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. Author manuscript; available in PMC: 2019 Nov 8.
Published in final edited form as: J Natl Compr Canc Netw. 2019 Nov 1;17(11):1318–1329. doi: 10.6004/jnccn.2019.7325

Contribution of Geographic Location to Disparities in Ovarian Cancer Treatment

Carolina Villanueva a, Jenny Chang b, Scott M Bartell a,c, Argyrios Ziogas b, Robert Bristow d,e, Verónica M Vieira a,d
PMCID: PMC6839545  NIHMSID: NIHMS1057645  PMID: 31693984

1. Introduction

By the end of 2018, approximately 22, 240 women in the U.S. are estimated to receive an ovarian cancer (OC) diagnosis.1 Considered the most fatal of the gynecological cancers,2 this malignancy kills more than 14,000 U.S. women each year.1 Fortunately, substantial advances in treatment in the last four decades have led to gradual but consistent improvements in survival.3 Stage-specific guidelines have been established by the National Comprehensive Cancer Network (NCCN)4 for best care practices in treating OC and adherence to these recommendations has been validated as a significant predictor of disease-specific survival.5 Despite these evidence-based guidelines, inequities in access to and delivery of appropriate care still exist.

Although most efforts to understand the drivers of OC disparities have largely focused on factors such as race and socioeconomic status,613 there has been growing consideration of the role that geographic location may play.6,8,1417 A study of national data from the National Cancer Institute’s Surveillance, Epidemiology, and End Results (SEER) Program explored spatial variations in the delivery of OC treatment for Medicare recipients and found discrepancies existed by Hospital Referral Region.14 In British Columbia, despite theoretically having equal health care access under a single-payer system, differences were found in treatment practices by health authority region.15 Even with rising consensus that receiving specialized care is critical for OC outcomes,6,8,1424 a U.S. nationwide study emphasized the disparities in access to gynecological oncologists, highlighting their concentration in metropolitan-centers.16 The vast geographic areas without specialists represent a geographic barrier for those who must cover greater distances to reach them. ‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬

The objective of the current study is to examine how geocoded residence at diagnosis contributes to receiving care that is compliant with OC NCCN treatment guidelines in California (CA) among women of all stages, while exploring differences by race/ethnicity, SES, and insurance. CA accounts for 11% of all ovarian cancer cases diagnosed nationally and is highly relevant as a standalone study setting because of the large number of cases and its racial/ethnic diversity.

2. Methods

2.1. Study Population

We used a retrospective study design to examine the relationship between residential address at diagnosis and adherence to NCCN treatment guidelines. All cases of invasive epithelial OC diagnosed in CA between January 1, 1996 and December 31, 2014 were ascertained from the California Cancer Registry (CCR), with follow up data obtained through December 31, 2016. Reporting to the CCR within 6 months of diagnosis is close to 99%, with follow up nearly as high (95%).25,26 CCR data was linked with California’s Office of Statewide Health Planning and Development (OSHPD) patient discharge data.

Women of all OC stages (International Federation of Gynecology and Obstetrics (FIGO) - Stage I-IV) were eligible for inclusion. Cases 18 years of age or older at time of diagnosis were identified from the CCR using the International Classification of Disease Codes for Oncology (ICD-O-3 C56.9). The analysis was restricted to women with complete clinical information and no prior history of OC. After exclusions, presented in Figure 1, a total of 29,844 women diagnosed with incident invasive epithelial OC were included in the analyses. The study was approved by the Institutional Review Board of the University of California, Irvine (UCI 14–66/HS# 2014–1476).

Figure 1: Study Population Exclusions.

Figure 1:

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This diagram details how patients diagnosed between 1996 to 2014 were included in the study. CCR stands for the California Cancer Registry.

2.2. Study Data

The primary outcome was non-adherence to stage-specific NCCN treatment guidelines, examined as a binary variable (adherent vs. non-adherent). Non-adherence required either surgical or chemotherapy treatment be non-adherent to the NCCN guidelines of women’s respective diagnosis period.19,2732 Surgical guideline adherence for stages I-IIIB was a minimum of oophorectomy (± hysterectomy), pelvic and/or para-aortic lymph node biopsy, and omentectomy. Adherence for stages IIIC-IV was a minimum of oophorectomy (± hysterectomy) and omentectomy. For chemotherapy, receiving no adjuvant treatment was only appropriate for early stage and grade (stages IA-IB, grades 1–2). For all other stages (stage IC-IV) and grade 3 disease, multi-agent chemotherapy was guideline adherent. Chemotherapy must have been delivered subsequent to surgery, with the exception of stages IIIC-IV, in which it could have been received before or after surgery.19,2732

