as pre-operative rehabilitation.

By the time a scoring system finds its way into clinical practice it can already be out of date. A revised Thoracoscore (EPITHOR) for predicting in-hospital mortality specifically in cancer patients has been developed [10] since the publication of the new BTS guidelines and the development of our study. The EPITHOR score was not a significant predictor of mortality (OR 1.23, 95% CI 0.90–1.68; p=0.19) and had poor discriminative ability (area under the ROC curve 0.61, 95% CI 0.46–0.76) in our cohort of patients.

In addition, the ESOS has also been updated [11]. The European Society for Thoracic Surgery mortality score was more predictive of mortality (OR 2.33, 95% CI 1.24–4.37; p=0.008) than the ESOS score but the discriminative ability was slightly worse (area under the ROC curve 0.68, 95% CI 0.54–0.82). Therefore, a large national study is required to corroborate the findings from this study, and provide a validation of these new scores and a comparison of all scores in order to be able to inform and update the BTS guidelines.

In the new BTS guidelines much emphasis is placed on putting the risk of mortality to the patients to help them decide on surgery. By using a scoring system that inaccurately assesses mortality and morbidity are we unknowingly misleading patients rather than improving consent?