http://orcid.org/0000-0002-3098-6160
Figures
Abstract
Purpose
To assess the effect of marital status and the role of race/ethnicity on breast cancer specific mortality in women with triple negative breast cancer (TNBC).
Methods
The study utilized the California Cancer Registry to identify 22,812 cases of first primary female TNBC. Unadjusted Kaplan-Meier breast cancer specific survival was computed. Cox Proportional Hazards modeling was used to compute the adjusted risk of breast cancer specific mortality for women who were single, separated, divorced, and widowed when compared with women who were married. Models were adjusted for age, stage, tumor grade, SES, and treatment with surgery, chemotherapy, hormone therapy, and radiation therapy. Hazard ratios (HR) and 95% confidence intervals (CI) were reported.
Results
Separated (HR: 1.45; 95% CI: 1.14–2.01) and widowed (HR: 1.39; 95%CI: 1.23–1.57) white women had a higher risk of mortality than white married women whereas single and divorced white women had the same risk of mortality. For Asian/Pacific Islanders (API), only single (HR: 1.55; 95% CI: 1.17–2.06) and divorced (HR:1.81; 95% CI:1.26–2.60) women had a higher risk of mortality than married women. Marital status had no influence on risk of mortality for either black or Hispanic women.
Citation: Parise C, Caggiano V (2018) The influence of marital status and race/ethnicity on risk of mortality for triple negative breast cancer. PLoS ONE 13(4): e0196134. https://doi.org/10.1371/journal.pone.0196134
Editor: Robert M. Lafrenie, Sudbury Regional Hospital, CANADA
Received: October 27, 2017; Accepted: April 7, 2018; Published: April 26, 2018
Copyright: © 2018 Parise, Caggiano. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: The data underlying this study belong to the California Cancer Registry (CCR). Interested researchers can request access to the data by applying online using the following link: http://www.ccrcal.org/Data_and_Statistics/Cancer_Data_for_Research.shtml. Researchers are also required to submit the study to the California Committee for the Protection of Human Subjects and the researcher's local Institutional Review Committee before the CCR will release the data to the investigator. The authors did not have any special access privileges.
Funding: This study was funded by grant 947110-1107555 from the Sutter Medical Center Sacramento Foundation. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Breast cancer is the most common cancer among women but it is a heterogeneous disease and there is variability in both incidence and survival among breast cancer subtypes. Triple negative breast cancer (TNBC), characterized as being negative for estrogen receptor (ER), progesterone receptor (PR), and human epidermal receptor growth factor 2 (HER2), is the second most common breast cancer subtype and has the worst prognosis. [1–3]
When all breast cancer subtypes are combined and breast cancer is considered a single disease, tumor characteristics such as stage at diagnosis and tumor grade as well as social factors including race/ethnicity and marital status have been found to be associated with both breast cancer incidence and survival. Disparities in the incidence and mortality of breast cancer among white, African American, Hispanic, Asian, and American Indian women have been well-documented. [4–8] Studies of individual breast cancer subtypes have shown that TNBC is more common in young women, black and Hispanic women, and women of lower socioeconomic status (SES) when compared with the ER+/PR+/HER2- subtype, the most common breast cancer subtype. [9, 10]
Marriage has been found to have a survival advantage for many cancers including breast cancer. [11–15] However, it is unknown whether this advantage applies to all breast cancer subtypes. The purpose of this study is to assess the effect of marital status on breast cancer specific mortality in women with TNBC and evaluate the role of race/ethnicity on this association.
Methods
The study utilized the California Cancer Registry (CCR) to identify 22,812 cases of first primary female TNBC diagnosed between January 1, 2000 and December 31, 2014 and reported to the CCR as of December 31, 2015. (ICDO-3 sites C50.0-C50.9) [16] Cases had complete data for tumor size, grade, American Joint Commission on Cancer (AJCC) stage of diagnosis, surgery (lumpectomy, mastectomy), chemotherapy, hormone therapy, radiation therapy, cause of death, age, socioeconomic status (SES), marital status, and race/ethnicity. This research study involved analysis of existing data from the CCR without subject identifiers or intervention. Therefore, the study was categorized as exempt from institutional review board oversight.
