Skip to main content
Advertisement
Browse Subject Areas
?

Click through the PLOS taxonomy to find articles in your field.

For more information about PLOS Subject Areas, click here.

  • Loading metrics

Estimating the Effect of Intimate Partner Violence on Women’s Use of Contraception: A Systematic Review and Meta-Analysis

  • Lauren Maxwell ,

    lauren.maxwell@mail.mcgill.ca

    Affiliation Department of Epidemiology, Biostatistics, & Occupational Health, McGill University, Montréal, Québec, Canada

  • Karen Devries,

    Affiliation Social and Mathematical Epidemiology Group and Gender Violence and Health Centre, Department of Global Health and Development, London School of Hygiene and Tropical Medicine, London, United Kingdom

  • Danielle Zionts,

    Affiliation Department of Epidemiology, Biostatistics, & Occupational Health, McGill University, Montréal, Québec, Canada

  • Jeanne L. Alhusen,

    Affiliation Department of Community-Public Health, Johns Hopkins University School of Nursing, Baltimore, Maryland, United States of America

  • Jacquelyn Campbell

    Affiliation Department of Community-Public Health, Johns Hopkins University School of Nursing, Baltimore, Maryland, United States of America

Abstract

Background

Intimate partner violence (IPV) is an important global public health problem. While there is a growing literature on the association between IPV and women’s reproductive health (RH) outcomes, most studies are cross-sectional—which weakens inference about the causal effect of IPV on women’s RH. This systematic review synthesizes existing evidence from the strongest study designs to estimate the impact of IPV on women’s use of contraception.

Methods

We searched 11 electronic databases from January of 1980 to 3 December 2013 and reviewed reference lists from systematic reviews for studies examining IPV and contraceptive use. To be able to infer causality, we limited our review to studies that had longitudinal measures of either IPV or women’s use of contraception.

Results

Of the 1,574 articles identified by the search, we included 179 articles in the full text review and extracted data from 12 studies that met our inclusion criteria. We limited the meta-analysis to seven studies that could be classified as subject to low or moderate levels of bias. Women’s experience of IPV was associated with a significant reduction in the odds of using contraception (n = 14,866; OR: 0.47; 95% CI: 0.25, 0.85; I2 = 92%; 95% CII2: 87%, 96%). Restricting to studies that measured the effect of IPV on women’s use of partner dependent contraceptive methods was associated with a reduction in the heterogeneity of the overall estimate. In the three studies that examined women’s likelihood of using male condoms with their partners, experience of IPV was associated with a significant decrease in condom use (OR: 0.48; 95% CIOR: 0.32, 0.72; I2 = 51%; 95% CII2: 0%, 86%).

Conclusions

IPV is associated with a reduction in women’s use of contraception; women who experience IPV are less likely to report using condoms with their male partners. Family planning and HIV prevention programs should consider women’s experiences of IPV.

Introduction

Intimate partner violence (IPV) is both a human rights issue and an important public health concern. IPV is the most prevalent form of gender-based violence; the 2013 Global Burden of Disease Study estimates that 30% of women age 15 or over have experienced physical or sexual IPV [1]. Cross-sectional studies from a number of countries indicate that IPV is associated with a constellation of women’s reproductive health (RH) outcomes related to contraceptive use including rapid repeat pregnancy (pregnancy within 24 months of a previous pregnancy) [24]; unintended pregnancy [57]; pregnancy termination [79]; and incident HIV infection [913].

Reproductive coercion, taking control of women’s RH, is one form of IPV. Women may be forced to have sex or to practice unprotected sex by their male partners and male partners may sabotage women’s use of family planning (FP) to increase their female partner’s dependency or to otherwise express their control over their partner’s decision making [5,6,1418]. Qualitative and cross-sectional studies suggest that birth control sabotage is a type of reproductive coercion and that women may adopt contraceptive methods that they can hide from their partners or that do not require negotiation with their male partners to mitigate this barrier [16,19,20].

Women’s ability to control the timing, spacing, and number of their pregnancies is a critical health and human rights issue. Addressing the unmet need for FP is a key step to meeting Millennium Development Goals (MDGs) 3, 4 and 5 which aim to promote gender equity; reduce maternal and child mortality; and ensure universal access to RH including contraception and antenatal care, respectively. Understanding how IPV modifies women’s ability to adopt contraception is central to designing FP interventions that allow women who experience IPV to manage their fertility and to informing HIV prevention interventions.

Purpose of the Review

In this review we attempt to estimate the causal effect of IPV on contraceptive use. Most of the existing literature on the association between women’s experience of IPV and contraceptive use is based on estimates of associations and does not address issues of temporality, which restricts our ability to infer the causal effect of IPV on women’s contraceptive use. This study builds on recent systematic reviews that have found an association between IPV and different sexual health outcomes. A 2014 systematic review found an association between IPV and termination of pregnancy, but included all study designs, including cross-sectional studies [8]. A 2007 systematic review provided an overview of studies that estimated the association between physical IPV and women’s sexual health outcomes, including contraceptive use and pregnancy termination, but included all study designs and did not include a meta-analysis of included studies [21]. To understand the scope of existing evidence for the effect of IPV on women’s use of contraception, we restrict this systematic review to studies with longitudinal measures of IPV and/or contraceptive use and to studies that use a case-control design. In keeping with a prior systematic review related to IPV, we define a longitudinal study as one where either the exposure or the outcome was measured at a minimum of two time points [22].

Methods

Search Strategy

We searched 11 biomedical databases: PubMed (Medline); OvidSP (EMBASE, PsycINFO, CINAHL); Global Health Library (including LILACS, AFRO, EMRO, PAHO, WHOLIS, WPRO); and POPLINE from 1 January 1980 to 3 December 2013 to identify research studies on IPV and women’s RH outcomes. Because of the changes in women’s access to and knowledge of contraceptive methods over time with the introduction of novel contraceptive methods such as the IUD and oral contraceptives, we restricted our search to 1980 onwards. In addition to the electronic database searches, we identified citations by reviewing reference lists from relevant reviews and studies. We adapted Medical Subject Headings (MeSH) and text-based search terms for IPV from prior peer-reviewed literature and systematic reviews of intimate partner violence [23,24]. An information scientist reviewed the search strategy and pilot tested the search in Medline, EMBASE and PsycINFO with one of the authors (LM). The PubMed (Medline) search strategy is provided in S1 Supplementary Text.

