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Journal of Women's Health logoLink to Journal of Women's Health
. 2022 May 16;31(5):665–674. doi: 10.1089/jwh.2021.0176

Factors Associated with Unplanned Pregnancy Among Cancer Survivors

Lisa M Shandley 1,, Lauren M Kipling 2, Jessica B Spencer 1, Diane Morof 3,4, Ann C Mertens 5, Penelope P Howards 2
PMCID: PMC9133970  PMID: 34860591

Abstract

Background:

Approximately half of all pregnancies in the United States are unintended. However, women who are diagnosed with cancer in their reproductive years may be a unique population. This study examines the prevalence of and identifies factors associated with unplanned pregnancy among cancer survivors.

Materials and Methods:

Female cancer survivors aged 22–45 years, diagnosed between ages 20–35 years and at least 2 years postdiagnosis, and women with no history of cancer were interviewed about their reproductive histories, including pregnancy intention. Using a random matching process, comparison women were assigned an artificial age at cancer diagnosis equal to that of her cancer survivor match. An adjusted Cox model was fit examining time to unintended pregnancy after cancer for each of 1,000 matches. Cox proportional hazards models were also fit to assess associations between participant characteristics and unplanned pregnancy after cancer among survivors.

Results:

Cancer survivors (n = 1,282) and comparison women (n = 1,073) reported a similar likelihood of having an unplanned pregnancy in models adjusted for race, income, history of sexually-transmitted infection, and history of unplanned pregnancy before diagnosis (adjusted hazard ratio [aHR] 1.06, 95% simulation interval 0.85–1.36). After adjusting for confounders, unplanned pregnancy among survivors was associated with age <30 years at diagnosis (hazard ratio [HR]: 1.79, 95% confidence interval [CI]: 1.32–2.44), black race (HR: 1.55, 95% CI: 1.13–2.12; referent: white), receiving fertility counseling (aHR: 1.41, 95% CI: 1.04–1.92), and having at least one child before diagnosis (aHR: 1.44, 95% CI: 1.05–1.97).

Conclusion:

Cancer survivors and comparison women had similar likelihood of unplanned pregnancy. Rates of unplanned pregnancy after cancer were not higher for cancer survivors compared with comparison women, but 46.4% of survivors with a postcancer pregnancy reported an unplanned pregnancy. Cancer patients may benefit from patient-centered guidelines and counseling before cancer treatment that covers both risks of infertility and risks of unplanned pregnancy.

Keywords: unplanned pregnancy, fertility counseling, cancer survivorship, contraceptive counseling, family planning

Introduction

Approximately 92,960 women aged 44 years or younger were diagnosed with cancer in the United States in 2020.1,2 Meanwhile, the overall 5-year cancer survival rate approaches 70%3 leading to increasing focus on issues associated with cancer survivorship, including fertility and family planning. Nevertheless, studies suggest that many reproductive-aged cancer survivors feel that their concerns about reproduction and sexual health are inadequately addressed.4,5

In the United States, ∼45% of pregnancies are unintended (wanted later or not at all).6 However, little is known about reproductive-aged female cancer survivors.7 While some cancer treatments impair fertility8–10 or increase risk of premature ovarian failure (POF),11–15 most reproductive-aged cancer survivors continue to menstruate after treatment.16–18 Previous studies suggest that cancer survivors have sexual and contraceptive practices that put them at risk for unplanned pregnancy. Survivors have been reported to be thrice more likely to have regular unprotected intercourse compared with women with no history of cancer,16 and survivors who use contraception are less likely to use the most effective forms (Tier I/II).19,20 Female cancer survivors may also be more likely to use emergency contraception compared with the general population.21 Generally, survivors may have inadequate awareness of their contraceptive options.22,23

We report the prevalence of unplanned pregnancy in a cohort of reproductive-aged female cancer survivors and identify factors associated with unplanned pregnancy after cancer.

Materials and Methods

Study population

The Furthering Understanding of Cancer, Health, and Survivorship in Adult (FUCHSIA) Women's Study is a population-based study examining the effect of cancer during the reproductive years on future fertility. Female cancer survivors were identified across the state of Georgia in collaboration with the Georgia Cancer Registry as described in greater detail elsewhere.24 Survivors diagnosed between 1990 and 2009 with any reportable malignant cancer25 or ductal carcinoma in situ, who were between the ages of 20–35 years at diagnosis, and were at least 2 years postdiagnosis were eligible. Recruitment for those diagnosed with thyroid cancer and melanoma was restricted to Metropolitan Atlanta. Comparison women with no history of cancer represented the general population. Comparison women were identified using a purchased marketing list and were frequency matched to the survivors on age and location of residence. All women were 22–45 years old at enrollment (2012–2013), had a working telephone, and spoke English.