Several important patient characteristics were included as predictors: age at diagnosis, race/ethnicity, marital status, SES, insurance type, diagnosis year, tumor characteristics, and the Deyo-adapted Charlson Comorbidity Score.33,34 Race/ethnicity was categorized as non-Hispanic White, non-Hispanic Black, Hispanic, Asian/Pacific Islander, and American Indian/Other. Insurance type was categorized as managed care, Medicare, Medicaid, other insurance, not insured, and unknown. SES was stratified into quintiles using the Yost score35 for patients diagnosed prior to 2006 and the Yang index36 for those with a diagnosis after 2006. Tumor characteristics included tumor grade, size, histology type, and stage at diagnosis. The observed-to-expected (O/E) adherence ratio of women’s initial reporting hospital was included as a measure of hospital quality.19 This metric was calculated as the number of OC cases that received NCCN adherent care divided by the amount expected to receive standard care for that hospital, distributed into quartiles, and classified by annual hospital case volume.19 High quality hospitals were in the highest O/E quartile and had ≥5 cases/year.

To assess the role of geographic location on accessibility and potential barriers to treatment, we calculated the distance from each woman’s geocoded residential address at the time of diagnosis to the geocoded location of their initial reporting hospital. We also calculated how far each woman lived from the nearest high-quality hospital. Each variable was categorized into quintiles, with distances for both measures calculated with a geographic information system (GIS) using the Streetmaps routing dataset in the network analysis extension (ArcGIS version 10.4.1, ESRI; Redlands, CA).

2.3. Statistical Analysis

The main predictor variable of interest was geographic location as a smooth function of women’s geocoded residential location at diagnosis. We used generalized additive models (GAMs) to estimate the effect of a locally-weighted loess smoother of longitude and latitude on the log odds of not receiving adherent treatment while also adjusting for covariates.37,38 Details of the methods used are described elsewhere.38 Briefly, log odds of adherence was computed at thousands of locations points throughout California holding all other covariables constant, using the average odds for all of California as the referent group. Odds were not computed for areas with very few or no cases.8 The amount of smoothing depends on the span size, which represents the proportion of cases used locally to calculate the log odds at each point. The span size of 0.3 was chosen because it minimized the Akaike’s Information Criterion (AIC) for the majority of the models.37,38

Our base model examined the effect of residential location, while adjusting only for age and cancer characteristics at diagnosis. A fully-adjusted model additionally adjusted for demographic and treatment factors: SES, race/ethnicity, insurance type, marital status, quality of reporting hospital, comorbidities, and the two distance variables. Any differences in geographic areas of increased or decreased risk between the base and fully-adjusted models indicate that the additional demographic and treatment factors were affecting geographic variation in adherent care. We also conducted stage-stratified analyses. Permutation tests were used to calculate a global p-value for the importance of location. We produced color maps for each model displaying the odds ratios for treatment non-adherence throughout California, with contour lines delineating geographic areas that excluded odds ratios of 1. We also conducted Chi Square tests for differences between racial/ethnic, SES, and insurance groups across the distribution of distance variables. Statistical modeling and mapping were done in R version 3.4.0 using the MapGAM package.

3. Results

Patient characteristics are detailed in Table 1, with the case distribution shown in Figure 2. Of the 29,844 cases included in the analysis, 9,734 (32.6%) women were diagnosed at early stages (Stage1 and Stage2). The majority of the population was non-Hispanic White (63.4%) and the median age at time of diagnosis was 60 years old. Only 11,419 (38.3%) of all patients received care adherent to the National Comprehensive Care Network (NCCN) treatment guidelines. Women with Stage 3 disease were more likely to receive adherent care as compared to those diagnosed in early stages or Stage 4 (52.8% versus 25.2% and 34.2%, respectively).