Inclusion Criteria

We included studies of women and girls of any age that evaluated the association between respondents’ exposure to IPV by a male partner and an outcome related to women’s RH or to infant health in the initial review of titles and abstracts identified in our search. We included all types of IPV, whether the abuse was classified as physical, sexual, psychological, or economic. Because we identified more studies than expected with longitudinal measures of IPV and RH outcomes, we restricted our inclusion criteria to studies with an outcome related to women’s use of contraception subsequent to the initial search. We did not restrict our definition of contraception and included articles with modern contraceptive methods and traditional methods of FP. We did not restrict studies by geographic location or language of publication.

Study Designs

While we did not use study design filters in our search, we only considered longitudinal (panel, cohort, randomized controlled trails (RCTs)) or case-control studies for inclusion in the systematic review. Where the intervention arm of an RCT intervened on both the exposure to IPV and outcome of contraceptive use, we used the effect measure from the control arm of the RCT.

Screening and Data Extraction

We followed the Cochrane guidelines for the systematic review of non-randomized studies and for the review of randomized studies [25,26], and prepared the manuscript using PRISMA guidelines (See S1 Supplementary Table for the PRISMA checklist). We registered our systematic review protocol with the international prospective register of systematic reviews, PROSPERO, (registration number CRD42013006457, S2 Supplementary Text) before initiating our search. One reviewer (LM) conducted the search; removed duplicate studies; and identified additional studies through a review of related articles and systematic reviews. In keeping with the Cochrane recommendations for the systematic review of non-randomized studies, we assessed study design features, rather than study design labels, to evaluate whether studies could be classified as longitudinal or case-control study designs [26]. Two reviewers (LM and DZ) independently screened the titles and abstracts of all studies identified through the search strategy to identify studies that met the inclusion criteria for full text review. In cases of disagreement about study inclusion, the study was included in the full text review.

For studies that met our inclusion criteria, but where the study authors did not include a relevant effect measure, we contacted the authors for additional information or for participant-level data. For studies that included a definition of sexual or physical violence that was not limited to violence perpetrated by a male intimate partner, we contacted the authors to determine whether they had measured intimate partner-specific violence. For studies that were in languages other than English, French, or Spanish, an epidemiologist fluent in the language of the study worked with LM to determine whether the study was relevant for inclusion. Data were extracted independently by LM and DZ using a standardized, pre-piloted electronic data extraction form. Discrepancies in data extraction between assessors were resolved through consensus.

We extracted data on study location; design; sample characteristics and size; type of violence; interview method and setting; the scale used to measure IPV; IPV-specific interviewer training; confounders; outcome definitions; and effect measures.

Quality Assessment

We assessed the potential for bias within each study using the Cochrane Methodological Quality Assessment of Observational Studies for longitudinal and case-control studies (S3 Supplementary Text); the Cochrane Risk of Bias Tool for RCTs (S4 Supplementary Text); and a series of questions specific to assessing bias in measures of IPV exposure [26]. Two reviewers (LM, DZ) independently assessed each study’s potential for being affected by the most common forms of bias in observational studies: selection, confounding, performance, detection, and attrition bias. In consultation with other subject matter experts, we created a directed acyclic graph (DAG) to differentiate between important confounders and variables that are likely on the causal pathway between IPV and contraceptive use (S6 Fig.). DAGs are used to encode a priori causal knowledge to identify and distinguish between the variables that are likely to be common causes of the exposure and outcome (confounders) and the variables that are on the causal pathway between the exposure and outcome (mediators) [2729]. Focusing on the assessment of selection and confounding bias and temporal ordering of cause and effect, we classified studies as having a low, moderate, or high probability of bias. Studies were classified as having low probability of bias if they were not obviously affected by the aforementioned sources of bias and if they used methods to reduce the probability of measured confounding in non-randomized studies such as propensity score matching. Studies classified as subject to moderate bias adjusted for relevant confounders and had no obvious sources of bias.

Data Analysis

We used random effects meta-analysis to estimate the pooled odds ratio (OR) for the association between IPV and women’s use of contraception across studies. We chose random rather than fixed effects models because we expected a high level of heterogeneity across studies and standard errors estimated using random effects models are generally more conservative than those estimated with fixed effects models [30]. All studies reported ORs adjusted for confounding. We used the adjusted OR from each study in the meta-analysis. Where necessary, we inverted the adjusted OR presented in the published article so that all effect measures in the meta-analysis were operating in the same direction (contraceptive use versus non-use). All analysis were done using Stata version 13.0 (StataCorp LP, College Station Texas). While we calculated a pooled OR across all studies regardless of study quality, we restricted additional meta-analysis to studies that were classified as having a moderate or low probability of bias in keeping with the Cochrane recommendations for the synthesis of data from observational studies [26].

We used the I2 statistic to assess heterogeneity of effect estimates across included studies. The I2 statistic quantifies the proportion of variation across studies due to actual variation rather than chance [31]. Based on the Cochrane Handbook for Systematic Reviews’ recommendations, we interpreted an I2 statistic between 0% and 40% as representing an insignificant amount of heterogeneity; 30% to 60% as moderate heterogeneity; and 50% to 90% as substantial heterogeneity; and 75% to 100% as considerable heterogeneity [32]. We estimated the uncertainty in the heterogeneity estimate using Stata’s heterogi command [33] and used Stata’s metaninf command to estimate the influence of each individual study on the pooled estimate [34]. We assessed the degree of probable publication bias by reviewing funnel plots that compare log ORs to their standard errors. We used Egger’s test of funnel plot asymmetry to test the null hypothesis of no small-study effects.

Ethics Statement

Because the data included in this analysis contain no identifying information and are publically available, ethical approval was not required for this review.

Results

Overview of Selected Studies

Fig. 1 presents the PRISMA flow diagram of the study selection process. We reviewed the titles and abstracts of 1,574 articles and included 179 articles in the full text review. Twelve studies with 17,827 participants met our inclusion criteria (please refer to S2 Supplementary Table for a list of articles excluded following full text review). We excluded effect estimates from two RCTs that intervened on the exposure and the outcome in both the control and intervention arms (n = 385) [35,36]. Table 1 presents a detailed overview of the case-control, the control arm of the included RCT, and the eight other longitudinal studies included in the systematic review. The intervention and control arms of both the included and excluded RCTs are summarized in S3 Supplementary Table. All of the studies were fairly recent: the earliest publication date was 2005 and five of the 10 studies were published after 2010. Six of the 10 studies were conducted in the US [3742]; two studies were conducted in Central and South America [43,44]; one study was from India [45]; and the RCT was conducted in Africa [46]. The studies included a diversity of populations: two studies only included adolescents [40,41] and one study was limited to methadone clinic patients [37]. Three studies restricted their study populations to ever-pregnant or ever-delivered women. One study was limited to women who were pregnant at baseline and had delivered prior to follow-up [43]; and two studies included women who had given birth within the year prior to their baseline interview [39,41]. Five of the studies included clinic or hospital-based populations [37,38,41,42,44]; three studies included a subset of participants in a population-level longitudinal study [40,43,45]. The size of studies ranged from 225 to 6,414 (IQR = 337–2,058) subjects. While the median follow-up time was one year, the time between interviews ranged from three months [44] to five years [45].

