Nomograms to predict overall survival and cancer-specific survival in patients with adrenocortical carcinoma.
Journal: 2018/December - Cancer Management and Research
ISSN: 1179-1322
Abstract:
To develop nomogram models to predict individualized estimates of overall survival (OS) and cancer-specific survival (CSS) in patients with adrenocortical carcinoma (ACC).A total of 751 patients with ACC were identified within the Surveillance Epidemiology, and End Results (SEER) database between 1973 and 2015. The predictors comprised marital status, sex, age at diagnosis, year of diagnosis, laterality, histologic grade, ethnicity, historic stage, radiation therapy, chemotherapy, and surgery of primary site. Based on the results of the multivariate logistic regression analyses, the nomogram models were used for predicting OS and CSS in patients with ACC. The nomograms were tested using concordance index (C-index) and calibration curves.In univariate and multivariate analyses of OS, OS was significantly associated with age at diagnosis, year of diagnosis, histologic grade, historic stage, and chemotherapy. In univariate and multivariate analyses of CSS, age at diagnosis, year of diagnosis, historic stage, and chemotherapy were the independent risk factors with CSS. These characteristics were included in the nomograms predicting OS and CSS. The nomograms demonstrated good accuracy in predicting OS and CSS, with the C-index of 0.677 and 0.672.These clinically useful tools predicted OS and CSS in patients with ACC using readily available clinicopathologic factors and could aid individualized clinical decision making.
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Cancer Management and Research. Dec/31/2017; 10: 6949-6959
Published online Dec/12/2018

Nomograms to predict overall survival and cancer-specific survival in patients with adrenocortical carcinoma

Abstract

Purpose

To develop nomogram models to predict individualized estimates of overall survival (OS) and cancer-specific survival (CSS) in patients with adrenocortical carcinoma (ACC).

Patients and methods

A total of 751 patients with ACC were identified within the Surveillance Epidemiology, and End Results (SEER) database between 1973 and 2015. The predictors comprised marital status, sex, age at diagnosis, year of diagnosis, laterality, histologic grade, ethnicity, historic stage, radiation therapy, chemotherapy, and surgery of primary site. Based on the results of the multivariate logistic regression analyses, the nomogram models were used for predicting OS and CSS in patients with ACC. The nomograms were tested using concordance index (C-index) and calibration curves.

Results

In univariate and multivariate analyses of OS, OS was significantly associated with age at diagnosis, year of diagnosis, histologic grade, historic stage, and chemotherapy. In univariate and multivariate analyses of CSS, age at diagnosis, year of diagnosis, historic stage, and chemotherapy were the independent risk factors with CSS. These characteristics were included in the nomograms predicting OS and CSS. The nomograms demonstrated good accuracy in predicting OS and CSS, with the C-index of 0.677 and 0.672.

Conclusion

These clinically useful tools predicted OS and CSS in patients with ACC using readily available clinicopathologic factors and could aid individualized clinical decision making.

Introduction

Adrenocortical carcinoma (ACC) is a rare and typically aggressive malignancy with a poor prognosis. The estimated incidence of ACC is 1–2 cases per million populations per year leading to 0.2% of all cancer deaths in the United States.1 However, ACC is a quite heterogeneous disease. Consequently, the clinical outcome widely differs for any given tumor stage. For example, most patients with an advanced stage of disease had a median survival time of fewer than 12 months, even after complete tumor resection,2 while some patients might enjoy long-term remissions which lasted up to 8 years.3 Therefore, an accurate prognostic indicator is necessary to guide patients in individualized clinical decision making. According to patient and tumor characteristics, we established the nomogram models to provide individualized estimates of survival in patients with ACC using the Surveillance Epidemiology, and End Results (SEER) database, which is one of the largest population-based cancer databases.

Patients and methods

Data source

The SEER database was used to identify patients diagnosed with ACC from 1973 to 2015. SEER collects cancer incidence data from population-based cancer registries covering approximately 34.6% of the US population.4 The information in the SEER database is accrued from 18 regional cancer registries, including information on patients’ demographic, cancer diagnosis, and treatment, as well as the cause of death.4

Study population

We selected patients with positive histology of ACC (International Classification of Diseases for Oncology, third edition site codes: C740 and C749, and histologic subtype code: 8370). Then, the screening conditions were as follows: first and only malignant tumor, unilateral tumor. Patients whose death was reported by autopsy only or death certification only or who had an unknown marital status were excluded. These criteria resulted in 751 records (Figure 1).