The determination of mortality, ER, PR, HER2, race/ethnicity, and socioeconomic status are the same as reported in many of our previous publications [7, 9, 17–23] Cases were reported to the Cancer Surveillance Section of the California Department of Public Health from hospitals and other facilities providing care or therapy to cancer patients residing in California. [24] Breast cancer-specific mortality was defined as a death due to breast cancer as documented by the codes ranging from C50.01 to C50.91 of the International Statistical Classification of Diseases and Related Health Problems, 10th Revision. [25]
ER and PR status were recorded according to pathologists' interpretation of the assays. ER and PR were considered negative if immunoperoxidase staining of tumor cell nuclei was less than 5%. ER and PR status may also have been determined by examining cytosol protein. ER was considered negative if there were fewer than 3 femtomoles per milligram of cytosol protein and PR was considered negative if there were fewer than 5 femtomoles per milligram of cytosol protein. [16]
HER2 was assessed through immunohistochemistry (IHC) or fluorescence in situ hybridization (FISH). IHC is scored on a qualitative scale from 0 to 3+, based on interpretation of staining intensity, with 0 through 1+ classified as negative, 2+ as borderline, and 3+ as positive. [26] FISH was scored on a quantitative scale with less than 2 copies of the HER2 gene classified as negative and two or more copies as positive. [27]
Race was based on information obtained from the medical record which was derived from patient self-identification, assumptions based on personal appearance, or inferences based on the race of the parents, birthplace, surname, or maiden name. For the present study, race/ethnicity was classified into four mutually exclusive categories: non-Hispanic white, African American or black, Hispanic, and Asian/Pacific Islander.
SES was derived using data from the 2000 US census for cases diagnosed from 2000 through 2005, and the American Community Survey was used for cases diagnosed from 2006 through 2014. [28]This SES variable is an index that utilizes education, employment characteristics, median household income, proportion of the population living 200% below the Federal Poverty Level, median rent and median housing value of census tract of residence for case and denominator population. A principal component analysis was used to identify quintiles of SES ranging from 1 (the lowest) to 5 (the highest).[29] This area based SES measure has been used in many studies utilizing cancer registry data.[9, 17, 30–36]
Marital status was defined at the time of diagnosis as married, single/never married, separated, divorced, and widowed.
Statistical analysis
Contingency tables were used to evaluate the distribution of age, stage, subtype, tumor size, tumor grade, race/ethnicity, treatment, SES, and race/ethnicity for each classification of marital status. Difference in mean age by marital status was compared using analysis of variance and post hoc tests.
Kaplan–Meier survival analysis and the Log-Rank test were used to compare unadjusted survival rates by marital status for each race/ethnicity. Cox Proportional Hazards modeling was used to compute the risk of mortality for women who were single, separated, divorced, and widowed when compared with women who were married. The race by marital status interaction was tested to determine if the risk of mortality associated with marital status depended on race. Models were adjusted for age, stage, tumor grade, SES, and treatment with surgery (lumpectomy, mastectomy), chemotherapy, hormone therapy, and radiation therapy. Variables were considered statistically significant and HRs were interpreted only when the Wald Χ2 was p< 0.05.
All analyses were performed using IBM SPSS 21.0. [37]
Results and discussion
Over 50% of white, Hispanic, and API women were married and 39% of black women were married. Thirty-two percent of black women were single compared with less than 20% for all other ethnicities. There was an inverse association in stage at diagnosis for single and married women. The percent of single women increased with increasing stage at diagnosis and the opposite was true for married women. (Table 1)
Results of the Cox Regression analysis indicated that the race X marital status interaction was statistically significant (χ2 df = 12 = 31.05, p = 0.002). Therefore separate models were computed for each race/ethnicity so that Kaplan-Meier survival statistics, hazard ratios (HR), and 95% confidence intervals (CI) assessed differences between women of the same race. Fig 1. shows the Kaplan-Meier breast cancer specific survival graphs according to marital status for white (Panel A), black (Panel B), Hispanic (Panel C), and API (Panel D) women.
A marital advantage was apparent but differences were noted within the race/ethnicities. Married white women had superior survival over single (p = 0.006), separated (p < 0.001), divorced (p < 0.001), and widowed (p < 0.001) white women. Married black women only had better survival than single black women (p = 0.003). Married Hispanic women had better survival than both single (p = 0.002) and widowed Hispanic women (p < 0.001). Married API women had better survival than all except for separated API women (p = 0.067).