thumbnail
Table 1. Summary of longitudinal, RCT, and case-control studies that examine the association between IPV and women’s contraceptive use.

https://doi.org/10.1371/journal.pone.0118234.t001

Study Quality

Table 2 provides details on the quality of the one case-control and nine longitudinal studies (n = 17,442) that were included in the meta-analysis. We classified the estimate from the control arm of the RCT as having a low probability of bias [46]. Five of the other longitudinal studies were classified as subject to moderate bias [3739,43,45]; two longitudinal studies [40,44] and the case-control study [42] were determined to have a high level of bias.

thumbnail
Table 2. Quality assessment of included case-control, RCT, and longitudinal studies.

https://doi.org/10.1371/journal.pone.0118234.t002

IPV measurement. Studies varied in their description of IPV and in the time period over which they assessed IPV. Definitions of intimate partner ranged from “person you most often had sex with in the last 3 months” [46] to “husband” [45]. Seven of the 10 studies reported using a validated scale to measure women’s report of violence. The Conflict Tactics Scale was used in five studies [37,40,41,43,45]; two studies reported using the Abuse Assessment Screen [39,42]; one study used the CTS, in addition to the Severity of Violence Against Women Scale and the Women’s Experience with Battering Scale. Researchers generally classify IPV into four separate categories: emotional, physical, sexual, and economic. Physical violence was the most widely measured exposure; all studies included physical violence in their exposure definition; four studies only measured the effect of physical violence [39,41,42,45]. Different forms of IPV are not necessarily correlated [1] so studies that limited their classification of IPV to physical IPV may have underestimated the total effect of IPV. In two studies that included multiple categorizations of IPV (physical, sexual, and emotional) [42,43], we used the effect estimates from the most expansive definition to better understand the effect of IPV on women’s use of contraception. In one study with multiple categorizations of IPV, we used the classification that included physical and sexual IPV rather than the classification that included physical, sexual, emotional, and fear of IPV because this was the only study to include fear of IPV as a type of IPV [46].

Contraceptive use measurement. Five of the 10 studies limited their estimate of the effect of IPV on women’s contraceptive use to one or two methods, including oral contraceptives [44], condoms and diaphragms [46], and condoms [37,40,41]. Three of the five studies that included a number of different methods considered withdrawal and the rhythm method as contraceptive methods [38,42,43], while the remaining two studies limited their definition to modern methods of contraception. Women were asked to recall their contraceptive use during the last year [38,40,42], last six months [37,41] or to report current use [39,43]. Effect estimates included comparisons between use and non-use in seven studies [38,39,4246], and always and sometimes or never use in three studies [37,40,41]. The three studies that included women who had given birth measured women’s use of contraception one [41], two [39], and four [43] years after delivery, when women are unlikely to continue to use lactational amenorrhea for FP [47]. We inverted the ORs from six of the studies in Table 1 [38,4042,44,46] to facilitate the comparison of outcome measures (e.g., contraceptive use versus non-use) across studies.

Confounder adjustment. All studies reported effect measures that were adjusted for basic demographic confounders including maternal age, socioeconomic status, and minority status. Studies also adjusted for prior experience of non-partner abuse [37]; mental health [37]; fertility intentions [41,45]; and relationship status [42], amongst other potential confounders. Some studies adjusted for factors thought to mediate the relationship between IPV and contraceptive use including parity [45], partner refusal to wear condoms [41], social support, and depression [37].

Additional outcomes. Four studies provided effect estimates for additional RH outcomes, including: the likelihood of using a hidden method of contraception [38,44]; the odds of using emergency contraception [38]; reporting multiple sex partners [40]; shortened interpartum intervals [39] and the likelihood of engaging in unprotected anal sex [37]. We only extracted data on measures of contraceptive use to allow for a comparison across studies.

Meta-analysis

This review aims to evaluate and synthesize existing evidence for the effect of IPV on women’s use of contraception. As described a priori in our research protocol, we restricted our overall meta-analysis to studies that were classified as having low or moderate levels of bias and only included the three studies that were classified as having a high level of bias in the subgroup analysis of the association between the level of bias and the estimated pooled OR.

Subgroup Analysis

As indicated both in the forest plot of the seven studies classified having low or moderate levels of bias (Fig. 2) and in the forest plot that includes all 10 studies irrespective of bias (S1 Fig.), there is considerable heterogeneity in effect measures across studies. We performed a series of subgroup analysis to explore potential sources of heterogeneity. We planned to conduct subgroup analysis on study quality, type of IPV, and whether studies were limited to pregnant versus non-pregnant participants a priori. We included a subgroup analysis comparing studies with non-modern forms of FP and modern contraception post hoc after identifying several studies that included natural methods of FP, like the rhythm method and withdrawal, rather than restricting to modern contraceptive methods.

thumbnail
Fig 2. Meta-analysis of the association between IPV and contraceptive use.

Estimated effect measures from the Fantasia, Kacanek, and Van Horne studies have been inverted to present estimates of contraceptive use rather than non-use.

https://doi.org/10.1371/journal.pone.0118234.g002

Methodological quality. In Fig. 3, we show the changes in the effect estimates by level of probable bias. Of the 10 included studies (n = 17,442), three studies were classified as having a high probability of bias; six studies were found to have a moderate level of bias; and one study, the control arm of the included RCT, was classified as having a low probability of bias. Grouping studies according to their probable bias did not explain a significant amount of the heterogeneity in the overall estimate (I2 = 89%, 95% CII2: 81%, 93%). Both studies classified as having a high probability of bias and studies classified as subject to low or moderate levels of bias indicated that IPV was associated with a decrease in women’s odds of using contraception (ORhigh bias: 0.60; 95% CIOR: 0.46, 0.79; I2 = 0%, 95% CII2: 0%, 90%; ORmoderate: 0.44; 95% CIOR: 0.18, 1.09; I2moderate = 93%, 95% CII2: 88%, 96%; and ORlow: 0.60; 95% CIOR: 0.50, 0.72 respectively). While we extracted data from two longitudinal studies where the exposure was not clearly measured before the outcome and the case-control study which had different selection procedures for cases and controls (selection bias), we classified these studies as having a high probability of bias and excluded them from subsequent subgroup and meta-analysis.

thumbnail
Fig 3. Meta-analysis of the association between IPV and contraceptive use, by level of bias.