Study variables

The characteristics analyzed were marital status, sex, age at diagnosis, year at diagnosis, laterality, histologic grade, ethnicity, primary tumor size, historic stage, treatment modality (surgery, chemotherapy, radiotherapy), the cause of death, and survival months. Overall survival (OS) and cancer-specific survival (CSS) were the endpoint outcomes of the study. OS was determined from the vital status recode and was defined as the time from diagnosis until death. CSS was determined from the SEER cause-specific death classification and was defined as the time from diagnosis until death because of ACC.

Statistical analyses

The clinicopathologic characteristics were categorized. In this study, the univariate logistic regression analyses were used to identify the characteristics which were significantly associated with OS and CSS. In the univariate analyses, hazard ratios (HRs) were calculated per one standard deviation increase in predictor variables. Characteristics with P<0.05 were included in the multivariate logistic regression model. Then, we used a backward stepwise logistic regression to find the optimal multivariate model where all contained characteristics were statistically significant with P<0.05. Kaplan–Meier survival analysis5 with a log-rank test6 was used to demonstrate differences in survival between patient groups for all characteristics, including OS and CSS. The HR and 95% CI were used to evaluate the strength of association between each characteristics and OS or CSS. Based on the results of the multivariate logistic regression analyses, nomograms for 1-, 3-, and 5-year OS and CSS were performed, which was constructed as a visualizing aid to obtain predicted values manually from the multivariate logistic regression models. The performance of the nomograms was measured by concordance index (C-index), which was a measure of discriminative ability that quantified the proportion of all patient pairs. A C-index of 0.5 indicated no predictive ability, whereas a C-index of 1.0 indicated perfect discrimination. Additionally, calibration curves were provided to evaluate the performance of the nomograms based on the logistic regression models. We used the bootstrap validation method to estimate the predictive accuracy of the nomograms by using 200 bootstrap resamples. All data analyses were performed by using SAS (version 9.4; SAS Institute Inc., Cary, NC, USA) and R software (version 3.2.3), and all calculations were performed by using SPSS (version 24.0; IBM Corporation, Armonk, NY, USA). All tests were two-sided, and P<0.05 was considered statistically significant.

Results

Patient characteristics

The demographic, clinical, and pathologic characteristics of 751 patients with ACC are listed in Table 1. Marital status included married (n=448, 59.65%) and unmarried (n=303, 40.35%). The population consisted of 424 (56.46%) female and 327 (43.54%) male patients. As for age at diagnosis, more than 70% of the cases were diagnosed between 40 and 89 years of age, and there was a single peak that was seen in the fourth, fifth, and sixth decades of life (Figure 2). The number of cases increased over the years of study from 175 (23.30%) in 1973–1987 to 319 (42.78%) in 2002–2015. The locations of the lesions were similar, with 399 (53.13%) cases left and 352 (46.87%) cases right. Most cases were with an unknown grade (n=584, 77.76%), followed by grade III and IV (n=105, 13.98%), grade I and II (n=62, 8.26%). The main ethnicity was the white ethnicity (n=631, 84.02%). According to the SEER staging system, 202 (26.90%) patients presented with localized disease, followed by distant metastatic disease (n=160, 21.31%) and regional disease (n=96, 12.78%), additionally, the number of patients with unknown stage was 293 (39.01%). Treatment modality consisted of surgery, chemotherapy, and radiation therapy. Surgery included surgery of primary site (n=308, 41.01%), no surgery of primary site (n=87, 11.58%), and unknown (n=356, 47.41%). Of 751 patients, 124 (16.51%) patients received radiation therapy and 627 (83.49%) did not receive radiation therapy or unknown. 173 patients received chemotherapy, while 491 (65.38%) patients not or unknown.