Informed consent was obtained from all participants. The Emory University and Georgia Department of Public Health Institutional Review Boards approved this study.

Procedures

Participants were interviewed by telephone about their demographics, desire for children, reproductive history, menstrual history, medical history, and lifestyle. Cancer survivors also answered questions about their cancer history. Cancer diagnosis and treatment information were abstracted from medical records.

For each pregnancy, participants were asked their age at pregnancy and whether or not contraception was being used at the time. Pregnancies occurring when women were actively contracepting were considered unplanned pregnancies. Women who got pregnant while not using any contraception were asked whether they were trying to become pregnant with the options “trying,” “neither trying nor not trying,” or “not trying.” Women who reported a pregnancy for which they were “not trying” were classified as having an unplanned pregnancy.

Factors hypothesized to be associated with unplanned pregnancy included age, self-identified race, education, income, health insurance status, gravidity, parity, history of ever using hormonal contraception or a nonhormonal intrauterine device (Cu-IUD), marital status, obesity, smoking history, current alcohol use, and ever diagnosed with a chronic medical condition. Cancer-related factors of interest included type, chemotherapy or radiation treatment, time since diagnosis, fertility counseling, hormone-receptor sensitivity and tamoxifen use (breast cancer survivors only), and having an abortion before diagnosis. Receipt of fertility counseling was assessed by the question, “Did you talk to a doctor or other health professional about how this cancer treatment could affect your ability to become pregnant?”

Statistical analysis

Descriptive statistics was used to examine the population, comparing cancer survivors with comparison women.

To compare rates of unplanned pregnancy after cancer, each cancer survivor was randomly matched with replacement to a comparison woman in the study population based on birth year and parity at age of cancer diagnosis. Comparison women were assigned the cancer diagnosis age of their matched pair as a proxy-diagnosis age. Cox proportional hazards models were fit to estimate time from (actual or proxy) diagnosis to first unplanned pregnancy. Participants without an unplanned pregnancy were censored at hysterectomy, bilateral oophorectomy, bilateral tubal ligation, endometrial ablation, or study interview. The matching simulation was repeated 1,000 times for each model. We report the average hazard ratio (HR) and 95% simulation interval (SI) based on the 2.5 and 97.5 percentiles of the simulation results for each model.

For cancer survivors, we examined survivor characteristics associated with unplanned pregnancy. We fit separate Cox proportional hazards models to assess the unadjusted association between each hypothesized behavioral, socioeconomic, and cancer-related factor with unplanned pregnancy. We hypothesized that the association between each factor and unplanned pregnancy would be confounded by a different set of covariates based on causal diagrams. Therefore, instead of fitting a single model, including all factors of interest, we fit separate Cox models for each factor adjusted for the relevant set of confounders.26

Confounders for having a precancer unplanned pregnancy and for receiving fertility counseling included age at diagnosis and race.6,27,28 Confounders for being diagnosed with a sexually transmitted infection (STI) included race and age at the interview.29–31 We did not identify any confounders for age at diagnosis, race, or location of residence (urban vs. rural).

We also performed a subanalysis restricting to breast cancer survivors, the most common diagnosis.

Results

Risk of unplanned pregnancy in cancer survivors versus comparison women

We interviewed 1,282 cancer survivors and 1,073 comparison women. Sample characteristics are shown in Table 1. A similar proportion of cancer survivors and comparison women reported ever using hormonal contraception or Cu-IUD (79.9% vs. 84.8%, respectively), but a smaller proportion of survivors reported using contraception in the past year (23.0% vs. 32.9%). Approximately half of both the cancer survivors and the comparison women reported having at least one unplanned pregnancy, and just under 5% in each group reported at least one pregnancy for which they were neither trying nor not trying (Table 2). However, 23.9% of cancer survivors were nulligravida compared to 16.2% of comparison women.

Table 1.