Estimated effect measures from the Fantasia, McCarraher, Kacanek, Teitelman, Van Horne, and Williams studies have been inverted to present estimates of contraceptive use rather than non-use.

https://doi.org/10.1371/journal.pone.0118234.g003

Classification of contraceptive methods. In Fig. 4, we compare the pooled effect measures by whether studies included withdrawal and the rhythm method in their classification of contraceptive methods or restricted their definition to modern contraceptive methods (e.g., injectables, oral contraceptives, IUD, condoms, bilateral tubal ligation). As mentioned previously, we only included effect estimates from the seven studies classified as having a low or moderate probability of bias (n = 14,866). The three studies whose definition of contraception ranged from modern contraception to less effective forms of FP such as withdrawal and the rhythm method [38,42,43], were more likely to find a non-significant association between IPV and women’s use of contraception (n = 6,509; OR: 0.57; 95% CIOR: 0.12, 2.78; I2 = 97%, 95% CII2: 95%, 99%) than the four studies that estimated the effect of IPV on women’s use of modern contraceptive methods (n = 8,357; OR: 0.48; 95% CIOR: 0.34, 0.69; I2 = 35%, 95% CII2: 0%, 77%). Excluding estimates from studies that included the rhythm method and “natural family planning methods” and limiting inference to the effect of IPV on women’s use modern contraceptive methods reduced the heterogeneity in the pooled estimate from 97% to 35%. The high level of heterogeneity in the pooled estimate from studies that included natural FP methods remained after removing the Salazar study (I2 = 98%). The difference in heterogeneity when comparing studies whose definition of contraception includes withdrawal and the rhythm method to studies that limit inference to modern methods may indicate that the broad definition of contraception in these studies is a source of heterogeneity in the overall meta-analysis. In the three studies that measured women’s reports of their male partner’s condom use, (S1 Fig.) women who experienced IPV were significantly less likely to report that their partners used condoms than women who did not experience IPV (n = 1,943; OR: 0.48; 95% CIOR: 0.32, 0.72; I2 = 51%, 95% CII2: 0%, 86%).

thumbnail
Fig 4. Meta-analysis of the association between IPV and contraceptive use, by definition of FP.

Estimated effect measures from the Fantasia, Kacanek, and Van Horne studies have been inverted to present estimates of contraceptive use rather than non-use.

https://doi.org/10.1371/journal.pone.0118234.g004

Type of IPV. We used the estimated effect of physical IPV from the two studies that included multiple classifications of IPV [43,46] in a meta-analysis of the five studies that measured exposure to physical IPV, presented in S2 Fig. Physical IPV was significantly associated with a reduction in women’s use of contraception in four of the five studies, although the pooled OR was not statistically significant and was subject to a high degree of heterogeneity (n = 12,529; OR: 0.71; 95% CIOR: 0.45, 1.12; I2 = 79%, 95% CII2: 50%, 91%). Because there were only two studies that specifically explored the effect of sexual or emotional IPV on women’s use of contraception [43,46], we could not perform separate meta-analysis of these exposures.

Study population. In S3 Fig., we compare the pooled effect measures between studies that did and did not restrict to women who had given birth. The pooled effect measure for the three studies that restricted to delivered women was not significantly different from that of the four studies that did not restrict to delivered women and did not did not help to explain the heterogeneity in the overall estimate (ORrestricted to delivered women: 0.64; 95% CIOR: 0.13, 3.25; I2 = 87%, 95% CII2: 64%, 96%; ORnot restricted to delivered women: 0.38; 95% CIOR: 0.19, 0.76; I2 = 94%, 95% CII2: 90%, 97%).

Overview of Data Synthesis

The results of the meta-analysis, wherein we pooled the ORs from the 10 studies included in the meta-analysis irrespective of study quality, indicated that women who experience IPV have a lower odds of adopting contraception than women who do not experience IPV, although the results were subject to a high level of heterogeneity (n = 17,442; OR: 0.50; 95% CIOR: 0.32, 0.76; I2 = 89%, ORI2: 81%, 93%). When we restricted our inference to the seven studies classified as subject to low or moderate bias, the odds of women who had experienced IPV reporting contraceptive use were 53% lower than the odds for women who had not experienced IPV (n = 14,866; 95% CIOR: 0.25, 0.85; I2 = 92%, 95% CII2: 87%, 96%). While no single study was found to unduly influence the pooled OR, not all of the effect estimates operated in the same direction. In six of the seven studies included in the pooled meta-analysis, where we restricted to studies classified as subject to moderate or low bias, women who experienced IPV had a lower odds of reporting contraceptive use than women who did not. The Salazar study [43], which examined the effect of physical, sexual, and emotional IPV on the use of a contraceptive method other than sterilization was a notable exception: the odds of women who experienced IPV using contraception were 2.59 times the odds of women who did not experience IPV at either baseline or follow-up (95% CI: 1.24, 5.40). The difference between the effect estimates in the Salazar study and in the other six studies may be caused by country-level differences in access to contraception and norms surrounding contraceptive use. The Nicaraguan government works to ensure open access to contraception through FP programs in the public and private health sector and uses community-based distribution of contraception to reach underserved communities [48,49]. Nicaragua’s prevalence of contraceptive use, estimated at 73% in 2013, is well above the global average for contraceptive use of 63% [50]. While exclusion of the Salazar study from the pooled estimate did decrease the point estimate and increase the precision of the pooled OR, removal of the Salazar study did not lead to a decrease the degree of heterogeneity in the pooled estimate of studies with low and moderate bias (ORwithout Salazar: 0.36; 95% CIOR: 0.20, 0.65; I2 = 92%, 95% CII2: 85%, 96%).