Table 1:

Patient Characteristics by NCCN Treatment Adherence (n=29,844)

Characteristic Treatment Adherent Treatment Non-Adherent
N % N %
 Total 11419 38.3 18425 61.7
Age Group
 18–44 1511 35.9 2699 64.1
 45–54 2806 43.7 3617 56.3
 55–64 3359 46.5 3862 53.5
 65+ 3743 31.2 8247 68.8
Race/Ethnicity
 Non-Hispanic White 7533 39.8 11387 60.2
 Non-Hispanic Black 424 29.9 992 70.1
 Hispanic 2020 35.1 3729 64.9
 Asian/PI 1378 38.7 2186 61.3
 American Indian/Other 64 32.8 131 67.2
Socioeconomic Status
 Lowest SES 1222 30.3 2815 69.7
 Lower-Middle SES 1878 34.6 3557 65.4
 Middle SES 2374 37.5 3950 62.5
 Higher-Middle SES 2769 40.4 4091 59.6
 Highest SES 3176 44.2 4012 55.8
Insurance Type
 Managed Care 5830 41.2 8320 58.8
 Medicare 2438 31.9 5215 68.1
 Medicaid 1001 36.7 1724 63.3
 Other Insurance 1636 42.8 2189 57.2
 Not insured 275 30.9 614 69.1
 Unknown 239 39.7 363 60.3
Marital Status
 Not Married 5029 34.2 9659 65.8
 Married 6390 42.2 8766 57.8
Charlson Comorbidity Score
 CCS 0 5931 41.7 8288 58.3
 CCS 1 2743 40.3 4064 59.7
 CCS 2+ 2078 30.9 4648 69.1
 CCS Unknown 667 31.9 1425 68.1
Stage
 Stage 1 1720 23.8 5518 76.2
 Stage 2 731 29.3 1765 70.7
 Stage 3 5943 52.8 5320 47.2
 Stage 4 3025 34.2 5822 65.8
Hospital Quality Measure
 Low 1912 27.4 5078 72.6
 Intermediate 6533 37.8 10742 62.2
 High 2974 53.3 2605 46.7
Distance Traveled to Care
 <6 km 1911 32.0 4058 68.0
 6–9 km 2133 35.7 3836 64.3
 10–16 km 2262 37.9 3706 62.1
 17–32 km 2358 39.5 3611 60.5
 >32 km 2755 46.2 3214 53.8
Closest High Quality Hospital
 <9 km 2501 41.9 3468 58.1
 9–14 km 2247 37.6 3722 62.4
 15–24 km 2228 37.3 3740 62.7
 25–48 km 2289 38.3 3680 61.7
 >48 km 2154 36.1 3815 63.9
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CCS, Charlson Comorbidity Score; km, kilometers; NCCN, National Comprehensive Cancer Network; PI, Pacific Islander; SES, socioeconomic status

Figure 2:

Figure 2:

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Epithelial Ovarian Cancer Case Distribution in California between 1996 – 2014

3.1. Spatial Analysis of Treatment Adherence

Residential location was significantly associated with non-adherence to NCCN treatment guidelines among California women diagnosed with OC. All analyses, including stage-stratified models, resulted in a highly significant global test for location (<0.001). Compared to base model odds ratios (ORs) adjusted for only age and cancer characteristics for all stages (OR range: 0.46–1.57), fully-adjusted ORs were attenuated in some locations, but increased in other areas (OR range: 0.70–1.89). Figure 3 shows the protective effects observed in northern California were attenuated and no longer present in the San Francisco Bay area after full adjustment. Although the reduced risk observed in the southern-most portion of California was no longer present after full adjustment, risk in northern Los Angeles County and western Kern County increased. Spatial variability in risk of non-adherent treatment with the fully-adjusted models indicates geographic disparities in adherent treatment that are not explained by distance to initial reporting hospital, distance from the nearest high-quality hospital, or the other demographic and treatment variables included in our analyses.

Figure 3: Odds of Receiving Non-Adherent Care for Ovarian Cancer in California.

Figure 3:

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Effect of geographic location on risk of receiving non-adherent National Comprehensive Cancer Network guideline treatment for invasive epithelial ovarian cancer.

*Base model is adjusted for age and cancer characteristics only

Patterns of geographic risk for NCCN non-adherence varied across the different stage-stratified analyses. Regions of increased and decreased risk in the early stage analyses differed greatly from the other stages (comparison of Figure 3 to Figure 4). When controlling for age and cancer characteristics alone, we identified areas of increased risk of non-adherent treatment for early stage OC in mid-Central Valley and decreased risk in Northern California (OR range: 0.49–2.90). After full adjustment of the early stage model, there is no longer an association in northern California and San Diego County; however, Ventura and Santa Barbara Counties in the Central Coast become largely protective (OR range: 0.49–2.90). Models for Stages 3 and 4 display similar patterns to those of all stages combined although areas of higher and lower risk are smaller (Figure 4) and the magnitude of ORs are attenuated (OR ranges 0.61–2.13 and 0.47–1.86 for Stages 3 and 4 respectively).

