Prognostic factors for rural endometrial cancer patients in a population-based cohort

Background

Endometrial cancer is the second most common cancer among female cancer survivors in the US and is increasing in incidence. Rural endometrial cancer patients experience lower survival rates but the reasons for the lower survival are not known. The aim of this study is to examine whether prognostic factors are different for rural and urban patients in a population-based cohort.

Methods

Endometrial cancer patients diagnosed 1997-2012 were identified through the Utah Cancer Registry and Utah Population Database. The address at cancer diagnosis was used to classify patients in rural or urban residences. Demographic and cancer-specific characteristics were examined as prognostic factors for both all-cause and endometrial cancer-specific mortality using Cox proportional hazards models.

Results

There were 2,994 endometrial cancer patients and 14.1% of these patients lived in rural areas at diagnosis. Rural endometrial cancer patients were older at cancer diagnosis and did not appear to be different in terms of obesity or overweight at cancer diagnosis. There were no differences for treatment or stage at diagnosis although rural patients had higher proportions of higher grade. Age at diagnosis, poverty, education, and histology were significant prognostic factors for all-cause death. Rural patients with more advanced stages of cancer had significantly increased risks of all-cause and endometrial cancer-specific death than urban patients. Rural endometrial cancer patients diagnosed at advanced stage had a 17-fold increase in the risk of all-cause death compared to an 8-fold increase in death for urban patients.

Conclusions

Rural endometrial cancer patients in Utah were older at diagnosis, had higher grade and higher comorbidities. While urban and rural endometrial cancer patients shared many prognostic factors, the risk of mortality is greater among rural patients with advanced stage endometrial cancer. Future studies should examine where patients are receiving treatment and how that impacts their survival and how to reduce the mortality rates of high risk patients.

Endometrial cancer is the second most common cancer among female cancer survivors in the US, with an estimated 757,190 survivors in 2017 [1]. In addition, it is one of the few cancers in the US with an increasing incidence rates [2]. The death rate for this cancer has also been increasing, with an average increase of 1.4% per year between 2005-2014 and an estimated 10,470 deaths in 2016 [3, 4]. The overall five-year survival for endometrial cancer is 87% [3].

Older age, higher stage, grade, race, comorbidities, obesity, and treatment are associated with lower endometrial cancer survival [5,6,7,8]. There have been conflicting results in the associations between cancer survival and rural residence [5, 7, 9]. Bregar et al. reported decreased overall mortality for higher stage endometrial cancer patients in rural communities with no significant difference in lower stage patients in a population of more than 42,000 patients [7]. While Modesitt et al. reported significantly increased disease-specific survival for patients in rural areas, there was no significant difference in overall survival among 3,562 endometrial cancer patients [9].

Endometrial cancer treatment can include surgery, chemotherapy, radiation, hormone therapy, and/or targeted therapy [10]. Many of these treatment options require multiple visits over a longer period of time. Rural patients may have a greater geographic accessibility burden, which could account for the differences in treatment have been observed between rural and urban endometrial cancer patients [9, 11]. Rural patients received a less comprehensive surgical evaluation and are less likely to have multimodality treatment and have any lymph nodes removed [9, 11]. These treatment differences have been previously associated with lower survival rural endometrial cancer patients [11]. While previous studies have examined treatment differences as a factor in survival differences, they have not examined how prognostic factors, such as age at diagnosis, baseline health, and stage of diagnosis may be associated with decreased survival in rural areas. The aim of this study is to examine whether prognostic factors are different for rural and urban patients, as well as to examine the trends of treatment and mortality over time in rural and urban areas. We examined prognostic factors in a statewide population-based cohort of first primary endometrial cancer patients who were linked to medical record data, cancer registry data, death records, and demographic data from the Utah Department of Health.

This cohort was established within the Utah Population Database (UPDB), which links data from the Utah Cancer Registry (UCR) (one of the original NCI SEER cancer registries), electronic medical records (EMR), statewide healthcare data, voter registration records, residential histories, family history records, and birth and death certificates [12]. The healthcare data from UPDB includes ambulatory surgery and inpatient discharge data from the entire state of Utah as well as linkage to EMR data from 2 of the biggest healthcare providers in Utah, the University of Utah Healthcare and Intermountain Healthcare.

First primary endometrial cancer cases diagnosed between 1997 and 2012 were identified through UCR (SEER ICD-O-3 codes: C54.0-C55.9). Death dates were captured locally using Death certificates as well as nationwide genealogy, the Social Security Death Index (nationwide), and UCR records. Participants with endometrial cancer were excluded if the cancer was in situ (n=183), the cancer stage was unknown/missing (n=153), or if grade was missing (n=471). Follow up time was calculated as time from cancer diagnosis to either death or to their last known date to be alive and residing in Utah.