Factors associated with OS

Table 2 shows the univariate and multivariate analyses of OS. In the univariate analysis, OS was significantly associated with age at diagnosis (P<0.001), year of diagnosis (P<0.001), histologic grade (P=0.002), historic stage (P<0.001), chemotherapy (P=0.017), and surgery of primary site (P=0.009). Conversely, OS was not significantly associated with marital status, sex, laterality, ethnicity, and radiation therapy. As for the multivariate analysis, the independent prognostic factors were age at diagnosis (P<0.001), year of diagnosis (P<0.001), histologic grade (P=0.035), historic stage (P<0.001), and chemotherapy (P=0.001).

As shown in Table 4, the 1-year, 3-year, and 5-year OS differed significantly in age at diagnosis (P<0.001), year of diagnosis (P=0.016), histologic grade (P=0.003), historic stage (P<0.001), chemotherapy (P<0.001), and surgery of primary site (P<0.001). On the contrary, it did not differ significantly across marital status, sex, laterality, ethnicity, and radiation therapy.

Factors associated with CSS

The univariate and multivariate analyses of CSS are listed in Table 3. Based on the univariate analysis, age at diagnosis (P=0.016), year of diagnosis (P<0.001), histologic grade (P=0.013), historic stage (P<0.001), chemotherapy (P<0.001), and surgery of primary site (P<0.001) were significantly associated with CSS. Additionally, marital status, sex, laterality, ethnicity, and radiation therapy were not significantly associated with CSS. In the multivariate analysis, age at diagnosis (P<0.001), year of diagnosis (P=0.006), historic stage (P<0.001), and chemotherapy (P=0.001) were the independent risk factors. In contrast, histologic grade (P=0.099) was not the independent risk factor with CSS.

As shown in Table 4, the 1-year, 3-year, and 5-year CSS were significantly affected by age at diagnosis (P<0.001), histologic grade (P=0.013), historic stage (P<0.001), chemotherapy (P<0.001), and surgery of primary site (P=0.001). But it did not differ in marital status, sex, year of diagnosis, laterality, ethnicity, and radiation therapy.

Kaplan–Meier curves analyses

The OS and CSS Kaplan–Meier curves are shown in Figure 3. Patients with old age (60–89 years) had worse survival than those with young age. Instead, patients diagnosed in 1988–2001 and 2002–2015 had significantly better survival than in 1973–1987. What is more, patients who had distant metastatic disease and whose tumors were poorly differentiated or undifferentiated had worse survival. Survival was also worse for patients who underwent chemotherapy. Conversely, survival was much worse for patients who did not have surgery of primary site than patients who had surgery or unknown.

Nomogram development

As shown in Figure 4, nomograms were developed to predict 1-year, 3-year, and 5-year OS and CSS, which was aimed to provide accurate and specific prediction of prognosis. Because age at diagnosis, year of diagnosis, histologic grade, historic stage, and chemotherapy were the independent prognostic factors with OS, while age at diagnosis, year of diagnosis, historic stage, and chemotherapy were the independent risk factors with CSS, these characteristics were included in the nomograms. The total points that were used to provide estimates of 1-year, 3-year, and 5-year OS and CSS were calculated from these factors. For example, a 40-year-old patient who was with a grade III and regional ACC, diagnosed in 2001 and underwent chemotherapy, would score a total of 199 points for OS and 180 points for CSS. Therefore, his/her predicted 1-year OS and 1-year CSS would be approximately 66% and 61%, respectively.

Internal validation of the models

The nomogram models were internally validated by evaluating both discrimination and calibration. Discrimination was measured using the C-index, which was 0.677 (95% CI, 0.654–0.700) for the model predicting OS and 0.672 (95% CI, 0.648–0.696) for CSS. The calibration curves for 3-year OS and CSS are shown in Figure 5. In the calibration curves, we could see that there was a good correlation between the 3-year OS and CSS estimated from the nomograms and those derived from Kaplan–Meier estimated.

Discussion

ACC is a rare and typically aggressive malignancy with a poor prognosis. Although ACC is a highly malignant cancer, some patients could also die from other causes. Consequently, our objective was to develop the OS and CSS nomograms to accurately predict the prognosis of patients with ACC.7 In our study, the nomogram models relied on age at diagnosis, year of diagnosis, histologic grade, historic stage, and chemotherapy.