Figure 4: Odds of Receiving Non-Adherent Care for Ovarian Cancer in California.

Figure 4:

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Effect of geographic location on risk of receiving non-adherent National Comprehensive Cancer Network guideline treatment for invasive epithelial ovarian cancer, stratified by stage. Early stages includes stage 1 and stage 2.

*Base model is adjusted for age and cancer characteristics only.

Associations between all-stage non-adherent care and additional variables included in the spatial model are presented in Table 2. Increasing distance traveled to receive care decreased non-adherence ORs. Compared to patients living <6km of their initial reporting facility, those traveling >32km had decreased odds (OR=0.76, 95%CI=0.70–0.84) of receiving care that deviated from the NCCN guidelines. Increasing distance traveled to receive care was significantly protective against receiving non-adherent care for those in early stages (Table 3). Compared to women in closest proximity to a high-quality hospital (within 9km), living >48km was a significant deterrent to receiving adherent care for women diagnosed in early stages. Patterns with distance were similar for Stages 3 and 4 but generally not significant (not shown).

Table 2:

Multivariate Analysis of NCCN Treatment Non-adherence for All Stages

Characteristic OR 95% Confidence Interval
Age 1.02 1.02 - 1.02
Size Category
 <50mm 1.00 Referent
 50–99mm 0.93 0.85 - 1.02
 100+mm 0.91 0.83 - 0.99
 Size Unknown 1.12 1.03 - 1.22
Grade
 Grade I 1.00 Referent
 Grade II 1.00 0.89 - 1.13
 Grade III 0.85 0.76 - 0.95
 Grade IV 0.73 0.65 - 0.83
 Grade Unknown 2.25 2.00 - 2.54
Stage
 Stage 1 1.00 Referent
 Stage 2 0.75 0.68 - 0.84
 Stage 3 0.25 0.23 - 0.27
 Stage 4 0.33 0.30 - 0.36
Histology
 Serous 1.00 Referent
 Mucinous 1.40 1.24 - 1.58
 Endometrioid 1.22 1.11 - 1.34
 Clear cell 0.91 0.81 - 1.03
 Adenocarcinoma, NOS 2.89 2.59 - 3.22
 Others 1.78 1.66 - 1.91
Race/Ethnicity
 Non-Hispanic White 1.00 Referent
 Non-Hispanic Black 1.21 1.06 - 1.39
 Hispanic 1.01 0.93 - 1.09
 Asian/Pacific Islander 1.02 0.93 - 1.11
 American Indian/Other 1.47 1.05 - 2.05
Socioeconomic Status
 Lowest SES 1.28 1.16 - 1.42
 Lower-middle SES 1.15 1.06 - 1.26
 Middle SES 1.09 1.01 - 1.19
 Higher-middle SES 1.06 0.98 - 1.14
 Highest SES 1.00 Referent
Insurance
 Managed Care 1.00 Referent
 Medicare 1.10 1.03 - 1.19
 Medicaid 1.04 0.94 - 1.15
 Other Insurance 1.01 0.93 - 1.10
 Not insured 1.34 1.14 - 1.58
 Unknown 0.99 0.82 - 1.20
Marital Status
 Not Married 1.00 Referent
 Married 0.85 0.81 - 0.90
Charlson Comorbidity Score
 CCS 0 1.00 Referent
 CCS 1 0.99 0.92 - 1.05
 CCS 2+ 1.19 1.10 - 1.28
 CCS Unknown 1.26 1.13 - 1.41
Year of Diagnosis 1.01 1.00 - 1.01
Hospital Quality Measure
 Low 2.57 2.35 - 2.81
 Intermediate 1.76 1.64 - 1.89
 High 1.00 Referent
Distance Traveled to Care
 <6 km 1.00 Referent
 6–9 km 0.92 0.85 - 1.00
 10–16 km 0.89 0.82 - 0.97
 17–32 km 0.91 0.84 - 1.00
 >32 km 0.76 0.70 - 0.84
Closest High Quality Hospital
 <9 km 1.00 Referent
 9–14 km 1.06 0.97 - 1.15
 15–24 km 1.05 0.97 - 1.15
 25–48 km 1.13 1.04 - 1.23
 >48 km 1.18 1.07 - 1.29
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CCS, Charlson Comorbidity Score; km, kilometers; NCCN, National Comprehensive Cancer Network; NOS, Not otherwise specified; OR, Odds Ratio