Table 2 shows the HRs and 95% confidence intervals for women who were single, separated, divorced, or widowed when compared with married women of the same race. Separated and widowed white women had a higher risk of mortality than white married women whereas single and divorced white women had the same risk of mortality. For APIs, only single and divorced women had a higher risk of mortality than married women. Marital status had no influence on risk of mortality for either black (X24 = 2.06; p = 0.726) or Hispanic (X24 = 5.94, p = 0.204) women.
Hazard ratios are adjusted for age, stage, grade, socioeconomic status, and treatment.
Marriage has been found to be advantageous for cancer survival for both men and women. [38–41] Studies of the association of marital status with breast cancer survival have shown that younger, unmarried women are diagnosed with breast cancer at later stages and are more likely to die of the disease than married women. [12, 15, 42–47]
The so called marital advantage has been found to vary by race/ethnicity. [48] Martinez [46] and colleagues found that all-cause mortality in cancer patients was higher in unmarried versus married patients but risk of mortality was worse for unmarried white women than for unmarried API women. Simon and Severson [49] noted that marriage did not improve the relative risk of dying of breast cancer in African American versus white women and Weider et al. [50] reported that African American race was a poor prognostic indicator for breast cancer survival independent of marital status.
Although socioeconomic status (SES) is a known risk factor for survival for several types of cancer [9, 20, 33] it appears that marital status is an independent risk factor. [51] The most likely link between marriage and breast cancer survival is social support. Several studies suggest that a strong social network is associated with better survival. [52–58] Family, friends, and spouses motivate each other to seek medical care which can lead to an earlier cancer diagnosis. [12, 59] They also encourage their family and friends with cancer to follow up with their treatments and seek support from other breast cancer survivors. [60]
Conversely, stress and social isolation have been found associated with poorer health for breast cancer survivors. [61–65] Cancer patients with lower levels or loss of perceived support are at a higher risk for mortality. [39, 66] These studies suggest that if presence of a supportive spouse predicts lower mortality, [56] then women with breast cancer in stressful marriages would not benefit from the marital advantage.
Most studies of breast cancer survival combine all subtypes. However, incidence, survival, and prognostic factors vary among the breast cancer subtypes defined by ER, PR, and HER2. [18] We chose to exclusively study TNBC because it is the most lethal subtype and there are racial/ethnic differences in survival. Black and Hispanic women are more likely to be diagnosed with and die from TNBC than white women. [9, 67, 68]
Our results concur with studies that found that married women with breast cancer fare better than unmarried women. However, when adjusting for sociodemographic and tumor characteristics, marriage is only an advantage for white and API women, the races least likely to have TNBC, whereas black and Hispanic women with TNBC have no advantage if they are married. [1–3, 9, 10]
The present study was designed to compare the risk of mortality associated with marital status of women with TNBC within a single race/ethnicity so that the hazard ratios represented single, separated, divorced, and widowed women compared with married women of the same race/ethnicity. This makes it difficult to compare our findings to those of the literature because to our knowledge, this is the first study that assessed breast cancer mortality for a single subtype within four race/ethnicities.
Why do black and Hispanic women with TNBC not have a marital advantage? There is some evidence that black women have lower marital satisfaction than white women which may partially explain our results. [69–71] We found no evidence in the literature to support that Hispanic women have less satisfactory marriages than white women but our findings concur with Delgado et al [72] who found no difference in risk of breast cancer mortality in married versus unmarried Hispanic women. Future investigations that measure perceived marital support by race/ethnicity would be necessary to provide insight on the results of the present study.
Retrospective, population-based studies using cancer registry data have limitations. The determination of ER, PR, and HER2 were performed by a wide variety of laboratories without testing inter-rater reliability. Treatment information from the CCR lacks specific information regarding drug type and dose. The classification of race/ethnicity could have influenced the results, especially for the Asian/Pacific Islander group. Previous publications found marked variability within Asian/Pacific Islanders in both incidence and survival of the ER/PR/HER2 subtypes when this group was split into seven Asian categories versus combing them all into one. [7, 21]. It is possible that the results among Asian/Pacific Islander women may have been different had we stratified this category into seven groups. However, we did not have sufficient cases to break the category down any further since we were only including cases of TNBC.
