ABSTRACT
Objective: Lung cancer is a global public health problem and is associated with high mortality. Lung cancer could be largely avoided by reducing the prevalence of smoking. The objective of this study was to analyze the effects of social, behavioral, and clinical factors on the survival time of patients with non-small cell lung cancer treated at Cancer Hospital I of the José Alencar Gomes da Silva National Cancer Institute, located in the city of Rio de Janeiro, Brazil, between 2000 and 2003.
Methods: This was a retrospective hospital cohort study involving 1,194 patients. The 60-month disease-specific survival probabilities were calculated with the Kaplan-Meier method for three stage groups. The importance of the studied factors was assessed with a hierarchical theoretical model after adjustment by Cox multiple regression.
Results: The estimated 60-month specific-disease lethality rate was 86.0%. The 60-month disease-specific survival probability ranged from 25.0% (stages I/II) to 2.5% (stage IV). The performance status, the intention to treat, and the initial treatment modality were the major prognostic factors identified in the study population.
Conclusions: In this cohort of patients, the disease-specific survival probabilities were extremely low. We identified no factors that could be modified after the diagnosis in order to improve survival. Primary prevention, such as reducing the prevalence of smoking, is still the best method to reduce the number of people who will suffer the consequences of lung cancer.
Keywords: Lung neoplasms/epidemiology; Carcinoma, non-small-cell lung; Survival analysis
RESUMO
Objetivo: O câncer de pulmão é um problema de saúde pública global e é associado a elevada mortalidade. Ele poderia ser evitado em grande parte com a redução da prevalência do tabagismo. O objetivo deste estudo foi analisar os efeitos de fatores sociais, comportamentais e clínicos sobre o tempo de sobrevida de pacientes com câncer de pulmão de células não pequenas atendidos, entre 2000 e 2003, no Hospital do Câncer I do Instituto Nacional de Câncer José Alencar Gomes da Silva, localizado na cidade do Rio de Janeiro.
Métodos: Estudo retrospectivo de coorte hospitalar com 1.194 pacientes. As probabilidades de sobrevida doença-específica em 60 meses foram calculadas com o método de Kaplan-Meier para três grupos de estadiamento. A importância dos fatores estudados foi avaliada por um modelo teórico hierarquizado após o ajuste de modelos de regressão múltipla de Cox.
Resultados: Foi estimada uma taxa de letalidade doença-específica em 60 meses de 86,0%. A probabilidade de sobrevida doença-específica em 60 meses variou de 25,0%, nos estádios iniciais, a 2,5%, no estádio IV. A situação funcional, a intenção e a modalidade do tratamento inicial foram os principais fatores prognósticos identificados na população estudada.
Conclusões: As probabilidades de sobrevida doença-específica estimadas na amostra estudada foram muito baixas, e não foram identificados fatores que pudessem ser modificados após o diagnóstico visando uma melhora da sobrevida. A prevenção primária, como a redução da prevalência do tabagismo, ainda é a melhor forma de evitar que mais pessoas sofram as consequências do câncer de pulmão.
Descritores: Neoplasias pulmonares/epidemiologia; Carcinoma pulmonar de células não pequenas; Análise de sobrevida
INTRODUCTION
Lung cancer is the most common type of cancer worldwide; it is estimated that, in 2012, there were 1.8 million new cases.1 In Brazil in 2015, 27,000 new cases were estimated.2
Although lung cancer has various histological types, the most widely used classification system is that which divides tumors into small cell carcinomas (15%) and non-small cell carcinomas (85%).3
The 60-month survival probability of patients with non-small cell lung carcinoma is lower than 15% in Europe.4 A study conducted in the United States obtained estimates ranging from 66% (stage Ia) to 4% (stage IV). 5 A study involving patients from a university hospital in the city of Rio de Janeiro, Brazil, found that the 60-month survival probability was 6%, with it being 14% for the early stages and 5% for the advanced stages.6
Among the prognostic factors studied for lung cancer patients7 are stage, performance status,8 weight loss, gender, age, smoking, smoking history, quality of life, marital status, depression, and genetic mutations.6,9-11
Epidemiological studies have indicated that the effects of socioeconomic factors on health outcomes are indirect, occurring through behavioral and clinical factors. In this context, it is important to establish the hierarchy of these factors in determining the occurrence of lung cancer and in the survival probability of patients with this type of cancer.12,13
The objective of the present article was to analyze the importance of social, behavioral, and clinical factors on the survival time of patients with non-small cell lung cancer treated at Hospital do Câncer I do Instituto Nacional de Câncer José Alencar Gomes da Silva (HCI/INCA, Cancer Hospital I of the José Alencar Gomes da Silva National Cancer Institute), located in the city of Rio de Janeiro, Brazil, between 2000 and 2003.