Table 3:

Multivariate Analysis of NCCN Treatment Non-adherence for Early Stages (Stage 1 and Stage 2)

Variable OR* 95% Confidence Interval
Distance Traveled to Care
 <6 km 1.00  Referent
 6–9 km 0.82 0.69  - 0.96
 10–16 km 0.83 0.70  - 0.98
 17–32 km 0.77 0.66  - 0.91
 >32 km 0.57 0.49  - 0.68
Closest High Quality Hospital
 <9 km 1.00  Referent
 9–14 km 0.96 0.82  - 1.12
 15–24 km 1.02 0.87  - 1.20
 25–48 km 1.14 0.97  - 1.34
 >48 km 1.25 1.05  - 1.49
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km, kilometers; NCCN, National Comprehensive Cancer Network; OR, Odds Ratio

*

OR adjusted for geographic location, age, race/ethnicity, socioeconomic status, insurance, marital status, Charlson comorbidity score, stage, hospital quality

3.3. Geographic Disparities

The distribution of distance traveled to the reporting hospital by patient characteristics are shown in Table 4. Greater proportions of women treated at high-quality facilities traveled further for care. Among women reported by a high-quality hospital, more than a third (38.1%) lived within 9km, whereas only 9.3% lived >48km (Table 5). In contrast, women reported by low quality hospitals tended to live further from high-quality hospitals (31.4% in furthest category vs. 11.8% in closest).

Table 4:

Comparison of Patient Characteristics by Distance Traveled to Receive Care (n=29,844)*

<6 km 6 – 9 km 10 – 16 km 17 – 32 km > 32 km Total
Age Group N % N % N % N % N % N
 18–44 737 17.5 815 19.4 887 21.1 930 22.1 841 20.0 4210
 45–54 1148 17.9 1130 17.6 1303 20.3 1421 22.1 1421 22.1 6423
 55–64 1252 17.3 1320 18.3 1432 19.8 1535 21.3 1682 23.3 7221
 65+ 2832 23.6 2704 22.6 2346 19.6 2083 17.4 2025 16.9 11990
Race/Ethnicity
 Non-Hispanic White 3831 20.2 3716 19.6 3545 18.7 3657 19.3 4171 22.0 18920
 Non-Hispanic Black 291 20.6 293 20.7 345 24.4 300 21.2 187 13.2 1416
 Hispanic 1099 19.1 1205 21.0 1241 21.6 1226 21.3 978 17.0 5749
 Asian/PI 715 20.1 718 20.1 804 22.6 750 21.0 577 16.2 3564
 American Indian/Other 33 16.9 37 19.0 33 16.9 36 18.5 56 28.7 195
Socioeconomic Status
 Lowest SES 924 22.9 828 20.5 858 21.3 672 16.6 755 18.7 4037
 Lower-Middle SES 1127 20.7 1027 18.9 1070 19.7 1039 19.1 1172 21.6 5435
 Middle SES 1239 19.6 1212 19.2 1178 18.6 1257 19.9 1438 22.7 6324
 Higher-Middle SES 1357 19.8 1303 19.0 1382 20.1 1420 20.7 1398 20.4 6860
 Highest SES 1322 18.4 1599 22.2 1480 20.6 1581 22.0 1206 16.8 7188
Insurance Type
 Managed Care 2528 17.9 2763 19.5 2926 20.7 3111 22.0 2822 19.9 14150
 Medicare 1913 25.0 1687 22.0 1423 18.6 1194 15.6 1436 18.8 7653
 Medicaid 604 22.2 532 19.5 534 19.6 563 20.7 492 18.1 2725
 Other Insurance 675 17.6 717 18.7 730 19.1 764 20.0 939 24.5 3825
 Not insured 145 16.3 155 17.4 202 22.7 223 25.1 164 18.4 889
 Unknown 104 17.3 115 19.1 153 25.4 114 18.9 116 19.3 602
Marital Status
 Not Married 3300 22.5 3051 20.8 2905 19.8 2821 19.2 2611 17.8 14688
 Married 2669 17.6 2918 19.3 3063 20.2 3148 20.8 3358 22.2 15156
Charlson Comorbidity Score
 CCS 0 2664 18.7 2699 19.0 2844 20.0 2967 20.9 3045 21.4 14219
 CCS 1 1360 20.0 1394 20.5 1328 19.5 1321 19.4 1404 20.6 6807
 CCS 2+ 1597 23.7 1468 21.8 1338 19.9 1204 17.9 1119 16.6 6726
 CCS Unknown 348 16.6 408 19.5 458 21.9 477 22.8 401 19.2 2092
Stage
 Stage 1 1345 18.6 1391 19.2 1485 20.5 1542 21.3 1475 20.4 7238
 Stage 2 473 19.0 480 19.2 461 18.5 548 22.0 534 21.4 2496
 Stage 3 2148 19.1 2161 19.2 2203 19.6 2238 19.9 2513 22.3 11263
 Stage 4 2003 22.6 1937 21.9 1819 20.6 1641 18.5 1447 16.4 8847
NCCN Treatment Adherence
 Adherent 1911 16.7 2133 18.7 2262 19.8 2358 20.6 2755 24.1 11419
 Non-Adherent 4058 22.0 3836 20.8 3706 20.1 3611 19.6 3214 17.4 18425
Hospital Quality Measure
 Low 2157 30.9 1594 22.8 1315 18.8 1121 16.0 803 11.5 6990
 Intermediate 3036 17.6 3488 20.2 3590 20.8 3597 20.8 3564 20.6 17275
 High 776 13.9 887 15.9 1063 19.1 1251 22.4 1602 28.7 5579
Closest High Quality Hospital
 <9 km 1843 30.9 1850 31.0 975 16.3 809 13.6 492 8.2 5969
 9–14 km 1100 18.4 1240 20.8 2003 33.6 1109 18.6 517 8.7 5969
 15–24 km 860 14.4 1082 18.1 1404 23.5 1879 31.5 743 12.4 5968
 25–48 km 1023 17.1 1052 17.6 862 14.4 1375 23.0 1657 27.8 5969
 >48 km 1143 19.1 745 12.5 724 12.1 797 13.4 2560 42.9 5969
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*