Despite these limitations, a study of over 22,000 cases of triple negative breast cancer allows for stratified analysis of race/ethnicity and provides real world insight.
Conclusion
The risk of mortality associated with marital status is dependent on race/ethnicity. White and API women but not black and Hispanic women with TNBC have a marital advantage.
Acknowledgments
We wish to thank Melissa Taylor and the staff at the Sutter Resource Library for their valuable assistance.
References
- 1. Dawood S, Broglio K, Kau SW, Green MC, Giordano SH, Meric-Bernstam F, et al. Triple receptor-negative breast cancer: the effect of race on response to primary systemic treatment and survival outcomes. J Clin Oncol. 2009;27(2):220–6. pmid:19047281
- 2. Li X, Yang J, Peng L, Sahin AA, Huo L, Ward KC, et al. Triple-negative breast cancer has worse overall survival and cause-specific survival than non-triple-negative breast cancer. Breast Cancer Res Treat. 2017;161(2):279–87. pmid:27888421.
- 3. Vona-Davis L, Rose DP, Hazard H, Howard-McNatt M, Adkins F, Partin J, et al. Triple-negative breast cancer and obesity in a rural Appalachian population. Cancer Epidemiol Biomarkers Prev. 2008;17(12):3319–24. pmid:19064545
- 4. Shavers VL, Harlan LC, Stevens JL. Racial/ethnic variation in clinical presentation, treatment, and survival among breast cancer patients under age 35. Cancer. 2003;97(1):134–47. pmid:12491515.
- 5. Silber JH, Rosenbaum PR, Clark AS, Giantonio BJ, Ross RN, Teng Y, et al. Characteristics associated with differences in survival among black and white women with breast cancer. JAMA. 2013;310(4):389–97. pmid:23917289.
- 6. Tannenbaum SL, Koru-Sengul T, Miao F, Byrne MM. Disparities in survival after female breast cancer diagnosis: a population-based study. Cancer Causes Control. 2013;24(9):1705–15. pmid:23775026.
- 7. Parise C, Caggiano V. Disparities in the risk of the ER/PR/HER2 breast cancer subtypes among Asian Americans in California. Cancer Epidemiol. 2014;38(5):556–62. pmid:25172158.
- 8. Iqbal J, Ginsburg O, Rochon PA, Sun P, Narod SA. Differences in breast cancer stage at diagnosis and cancer-specific survival by race and ethnicity in the United States. JAMA. 2015;313(2):165–73. pmid:25585328.
- 9. Bauer KR, Brown M, Cress RD, Parise CA, Caggiano V. Descriptive analysis of estrogen receptor (ER)-negative, progesterone receptor (PR)-negative, and HER2-negative invasive breast cancer, the so-called triple-negative phenotype: a population-based study from the California cancer Registry. Cancer. 2007;109(9):1721–8. pmid:17387718.
- 10. Parise CA, Caggiano V. Risk factors associated with the triple-negative breast cancer subtype within four race/ethnicities. Breast Cancer Res Treat. 2017;163(1):151–8. pmid:28213780.
- 11. Neale AV. Racial and marital status influences on 10 year survival from breast cancer. J Clin Epidemiol. 1994;47(5):475–83. pmid:7730873.
- 12. Aizer AA, Chen MH, McCarthy EP, Mendu ML, Koo S, Wilhite TJ, et al. Marital status and survival in patients with cancer. J Clin Oncol. 2013;31(31):3869–76. pmid:24062405
- 13. Eskander MF, Schapira EF, Bliss LA, Burish NM, Tadikonda A, Ng SC, et al. Keeping it in the family: the impact of marital status and next of kin on cancer treatment and survival. Am J Surg. 2016;212(4):691–9. pmid:27712668.
- 14. Bender PFM, de Oliveira LL, Costa CR, de Aguiar SS, Bergmann A, Thuler LCS. Men and women show similar survival rates after breast cancer. J Cancer Res Clin Oncol. 2017;143(4):563–71. pmid:27933394.
- 15. Martinez ME, Unkart JT, Tao L, Kroenke CH, Schwab R, Komenaka I, et al. Prognostic significance of marital status in breast cancer survival: A population-based study. PLoS One. 2017;12(5):e0175515. pmid:28475579
- 16.