Demographic Characteristics of Women Who Participated in the Telephone Interview by Cancer Survivorship Status, 2012–2013

  Cancer survivors (n = 1,282)
Comparison women (n = 1,073)
n % n %
Age at interview (years)
 22–28 53 4.1 55 5.1
 29–35 340 26.5 226 21.1
 36–40 489 38.1 450 41.9
 40–45 400 31.2 342 31.9
Race
 White 889 69.9 712 66.8
 Black 325 25.6 309 29.0
 Othera 58 4.6 45 4.2
Level of education
 High school or less 98 7.7 52 4.9
 Some college 343 26.8 257 24.0
 College graduate 461 36.0 396 36.9
 Some grad school or grad degree 379 29.6 367 34.2
Location of residence at interview
 Metropolitan area 127 9.9 113 10.5
 Nonmetropolitan area 1,154 90.1 960 89.5
Relationship status at interview
 Married, living with a partner, or in a committed relationship 973 76.0 879 82.1
 Single 292 22.8 191 17.8
 Otherb 15 1.2 1 0.1
Annual income
 Greater than $50,000 822 64.8 760 71.8
 $50,000 or less 447 35.2 229 28.2
Health insurance status at interview
 Insured 1,150 89.7 961 89.6
 No insurance 132 10.3 112 10.4
Had a hysterectomy or bilateral oophorectomy by interview
 Yes 322 25.1 81 7.6
 No 960 74.9 992 92.5
BMIc
 Underweight 16 1.3 20 1.9
 Normal weight 565 44.3 434 40.7
 Overweight 322 25.2 308 28.9
 Obese 373 29.2 305 28.6
Chronic medical conditiond
 Yes 840 65.5 550 51.3
 No 442 34.5 523 48.7
Ever had sex with a male partner
 Yes 1,248 97.4 1,040 97.0
 No 33 2.6 32 3.0
Ever used contraceptione
 Yes 1,024 79.9 910 84.8
 No 258 20.1 163 15.2
Used contraception in the past 12 monthse
 Yes 295 23.0 353 32.9
 No 987 77.0 720 67.1
a

Race category “other” includes: American Indian, Alaskan Native, Asian, Native Hawaiian, and Pacific Islander.

b

Relationship category “other” was reserved for women who felt the other listed options did not accurately reflect their relationship status.

c

BMI calculated using self-reported weight in pounds and self-reported height in inches. Weight was converted to kilograms (kg). Height was converted to meters (m). The formula kg/m2 was used to calculate BMI. Underweight: BMI <18.5; Normal weight: 18.5 ≤ BMI <25; Overweight: 25 ≤ BMI <30; Obese: BMI ≥30.

d

Chronic medical conditions included hypertension, congestive heart failure, cardiomyopathy, previous myocardial infarction, diabetes, depression, osteoporosis or osteopenia, eating disorders, rheumatologic conditions, and thyroid disorders.

e

Contraception included report of use of a hormone or copper intrauterine device, oral contraceptives (combined or progesterone only), patches, vaginal ring, Depo Provera, or the subdermal implant.

BMI, body mass index.

Table 2.

Pregnancies to Women Who Participated in the Telephone Interview by Cancer Survivorship Status, 2012–2013

  Cancer survivors (n = 1,282)
Comparison women (n = 1,073)
n % N %
Pregnancy history at interview
 Nulligravida 306 23.9 174 16.2
 Gravid 976 76.1 899 83.8
Number of pregnancies by interview
 0 306 23.9 174 16.2
 1 223 17.4 144 13.4
 2 316 24.6 299 27.9
 3 234 18.3 229 21.3
 4 or more 203 15.8 227 21.2
Had at least one child by interview
 Yes 890 69.2 857 79.9
 No 392 30.6 216 20.1
Had at least one unplanned pregnancy
 Yes 639 49.8 533 49.7
 No 643 50.2 540 50.3
Number of unplanned pregnancies by interview
 0 643 50.2 540 50.3
 1 299 23.3 245 22.8
 2 162 12.6 155 14.4
 3 103 8.0 65 6.1
 4 or more 75 5.9 68 6.3
Reported a pregnancy that was neither planned nor unplanned
 Yes 52 4.1 52 4.8
 No 1,230 95.9 1,021 95.2

After matching on birth year and parity, cancer survivors and comparison women were equally likely to report having an unplanned pregnancy after (actual or proxy) diagnosis (HR: 1.08, 95% SI: 0.84–1.40). The results remained null after adjusting for race, income, history of STI, and history of unplanned pregnancy before diagnosis (adjusted hazard ratio [aHR]: 1.06, 95% SI: 0.85–1.36).