Statistical significance of differences between groups were calculated using chi-square tests. P-values were <0.001 for all categories

CCS, Charlson Comorbidity Score; km, kilometers; NCCN, National Comprehensive Cancer Network; PI, Pacific Islander; SES, socioeconomic status

Table 5:

Patient Characteristics by Distance to Closest High Quality Hospital (n=29,844)*

< 9 km 9 – 14 km 15 – 24 km 25 – 48 km > 48 km Total
Age Group N % N % N % N % N % N
 18–44 877 20.8 893 21.2 895 21.3 817 19.4 728 17.3 4210
 45–54 1328 20.7 1309 20.4 1273 19.8 1353 21.1 1160 18.1 6423
 55–64 1444 20.0 1452 20.1 1455 20.1 1401 19.4 1469 20.3 7221
 65+ 2320 19.3 2315 19.3 2345 19.6 2398 20.0 2612 21.8 11990
Race/Ethnicity
 Non-Hispanic White 3418 18.1 3399 18.0 3547 18.7 4034 21.3 4522 23.9 18920
 Non-Hispanic Black 308 21.8 319 22.5 436 30.8 234 16.5 119 8.4 1416
 Hispanic 1121 19.5 1275 22.2 1267 22.0 1050 18.3 1036 18.0 5749
 Asian/PI 1083 30.4 939 26.3 692 19.4 619 17.4 231 6.5 3564
 American Indian/Other 39 20.0 37 19.0 26 13.3 32 16.4 61 31.3 195
Socioeconomic Status
 Lowest SES 814 20.2 902 22.3 691 17.1 553 13.7 1077 26.7 4037
 Lower-Middle SES 851 15.7 1094 20.1 1006 18.5 955 17.6 1529 28.1 5435
 Middle SES 1165 18.4 1163 18.4 1196 18.9 1185 18.7 1615 25.5 6324
 Higher-Middle SES 1433 20.9 1264 18.4 1480 21.6 1529 22.3 1154 16.8 6860
 Highest SES 1706 23.7 1546 21.5 1595 22.2 1747 24.3 594 8.3 7188
Insurance Type
 Managed Care 3034 21.4 2867 20.3 3055 21.6 3166 22.4 2028 14.3 14150
 Medicare 1412 18.5 1421 18.6 1385 18.1 1393 18.2 2042 26.7 7653
 Medicaid 595 21.8 662 24.3 496 18.2 399 14.6 573 21.0 2725
 Other Insurance 647 16.9 684 17.9 702 18.4 749 19.6 1043 27.3 3825
 Not insured 166 18.7 187 21.0 203 22.8 167 18.8 166 18.7 889
 Unknown 115 19.1 148 24.6 127 21.1 95 15.8 117 19.4 602
Marital Status
 Not Married 3205 21.8 3049 20.8 2926 19.9 2815 19.2 2693 18.3 14688
 Married 2764 18.2 2920 19.3 3042 20.1 3154 20.8 3276 21.6 15156
Charlson Comorbidity Score
 CCS 0 2844 20.0 2800 19.7 2789 19.6 2925 20.6 2861 20.1 14219
 CCS 1 1324 19.5 1319 19.4 1380 20.3 1360 20.0 1424 20.9 6807
 CCS 2+ 1296 19.3 1363 20.3 1407 20.9 1250 18.6 1410 21.0 6726
 CCS Unknown 505 24.1 487 23.3 392 18.7 434 20.7 274 13.1 2092
Stage
 Stage 1 1476 20.4 1548 21.4 1500 20.7 1396 19.3 1318 18.2 7238
 Stage 2 536 21.5 502 20.1 475 19.0 477 19.1 506 20.3 2496
 Stage 3 2246 19.9 2177 19.3 2261 20.1 2312 20.5 2267 20.1 11263
 Stage 4 1711 19.3 1742 19.7 1732 19.6 1784 20.2 1878 21.2 8847
NCCN Treatment Adherence
 Adherent 2501 21.9 2247 19.7 2228 19.5 2289 20.0 2154 18.9 11419
 Non-Adherent 3468 18.8 3722 20.2 3740 20.3 3680 20.0 3815 20.7 18425