Fritz AG. International classification of diseases for oncology: ICD-O. 3rd ed. Geneva: World Health Organization, Geneva; 2000. p. vi, 239.
- 17. Brown M, Tsodikov A, Bauer KR, Parise CA, Caggiano V. The role of human epidermal growth factor receptor 2 in the survival of women with estrogen and progesterone receptor-negative, invasive breast cancer: The California Cancer Registry, 1999–2004. Cancer. 2008;112(4):737–47. pmid:18189290.
- 18. Parise CA, Bauer KR, Brown MM, Caggiano V. Breast Cancer Subtypes as Defined by the Estrogen Receptor (ER), Progesterone Receptor (PR), and the Human Epidermal Growth Factor Receptor 2 (HER2) among Women with Invasive Breast Cancer in California, 1999–2004. Breast J. 2009;15(6):593–602. pmid:19764994.
- 19. Parise CA, Bauer KR, Caggiano V. Variation in breast cancer subtypes with age and race/ethnicity. Crit Rev Oncol Hematol. 2010;76(1):44–52. pmid:19800812.
- 20. Parise CA, Caggiano V. The Influence of Socioeconomic Status on Racial/Ethnic Disparities among the ER/PR/HER2 Breast Cancer Subtypes. J Cancer Epidemiol. 2015;2015:813456. pmid:26339244
- 21. Parise C, Caggiano V. Breast Cancer Mortality among Asian-American Women in California: Variation according to Ethnicity and Tumor Subtype. J Breast Cancer. 2016;19(2):112–21. pmid:27382386
- 22. Parise CA, Caggiano V. Risk of mortality of node-negative, ER/PR/HER2 breast cancer subtypes in T1, T2, and T3 tumors. Breast Cancer Res Treat. 2017;165(3):743–50. pmid:28689363.
- 23. Parise CA, Caggiano V. Regional Variation in Disparities in Breast Cancer Specific Mortality Due to Race/Ethnicity, Socioeconomic Status, and Urbanization. J Racial Ethn Health Disparities. 2017;4(4):706–17. pmid:27604380.
- 24.
Cancer reporting in California: Abstracting and coding procedures for hospitals. California cancer reporting system standards, Volume I. Sacramento, CA: California Department of Public, Cancer Surveillance and Research Branch; 2008.
- 25.
ICD10Data.com. http://www.icd10.com. Accessed, January 2016.
- 26.
DAKO HERCEPTest® Information Web site. Summary of Procedure. 2003 [June, 2006]. October 15:[http://www.dako.com/.
- 27.
PathVision HER-2 DNA Probe Kit Package Insert. Vysis, Inc. 2002.
- 28.
American Community Survey. U.S Department of Commerce, United States Census Bureau https://www.census.gov/programs-surveys/acs/ Accessed January, 2016.
- 29. Yost K, Perkins C, Cohen R, Morris C, Wright W. Socioeconomic status and breast cancer incidence in California for different race/ethnic groups. Cancer Causes Control. 2001;12(8):703–11. pmid:11562110.
- 30. Clarke CA, Glaser SL, Keegan TH, Stroup A. Neighborhood socioeconomic status and Hodgkin's lymphoma incidence in California. Cancer Epidemiol Biomarkers Prev. 2005;14(6):1441–7. pmid:15941953.
- 31. Parikh-Patel A, Bates JH, Campleman S. Colorectal cancer stage at diagnosis by socioeconomic and urban/rural status in California, 1988–2000. Cancer. 2006;107(5 Suppl):1189–95. pmid:16835910.
- 32. Zell JA, Rhee JM, Ziogas A, Lipkin SM, Anton-Culver H. Race, socioeconomic status, treatment, and survival time among pancreatic cancer cases in California. Cancer Epidemiol Biomarkers Prev. 2007;16(3):546–52. pmid:17372250.
- 33. Ou SH, Zell JA, Ziogas A, Anton-Culver H. Low socioeconomic status is a poor prognostic factor for survival in stage I nonsmall cell lung cancer and is independent of surgical treatment, race, and marital status. Cancer. 2008;112(9):2011–20. pmid:18361399.
- 34. Yin D, Morris C, Allen M, Cress R, Bates J, Liu L. Does socioeconomic disparity in cancer incidence vary across racial/ethnic groups? Cancer Causes Control. 2010;21(10):1721–30. pmid:20567897.