METHODS
This was a retrospective observational hospital cohort study in which the object of interest was the time from diagnosis to death from lung cancer or metastasis.
The target population consisted of patients diagnosed with primary non-small cell lung carcinoma, between 2000 and 2003, who were registered in the Registro Hospitalar de Câncer (RHC, Hospital Cancer Registry) of HCI/INCA, which is a tertiary referral hospital for the treatment of cancer in the state of Rio de Janeiro, Brazil.
Eligible patients were defined as those from the state of Rio de Janeiro, where HCI/INCA is located, in whom diagnosis was confirmed by either anatomic pathological or cytological examination of the tumor and who had not been previously treated. The list of patients who met the eligibility criteria was extracted from the RHC of HCI/INCA, with the primary source of cancer registry information being medical records. At HCI/INCA, medical records were not electronic. To update data on patient survival, we searched the Rio de Janeiro State Mortality Database, and, for patients for whom the information was missing, we conducted an active search according to the RHC routine.14 In addition, medical records were abstracted for information about smoking history and performance status, which is measured with scales that are used to evaluate how the disease progresses and affects the daily living abilities of the patient, in order to determine appropriate treatment and prognosis.8 Patients who had ever smoked were considered smokers.
Of the 1,502 cases of non-small cell lung cancer registered in the RHC between 2000 and 2003, 1,394 lived in the state of Rio de Janeiro. Of those, 200 were excluded because it was impossible to determine disease stage by reviewing the medical records.
To reduce the influence of anticipation bias,15 all analyses were stratified by clinical stage group, as determined by the tumor-node-metastasis classification system16: stages I/II (early stage); stage III; and stage IV. Stages I and II were gathered into one group in order to provide greater stability to the results of the models.
The factors identified in the review of the literature were organized into a hierarchical theoretical model (Figure 1).1-6 Distal factors included sociodemographic characteristics and family history of cancer; intermediate factors included behavioral characteristics as well as access to and effectiveness of the health care system, all of which are generally influenced by sociodemographic characteristics; and proximal factors included patient clinical characteristics, disease characteristics, and treatment characteristics, all of which can be influenced by the previous level factors. Of the 28 factors identified, 10 were not analyzed because they were unavailable or because they were available in very few medical records. In the categorization of the studied factors, priority was given not only to coherence in the object of study but also to data stability as a function of the sample, especially in relation to stages I/II.
Age at diagnosis was included in all multiple regression models because it is directly related to death (from a biological standpoint), because it characterizes the birth cohort, and because it influences other factors (smoking, occupation, etc.)
The 60-month disease-specific survival probability in lung cancer was estimated with the Kaplan-Meier method, on the basis of the following criteria: i) initial event: diagnosis of lung cancer; ii) final event: death from lung cancer or metastasis; iii) survival time: time from initial to final event or time to loss to follow-up; and iv) censored cases: cases that were lost to follow-up over the 60-month period; cases in which death from lung cancer or metastasis was not confirmed; and cases in which patients survived the 60-month follow-up.
Differences between the estimated probability curves were determined via log-rank test. Variables that had a value of p < 0.20 in the log-rank test were included in the Cox models.17 The adjusted effects of factors on survival time were calculated, for each stage, by using the Cox model, on the basis of the hierarchical theoretical model proposed in Figure 1.
In the preparation of the models, variables were entered in blocks. First, distal factors were entered; those with a value of p < 0.10 were maintained in model 1. Subsequently, intermediate factors were added to model 1, and the same selection criterion was applied (model 2). The same procedure was repeated for proximal factors, and the final model was obtained. In the modeling process, the previous level factors that lost significance upon inclusion of more proximal-level factors were maintained. The goodness-of-fit of the models was determined by calculating the likelihood ratio, the probability of agreement, and the overall goodness-of-fit.17
The research project that generated the present article is registered with the research ethics committees of the INCA and the Sérgio Arouca National School of Public Health (Protocol nos. CAAE-012.0.007.031-11 and CAAE-0163.0.031.007-11).
RESULTS
A comparison of cases included and excluded as per the eligibility criteria indicated no statistically significant differences (chi-square test) in the distribution by gender, level of education, smoking, histological type, or treatment.
The mean age of the 1,194 patients included in the study was 62 years, and it decreased with the severity of tumor stage (stages I/II, 65 years; stage III, 62 years; and stage IV, 60 years). Most subjects were male and smokers; in stage III, the smoker/nonsmoker ratio reached its maximum value (20.9:1.0). The mean smoking history was 60 pack-years, and less than one third of the patients had a confirmed diagnosis prior to admission to HCI/INCA (Table 1).