Factors associated with unplanned pregnancy in cancer survivors

Among survivors in the postcancer analysis (n = 1,070), 37.3% had at least one pregnancy after diagnosis. Of the survivors with a postcancer pregnancy, 46.4% reported at least one unplanned postcancer pregnancy. Of the unplanned pregnancies after cancer, 78.4% occurred in women not using contraception at the time. Eighty-nine women reported becoming permanently amenorrheic due to cancer treatment; 3.4% of these women reported an unintended pregnancy following cancer treatment.

Factors associated with unplanned pregnancy in survivors after cancer in unadjusted models were black race (HR: 1.55, 95% confidence interval [CI]: 1.13–2.12; referent: white), being <30 years at diagnosis (HR: 1.79, 95% CI: 1.32–2.44), and receiving fertility counseling at cancer diagnosis (HR: 1.40, 95% CI: 1.03–1.90) (Table 3). Modest associations were also seen for annual income ≤$50,000, having an unplanned pregnancy before cancer diagnosis, and ever being diagnosed with an STI. Diagnosis of a hematological cancer was associated with unplanned pregnancy (HR: 1.43, 95% CI: 0.98–2.07) compared to other (referent) cancers, while breast (HR: 0.92, 95% CI: 0.65–1.32) and reproductive (HR: 1.23, 95% CI: 0.67–2.26) cancers were not associated with unplanned pregnancy.

Table 3.

Demographic Characteristics of Cancer Survivors by Whether or Not They Reported an Unplanned Pregnancy After Cancer Diagnosis Among Survivors Who Had Not Had a Hysterectomy, Bilateral Oophorectomy, Tubal Ligation, or Endometrial Ablation Before Cancer Diagnosis with Unadjusted and Adjusted Hazard Ratios for Factors Associated with Unplanned Pregnancy After Cancer

  At least one unplanned pregnancy after cancer diagnosis (n = 185)
No unplanned pregnancies after cancer diagnosis (n = 885)
 