All participants were linked to the available healthcare data in the UPDB. International Classification of Diseases, Ninth Revision, Clinical Modification (ICD-9-CM) codes prior to cancer diagnosis were used to create the Charlson Comorbidity Index (CCI) for each patient at the time of cancer diagnosis [13]. Cause of death codes (ICD-10) were used to classify deaths as all-cause and endometrial cancer specific deaths (C541, C549, C55). Residence at cancer diagnosis was collected through several sources in the UPDB. The mean time from diagnosis to the date the residence was captured was 0.44 years. The zip codes were linked to the Rural Urban Commuting Area Codes (RUCA) Version 2.0 and each zip code was designated as either urban or rural based on the RUCA level [14]. This was based on the metropolitan/nonmetropolitan definition where all zip codes within an urbanized area core (population > 50,000) and those zip codes with more than 25% of their population commuting to urbanized area core [15]. All zip codes were also linked to poverty and education data obtained through UDS Mapper, which incorporates data from the American Community Survey [16]. The poverty data used were the percentage of population in each zip code below the federal poverty level. The education data were the percentage of population in each zip code who had not obtained a high school diploma.

Endometrial cancer histologies were categorized using SEER ICD-O-3 morphology codes. Cancers were classified as type I and II based on histological subtypes: adenocarcinoma, endometrioid, mucinous adenocarcinoma, and adenocarcinoma with squamous differentiation were classified as type I (ICD-O-3 morphology codes: 8140, 8260, 8380, 8382, 8480, 8482, 8560, and 8570) and clear-cell carcinomas and papillary serous carcinomas as type II (ICD-O-3 morphology codes: 8310, 8441, and 8460) which were grade 3 or higher [17, 18].

Statistical Methods

The earliest body mass index (BMI) measurement at least 1 year before cancer diagnosis was calculated to assess baseline BMI. Approximately 28% of all subjects were missing BMI, thus we imputed BMI for the 28% who were missing it using age at diagnosis, sex, race, and CCI as predictors using multiple imputation. We compared Cox proportional hazards regression models including only those who had BMI in the data and with the full study population, including those who had imputed BMI, to assure that our inferences did not change due to the imputed BMI.

Chi-square tests were used to assess differences in the demographic characteristics between endometrial cancer patients in rural and urban areas. Unadjusted Kaplan-Meier survival curves by residence were created and the logrank test was used to compare the survival between rural and urban endometrial cancer patients. Cox proportional hazards were used to calculate hazard ratios for the risk factors of all-cause death as well as endometrial cancer specific death. Models were adjusted on potential confounders selected based on prior knowledge as appropriate. All models were stratified by residence (urban/rural). All analyses were conducted using SAS 9.4. This study was approved by the University of Utah Institutional Review Board.

There were a total of 2,994 endometrial cancer patients included in this study, with 85% (2,573) living in urban areas at diagnosis. The average follow-up time was 7.3 years (standard deviation=6.2). The majority of patients were overweight (29.1%) or obese (43.4%) at diagnosis. Patients in urban areas were significantly younger on average at diagnosis (60.8 vs 63.0 years old, P = .0009) and had significantly lower mortality (P = .0246) than those in rural areas (Table 1). Table 2 shows the clinical characteristics by residence. The majority of patients in both rural (67.0%) and urban (65.2%) areas received surgery as their only treatment for the endometrial cancer. Grade of endometrial cancer was significantly different between the 2 groups with the urban population having higher rates of grade I (48.2% vs 43.5%). Figure 1 shows the survival curves for all-cause death and endometrial cancer specific death by residence. While in both survival curves, rural endometrial cancer patients had lower survival, neither all-cause death nor endometrial cancer specific death had a significant p-value in the logrank test.

Unadjusted Kaplan-Meier survival curves for all-cause death and endometrial cancer specific death by residence (rural/urban) with logrank test p-value

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While the crude hazard ratio for all-cause death was significantly increased for rural patients compared to urban patients, increased risks were not observed in the adjusted models for both all-cause death (HR=1.12, 95% CI=0.94, 1.35) and endometrial cancer specific death (HR=1.09, 95% CI=0.80, 1.48). All-cause risk of death significantly decreased in 2005-2008 and 2009-2012 in urban endometrial patients (HR=0.70, 95% CI=0.56, 0.86 and HR=0.74, 95% CI=0.59, 0.93) (Table 3). However, this decrease was not observed among rural endometrial cancer patients (HR=1.29, 95% CI=0.81, 2.07 and HR=1.32, 95% CI=0.81, 2.14). Neither urban nor rural residence had significant changes in endometrial cancer specific death over time. The risk of all-cause death and death from endometrial cancer were lower in nearly all age groups in urban areas than in rural areas. However, there was no significant difference between rural vs. urban residence. Neither BMI nor CCI were associated with an increased risk for all-cause death or endometrial cancer death. However, urban patients with a CCI score of 2 or greater had significantly lower rates of endometrial cancer death (HR=0.70, 95% CI=0.52, 0.94).