In our study, there was a predominance of females and whites with a female to male ratio of 1.30:1 and Whites to non-Whites ratio of 5.26:1, which were similar to previous studies.810 Historically, there was a bimodal age distribution which had been described for ACC, with one peak in early childhood and another peak in fourth and fifth decades of life.11,12 However, we did not find such bimodal age distribution in our study. Instead, we only found a single peak that was seen in the fourth, fifth, and sixth decades of life. A similar absence of bimodal age distribution was reported in a few previous studies.8,13 As for the year of diagnosis, we could see more patients were diagnosed in 2002–2015, which may be due to the increased use of sensitive imaging studies and the increased awareness of physical examination in recent years.14 The left adrenal gland was slightly more affected than the right one, this peculiar difference in the laterality was also seen in previous studies.13,15,16 However, the mechanism behind this observation was unknown.14

The majority of the tumors were of high grade at diagnosis, which was the opposite of our inherent cognition because of the increased use of sensitive imaging studies in recent years. The contrary was seen in multiple studies.8,13,14 One possible explanation was that due to limitations in the specificity of current diagnostic tools, the lower grade tumors might be initially misclassified as benign and were only picked up later as ACC when they were in high grade. As for historic stage, the main disease was localized, which was parallel to previ ous studies.9,17,18 The likely reason for this was that imaging examinations were more likely to find tumors located in the adrenal gland, and ACC accounted for 0%–25% of adrenal cortical masses19 and up to 14% of adrenal incidentalomas.20

In our study, surgical resection of the primary site remained the mainstay of therapy. However, in our multivariate analyses of OS and CSS, surgery of primary site was not the independent prognostic factor with P<0.05. But we could see that in the survival analyses, both the 3-year and 5-year of OS and CSS were 0. That was to say, if patients with adrenal cortical cancer did not have surgery, they would live less than 3 years, which was similar to the previous study.18 The reason for this was that adrenal cortical cancer was an extremely malignant and rapidly progressing cancer. Therefore, surgery was virtually the only option to achieve cure for local disease. Besides, it might yield survival benefit in advanced diseases.1,14,2124 Interestingly, we found that there were nearly twice as many people who received chemotherapy for those who received radiotherapy. This was because ACC was still considered radioresistant even though increasing evidence supported that ACC was not radiotherapy-resistant.25,26 Therefore, only a very small portion of patients would receive radiotherapy as a palliative treatment. Although radiotherapy could not change the OS, it could reduce the risk of local recurrence and ameliorate tumor-related symptoms.14,21,25,27 Patients who received radiotherapy did not benefit from recurrence control and ameliorate tumor-related symptoms, as ACC was an intrinsically high malignant tumor. Consequently, the mild benefits could not change the ultimate end. The advantages of adjuvant mitotane administration after surgery remained controversial. It was reported that mitotane could be effective for certain patients. What is more, predictors of response to mitotane therapy and other cytotoxic drugs could facilitate individualized treatment.1,14,21,24,28

The clinical implications of our nomograms were mainly the ability to provide individualized estimates of OS and CSS in patients with ACC. The nomogram models were derived and validated for that specific purpose. For example, a 30-year-old (0 points) woman with a grade III (20 points) and regional (33 points) ACC, diagnosed in 2015 (0 points) who underwent chemotherapy (48 points) had a total of 101 points for OS, yielding an estimated 1-year OS of 86%, 3-year OS of 72%, and 5-year OS of 66%. Additionally, CSS estimated by the nomogram-derived might be used for adjusting the frequency and intensity of follow-up.