n % n % HR 95% CI aHRa 95% CI
Demographics
Age at interview (years)         1.49 0.70–3.16    
 22–28 8 4.3 41 4.6
 29–35 60 32.4 243 27.5 1.64 1.12–2.40
 36–40 64 34.6 331 37.4 1.23 0.85–1.78
 41–45 53 28.7 270 30.5 Referent  
Race
 White 113 61.8 636 72.3 Referent  
 Black 59 32.2 208 23.7 1.55 1.13–2.12
 Otherb 11 6.0 35 4.0 1.66 0.89–3.08
Level of education
 High school or less 14 7.6 49 5.5 Referent   Referent  
 Some college 45 24.3 219 24.8 0.83 0.46–1.51 0.78 0.42–1.46
 College graduate 78 42.1 327 37.0 0.89 0.50–1.57 0.93 0.51–1.67
 Some grad school or grad degree 48 26.0 289 32.7 0.65 0.36–1.17 0.66 0.36–1.22
Location of residence at interview
 Metropolitan area 167 90.3 813 92.0 Referent  
 Nonmetropolitan area 18 9.7 71 8.0 1.40 0.86–2.28
Relationship status at interview
 Married, living with a partner, or in a committed relationship 149 80.5 668 75.7 Referent   Referent  
 Single 35 18.9 205 23.2 0.78 0.54–1.12 0.77 0.53–1.11
 Otherc,d 1 0.5 10 1.1
Marital status at diagnosis
 Married 118 63.8 587 66.3 1.05 0.78–1.42 1.19 0.87–1.61
 Not married 67 36.2 298 33.7 Referent   Referent  
Income
 Greater than $50,000 113 61.4 598 68.3 Referent   Referent  
 $50,000 or less 71 38.6 278 31.7 1.33 0.99–1.79 1.15 0.83–1.59
Health insurance status at interview
 Insured 162 87.6 809 91.4 Referent   Referent  
 No insurance 23 12.4 76 8.6 1.38 0.89–2.13 1.30 0.83–2.02
Reproductive outcomes
Had at least one precancer pregnancy
 Yes 96 51.9 469 53.0 1.15 0.86–1.54 1.33 0.97–1.83
 No 89 48.1 416 47.0 Referent   Referent  
Parity at diagnosis                
 Had at least one child 82 44.3 397 44.9 1.19 0.89–1.59 1.44 1.05–1.97
 Had no children 103 55.7 488 55.1 Referent   Referent  
Had an abortion before diagnosis
 Yes 19 10.3 112 12.7 0.86 0.53–1.38 0.77 0.47–1.26
 No 166 89.7 773 87.3 Referent   Referent  
Had an unplanned pregnancy before diagnosis
 Yes 75 40.5 313 35.4 1.33 0.99–1.79 1.32 0.96–1.81
 No 110 59.5 572 64.6 Referent   Referent  
Ever diagnosed with an STI
 Yes 66 35.7 254 28.7 1.32 0.98–1.78 1.26 0.93–1.71
 No 119 64.3 631 71.3 Referent   Referent  
Ever reported a period of infertilitye
 Yes 78 42.6 316 37.3 1.21 0.90–1.62 1.23 0.92–1.65
 No 105 57.4 531 62.7 Referent   Referent  
Ever used contraceptionf
 Yes 151 81.6 715 80.8 Referent   Referent  
 No 34 18.4 170 19.2 0.98 0.68–1.43 0.93 0.63–1.38
Cancer and treatment
Age at diagnosis
 Under 30 years 122 66.0 396 44.7 1.79 1.32–2.44
 30 years or older 63 34.0 489 55.3 Referent  
Time since diagnosis
 0–4 years 24 13.0 194 21.9
 5–7 years 51 27.6 273 30.9
 8–10 years 38 20.5 200 22.6
 11+ years 72 38.9 218 24.6
Cancer diagnosis
 Breast 49 26.5 310 35.0 0.92 0.65–1.32 1.02 0.70–1.51
 Hematological 42 22.7 126 14.2 1.43 0.98–2.07 1.31 0.90–1.92
 Reproductive 12 6.5 69 7.8 1.23 0.67–2.26 1.22 0.65–2.29
 Other 82 44.3 380 42.9 Referent   Referent  
Cancer treatment
Surgery
 Yes 139 75.1 715 80.8 0.82 0.59–1.15 1.06 0.68–1.64
 No 46 24.9 170 19.2 Referent   Referent  
Radiation
 Yes 98 53.0 416 47.0 1.19 0.89–1.59 1.22 0.90–1.65
 No 87 47.0 469 53.0 Referent   Referent  
Chemotherapy                
 Yes 108 58.4 507 57.3 1.13 0.84–1.51 1.08 0.74–1.58
 No 77 41.6 378 42.7 Referent   Referent  
Received fertility counseling
 Yes 125 67.6 536 60.6 1.40 1.03–1.90 1.41 1.04–1.92
 No 60 32.4 349 39.4 Referent   Referent  
Pursued fertility preservationd,g
 Yes 2 1.1 20 2.2
 No 184 98.9 882 97.8
Menses after diagnosisd,h
 Had menses 182 98.4 799 90.3
 Menses absent 3 1.6 86 9.7
Other health information
Had a hysterectomy or bilateral oophorectomy by interview
 Yes 14 7.6 156 17.6 0.68 0.39–1.18 0.74 0.42–1.31
 No 171 92.4 729 82.4 Referent   Referent  
BMIi
 Underweightd 2 1.1 13 1.5
 Normal weight 90 48.7 408 46.4 Referent  
 Overweight 45 24.3 225 25.6 0.93 0.65–1.33
 Obese 48 26.0 234 26.6 1.02 0.72–1.45
Chronic medical conditionj
 Yes 123 66.5 565 63.8 1.14 0.84–1.54 1.15 0.84–1.56
 No 62 33.5 320 36.2 Referent   Referent  
Ever identified as a regular smoker
 Yes 41 22.2 210 23.7 0.89 0.63–1.26 0.92 0.64–1.32
 No 144 77.8 675 76.3 Referent   Referent  
Ever identified as a weekly drinker
 Yes 72 38.9 352 39.8 0.89 0.66–1.20 0.96 0.70–1.30
 No 113 61.1 533 60.2 Referent   Referent  
a

Models for age at diagnosis, age at the interview, race, location of residence, and BMI are unadjusted. Models for relationship status at the time of the interview and chronic medical condition are adjusted for age at time of interview. Model for relationship status at the time of diagnosis is adjusted for age at diagnosis. Models for income, insurance status, history of STI, ever drinker, and ever smoker are adjusted for age at interview and race. Models for level of education, having an abortion before diagnosis, receiving fertility counseling, having an unplanned pregnancy before cancer diagnosis, having at least one pregnancy before cancer, having at least one child before cancer, and cancer diagnosis are adjusted for age at diagnosis and race. Model for ever having a period of infertility is adjusted for age at diagnosis and age at the interview. Model for use of contraception is adjusted for age at interview, race, parity at cancer diagnosis, and receipt of fertility counseling. Model for receipt of cancer treatment (surgery, chemotherapy, radiation) is adjusted for cancer type. Model for hysterectomy or oophorectomy by the time of the interview is adjusted for age at interview and cancer type.