Table 4 shows the hazard ratios for clinical characteristics by residence for both all-cause death and endometrial cancer specific death. Both treatment and tumor type were significantly associated with all-cause death and endometrial cancer specific death in both urban and rural areas. Patients with regional and advanced endometrial cancer when compared to local endometrial cancer had significantly increased risks in both all-cause death and endometrial cancer specific deaths in rural areas compared to urban areas. The risks for endometrial cancer specific death were more than doubled in rural areas compared to urban areas for regional cancer (HR=7.63, 95% CI=3.64, 16.01 vs HR=3.08, 95% CI=2.31, 4.10). Two histologies were associated with significantly higher risk of all-cause death in rural patients: serous adenocarcinoma (HR=2.16, 95% CI=1.05, 4.48 vs HR=0.90, 95% CI=0.66, 1.24) and clear cell carcinoma (HR=6.45, 95% CI=2.37, 17.54 vs HR=1.84, 95% CI=1.00, 3.38). Those with clear cell carcinoma also had a significantly increased risk in rural areas compared to urban areas for endometrial cancer specific death (HR=10.85, 95% CI=3.12, 37.73 vs HR=0.58, 95% CI=0.14, 2.34).

We conducted the first population-based assessment of prognostic factors in urban and rural areas among endometrial cancer patients. As expected, age at cancer diagnosis, treatment, grade, stage, type, and histology were significant risk factors for all-cause death. However, the levels of risk were different between urban and rural endometrial cancer patients in Utah. Endometrial cancer patients with regional and advanced stages disease were significantly more likely to die either due to all-cause and endometrial cancer specific mortality in rural areas than in urban areas. There were also differences in histology and grade, with rural endometrial cancer patients with clear cell carcinoma having significantly increased risk of death and urban endometrial cancer patients with higher grade cancer having increased risk of death.

Studies have shown that rural cancer survivors have worse overall health than urban cancer survivors [19]. This includes comorbidities, psychological distress, and lower levels of physical activity [19, 20]. A recent study observed significantly increased risk of death in rural endometrial cancer patients compared to urban patients, however they were not able to include BMI and baseline health which we included [11]. Generally, in our study rural endometrial cancer patients had higher rates of multiple comorbidities. Much of these differences have been explained through socioeconomic status (SES) and education [9]. While those living in rural areas in our study overall lived in zip codes with higher rates of poverty and lower rates of education, we did not observe any significant differences of the effect of education and poverty on mortality between urban and rural patients.

We observed that patients in rural areas with regional and advanced endometrial cancer had significantly higher risk of both endometrial cancer specific death and all-cause death than those in urban areas. This may be a result of reduced access to healthcare. Patients in rural areas are likely to live much farther from a cancer center and may have less access to adjuvant therapy, which has been associated with decreased survival [11, 21]. Patients may also be offered therapy, but may decline it due to reasons such as distance and cost. This difference in treatment, especially treatment beyond surgery, may account for decreased survival in rural areas.

Non-white endometrial cancer patients living in urban areas had a significantly increased risk for endometrial cancer specific death. This risk was not increased for rural endometrial cancer patients, which may be due to the small sample of non-white patients (n=19). Decreased survival has been well established in black women with endometrial cancer when compared to white women [22,23,24]. Out of the non-white urban population in our study, only 12 (10.4%) were black. The other non-white women were Asian and Pacific Islander (66.1%) and American Indian (23.5%). Asians have similar or higher survival rates to non-Hispanic white women, whereas American Indian/Alaska Natives h have worse survival [23, 25]. The sample sizes of individual non-white racial groups were too small to determine alone.

This study has several limitations. First, the population includes only to endometrial cancer patients diagnosed in Utah. Utah has a less diverse population than the rest of the nation on average and tends to be one the healthiest states. This allowed for a more homogenous study population. Another limitation is having a small rural population. There were several risk factors where we may not have had enough power to detect a significant risk, as well as risk factors, like some histologies, that did not have any rural patients. We also did not have data on where the patients received treatment, only where their residence was at the time of diagnosis. Patients in rural areas may have travelled to large cancer centers for treatment or have been offered treatment and had to decline due to distance, which we could not assess.