- 35. Telli ML, Chang ET, Kurian AW, Keegan TH, McClure LA, Lichtensztajn D, et al. Asian ethnicity and breast cancer subtypes: a study from the California Cancer Registry. Breast Cancer Res Treat. 2011;127(2):471–8. pmid:20957431.
- 36. Parise CA, Bauer KR, Caggiano V. Disparities in receipt of adjuvant radiation therapy after breast-conserving surgery among the cancer-reporting regions of California. Cancer. 2012;118(9):2516–24. pmid:21918967.
- 37.
IBM SPSS Statistics for Windows. vol 21.0. IBM Corp. Armonk NY. 2012.
- 38. Ernster VL, Sacks ST, Selvin S, Petrakis NL. Cancer incidence by marital status: U.S. Third National Cancer Survey. J Natl Cancer Inst. 1979;63(3):567–85. pmid:288925.
- 39. Pinquart M, Duberstein PR. Associations of social networks with cancer mortality: a meta-analysis. Crit Rev Oncol Hematol. 2010;75(2):122–37. pmid:19604706
- 40. Kravdal H, Syse A. Changes over time in the effect of marital status on cancer survival. BMC Public Health. 2011;11(1):804. pmid:21999466
- 41. O'Brien B, Koru-Sengul T, Miao F, Saclarides C, Tannenbaum SL, Alghamdi H, et al. Disparities in Overall Survival for Male Breast Cancer Patients in the State of Florida (1996–2007). Clin Breast Cancer. 2015;15(4):e177–87. pmid:25726509.
- 42. Goodwin JS, Hunt WC, Key CR, Samet JM. The effect of marital status on stage, treatment, and survival of cancer patients. JAMA. 1987;258(21):3125–30. pmid:3669259.
- 43. Kato I, Tominaga S, Terao C. An epidemiological study on marital status and cancer incidence. Jpn J Cancer Res. 1989;80(4):306–11. pmid:2501246.
- 44. Chang SM, Barker FG 2nd. Marital status, treatment, and survival in patients with glioblastoma multiforme: a population based study. Cancer. 2005;104(9):1975–84. pmid:16130137.
- 45. Du KL, Bae K, Movsas B, Yan Y, Bryan C, Bruner DW. Impact of marital status and race on outcomes of patients enrolled in Radiation Therapy Oncology Group prostate cancer trials. Support Care Cancer. 2012;20(6):1317–25. pmid:21720747.
- 46. Martinez ME, Anderson K, Murphy JD, Hurley S, Canchola AJ, Keegan TH, et al. Differences in marital status and mortality by race/ethnicity and nativity among California cancer patients. Cancer. 2016;122(10):1570–8. pmid:27065455.
- 47. Hinyard L, Wirth LS, Clancy JM, Schwartz T. The effect of marital status on breast cancer-related outcomes in women under 65: A SEER database analysis. Breast. 2017;32:13–7. pmid:28012410.
- 48. Swanson GM, Belle SH, Satariano WA. Marital status and cancer incidence: differences in the black and white populations. Cancer Res. 1985;45(11 Pt 2):5883–9. pmid:4053058.
- 49. Simon MS, Severson RK. Racial differences in survival of female breast cancer in the Detroit metropolitan area. Cancer. 1996;77(2):308–14. pmid:8625239.
- 50. Wieder R, Shafiq B, Adam N. African American Race is an Independent Risk Factor in Survival from Initially Diagnosed Localized Breast Cancer. J Cancer. 2016;7(12):1587–98. pmid:27698895
- 51. Gomez SL, Hurley S, Canchola AJ, Keegan TH, Cheng I, Murphy JD, et al. Effects of marital status and economic resources on survival after cancer: A population-based study. Cancer. 2016;122(10):1618–25. pmid:27065317.
- 52. Spiegel D, Bloom JR, Kraemer HC, Gottheil E. Effect of psychosocial treatment on survival of patients with metastatic breast cancer. Lancet. 1989;2(8668):888–91. pmid:2571815.
- 53. Maunsell E, Brisson J, Deschenes L. Social support and survival among women with breast cancer. Cancer. 1995;76(4):631–7. pmid:8625157.
