Abstract
Data on prognosis and predictors of overall survival in advanced lung cancer patients diagnosed following emergency admission (DFEA) are currently lacking.
We retrospectively analysed data from 771 patients with advanced nonsmall cell lung cancer between April 2004 and April 2012.
Of the 771 patients, 103 (13%) were DFEA. DFEA was not an independent predictor of overall survival by multivariate Cox proportional hazard models, whereas good performance status (PS), epidermal growth factor receptor gene mutation, stage IIIB, adenocarcinoma and chemotherapy were independent predictors of overall survival (hazard ratio (95% CI) 0.36 (0.29–0.44), p<0.001; 0.49 (0.38–0.63), p<0.001; 0.64 (0.51–0.80), p<0.001; 0.81 (0.67–0.99), p=0.044; and 0.40 (0.31–0.52), p<0.001, respectively). Good PS just prior to opting for chemotherapy, but not at emergency admission, was a good independent predictor of overall survival in DFEA patients (hazard ratio (95% CI) 0.26 (0.12–0.55); p<0.001).
DFEA is relatively common. DFEA and PS at emergency admission were not independent predictors of overall survival, but good PS just prior to opting for chemotherapy was an independent predictor of longer overall survival. Efforts to improve patient PS after admission should be considered vital in such circumstances.
Abstract
Efforts to improve performance status after admission are vital in patients diagnosed following emergency admission http://ow.ly/C3BDQ
Introduction
Lung cancer is the leading cause of cancer-related deaths worldwide [1, 2]. Nonsmall cell lung cancer (NSCLC) accounts for ∼80% of lung cancers, and the majority are already unresectable and metastatic upon their initial diagnosis [1, 2]. Some patients are admitted to hospital through the emergency department with lung cancer-associated symptoms, and this route to diagnosis, defined as the sequence of interactions between the patient and the healthcare system, has been well-studied in the UK. Indeed, about 40% of patients with lung cancer are diagnosed following an emergency admission (DFEA) to hospital, the highest percentage for any cancer, and survival is particularly poor in this group, most of whom have advanced disease [3]. DFEA is more common in women, and more likely with increasing age and deprivation [4, 5]. However, there are relatively few data on prognosis and prognostic factors in patients with advanced lung cancer DFEA. Additionally, the route to diagnosis differs among countries.
The clinical features of DFEA patients are heterogeneous. Although previous studies found that performance status (PS) was poorer in DFEA patients compared with non-DFEA patients, the reasons for emergency admission and the cause of poor PS vary [6]. Furthermore, we have experienced some DFEA patients whose PS was improved following non-chemotherapeutic supportive care after emergency admission, such as radiation therapy, drainage of fluid or antibiotics [7–9]. Understanding the demographics and clinical features of patients who present as an emergency is, therefore, important in facilitating the appropriate interventions.
The aim of this study was to obtain a detailed understanding of the characteristics, needs, experiences and outcomes of patients with lung cancer who were DFEA and to identify areas with scope for improving the care provided to this group of patients and their carers.
Patients and methods
Patients
The Kobe City Medical Center General Hospital (Kobe, Japan) is a 900-bed, tertiary referral centre, which plays a central role in treating emergency patients from the surrounding area. We retrospectively analysed patients diagnosed with advanced (stage IIIB or IV) NSCLC at this hospital between April 2004 and April 2012 (fig. 1). Patients who reported never having smoked were defined as never-smokers, those who had smoked within 1 year of the diagnosis were categorised as current smokers and the rest were considered to be former smokers. All patients were classified on the basis of clinical stage according to the 7th edition TNM (tumour, node, metastasis) classification [10]. DFEA patients were defined as those without a lung cancer diagnosis before admission to our hospital via the emergency department and who presented directly (non-referral) to hospital with symptoms associated with lung cancer as their main complaint. We defined the patients referred to our hospital from other institutions because of suspected of lung cancer, as well as those admitted to our hospital because of symptoms not associated with lung cancer, as non-DFEA. The reason for emergency admission was evaluated by at least two pulmonologists using case and radiographic records. Overall survival was measured as the period from the diagnosis of lung cancer until death from any cause or the end of the follow-up. The Eastern Cooperative Oncology Group (ECOG) PS of DFEA patients was evaluated at emergency admission and just prior to opting for chemotherapy, and the PS of non-DFEA patients was evaluated just prior to opting for chemotherapy. “Just prior to opting for chemotherapy” was defined as the time when the decision to start chemotherapy or not was made. Improvement in PS was defined as either a change from a PS of 2 at emergency admission to a PS of 0 or 1 just prior to opting for chemotherapy, or from a PS of 3 or 4 to a PS of 0–2 by supportive care other than systemic chemotherapy. We isolated tumour DNA from various specimens and analysed epidermal growth factor receptor gene (EGFR) mutation status at exons 18–21 using the peptide nucleic acid–locked nucleic acid PCR clamp method, as described previously [11]. All chart reviews were approved by the Ethics Committee of Kobe City Medical Center General Hospital.