b

Race category “other” includes: American Indian, Alaskan Native, Asian, Native Hawaiian, and Pacific Islander

c

Relationship category “other” was reserved for women who felt that the other listed options did not accurately reflect their relationship status

d

HRs were suppressed where cell sizes had fewer than five observations.

e

A period of infertility was defined as a 12-month period having regular (at least three times per month) unprotected intercourse with a male partner without getting pregnant.

f

Contraception included report of use of a hormone or copper intrauterine device, oral contraceptives (combined or progesterone only), patches, vaginal ring, Depo Provera, or the subdermal implant.

g

Fertility preservation included those who reported having oocytes retrieved to freeze oocytes or embryos.

h

Menstrual status assessed by participant's response to the questions, “Did your menstrual periods stop during your cancer treatment?” and “For how long did your period stop?” Women who reported their period stopping and never returning are classified as having absent menses.

i

BMI calculated using self-reported weight in pounds and self-reported height in inches. Weight was converted to kilograms (kg). Height was converted to meters (m). The formula kg/m2 was used to calculate BMI. Underweight: BMI <18.5; Normal weight: 18.5 ≤ BMI <25; Overweight: 25 ≤ BMI <30; Obese: BMI ≥30.

j

Chronic medical conditions included hypertension, congestive heart failure, cardiomyopathy, previous myocardial infarction, diabetes, depression, osteoporosis or osteopenia, eating disorders, rheumatologic conditions, and thyroid disorders.

95% CI, 95% confidence interval; aHR, adjusted hazard ratio; HR, hazard ratio; STI, sexually transmitted infection.

After adjusting for confounding, having an annual income ≤$50,000 and having a history of a STI were no longer associated with unplanned pregnancy after cancer. However, other factors remained associated, including: receiving fertility counseling (aHR: 1.41, 95% CI: 1.04–1.92) and having an unplanned pregnancy before cancer diagnosis (aHR: 1.32, 95% CI: 0.96–1.81). In addition, having been pregnant at least once before cancer diagnosis (aHR: 1.33, 95% CI: 0.97–1.83) and having at least one child before diagnosis (aHR: 1.44, 95% CI: 1.05–1.97) were associated with increased risk of unplanned pregnancy after diagnosis in adjusted models.

Factors associated with unplanned pregnancy among breast cancer survivors

There were 359 breast cancer survivors who had not had a hysterectomy, bilateral oophorectomy, tubal ligation, or endometrial ablation before cancer diagnosis. Approximately 22.3% of these women reported at least one pregnancy after cancer diagnosis; among these, 61.3% reported having at least one unplanned postcancer pregnancy.

In unadjusted analyses among breast cancer survivors, there was an association between unplanned pregnancy after cancer and being <30 years at diagnosis (HR: 2.70, 95% CI: 1.53–4.76), living in a rural area (HR: 2.29, 95% CI: 1.07–4.92), and receiving fertility counseling (HR: 2.73, 95% CI: 1.16–6.41) (Supplementary Table S1). Use of adjuvant tamoxifen treatment and being hormone-receptor positive were associated with lower likelihood of unplanned pregnancy. In adjusted analyses, receiving fertility counseling (aHR: 2.70, 95% CI: 1.14–6.39) remained strongly associated with unplanned pregnancy. In addition, having hormone receptor positive cancer (aHR: 0.36, 95% CI: 0.19–0.68) and using adjuvant tamoxifen (aHR: 0.29, 95% CI: 0.11–0.74) remained associated with lower likelihood of unplanned pregnancy among survivors.

Discussion

A similar proportion of cancer survivors and cancer-free women reported unplanned pregnancies. Nevertheless, unplanned pregnancy after cancer was common (46.4% of survivors reporting at least one pregnancy after cancer) among reproductive-aged cancer survivors despite cancer treatment having a potentially negative impact on reproductive potential.8–10

Factors associated with cancer survivors having an unplanned pregnancy after cancer included black race, age <30 years at diagnosis, and receipt of fertility counseling at cancer diagnosis. Some of the factors associated with unplanned pregnancy in cancer survivors are also seen in the general population, such as black race and young age.6 In the general population, lower income is associated with risk of unplanned pregnancy,6 while annual income was associated with unplanned pregnancy among cancer survivors in our unadjusted analysis; it was no longer associated with unplanned pregnancy after adjusting for age and race. However, additional factors related to cancer were predictive of unplanned pregnancy in adjusted models, such as having an unplanned pregnancy before cancer or receiving fertility counseling during cancer treatment, and these factors may help identify which cancer survivors are in greatest need of contraception counseling.