- 54. Osborne C, Ostir GV, Du X, Peek MK, Goodwin JS. The influence of marital status on the stage at diagnosis, treatment, and survival of older women with breast cancer. Breast Cancer Res Treat. 2005;93(1):41–7. pmid:16184457.
- 55. Soler-Vila H, Kasl SV, Jones BA. Prognostic significance of psychosocial factors in African-American and white breast cancer patients: a population-based study. Cancer. 2003;98(6):1299–308. pmid:12973855.
- 56. Kroenke CH, Kubzansky LD, Schernhammer ES, Holmes MD, Kawachi I. Social networks, social support, and survival after breast cancer diagnosis. J Clin Oncol. 2006;24(7):1105–11. pmid:16505430.
- 57. Hanske J, Meyer CP, Sammon JD, Choueiri TK, Menon M, Lipsitz SR, et al. The influence of marital status on the use of breast, cervical, and colorectal cancer screening. Prev Med. 2016;89:140–5. pmid:27215758.
- 58. Merrill RM, Johnson E. Benefits of marriage on relative and conditional relative cancer survival differ between males and females in the USA. J Cancer Surviv. 2017. pmid:28770444.
- 59. Aizer AA, Paly JJ, Zietman AL, Nguyen PL, Beard CJ, Rao SK, et al. Multidisciplinary care and pursuit of active surveillance in low-risk prostate cancer. J Clin Oncol. 2012;30(25):3071–6. pmid:22851571.
- 60. Napoles-Springer AM, Ortiz C, O'Brien H, Diaz-Mendez M, Perez-Stable EJ. Use of cancer support groups among Latina breast cancer survivors. J Cancer Surviv. 2007;1(3):193–204. pmid:18648970.
- 61. Funch DP, Marshall J. The role of stress, social support and age in survival from breast cancer. J Psychosom Res. 1983;27(1):77–83. pmid:6834302.
- 62. Yang HC, Schuler TA. Marital quality and survivorship: slowed recovery for breast cancer patients in distressed relationships. Cancer. 2009;115(1):217–28. pmid:18951520
- 63. Elefteriou F. Chronic stress, sympathetic activation and skeletal metastasis of breast cancer cells. Bonekey Rep. 2015;4:693. pmid:25987989
- 64. Fleisch Marcus A, Illescas AH, Hohl BC, Llanos AA. Relationships between social isolation, neighborhood poverty, and cancer mortality in a population-based study of US adults. PLoS One. 2017;12(3):e0173370. pmid:28273125
- 65. Leung J, Smith MD, McLaughlin D. Inequalities in long term health-related quality of life between partnered and not partnered breast cancer survivors through the mediation effect of social support. Psychooncology. 2016;25(10):1222–8. pmid:27062092.
- 66. Sephton SE, Sapolsky RM, Kraemer HC, Spiegel D. Diurnal cortisol rhythm as a predictor of breast cancer survival. J Natl Cancer Inst. 2000;92(12):994–1000. pmid:10861311.
- 67. Lara-Medina F, Perez-Sanchez V, Saavedra-Perez D, Blake-Cerda M, Arce C, Motola-Kuba D, et al. Triple-negative breast cancer in Hispanic patients: high prevalence, poor prognosis, and association with menopausal status, body mass index, and parity. Cancer. 2011;117(16):3658–69. pmid:21387260.
- 68. Hines LM, Risendal B, Byers T, Mengshol S, Lowery J, Singh M. Ethnic disparities in breast tumor phenotypic subtypes in Hispanic and non-Hispanic white women. J Womens Health (Larchmt). 2011;20(10):1543–50. pmid:21721934
- 69. Broman C. Race differences in marital well-being. Journal of Marriage and the Family. 1993;55(August 1993):724–32.
- 70. Dillaway H, Broman C. Race, class, and gender differences in marital satisfaction and divisions of household labor among dual-earner couples. Journal of Family Issues. 2001;22(3):309–27.
- 71. Bryant CM, Taylor RJ, Lincoln KD, Chatters LM, Jackson JS. Marital Satisfaction Among African Americans and Black Caribbeans: Findings From the National Survey of American Life. Fam Relat. 2008;57(2):239–53. pmid:21151891
- 72. Delgado DJ, Lin WY, Coffey M. The role of Hispanic race/ethnicity and poverty in breast cancer survival. P R Health Sci J. 1995;14(2):103–16. pmid:7617830.