Statistical analysis
Continuous variables were analysed using t-tests. Dichotomous variables were analysed using Chi-squared or Fisher’s exact tests, as appropriate. The Kaplan–Meier method was used to estimate the survival outcomes and groups were compared using the log-rank test. Cox proportional hazard models were fitted to determine the associations between patient characteristics and survival outcomes. A multivariate Cox proportional hazard model was developed on all clinically important factors to determine the associations between patient characteristics and survival outcomes in all patients included in this study. When we conducted subgroup analysis on DFEA patients, a similar multivariate model was constructed on variables selected by univariate analysis (p<0.05) because of the small number of events. The results are expressed as hazard ratios (HRs) with 95% confidence intervals. A p-value of <0.05 was considered to indicate statistical significance. We conducted statistical analyses using JMP 9 software (SAS Institute, Cary, NC, USA).
Results
Patient characteristics
A total of 771 patients with advanced NSCLC were included in the study, of whom 103 (13%) were DFEA. Patient characteristics and comparisons between DFEA and non-DFEA patients are summarised in table 1. Most patients (67%) had a PS of 0 or 1 just prior to opting for chemotherapy and adenocarcinoma (69%). EGFR mutations were investigated in 368 (48%) patients. Of these, EGFR mutations were detected in 128 (35%) patients. In the DFEA patients, the main reasons for emergency admission were brain metastasis symptoms (23%), pleural effusion (16%) and pneumonia (15%).
Comparison of the clinical profiles of DFEA and non-DFEA patients showed that DFEA patients included significantly lower proportions of patients with good PS (33 out of 103 versus 483 out of 668, respectively; p<0.001) and patients who received chemotherapy, including definitive chemoradiotherapy (65 out of 103 versus 586 out of 688, respectively; p<0.001).
We also investigated the reasons of not offering specific lung cancer treatment, except for poor PS. Of the 58 DFEA and 596 non-DFEA patients with PS 0–2, 5 (9%) and 48 (8%) patients did not receive chemotherapy because of patient preference.
Analyses of overall survival time
Overall survival time is summarised in table 2 and figure 2. At the time of analysis, the median (95% CI) overall survival was 15.4 (14.1–17.0) months. Findings from univariate analyses using Cox proportional hazards models of the influence of clinical characteristics on survival outcomes indicated that longer overall survival was significantly associated with younger age, female sex, never-smoker, good PS, mutated EGFR, stage IIIB, adenocarcinoma, chemotherapy and non-DFEA. Multivariate analysis identified good PS, mutated EGFR, stage IIIB, adenocarcinoma and chemotherapy as good independent predictors of overall survival (HR (95% CI) 0.36 (0.29–0.44), p<0.001; 0.49 (0.38–0.63), p<0.001; 0.64 (0.51–0.80), p<0.001; 0.81 (0.67–0.99), p=0.044; and 0.40 (0.31–0.52), p<0.001, respectively).