Hospital Quality Measure
 Low 827 11.8 1042 14.9 1448 20.7 1477 21.1 2196 31.4 6990
 Intermediate 3017 17.5 3712 21.5 3604 20.9 3687 21.3 3255 18.8 17275
 High 2125 38.1 1215 21.8 916 16.4 805 14.4 518 9.3 5579
Distance to Receive Care
 <6 km 1843 31.5 1100 18.8 860 14.7 1023 17.5 1023 17.5 5849
 6–9 km 1850 29.5 1240 19.8 1082 17.2 1052 16.8 1052 16.8 6276
 10–16 km 975 16.0 2003 32.8 1404 23.0 862 14.1 862 14.1 6106
 17–32 km 809 12.4 1109 16.9 1879 28.7 1375 21.0 1375 21.0 6547
 >32 km 492 9.7 517 10.2 743 14.7 1657 32.7 1657 32.7 5066
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*

Statistical significance of differences between groups were calculated using chi-square tests. P-values were <0.001 for all categories

CCS, Charlson Comorbidity Score; km, kilometers; NCCN, National Comprehensive Cancer Network; PI, Pacific Islander; SES, socioeconomic status

Non-Hispanic White women and American Indian/Other race made up the largest proportions of women traveling >32km for care (Table 4). Non-Hispanic Black women were the least likely to travel greater distances for care across all analyses. Overall, women diagnosed in Stage 4 were the least likely to travel far, regardless of race, SES, or insurance (data not shown). Noteworthy, Asian/Pacific Islanders (30.4%) and Non-Hispanic Blacks (21.8%) made up the largest proportion of those living <9km of the closest high-quality hospital (Table 5). While less than 10% of women of the highest SES lived >48km from a high-quality hospital, more than 25% of the lower SES quintiles lived >48km.

4. Discussion

Overall, just over one third of women received NCCN guideline-adherent care. This is possibly a result of comorbidities, disease progression, access to specialized facilities, and lower SES.57,12,13,39 Studies examining other cancers have shown similar low rates (<50%) of adherence to NCCN guidelines.40,41 The current study found residential location to be significantly associated with the likelihood of receiving NCCN adherent treatment for women diagnosed with OC. Due to a growing awareness of the impact of residential location on health and the development of more sophisticated analysis tools, the value of geospatial research in cancer is increasing.42 With the availability of geocoded addresses and the use of GAMs, we identified disparities within the state of California where women were more or less at risk of non-adherent care, despite adjusting for numerous important factors and further showed that the impact of location depended on stage at diagnosis. This methodology was previously used to examine late-stage OC survival disparities across California census tracts.8