Analysis of Violence Severity

There are different ways of conceptualizing the severity of violence. Some classifications use the type of violence; others examine the frequency of violent acts. Three of the longitudinal studies in this review conceptualized violence severity using the duration of reported violence [38,43,46]. For studies that included several measures of violence duration, we used the measure that most closely matched the duration of violence reported in other studies in the violence severity meta-analysis. In Table 3, we report the effect estimates for the three studies that included measures of the duration of violence. Categorizing violence as either moderate or severe by using the type of violence has been used previously to predict the severity of adverse health outcomes [51,52]. Using the classification of violence severity from the Kacanek article [46], these three studies’ classification of each participant’s experience of IPV as persistent, measured at both time points; incident, only measured at the most recent time; or remitting, not measured at the most recent time, but measured previously, provide an opportunity to explore how the duration of IPV can differentially affect contraceptive use. Fig. 5 presents a forest plot of these duration measures.

thumbnail
Table 3. Association between the duration of intimate partner violence and women’s contraceptive use as compared to women who have no history of intimate partner violence.

https://doi.org/10.1371/journal.pone.0118234.t003

thumbnail
Fig 5. Meta-analysis of the association between IPV and contraceptive use, by duration of exposure.

Estimated effect measures from the Fantasia and Kacanek studies have been inverted to present estimates of contraceptive use rather than non-use.

https://doi.org/10.1371/journal.pone.0118234.g005

In contrast to the estimated effect of IPV on women’s use of contraception in the other two studies, the estimates from the Salazar study [43] indicate that women who experience IPV are more likely to adopt contraception than women who do not. Across all three studies that include measures of IPV duration, the magnitude of the effect of IPV on women’s use (or non-use) of contraception is greatest for women who experience persistent IPV.

Discussion

Summary of Main Findings

Results of the meta-analysis suggest that IPV affects women’s use of contraception. Author’s classification of contraceptive methods was a potential source of heterogeneity. There is some evidence for a dose-response relationship between duration of IPV exposure and women’s contraceptive use. IPV is associated with a decrease in women’s use of partner dependent methods; women who experienced IPV were less likely to report that their male partners used condoms than women who did not. The association between IPV and contraceptive use is likely modified by contextual factors. In Nicaragua, for example, open access to contraceptive methods and the wide cultural acceptability of contraception may mean that women who experience IPV are more likely to use contraception than women who do not in the Nicaraguan context.

Limitations of Included Studies

While the objective of this review was to identify and synthesize the best available estimates of the effect of IPV on women’s use of contraception, the studies that we identified were subject to a number of limitations that could have biased our assessment of the relationship between IPV and women’s use of contraception.

Misclassification of the exposure. Three of the studies limited their definition of IPV to physical violence. Exposure to different forms of IPV is not necessarily correlated [1]; limiting the definition of IPV may underestimate the total effect of IPV which would bias effect estimates towards the null value if IPV affect contraceptive use. As expected, the magnitude of effect estimates from studies that included multiple forms of IPV was greater than the magnitude of effect estimates from studies that only measured one form of IPV. The range in the definition of intimate partners across studies may have led to underreporting of violence in studies that did not consider previous partners or sexual partners as intimate partners. This misclassification could have also biased results towards the null value.

All exposure and outcome measures were based on self-reports. Under-reporting of IPV is both difficult to evaluate and a pervasive issue in IPV-related research [53]. Women who report IPV may experience an increase in IPV incidence or severity [5456]. Women may be unlikely both because of the fear of increased violence and because of the stigma associated with reporting [54,57]. Studies that do not interview participants alone or that use interviewers who have not been trained in interviewing survivors of IPV likely lead to higher levels of under-reporting of the exposure than studies that follow the WHO best practices for interviewing women about IPV [9]. No included studies described their interviewer training practices.

Misclassification of the outcome. Three of the 10 studies included in the systematic review used expansive definitions of contraception that included withdrawal, “natural methods,” and/or the rhythm method [38,42,43]. Women who report using withdrawal or the rhythm method may not experience the same barriers to access and complicated negotiations with their partners and family members faced by women who try to use modern contraceptive methods. The classification of women who are not using a modern method of contraception as using contraception could have biased the association between IPV and women’s adoption of contraception towards the null value in these three studies.

Potential selection bias. Studies that restrict inference to participants who are retained in each survey wave may introduce selection bias if participants who are retained differ from those who are not in ways that are related to the exposure and to the outcome of interest [58]. In one study that restricted to participants who were retained in both survey waves, researchers found that retained participants had lower levels of self-efficacy and higher levels of depression than those who were not retained [41]. The three studies that restricted their populations to women who had given birth [39,41,43] may have introduced selection bias by selecting a lower percentage of women who experience IPV than that of the target population given that women who experience IPV may be more likely to terminate their pregnancies than women who do not [8].

Strengths and Limitations of This Review

This is the first systematic review to provide a quantitative estimate of the relationship between IPV and contraceptive use. We did not restrict our review by language and included a diversity of databases. Two researchers independently screened all articles and extracted data from research studies included in the systematic review. For studies that included a measure of gender based violence that was not limited to IPV, we contacted authors to see if they could provide us with an effect estimate limited to IPV.

In addition to the aforementioned limitations of individual studies that may underestimate the association between IPV and contraceptive use, there are several limitations to this analysis. All of the studies included in the systematic review estimate the odds of contraceptive uptake. Odds ratios estimated using logistic regression generally overestimate relative risks for prevalent outcomes [59], like contraceptive use, so the pooled ORs likely overestimate the magnitude of the relative probability of using contraception when comparing women who do and do not experience IPV. Because the pooled estimates include studies with different measures of IPV and the type and duration of contraceptive use, the pooled estimates are meant to provide an approximate estimate of the average association between IPV and contraceptive use and should be interpreted with caution.

Although contraceptive method type seemed to account for some heterogeneity in the overall estimate, statistical heterogeneity is not necessarily reflective of clinically important heterogeneity [60]. While the test for heterogeneity of the OR of included studies was not significant when restricting to studies that restricted inference to modern contraception, the statistical test for heterogeneity is underpowered and may not distinguish between actual and chance heterogeneity [60,61]. Given the limited number of studies included in the meta-analysis, we were not able to use meta-regression to explore sources of heterogeneity in the overall estimate [32,62,63].

Because researchers are unlikely to publish research protocols for observational studies, the results presented here are likely subject to publication bias. The heterogeneity of our exposure and outcome and the small number of included studies necessarily complicates the assessment of publication bias [60]. We assessed the degree of probable publication bias visually by using a funnel plot to compare study log ORs with their standard errors for all 10 studies included in the overall meta-analysis (S4 Fig.) and for the seven studies classified as having a low or moderate probability of bias (S5 Fig.). With few studies it is difficult to assess potential publication bias, but both contour funnel plots used to evaluate publication bias are missing studies from the area of non-significance, which suggests the possibility of some publication bias. Similarly, Egger’s test of funnel plot asymmetry indicated that we could not reject the null hypothesis of no small-study effects when considering all 10 studies (p = 0.764) or when limiting inference to the seven studies classified as having a low or moderate probability of bias (p = 0.640) [64].