Cancer survivors in our study were more likely to have an unplanned pregnancy after cancer than survivors in a small study that collected information about unplanned pregnancy.19 Of 295 cancer survivors in that study, only 31 reported a pregnancy after cancer. Of those with a postcancer pregnancy, 16% reported an unplanned pregnancy. However, the median length of follow-up in that study was only 2.4 years (interquartile range [IQR]: 1.1–5.1 years) compared with 7 years (IQR: 5–11 years) in our study.

Pregnancy intent is a complex and multifactorial issue, especially among reproductive-aged cancer survivors.32,33 Some survivors may feel conflicted about their ongoing survival and desire for parenthood.34 Cvancarova et al.35 reported that women with a history of cancer were half as likely to have a pregnancy after cancer as cancer-free women, and they found that postcancer reproduction was affected by age at diagnosis, parity at diagnosis, and time since diagnosis, with the strongest association being childlessness at diagnosis.35 However, they were unable to distinguish planned and unplanned pregnancies. We found that being younger at diagnosis was associated with a higher probability of having an unplanned pregnancy after cancer among survivors. We did not see an association between unplanned pregnancy and parity at diagnosis in our main analysis.

Some have hypothesized that cancer survivors are at high risk of unplanned pregnancy due to less frequent use of contraception compared with women without cancer.16,19,36 In our study, cancer survivors were less likely than comparison women to have used contraception in the past year. However, they were not more likely to report an unplanned pregnancy. Decreased fertility in cancer survivors8–10 may partially explain why our results do not support the hypothesis in the literature.

Nevertheless, cancer survivors could benefit from patient-centered counseling on risk and available contraceptive options that address their specific situation.37 One study found that survivors who received contraceptive counseling were more likely to use Tier I/II methods.20,38 However, providers may not be adequately counseling cancer survivors about contraception. One study reported that only 57% of gynecological oncologists believed that their patients understood that unplanned pregnancy was possible during and after cancer treatment.39 Furthermore, 30% of gynecological oncologists did not routinely provide fertility or contraception counseling following cancer and 19% reporting that they only routinely provided fertility counseling.39 In a study that reviewed medical records, only 45% of initial consultations documented a contraceptive plan in reproductive-aged patients.40 The content of counseling is important because our study suggests that fertility counseling is associated with an increased risk of unplanned pregnancy following cancer treatment, a finding seen in both our primary analysis, as well as in our supplemental analysis, among only breast cancer survivors.

Cancer survivors, particularly those who undergo pelvic or total body irradiation or systemic chemotherapy, are more likely to experience permanent treatment-related amenorrhea.11–15 Although women who resumed menses following cancer treatment were at a greater risk of an unplanned pregnancy following cancer diagnosis, unplanned pregnancies also occurred among women whose menses never returned.

Women may overestimate the risk of becoming postmenopausal as a result of treatment.4 The majority of cancer survivors remain fertile after treatment.41 In cancer patients <30 years treated with standard chemotherapy regimens, POF is more common than in the general population but is still rare.18,42 Some argue that ovarian function should be reassessed following cancer treatment.36 However, assessment of ovarian function following treatment may have limited utility because pregnancy has been reported in cancer survivors despite amenorrhea and follicle-stimulating hormone levels suggestive of menopause.41

We defined unplanned pregnancy as pregnancy occurring when using contraception and pregnancies occurring when women were not trying to get pregnant despite not using contraception. Pregnancies occurring when women were “neither trying nor not trying” to get pregnant were not counted as unplanned. However, this group may be noteworthy. One study found that ambivalence toward pregnancy is more likely among women >30 years at the time of pregnancy, those who report being nonwhite, and those who report a personal or religious objection to abortion.43 In addition, a large proportion of women (30%–56%) report ambivalence about childbearing at the time of their last pregnancy.43 We found that of the women with a pregnancy after cancer, only 4.1% of them reported a pregnancy for which they were neither trying nor not trying, suggesting a low level of ambivalence among survivors in our study.