Differences in spatial patterns of care are increasingly being recognized in the OC literature. One population-based study exploring geographic patterns in treatment delivery and epithelial OC mortality by Health Referral Regions found hospital region to be associated with regional discrepancies in cancer-specific surgery, with women in more remote areas less likely to receive it.14 Our results also show that women living in remote areas of central California, especially those diagnosed at early stages, are more vulnerable to receiving substandard care. Although there is a low density of high-quality centers in nonmetropolitan areas, the risk of treatment non-adherence in California differed depending on residential location. While patients living in rural areas of Northern California had favorable odds, those residing in counties encompassing greater Los Angeles received nonstandard care despite the availability of high-quality centers.

It is well documented that the location of initial treatment for OC is important, in particular high-volume and high-quality centers showing superior outcomes.19,20,22,43 A comprehensive cancer center examining its own patients’ travel distance found that those residing farthest from the hospital had worse cervical cancer outcomes,44 yet a similar analyses of gynecological malignancies treated at a National Cancer Institute-designated center found women living less than 10 miles were less likely to be treatment compliant although those making the longest journey had greater mortality before treatment completion.45 We found women were more likely to access a high-quality hospital if they lived close to one, an association similarly observed by Tracey and colleagues.17 They found more than half of women living within 5km of high-quality hospitals utilized these facilities compared to 16% of women in the farthest quintile.17

The considerable financial challenges already faced coupled with the additional burden that travel poses for women diagnosed with OC must be acknowledged.45 Travel is a geographic barrier to treatment and may disproportionately affect those of lower SES,46 a point illustrated by their overall remoteness from high-quality centers. The implications of geographic access and travel are worth noting, given that women of lower SES and with safety-net insurance or uninsured were less likely to travel for care, obtain care at quality centers, or receive NCCN guideline treatment. Furthermore, women may choose to stay local for care. One study found that approximately 20% of women indicated that they would not travel over 50 miles for care, despite the potential survival advantages.47 This may be particularly true for older women, those with comorbidities, or with limited social support. Greater distances may be less viable for women who may be managing multiple conditions.48 We found women with two or more comorbidities and over 65 years were less likely to travel farther, which is consistent with prior work that older age is associated with shorter journeys.24,48

The present study has several noteworthy features. Among them is the large sample size, with almost 20 years of data available from the CCR, a registry with demonstrated reliability. Additionally, the investigation of geocoded residential location and its differing effects on OC treatment adherence by stage and social demographics is novel. Unlike previous studies that used zip code and census block variables as spatial proxies, utilizing an individual-level measure of patient location allows for a more accurate assessment of the effect of geographic location. Furthermore, the network analyst tool in GIS provided a more precise calculation of travel distance. We were also able to adjust for several important covariates including comorbidity which has been shown to be a main reason for failure to complete chemotherapy.39 Lastly, the GAM framework is particularly useful for investigating nonlinear geographic disparities while accounting for known risk factors.

The study is limited by the potential for reporting bias and the presence of unmeasured confounders given reliance on previously collected registry data. Furthermore, the collection and interpretation of CCR data may be limited by the possibility that reporting facilities are not the main treating hospital, satellite hospitals may report under one hospital, and chemotherapy treatment may be underreported. However, these are thought to be uncommon and unlikely to influence the results in this secondary analysis of large population-based data. Also, we cannot account for several potentially important access characteristics such as travel times and utilization or availability of public transportation. We assumed patients would drive the shortest route between their residence and hospitals to compute distances. However, when reliable transportation is unavailable, difficult, or expensive, travel may pose additional burdens to patients of lower SES. Another limitation is that the CCR does not collect information on the treating physician’s OC case volume or their medical specialty. These characteristics may vary geographically and have been previously found to be predictors of treatment adherence and survival.4951

5. Conclusions

Quality care is vital to decreasing OC mortality, yet the majority of women do not receive it. Future research should examine how location differentially affects access to care and impacts survival. Non-Hispanic Black women, those of lower SES and non-married women were less likely to travel far for care and were more likely to receive non-adherent treatment. Spatial analyses of geographic barriers, using linear and nonlinear methods may provide an opportunity for targeted intervention to broaden access to care among vulnerable populations. Providing transportation, opening satellite clinics, employing patient navigators, and ensuring that those services are covered by all insurance carriers are potential avenues to facilitate access to high-quality care, ultimately improving OC survival overall.16,45

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