Distribution and 60-month disease-specific survival probability of the study cohort of patients with non-small cell lung cancer by clinical stage, as well as by distal factor and by intermediate factor of the proposed model. Cancer Hospital I, José Alencar Gomes da Silva National Cancer Institute, 2000-2003.
At diagnosis, more than half of the patients in stages I/II and III presented with restrictions for performing vigorous physical activities. The most common first treatment was radiotherapy, and, in stages I/II, surgery was the first treatment in only one fourth of the cases. Adenocarcinoma predominated in stages I/II and stage IV, followed by squamous carcinoma, chiefly in stage III (Table 2).
By the end of the 60-month follow-up, 1,027 patients (86.0%) had died from lung cancer, 66 (5.5%) had died from other causes, 70 (5.9%) had survived, and 31 (2.6%) had been lost. The estimated 12-month and 60-month disease-specific survival probabilities were 32.7% (95% CI: 30.0-35.5%) and 7.9% (95% CI: 6.3-9.7%), respectively. The median survival time was estimated to be 17.7 months for stages I/II, 8.0 months for stage III, and 5.5 months for stage IV.
Patients with stage IV disease who were nonsmokers had a better prognosis than did those who were smokers/former smokers. Being admitted to HCI/INCA with a confirmed diagnosis doubled the survival probability of stage III patients (Table 1). Survival decreased with increasing limitation as assessed by the performance status scale, regardless of stage. Among the patients for whom information on tumor location was available, stage I/II and stage III patients had a better prognosis (Table 2).
In the modeling process, the cases with missing values for the variables included in the final models were excluded to allow comparability between the models of the different levels. We excluded 20 stage I/II cases, 108 stage III cases, and 75 stage IV cases. Excluded and analyzed cases were compared, and no statistically significant differences were observed for the variables gender, age, level of education, race, marital status, smoking, histological type, treatment, vital status, or follow-up period.
In stages I/II, age, gender, performance status, detailed tumor location, histological type, initial treatment intent, and initial treatment modality proved to be important prognostic factors in the crude analysis of the Cox models and were used in the hierarchical modeling.
None of the intermediate factors were included in the multiple regression model of stages I/II (p > 0.20 in the log-rank test). When the proximal factors were added to model 1, the risk estimates decreased. The risk of death, adjusted for the other variables of the final model, was 2.34 times higher among patients who were unable to perform work activities than among those who were active, was twice as high among those for whom information on tumor location was unavailable as among those for whom this information was available, and was thirteen times higher among untreated patients than among operated patients. The risk of death associated with the use of radiotherapy or chemotherapy was high when compared with that related to surgery (Table 3).
In stage III, the prognostic factors used in the hierarchical modeling were age, diagnosis occurring prior to admission, distance from home to HCI/INCA, performance status, tumor laterality, tumor location, initial treatment intent, and initial treatment modality.
In the adjusted model for stage III, there were no differences in the estimates when the intermediate factors were added to model 1; however, when the proximal factors were included, the age-related risk estimate decreased. The effect of diagnosis occurring prior to admission increased when the proximal factors were included. The final model showed an excess risk of death of 70.0%, adjusted for the other factors, among the patients who had not been given a diagnosis prior to admission (Table 4).
Performance status maintained a strong association with outcome in the final model and showed an increasing gradient of risk of death/worsening of the patient's physical state. Patients who underwent palliative treatments had a risk of death, adjusted for the other factors in the final model, 2.48 times that of those who underwent curative treatments. Among the untreated patients, this estimate was even higher (Table 4).
In stage IV, the study characteristics gender, smoking, smoking history, diagnosis occurring prior to admission, distance from home to HCI/INCA, performance status, tumor laterality, histological type, initial treatment intent, and initial treatment modality were used in the hierarchical modeling. The age-related risk estimate decreased and gained statistical significance when the proximal factors were included in the final model. The effect associated with smoking decreased and lost statistical significance when the proximal factors were entered. This behavior probably occurs because the effect of smoking is mediated by proximal factors. Adjusted for the other factors, the risk of death by the end of the 60-month follow-up was found to be 50.0% higher among those who had not been given a diagnosis prior to admission. Those who lived within a radius of 20-30 km of HCI/INCA had an adjusted risk of death that was 28.0% lower than that for those who lived closer to HCI/INCA (Table 5).
Performance status maintained a strong association with outcome after adjustment and showed an increasing gradient of risk of death/worsening of the patient's physical state. The risks associated with nonsurgical treatments, as compared with surgical treatments, are extremely high in that stage. In addition, the risk of death by the end of the 60-month follow-up is estimated to be eight times higher among untreated patients than among operated patients (Table 5).