Analyses of overall survival time in DFEA patients
Subgroup analyses of overall survival time in DFEA patients are summarised in table 3. Findings from univariate analyses using Cox proportional hazards models indicated that longer overall survival was significantly associated with good PS at emergency admission, good PS just prior to opting for chemotherapy, adenocarcinoma and chemotherapy. Multivariate analysis identified good PS just prior to opting for chemotherapy as a good independent predictor of overall survival (HR 0.26 (95% CI 0.12–0.55); p<0.001).
Analyses of the predictive factor for improved PS in DFEA patients
We investigated the predictive factors for PS improvement in DFEA patients (table 4). 95 DFEA patients who had PS of 2–4 were analysed. PS improvements were significantly more frequent in younger patients compared with older patients (28 out of 59 versus 9 out of 36, respectively; p=0.033), patients with a PS of 2 compared with those with a PS of 3–4 (16 out of 29 versus 21 out of 66, respectively; p=0.041) and in patients admitted because of pleural effusion compared with those without pleural effusion (12 out of 16 versus 25 out of 79, respectively; p=0.002). The median interval between the emergency admission and the diagnosis was 3 days (interquartile range: 1–8 days), and the median interval between the diagnosis and the time when the decision to start chemotherapy or not was made (just prior to opting for chemotherapy) was 16 days (interquartile range: 8–29 days).
We also investigated the patients who were admitted because of symptoms associated with brain metastases as it was a main reason for emergency admission. Of these 24 patients, 12 patients underwent radiotherapy, three underwent operation, six underwent operation and radiotherapy, and three received no therapy. There were six (50%), one (33%), five (83%) and 0 (0%) patients who presented improved PS, respectively.
Discussion
To the best of our knowledge, this study provides the first report of the characteristics, prognosis and predictors of overall survival in DFEA patients with advanced lung cancer.
Our results indicated that 13% of advanced NSCLC patients were DFEA. This is lower than in previous studies from the UK, which reported that 20–40% of advanced lung cancer patients were DFEA [3, 6]. The reason for this discrepancy is unclear. One possible explanation may be the difference in the definition of DFEA; we used a narrow definition of DFEA in the current study and considered other non-elective referrals, such as emergency referrals to pulmonologists, as non-DFEA. Another possible explanation may be a difference in the accessibility of respiratory specialists; the route to specialists in the UK is generally through a general practitioner, while patients in Japan may see specialists directly, leading to shorter diagnostic delays and less cancer progression during the interval. From these points, quality management in lung cancer care might be very important to reduce the number of DFEA patients, as reported previously in European countries [12].
In this study, the main reasons for emergency admissions were symptoms of brain metastasis, pleural effusion and pneumonia. Previous studies reported that patients who had already been diagnosed with lung cancer mainly visited the emergency department with respiratory or neuropsychiatric symptoms, fever and pain [13–15]. Another study reported that the most frequent cause of intensive care unit (ICU) admission in cancer patients was respiratory failure [16]. The reasons for emergency department visits may, thus, be similar between patients before and after the diagnosis of lung cancer.
In this study, we adapted overall survival as the criterion for predicting treatment efficacy, because it has been reported that overall survival is still the best criterion for this purpose [17]. Overall survival was significantly shorter in DFEA compared with non-DFEA patients, as reported in previous studies [6, 18]. However, DFEA was not an independent predictor of overall survival according to multivariate analysis, while PS just prior to opting for chemotherapy, mutated EGFR, stage IV, adenocarcinoma histology and chemotherapy were independent predictors. Additionally, subgroup analyses of DFEA patients indicated that good PS just prior to opting for chemotherapy, but not at emergency admission, was the only independent predictor of longer overall survival. Together with the characteristics of DFEA patients, these findings suggest that shorter overall survival in DFEA patients may be associated with their poor PS, and efforts to improve patient PS after emergency admission should, thus, be considered vital in such circumstances.