Causal Inference

Temporality, consistency, strength of association, biological plausibility, and dose-response are necessary components of the classical approach to causal inference [65] and are used to evaluate the strength of evidence from meta-analysis of observational studies [66]. In all studies included in the meta-analysis, the measurement of the exposure proceeded the outcome. The estimates of the effect of IPV on women’s use of contraception are relatively strong and consistent across a diversity of populations in four countries, with the exception of the estimate from the Nicaraguan study as noted previously. A prior systematic review provides a comprehensive overview of the direct and indirect pathways through which IPV may affect women’s contraceptive use [21]. Pre-existing research in a number of countries suggests that women change their contraceptive behavior in the face of IPV and that IPV affects women’s ability to negotiate condom use with their male partners [5,15,19,67,68]. The meta-analysis of the three studies that examined violence severity suggests a dose-response relationship between women’s exposure to IPV and their use of contraception. The results from this review suggest that IPV may have a causal effect on women’s use of contraception and may affect women’s use of male condoms with their partners. The suggestion that IPV may have a causal effect on women’s use of contraception must be evaluated with the understanding that this is a meta-analysis of effect estimates from observational studies. While we limited the meta-analysis to studies classified as having a low or moderate probability of bias, the findings of our meta-analysis are subject to the residual confounding that likely affects effect estimates from included studies [69]. In the absence of individual patient level data, as would be used in an individual patient data meta-analysis, we cannot be sure that the decrease in contraceptive use across studies is caused by women’s experience of IPV and not by miss-measured or unmeasured confounders.

Implications for Future Research

The purpose of this review was to summarize existing evidence from longitudinal and case-control studies for the effect of IPV on women’s use of contraception. Of the nine studies that included longitudinal measures, two studies could not be used to estimate the effect of IPV on women’s use of contraception because the exposure and the outcome were measured contemporaneously. There is a clear need for additional research where the temporal ordering of exposure and outcome allow for a better understanding of the causal effect of IPV on women’s use of contraception.

Two of the seven studies included in the meta-analysis only assessed the effect of physical violence on women’s use of contraception. Future research should include a more complete definition of IPV to better estimate the total impact of IPV on women’s use of contraception. Sexual and physical IPV may have differential effects on women’s use of contraception; additional research should consider including estimates of the association between different forms of IPV and contraceptive use. Reproductive coercion may affect women’s contraceptive use in the absence of other forms of IPV. Future research could explore additional causal pathways through which reproductive coercion, community norms about violence, gender inequality, and the influence of in-laws interact with other forms of IPV to affect women’s contraceptive use.

This review indicates that women who experience IPV are less likely to report that their male partners use condoms than women who do not. Future research might examine the impact of harm reduction strategies on the ability of women who experience IPV to use condoms with their male partners. Condom use requires a complex set of negotiations between a woman and her male partner. Prior research indicates that women who experience IPV may be more likely to adopt contraceptive methods that they can hide from their partners [14,70,71]. Further research is needed to understand whether women who experience IPV prefer to adopt long-acting reversible and permanent contraceptive methods that are less likely to require their partner’s involvement. In meta-analysis, sources of heterogeneity may indicate important sources of bias [72]. This review suggests that contraceptive method type should be considered as a source of bias in estimates of the effect of IPV on women’s contraceptive use. To best understand how IPV modifies women’s adoption of contraception or the type of method that women choose to adopt, future research should consider limiting inference to modern methods of contraception and might differentiate between methods that do and do not require ongoing negotiations between a woman and her male partner.

Across studies that included a classification of IPV duration, the magnitude of the effect of persistent IPV on women’s use of contraception was greater than that of remittent or incident IPV. Future research could continue to explore the importance of IPV duration in predicting women’s use of contraception.

Implications for Practice

Understanding how IPV modifies women’s ability to adopt or to continue to use contraception is central to informing evidence-based FP and HIV prevention interventions. Prior research indicates that IPV is associated with HIV infection [1012]. Given that this systematic review found that women who report IPV are less likely to use condoms than women who do not report IPV, HIV prevention interventions should consider addressing IPV.

The WHO recommends that providers ask women about exposure to IPV when assessing conditions that may be caused or complicated by IPV [73] and FP providers should consider asking specifically about reproductive coercion when screening for IPV [18,74]. The American College of Obstetricians and Gynecologists offers specific guidance for providers to ask women about their experience of reproductive coercion [74]. Recent clinical guidelines suggest that health care providers caring for women who experience reproductive coercion should offer contraceptive methods that are less susceptible to partner sabotage (e.g., IUD and implant) while counseling women about IPV and safety planning strategies [75]. Ensuring that women can access long-acting and permanent contraceptive methods could help women who experience IPV plan their families.

Conclusion

Pooling estimates from seven longitudinal studies that included 14,866 participants, women who experienced IPV were less likely to use contraception than women who did not. The high level of heterogeneity in the pooled estimate is typical of systematic reviews of non-randomized studies and may be due to the inclusion of heterogeneous populations and exposure and outcome measures or to residual confounding of effect measures from individual studies [26]. Future research that includes longitudinal measures of IPV and women’s use of modern contraceptive methods is needed to better understand the impact of IPV on women’s adoption of contraception.

Supporting Information

S1 Fig. Meta-analysis of the association between IPV and condom use.

https://doi.org/10.1371/journal.pone.0118234.s001

(PDF)

S2 Fig. Meta-analysis of the association between physical partner violence and contraceptive use.

https://doi.org/10.1371/journal.pone.0118234.s002

(PDF)

S3 Fig. Meta-analysis of the association between IPV and contraceptive use, by whether study restricted to delivered women.

https://doi.org/10.1371/journal.pone.0118234.s003

(PDF)

S4 Fig. Funnel plot to assess publication bias.

https://doi.org/10.1371/journal.pone.0118234.s004

(PDF)

S5 Fig. Funnel plot to assess publication bias in seven studies classified as having a low or moderate probability of bias.

https://doi.org/10.1371/journal.pone.0118234.s005

(PDF)

S6 Fig. Directed acyclic graph of hypothesized causal relationship between IPV and women’s contraceptive use.

https://doi.org/10.1371/journal.pone.0118234.s006

(PDF)

S2 Table. List of articles excluded after full text review with reasons for exclusion.

https://doi.org/10.1371/journal.pone.0118234.s008

(PDF)

S3 Table. Summary of randomized controlled trials that examine the association between IPV and women contraceptive use.

https://doi.org/10.1371/journal.pone.0118234.s009

(PDF)

S3 Text. Cochrane Methodological Quality Assessment of Observational Studies for Longitudinal and Case Control studies.

https://doi.org/10.1371/journal.pone.0118234.s012

(PDF)

S4 Text. Cochrane Risk of Bias Tool for Randomized Controlled Trials.

https://doi.org/10.1371/journal.pone.0118234.s013

(PDF)

Acknowledgments

We would like to acknowledge the invaluable support of Genevieve Gore, the information scientist who guided us through the initial search process. We would also like to thank the researchers who responded to our request for articles that we could not otherwise locate or to our requests for additional information. In particular we would like to thank Nilda Calandra; Phillip Scribano; and Virgilio Mariano Salazar Torres. Finally, we would like to thank Arijit Nandi and Madhu Pai for their guidance on the manuscript.