There was only one prognostic model to compare with these nomogram models in the field of ACC.18 Compared with the prognostic model, our study had the following strength. First, our study included data of ACC in the SEER database between 1973 and 2015 and 2015 was the year of the latest data for the database. Second, the indicators were more comprehensive than others’ study. The indicators we used included marital status, sex, age at diagnosis, year at diagnosis, laterality, histologic grade, ethnicity, historic stage, and treatment modality (surgery, chemotherapy, radiotherapy). Besides, the most important point was that our study included the univariate and multivariate analyses, survival analyses, Kaplan–Meier curves analyses, nomogram models, C-index, and calibration curves, which was more complete than others’ study. Additionally, the accuracy of our models could also be assessed by bladder, kidney, and prostate-cancer nomograms, and the C-index of these models was generally 0.620–0.774 and the trend of the calibration curves of our models was almost the same as the calibration curves of these models.2931

Apart from the prognostic nomogram model of defining the prognosis of patients with ACC, there were some large-scale studies that were performed to examine OS and CSS in patients with ACC. Wang et al examined a cohort of 749 patients with ACC within the SEER database between 1973 and 2014.32 Their studies showed that the prognostic factors for overall and cancer-specific mortality were age, treatment of primary site, chemotherapy, and tumor stage, and tumor stage had a dominant effect. Kebebew et al examined a cohort of 725 patients with ACC within the SEER database between 1973 and 2000.8 The authors found that the most important predictors of survival in patients with ACC were tumor grade, tumor stage, and surgical resection. Xiao et al also examined a cohort of 641 patients exposed to surgery with ACC, within the SEER database between 1988 and 2012.33 They found that age, tumor stage, tumor grade, and marital status affected OS and CSS. Paton et al assessed the OS in 602 patients with ACC within the SEER database between 1988 and 2002.9 The authors showed the relative effect of different stages on OS, and they found that if patients with ACC were not diagnosed at an earlier stage or with tumors smaller, survival would not improve. We corroborated these findings for age, tumor grade, tumor stage, and chemotherapy, and we found that in multivariate analyses, surgical resection did not affect OS and CSS in patients with ACC.

Our study had some limitations. First of all, our study was of a relatively small sample size (751). Our data also suffered from a lack of details. Comorbidity data were also not included in the SEER database. Therefore, we could not adjust for this important cofactor. What is more, massive missing data were the flaw for the SEER database. For example, it was interesting that the survival rates for patients who underwent chemotherapy were much lower than patients who did not undergo chemotherapy or unknown. A possible explanation was that these patients of unknown chemotherapy status had actually undergone chemotherapy and had a long survival time. However, lack of information made them classified as a class with patients who did not undergo chemotherapy. With any predictive model, the point estimates had an inherent range of uncertainty.34 Finally, there was the unavoidable selection bias of all retrospective studies. Although the SEER database had these inherent limitations which might have played a role in the selection of available patients for our study, we still considered the SEER database as a high-quality data to provide medical records at participating institutions of ACC.

In summary, although the nomogram models had some limitations, they were enough to be trusted to provide individualized estimates of OS and CSS in patients with ACC. Therefore, we strongly recommend using these models in patients with ACC to aid individualized clinical decision making. Meantime, future prospective studies should be done to search for a more accurate prognostic model.

Ethics

The SEER database is freely available and the data are anonymized so that there were no ethical issues.

Figure 1

Flow chart for creation of the SEER data set.

Abbreviations: ICD-O, International Classification of Diseases for Oncology; SEER, Surveillance Epidemiology and End Results; OS, overall survival; CSS, cancer specific survival.

Figure 2

Number of patients diagnosed in each age group with ACC.

Abbreviation: ACC, adrenocortical carcinoma.

Figure 3

Kaplan–Meier survival curves of overall survival (A, C, E, G, I, K) and cancer-specific survival (B, D, F, H, J, L).

Notes: (A, B) Age at diagnosis, (C, D) year of diagnosis, (E, F) histologic grade, (G, H) historic stage, (I, J) chemotherapy, and (K, L) surgery of primary site.

Abbreviation: OS, overall survival.

Figure 4

Nomograms for predicting the OS and CSS rates at 1-year, 3-year, and 5-year in patients with adrenocortical carcinoma.

Notes: (A) Predicting1-year, 3-year, and 5-year OS rates, (B) predicting 1-year, 3-year, and 5-year CSS rates.

Abbreviations: CSS, cancer-specific survival; OS, overall survival.

Figure 5

Calibration curves of the nomograms for predicting 3-year OS (A) and 3-year CSS (B) in patients with adrenocortical carcinoma.

Abbreviations: OS, overall survival; CSS, cancer-specific survival.