In this study, a small number of patients (10 (10%) out of 103) were admitted to the ICU. Although it is possible that most DFEA patients did not require ICU admission, this result may be a product of the triage policies at our hospital. Almost all the patients admitted at the emergency room were hospitalised in an intermediate care unit, which is an ICU step-down unit for patients who need a higher level of care, such as vasopressor infusions or noninvasive mechanical ventilation. Patients who required more intensive care, including intubation, were admitted to the ICU at our hospital. Thus, almost all the patients received intensive care soon after the emergency admission. In this study, 15 (15%) and seven (7%) DFEA patients required mechanical ventilation and vasopressors, respectively. The prognoses of these 22 patients were poor (median (95% CI) overall survival: 3.1 (1.7–10.8) months). Similar results were obtained in previous studies for patients requiring ICU admission [19–24]. However, five (23%) patients who required mechanical ventilation or vasopressor treatment survived for a period longer than 6 months. In a recent report, the prognosis of cancer patients with good PS requiring ventilatory support was better [25]. In addition, another study reported that ICU management may be appropriate, especially in patients with good PS [21, 26]. Together with the results of our study, this indicates that efforts to improve patient PS after admission might also be vital, even for ICU patients. A larger study of DFEA patients who require ICU attention is required to study this hypothesis further.
In patients with advanced lung cancer, a multidisciplinary approach is important as well as supportive care. This study indicated that a multidisciplinary approach might lead to PS improvement in DFEA patients who were admitted because of symptoms associated with brain metastases, which were the main reason for DFEA. According to previous studies of lung cancer patients who required ICU admission, admission to high-volume centres was associated with lower mortality, and this effect may be related to closer collaboration between the experts [19, 21]. For the management of DFEA patients, a multidisciplinary approach is also necessary to improve PS and facilitate patient-centred decision making for most patients. Furthermore, previous studies also demonstrated that this approach had many benefits for patients with advanced lung cancer [27–30]. Therefore, a multidisciplinary approach should be employed for the treatment of advanced lung cancer patients, especially for DFEA patients.
We also investigated factors affecting PS improvement after emergency admission in DFEA patients. 37 (39%) DFEA patients showed improved PS after admission and the predictive factors for PS improvement were younger age, PS of 2, and emergency admission due to pleural effusion. These results indicate that particular attention should be paid to DFEA patients with these features.
PS was the most important factor for evaluating the appropriateness of chemotherapy. The benefits of chemotherapy in patients with poor PS are speculative, and many oncologists only consider chemotherapy appropriate for patients with an ECOG PS of 2 [31–35]. However, the results of the present study suggest that non-chemotherapeutic supportive care can improve the PS in DFEA patients and that PS after supportive care is a better predictor of overall survival than PS at emergency admission. The appropriateness of chemotherapy should, therefore, not be assessed on the basis of PS at emergency admission, and maximum supportive care should be applied in all patients.
This study had some limitations. First, there was the potential for selection bias, because this study was conducted at a single institution and our hospital plays a central role in treating emergency patients in the surrounding area. Secondly, we were unable to distinguish fully between patients with disease-related poor PS and those with long-standing poor PS. Although the PS improved in some patients after chemotherapy, we were unable to analyse the effects of improvements in PS after chemotherapy. Thirdly, the duration of supportive care before chemotherapy was determined by each doctor and, therefore, differed among patients.
In conclusion, DFEA is relatively common. Although the survival of DFEA patients is poor, DFEA was not an independent predictor of overall survival according to multivariate analysis. Additionally, good PS just prior to opting for chemotherapy, but not at emergency admission, was the only independent predictor of longer overall survival in DFEA patients. Efforts to improve patient PS after admission should, thus, be considered vital in such circumstances.
Acknowledgements
The authors would like to thank Keiko Sakuragawa (Dept of Respiratory Medicine, Kobe City Medical Center General Hospital, Kobe, Japan) for her administrative assistance.
Footnotes
For editorial comments see Eur Respir J 2015; 45: 867–868 [DOI: 10.1183/09031936.00198814]
Support statement: This study was supported by internal funding and the Ethics Committee of Kobe City Medical Center General Hospital.
Conflict of interest: None declared.
- Received April 10, 2014.
- Accepted August 29, 2014.
- Copyright ©ERS 2015