Author Contributions

Conceived and designed the experiments: LM. Performed the experiments: LM DZ. Analyzed the data: LM. Contributed reagents/materials/analysis tools: LM KD. Wrote the paper: LM KD JA JC.

References

  1. 1. Devries K, Mak J, García-Moreno C, Petzold M, Child J, et al. (2013) The global prevalence of intimate partner violence against women. Science 340: 1527–1528. pmid:23788730
  2. 2. Raneri LG, Wiemann CM (2007) Social ecological predictors of repeat adolescent pregnancy. Perspectives on sexual and reproductive health 39: 39–47. pmid:17355380
  3. 3. Jacoby M, Gorenflo D, Wunderlich C, Eyler A (1999) Rapid repeat pregnancy and experiences of interpersonal violence among low-income adolescents. American Journal of Preventive Medicine 16: 318–321. pmid:10493289
  4. 4. Hung KJ, Scott J, Ricciotti HA, Johnson TR, Tsai AC (2012) Community-Level and Individual-Level Influences of Intimate Partner Violence on Birth Spacing in Sub-Saharan Africa. Obstetrics & Gynecology 119: 975–982 910.1097/AOG.1090b1013e31824fc31829a31820. pmid:25626177
  5. 5. Miller E, Decker MR, McCauley HL, Tancredi DJ, Levenson RR, et al. (2010) Pregnancy coercion, intimate partner violence and unintended pregnancy. Contraception 81: 316–322. pmid:20227548
  6. 6. Miller E, McCauley HL, Tancredi DJ, Decker MR, Anderson H, et al. (2014) Recent reproductive coercion and unintended pregnancy among female family planning clients. Contraception 89: 122–128. pmid:24331859
  7. 7. Hindin MJ, Kishor S, Ansara DL (2008) Intimate partner violence among couples in 10 DHS countries: predictors and health outcomes.
  8. 8. Hall M, Chappell LC, Parnell BL, Seed PT, Bewley S (2014) Associations between Intimate Partner Violence and Termination of Pregnancy: A Systematic Review and Meta-Analysis. PLoS medicine 11: e1001581. pmid:24409101
  9. 9. Organization. WH (2013) Global and regional estimates of violence against women: prevalence and health effects of intimate partner violence and non-partner sexual violence. World Health Organization. 9241564628 9241564628.
  10. 10. Kouyoumdjian F, Calzavara L, Bondy S, O’Campo P, Serwadda D, et al. (2013) Intimate partner violence is associated with incident HIV infection in women in Rakai, Uganda. AIDS 27: 1331–1338. pmid:23925380
  11. 11. Jewkes R, Sikweyiya Y, Morrell R, Dunkle K (2011) The relationship between intimate partner violence, rape and HIV amongst South African men: a cross-sectional study. PLoS One 6: e24256. pmid:21935392
  12. 12. Jewkes R, Dunkle K, Nduna M, Levin J, Jama N, et al. (2006) Factors associated with HIV sero-status in young rural South African women: connections between intimate partner violence and HIV. International Journal of Epidemiology 35: 1461–1468. pmid:17008362
  13. 13. Dude A (2011) Spousal intimate partner violence is associated with HIV and Other STIs among married Rwandan women. AIDS Behav 15: 142–152. pmid:19205864
  14. 14. Gee RE, Mitra N, Wan F, Chavkin DE, Long JA (2009) Power over parity: intimate partner violence and issues of fertility control. American journal of obstetrics and gynecology 201: 148. e141–148. e147.
  15. 15. Moore AM, Frohwirth L, Miller E (2010) Male reproductive control of women who have experienced intimate partner violence in the United States. Social Science & Medicine 70: 1737–1744. pmid:25626040
  16. 16. Coggins M, Bullock LF (2003) The wavering line in the sand: the effects of domestic violence and sexual coercion. Issues in mental health nursing 24: 723–738. pmid:12907386
  17. 17. Miller E, Decker MR, Reed E, Raj A, Hathaway JE, et al. (2007) Male Partner Pregnancy-Promoting Behaviors and Adolescent Partner Violence: Findings from a Qualitative Study with Adolescent Females. Ambulatory pediatrics: the official journal of the Ambulatory Pediatric Association 7: 360–366.
  18. 18. Clark LE, Allen RH, Goyal V, Raker C, Gottlieb AS (2013) Reproductive coercion and co-occurring intimate partner violence in obstetrics and gynecology patients. American Journal of Obstetrics & Gynecology. pmid:25611896
  19. 19. de Bocanegra HT, Rostovtseva DP, Khera S, Godhwani N (2010) Birth control sabotage and forced sex: experiences reported by women in domestic violence shelters. Violence Against Women 16: 601–612. pmid:20388933
  20. 20. Hathaway JE, Willis G, Zimmer B, Silverman JG (2004) Impact of partner abuse on women’s reproductive lives. Journal of the American Medical Women’s Association (1972) 60: 42–45.
  21. 21. Coker AL (2007) Does physical intimate partner violence affect sexual health? A systematic review. Trauma, Violence, & Abuse 8: 149–177. pmid:25624493
  22. 22. Devries KM, Mak JY, Bacchus LJ, Child JC, Falder G, et al. (2013) Intimate partner violence and incident depressive symptoms and suicide attempts: a systematic review of longitudinal studies. PLoS medicine 10: e1001439. pmid:23671407
  23. 23. Friedman SH, Loue S (2007) Incidence and prevalence of intimate partner violence by and against women with severe mental illness. J Womens Health (Larchmt) 16: 471–480. pmid:17521250
  24. 24. Ramsay J, Carter Y, Davidson L, Dunne D, Eldridge S, et al. (2009) Advocacy interventions to reduce or eliminate violence and promote the physical and psychosocial well-being of women who experience intimate partner abuse. Cochrane Database Syst Rev: CD005043. pmid:19588364
  25. 25. Moher D, Liberati A, Tetzlaff J, Altman DG (2009) Preferred reporting items for systematic reviews and meta-analyses: the PRISMA statement. Annals of internal medicine 151: 264–269. pmid:19622511