Table 1
Demographics, clinical, and pathologic characteristics of 751 patients with adrenocortical carcinoma
CharacteristicsAll patients, N (%)

Marital status
Married448 (59.65)
Unmarried303 (40.35)
Sex
Male327 (43.54)
Female424 (56.46)
Age at diagnosis
0–39209 (27.83)
40–59283 (37.68)
60–89259 (34.49)
Year of diagnosis
1973–1987175 (23.30)
1988–2001257 (34.22)
2002–2015319 (42.78)
Laterality
Right352 (46.87)
Left399 (53.13)
Histologic grade
Grade I+II62 (8.26)
Grade III+IV105 (13.98)
Unknown584 (77.76)
Ethnicity
White631 (84.02)
Black56 (7.46)
Others64 (8.52)
Historic stage
Localized202 (26.90)
Regional96 (12.78)
Distant160 (21.31)
Unknown293 (39.01)
Radiation therapy
Yes124 (16.51)
No/unknown627 (83.49)
Chemotherapy
Yes260 (34.62)
No/unknown491 (65.38)
Surgery of primary site
Yes308 (41.01)
No87 (11.58)
Unknown356 (47.41)
Table 2
Univariate and multivariate analyses of variables associated with OS
CharacteristicsUnivariate analysis
Multivariable analysis
HR (95% CI)P-valueHR (95% CI)P-value

Marital status
MarriedReference
Unmarried0.817 (0.591–1.131)0.224
Sex
MaleReference
Female0.753 (0.543–1.046)0.090
Age at diagnosis<0.001<0.001
0–39ReferenceReference
40–591.534 (1.054–2.235)0.0262.153 (1.390–3.335)0.001
60–893.952 (2.533–6.167)<0.0016.332 (3.801–10.549)<0.001
Year of diagnosis<0.001<0.001
1973–1987ReferenceReference
1988–20010.627 (0.370–1.063)0.0820.667 (0.371–1.198)0.175
2002–20150.234 (0.144–0.380)<0.0010.163 (0.078–0.340)<0.001
Laterality
RightReference
Left0.971 (0.704–1.340)0.859
Histologic grade0.0020.035
Grade I+IIReferenceReference
Grade III+IV2.812 (1.437–5.502)0.0032.318 (1.071–5.019)0.033
Unknown2.520 (1.480–4.290)0.0012.222 (1.199–4.117)0.011
Ethnicity0.827
WhiteReference
Black1.151 (0.614–2.161)0.661
Others1.151 (0.637–2.081)0.641
Historic stage<0.001<0.001
LocalizedReferenceReference
Regional1.853 (1.054–0.258)0.0322.271 (1.228–4.198)0.009
Distant16.083 (6.302–41.041)<0.00113.493 (5.092–35.754)<0.001
Unknown0.863 (0.593–1.256)0.4412.145 (1.099–4.187)0.025
Radiation therapy
YesReference
No/unknown1.007 (0.654–1.552)0.973
Chemotherapy
YesReferenceReference
No/unknown0.651 (0.458–0.925)0.0170.478 (0.310–0.736)0.001
Surgery of primary site0.0090.099
YesReference
No3.806 (2.057,7.043)<0.0011.987 (1.033,3.822)0.040
Unknown3.664 (2.562,5.239)<0.0011.336 (0.642,2.776)0.438

Abbreviations: HR, hazard ratio; OS, overall survival.

Table 3
Univariate and multivariate analyses of variables associated with CSS
CharacteristicsUnivariate analysis
Multivariate analysis
HR (95% CI)P-valueHR (95% CI)P-value