The inclusion of the proximal factors in the more distal-level models significantly increased the likelihood ratio of the final models, regardless of stage. In addition, the probability of agreement of these models can be classified as very good in stages I/II and stage III and as coherent in stage IV. The all-level adjusted models were significantly different from the null model (p < 0.001) in the three stages analyzed (Tables 2, 3, and 4).
DISCUSSION
Among the factors evaluated, performance status, initial treatment intent, and initial treatment modality stood out for influencing the survival time of patients with non-small cell lung cancer treated at HCI/INCA between 2000 and 2003, in all stage groups. The magnitudes and directions of the estimated effects related to these factors in the present study are consistent with those reported in other studies and will be addressed below.6,18,19
Survival studies of lung cancer patients commonly involve clinical trial patients. A review of the literature revealed two survival studies of patients with non-small cell lung cancer, both of which were conducted in the city of Rio de Janeiro, Brazil: one in a public hospital, in which 60-month survival probabilities were estimated6; and one in a private clinic,19 in which 24-month survival probabilities were estimated.
The predominance of advanced stage disease (stage IV, 40.3%), males (71.5%), and smokers (92.0%) observed in the present study is consistent with the characteristics of other study populations.1,6,18-20
Results that are consistent and in agreement with findings of previous studies were observed for the distribution of the study population by smoking history (mean, 60 pack-years),6 performance status (approximately 90.0% were limited),6,18,19 and histological type (more than 40.0% had adenocarcinoma).5,18,20
The median estimated survival time was slightly higher than that found in the study conducted in a public hospital in Rio de Janeiro, for all stages.6 It is likely that, because HCI/INCA is an oncology referral center, it has a health care infrastructure that favors a better prognosis, in comparison with the other public hospital not specializing in oncology. In contrast, the low proportion of operated patients, especially stage I/II patients, indicates limited access to this treatment modality.
The 60-month survival probabilities below 25.0% found in most of the analysis categories in stages I/II illustrate how devastating cancer is, regardless of what factors are evaluated, even when the disease is diagnosed in early stages. This finding underscores the importance of primary prevention with two major strategies: encouraging smoking cessation and increasing young people's awareness regarding the dangers of smoking in order to prevent them from acquiring this behavior.
In the evaluation of prognostic factors through the use of the Cox models, results that are consistent with those of other studies were observed for performance status,18 that is, patients who are more limited have a lower survival probability.
Regarding initial treatment intent and initial treatment modality, the adjusted results of the final models of the present study are consistent with what is expected in oncology,21,22 that is, survival probabilities are higher among those initially treated with curative intent and among those treated with surgery, which, for lung cancer, is the treatment modality that is most likely to result in a cure.
In stage IV, a mediation effect of smoking was observed for the proximal factors. Considering that variables are entered in blocks, it is impossible to determine which factor is responsible for this effect.13
The results associated with the distance from the patient's home to HCI/INCA can be explained on the basis of how the health care system in the state of Rio de Janeiro was organized in terms of lung cancer treatment during the study period. A medical referral, together with test results indicating the presence of a malignant tumor, was required for admission to HCI/INCA. Patients who lived outside the city of Rio de Janeiro and were referred to HCI/INCA usually benefited from a free shuttle service organized and provided by each municipal government. In general, this service facilitated continuation of treatment and follow-up. Perhaps other ways of evaluating access to the hospital in relation to place of residence, taking into account the route traveled and the transport used as reported by patients, can provide survival analysis results that are more consistent.
In the present study, the incompleteness of the medical records limited the use of some factors in the model proposed in Figure 1 and case inclusion in the analyses. Since the clinical stage was not recorded, we lost 14.3% of the eligible cases, which affected the stability of the estimates for some analysis categories. An evaluation of cases included and excluded on the basis of missing information revealed a statistically significant difference regarding treatment-approximately 50.0% of the patients excluded from the analysis had not been treated, whereas among the cases analyzed, the proportion was 14.9%. This loss could influence the results obtained, but it is impossible to determine the magnitude of this effect because we do not know the stage of the patients who were not analyzed. Progressive improvement in the quality of data entry into medical records should be encouraged, since these documents are often used as a source for database building. Despite the limitations inherent to retrospective studies that use medical records, such studies are of great value in increasing knowledge about disease involvement in populations that are treated at health care clinics.
In summary, it can be noted that the estimated 60-month disease-specific survival probabilities were very low, even in stages I/II. In addition, we identified no factors that could be modified after the diagnosis in order to improve survival. Lung cancer is a silent disease whose symptoms are associated with other less lethal diseases, which can lead to a delay in diagnosis in relation to the natural history of the disease. The best method to reduce the number of people who will suffer the consequences of lung cancer is primary prevention, reducing smoking.
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Publication Dates
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Publication in this collection
Sep-Oct 2016
History
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Received
30 Mar 2015 -
Accepted
27 Jan 2016