There are several strengths to this study as well. This is a statewide study covering a time period of more than 15 years. The major strength of this study is the population based design with nearly 3000 endometrial cancer survivors. Another strength is the amount of medical record data. By having complete EMR data from 2 of the biggest medical care providers in the state of Utah as well as complete statewide ambulatory surgery and inpatient data, we were able to capture the baseline Charlson Comorbidity Index. We also had data on obesity at baseline through the UPDB. Most studies on cancer survival that are population-based have not been able to report on obesity. Also, through UPDB and UCR, we were able to have data from numerous sources to assess demographic and cancer specific risk factors in rural and urban areas.

Overall, many of the expected risk factors for death in endometrial cancer patients were significantly increased in both rural and urban areas. However, there were some significant differences including rural endometrial cancer patients in more advanced stages having higher risk of death. More research needs to be done specifically looking at rural endometrial cancer patients in advanced stages to learn what can be done to reduce the mortality. Future studies should also examine not only where patients live at diagnosis, but where they are receiving treatment and how that impacts their survival.

The data that support the findings of this study are available from the Utah Population Database but restrictions apply to the availability of these data, which were used under license for the current study, and so are not publicly available. Data are however available from the authors upon reasonable request and with permission of the Utah Population Database.

Not applicable

This work was supported by a NCI grant (R21 CA185811; Hashibe), the Huntsman Cancer Institute Cancer Control and Population Sciences Program (HCI Cancer Center Support Grant P30CA042014), and the NCRR grant, “Sharing Statewide Health Data for Genetic Research” (R01 RR021746, G. Mineau, PI) with additional support from the Utah State Department of Health and the University of Utah. We thank the Pedigree and Population Resource of the Huntsman Cancer Institute, University of Utah (funded in part by the Huntsman Cancer Foundation) for its role in the ongoing collection, maintenance and support of the Utah Population Database (UPDB). We thank the University of Utah Center for Clinical and Translational Science (CCTS) (funded by NIH Clinical and Translational Science Awards), the Pedigree and Population Resource, University of Utah Information Technology Services and Biomedical Informatics Core for establishing the Master Subject Index between the Utah Population Database, the University of Utah Health Sciences Center and Intermountain Healthcare.

Authors and Affiliations

1. Division of Public Health, Department of Family and Preventive Medicine, Huntsman Cancer Institute, University of Utah School of Medicine, 2000 Circle of Hope, Salt Lake City, UT, 84112, USA

   Brenna E. Blackburn, Sean Soisson, Michael Newman & Mia Hashibe

2. Huntsman Cancer Institute, Salt Lake City, UT, USA

   Brenna E. Blackburn, Sean Soisson, Anne C. Kirchhoff, Deanna Kepka, Theresa L. Werner, David Gaffney, Kathi Mooney & Mia Hashibe

3. Intermountain Healthcare, Salt Lake City, UT, USA

   Kerry Rowe & John Snyder

4. Pedigree and Population Resource, Population Sciences, Huntsman Cancer Institute, Salt Lake City, UT, USA

   Alison Fraser & Ken Smith

5. University of Utah Health Sciences Center, Salt Lake City, UT, USA

   Vikrant Deshmukh & Michael Newman

6. Utah Cancer Registry, University of Utah, Salt Lake City, UT, USA

   Kimberly Herget

7. Department of Pediatrics, University of Utah School of Medicine, Salt Lake City, UT, USA

   Anne C. Kirchhoff

8. Department of Pediatrics, University of Utah School of Medicine, Salt Lake City, UT, USA

   Deanna Kepka

9. Division of Oncology, Department of Medicine, University of Utah School of Medicine, Salt Lake City, UT, USA

   Theresa L. Werner

10. Department of Radiation Oncology, University of Utah School of Medicine, Salt Lake City, UT, USA

    David Gaffney

11. College of Nursing, University of Utah, Salt Lake City, UT, USA

    Kathi Mooney

Contributions

BB and MH participated in obtaining the data, data analysis, and the writing of the paper. SS participated in the data analysis. KR, JS, YW, VD, MN, AF, KS, and KH participated in obtaining the data and reviewing the manuscript. AK, DK, TW, DG, AL, and KM participated in the writing of the paper. All authors read and approved the final manuscript.

Corresponding author

Correspondence to Mia Hashibe.

Ethics approval and consent to participate

This study was approved by the University of Utah IRB # 00065816.

Consent for publication

Not applicable

Competing interests

The authors declare that they have no competing interests.

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