Breast cancer survivors may be a unique group with respect to unplanned pregnancy and contraceptive use following cancer. Cancer type has previously been associated with a risk of unintended pregnancy, with breast cancer survivors being at increased risk compared to other cancers.16 However, risk of unplanned pregnancy in that study was defined as having unprotected intercourse rather than actual incidence of unplanned pregnancy.16

We found that breast cancer survivors were less likely than other survivors to report a pregnancy after cancer, but among breast cancer survivors reporting a pregnancy after diagnosis, there was a high proportion of unplanned pregnancies (61.3%). Given the hormone-sensitive nature of some breast cancers, women with a history of breast cancer may fear using hormonal contraception in the absence of counseling about which contraception is safe for them and which should be avoided.

Unplanned pregnancies are often viewed as problematic in the public health literature, in part, due to their association with adverse prenatal and peripartum outcomes.44,45 However, unplanned pregnancy does not necessarily mean a pregnancy is unwanted or unwelcome.46,47 In addition, feelings about pregnancy may change over time.48,49 Given that some cancer survivors may be infertile or experience a shortened window in which to have children after cancer while others may continue to be fertile, cancer survivors may benefit from tailored counseling that incorporates information about both fertility planning, fertility services, and contraception options to help them achieve their desired number and spacing of pregnancies.

Strengths and limitations

Our study has many strengths. We recruited a large number of cancer survivors of various cancers. We were able to compare cancer survivors to comparison women with regards to rates of unplanned pregnancy after cancer diagnosis using a proxy date of diagnosis for those with no history of cancer. The median time from cancer diagnosis to the interview was 7.0 years, allowing time for women to become pregnant with planned and unplanned pregnancies. In addition, we performed many sensitivity analyses to investigate factors associated with unplanned pregnancy among groups that may have differential risk.

Our study has some limitations. Our data are based on self-report. As time passes after a child's birth, parents may be less likely to describe the pregnancy as an unplanned pregnancy.43 Therefore we may underestimate the number of women who actually had an unplanned pregnancy. However, we have no reason to believe that cancer survivors or comparison women would be more likely to recall a pregnancy as unplanned. Nevertheless, the probability of reporting a pregnancy as unplanned may differ by some participant characteristics, including low income, young age, cohabitating, race, and education.50 It is unclear whether these factors are associated with actual risk of unplanned pregnancy or with acceptability of referring to a pregnancy as unplanned.

These data were collected in 2012–2013; it is possible that patterns in contraceptive counseling among cancer survivors have evolved since then. In addition, we were unable to evaluate use of certain methods of nonhormonal contraception, such as condoms or a partner's vasectomy, as these questions were not included in the interview. Furthermore, pregnancy intention was assessed using a simplified measure of pregnancy intention, which may be less valid compared to psychometrical validated measures such as the London Measure of Unplanned Pregnancy.51,52

Conclusion

Rates of unplanned pregnancy after cancer were not higher for our cancer survivors compared with our comparison group, but nearly one-half of cancer survivors who had a pregnancy following cancer reported an unplanned pregnancy. Therefore, cancer patients may still benefit from counseling before cancer treatment that includes patient-centered screening and a discussion of postcancer reproductive care that integrates information regarding risks of infertility with risks of unplanned pregnancy following treatment, including access to family planning resources and contraceptive options.

Supplementary Material

Supplemental data
Supp_TableS1.docx (31.2KB, docx)

Disclaimer

The findings and conclusions in this report are those of the authors and do not necessarily represent the official position of the Centers for Disease Control and Prevention. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health or Centers for Disease Control and Prevention.

Authors' Contributions

Conceptualization: [L.M.S., J.B.S., P.P.H.]; Methodology: [L.M.S., L.M.K., P.P.H.]; Formal analysis and investigation: [L.M.S., L.M.K., P.P.H.]; Writing—original draft preparation: [L.M.S., P.P.H.]; Writing—review and editing: [J.B.S., D.M., A.C.M.]; Funding acquisition: [P.P.H.]; Supervision: [P.P.H.].

Author Disclosure Statement

L.M.S. has nothing to disclose. L.M.K. has nothing to disclose. J.B.S. has nothing to disclose. A.C.M. has nothing to disclose. D.M. has nothing to disclose. P.P.H. reports a grant from NICHD 1R01HD066059 during the conduct of the study and reports previously owning stock in ContraVac, Inc., outside of the submitted work.

Funding Information

Funding for this research was provided by The Eunice Kennedy Shriver National Institute of Child Health and Human Development Grant 1R01HD066059.

Supplementary Material

Supplementary Table S1

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Supplementary Materials

Supplemental data
Supp_TableS1.docx (31.2KB, docx)

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