Marital status
MarriedReference
Unmarried0.776 (0.573–1.052)0.103
Sex
MaleReference
Female0.868 (0.641–1.175)0.359
Age at diagnosis0.016<0.001
0–39ReferenceReference
40–591.265 (0.877–1.826)0.2081.610 (1.062–2.441)0.025
60–891.750 (1.191–2.569)0.0042.468 (1.591–3.828)<0.001
Year of diagnosis<0.0010.006
1973–1987ReferenceReference
1988–20010.738 (0.477–1.144)0.1740.801 (0.492–1.305)0.373
2002–20150.379 (0.251–0.572)<0.0010.363 (0.195–0.682)0.002
Laterality
RightReference
Left0.916 (0.678–1.237)0.567
Histologic grade0.0130.099
Grade I+IIReferenceReference
Grade III+IV2.546 (1.328–4.883)0.0052.139 (1.042–4.392)0.038
Unknown2.033 (1.200–3.441)0.0081.763 (0.983–3.163)0.057
Ethnicity0.918
WhiteReference
Black0.984 (0.556–1.740)0.955
Others1.119 (0.648–1.933)0.687
Historic stage<0.001<0.001
LocalizedReferenceReference
Regional2.537 (1.496–4.301)0.0012.753 (1.589–4.769)<0.001
Distant12.764 (6.521–24.986)<0.0019.308 (4.660–18.593)<0.001
Unknown1.198 (0.836–1.716)0.3251.754 (0.965–3.187)0.065
Radiation therapy
YesReference
No/unknown0.820 (0.543–1.239)0.345
Chemotherapy
YesReferenceReference
No/unknown0.461 (0.330–0.646)<0.0010.415 (0.279–0.618)<0.001
Surgery of primary site<0.0010.210
YesReference
No2.594 (1.523,4.420)<0.0011.643 (0.922,2.928)0.092
Unknown2.312 (1.674,3.192)<0.0010.891 (0.458,1.734)0.733

Abbreviations: HR, hazard ratio; CSS, cancer-specific survival.

Table 4
1-year, 3-year, and 5-year OS and CSS in patients with adrenocortical carcinoma
CharacteristicsOS
CSS
1-year (%)3-year (%)5-year (%)P-value1-year (%)3-year (%)5-year (%)P-value

Marital status0.5310.337
Married63.3040.5032.7065.7042.3034.60
Unmarried61.1041.4035.2064.2045.2038.90
Sex0.1060.225
Male58.1039.7031.4062.0042.6034.10
Female65.7041.8035.5067.4044.1038.00
Age at diagnosis<0.001<0.001
0–3973.5052.6045.6074.0052.9045.90
40–5969.1045.3035.5071.3047.6038.10
60–8945.8026.3021.2050.2030.4025.70
Year of diagnosis0.0160.220
1973–198752.0037.1030.0054.2039.8032.70
1988–200164.0043.6034.5066.6046.4037.20
2002–201567.0040.1034.4070.1053.2042.30
Laterality0.8310.662
Right60.5042.6033.2062.6044.9036.00
Left64.0039.4033.5067.2042.2035.90
Histologic grade0.0030.013
Grade I+II83.3061.8053.9083.3065.6055.50
Grade III+IV58.4535.7028.9060.6037.8030.70
Unknown60.8039.4032.2063.8042.1035.00
Ethnicity0.0410.075
White63.1042.3035.4065.4044.6037.80
Black66.7038.9028.3071.2043.2033.80
Others48.7026.0018.7553.8028.7020.70
Historic stage<0.001<0.001
Localized84.0068.0056.9086.7072.1060.90
Regional63.5042.7034.4065.2044.7036.00
Distant28.109.405.0030.0010.405.60
Unknown66.1038.0033.2069.8040.1036.10
Radiation therapy0.5150.274
Yes66.3036.1028.3068.2037.1029.20
No/unknown61.6041.8034.5064.4044.7037.40
Chemotherapy<0.001<0.001
Yes56.7026.6019.6057.9027.2020.50
No/unknown65.3048.0040.5068.9051.9044.30
Surgery of primary site<0.0010.001
Yes77.6049.6041.4079.7051.3043.20
No19.900.000.0023.100.000.00
Unknown58.7040.7032.9061.2043.8035.90

Abbreviations: CSS, cancer-specific survival; OS, overall survival.

Footnotes

Author contributions

YL and XHB designed the study. YL, XHB, JYOY, and SYW collected the data. YL, XHB, and JYOY analyzed the data. YL, XHB, and MZH organized the manuscript. ZLL reviewed the papers and revised the manuscript. All the authors have read and approved the final manuscript, contributed toward data analysis, drafted and revised the paper, and agreed to be accountable for all aspects of the work.

Disclosure

The authors report no conflicts of interest in this work.

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