  26. 26. Reeves BC, Deeks JJ, Higgins JP (2008) Chapter 13: Including non-randomized studies. In: Higgins JG, S , editor. Cochrane handbook for systematic reviews of interventions. Chichester (UK): John Wiley & Sons.
  27. 27. Shrier I, Platt RW (2008) Reducing bias through directed acyclic graphs. BMC medical research methodology 8: 70. pmid:18973665
  28. 28. Hernán MA, Hernández-Díaz S, Werler MM, Mitchell AA (2002) Causal Knowledge as a Prerequisite for Confounding Evaluation: An Application to Birth Defects Epidemiology. American Journal of Epidemiology 155: 176–184. pmid:11790682
  29. 29. Howards PP, Schisterman EF, Poole C, Kaufman JS, Weinberg CR (2012) “Toward a Clearer Definition of Confounding” Revisited With Directed Acyclic Graphs. American Journal of Epidemiology 176: 506–511. pmid:22904203
  30. 30. Field AP (2003) The problems in using fixed-effects models of meta-analysis on real-world data. Understanding Statistics: Statistical Issues in Psychology, Education, and the Social Sciences 2: 105–124.
  31. 31. Higgins JP, Thompson SG, Deeks JJ, Altman DG (2003) Measuring inconsistency in meta-analyses. BMJ: British Medical Journal 327: 557. pmid:12958120
  32. 32. Deeks J, Higgins J, Altman D (2011) Chapter 9: Analysing Data and Undertaking Meta-analyses: Cochrane Handbook for Systematic Reviews of Interventions Version 5.1. 0 [updated March 2011]. Cochrane Handbook for Systematic Reviews of Interventions 5.
  33. 33. Orsini N, Bottai M, Higgins J, Buchan I (2006) Heterogi: Stata module to quantify heterogeneity in a meta-analysis. Statistical Software Components.
  34. 34. Steichen T (2001) METANINF: Stata module to evaluate influence of a single study in meta-analysis estimation. Statistical Software Components.
  35. 35. Wingood GM, DiClemente RJ, Harrington KF, Lang DL, Davies SL, et al. (2006) Efficacy of an HIV prevention program among female adolescents experiencing gender-based violence: American Journal of Public Health. 96 (6) (pp 1085–1090), 2006. Date of Publication: June 2006. pmid:16670238
  36. 36. Jones D, Peltzer K, Villar-Loubet O, Shikwane E, Cook R, et al. (2013) Reducing the risk of HIV infection during pregnancy among South African women: A randomized controlled trial. AIDS Care 25: 702–709. pmid:23438041
  37. 37. El-Bassel N, Gilbert L, Wu E, Go H, Hill J (2005) HIV and intimate partner violence among methadone-maintained women in New York City. Social Science & Medicine 61: 171–183. pmid:25626040
  38. 38. Fantasia HC, Sutherland MA, Fontenot HB, Lee-St John TJ (2012) Chronicity of partner violence, contraceptive patterns and pregnancy risk. Contraception 86: 530–535. pmid:22520646
  39. 39. Scribano PV, Stevens J, Kaizar E (2013) The effects of intimate partner violence before, during, and after pregnancy in nurse visited first time mothers. Maternal and Child Health Journal 17: 307–318. pmid:22426619
  40. 40. Teitelman A, Ratcliffe S, Dichter M, Sullivan C (2008) Recent and past intimate partner abuse and HIV risk among young women. JOGNN—Journal of Obstetric, Gynecologic, & Neonatal Nursing 37: 219–227. pmid:25589047
  41. 41. Van Horne BS, Wiemann CM, Berenson AB, Horwitz IB, Volk RJ (2009) Multilevel predictors of inconsistent condom use among adolescent mothers. (Special Issue: Influenza preparedness and response.). American Journal of Public Health 99: S417–S424. pmid:19372530
  42. 42. Williams CM, Larsen U, McCloskey LA (2008) Intimate partner violence and women’s contraceptive use. Violence Against Women 14: 1382–1396. pmid:18845676
  43. 43. Salazar M, Valladares E, Hogberg U (2011) Questions about intimate partner violence should be part of contraceptive counselling: findings from a community-based longitudinal study in Nicaragua. Journal of Family Planning and Reproductive Health Care. pmid:22167533
  44. 44. McCarraher DR, Martin SL Sr, Bailey PE (2006) The influence of method-related partner violence on covert pill use and pill discontinuation among women living in La Paz, El Alto and Santa Cruz, Bolivia: Journal of Biosocial Science. 38 (2) (pp 169–186), 2006. Date of Publication: March 2006. pmid:16490152
  45. 45. Stephenson R, Jadhav A, Hindin M (2013) Physical domestic violence and subsequent contraceptive adoption among women in rural India. Journal of Interpersonal Violence 28: 1020–1039. pmid:23008052
  46. 46. Kacanek D, Bostrom A, Montgomery ET, Ramjee G, de Bruyn G, et al. (2013) Intimate Partner Violence and Condom and Diaphragm Nonadherence Among Women in an HIV Prevention Trial in Southern Africa. Journal of Acquired Immune Deficiency Syndromes: JAIDS 64: 400–408. pmid:24165561
  47. 47. Van der Wijden C, Kleijnen J, Van den Berk T (2003) Lactational amenorrhea for family planning. Cochrane Database Syst Rev 4. pmid:14584022
  48. 48. Commodity Security Branch UNPF (2011) Nicaragua: Country Profile. New York, NY: UNFPA.
  49. 49. Stupp PW, Daniels D, Ruiz A (2007) Reproductive, Maternal, and Child Health in Central America: Health Equity Trends: El Salvador, Guatemala, Honduras, Nicaragua: Centers for Disease Control and Prevention.
  50. 50. Alkema L, Kantorova V, Menozzi C, Biddlecom A (2013) National, regional, and global rates and trends in contraceptive prevalence and unmet need for family planning between 1990 and 2015: a systematic and comprehensive analysis. The Lancet 381: 1642–1652. pmid:23489750
  51. 51. Campbell JC (2002) Health consequences of intimate partner violence. The Lancet 359: 1331–1336. pmid:11965295
  52. 52. Dutton MA, Kaltman S, Goodman LA, Weinfurt K, Vankos N (2005) Patterns of intimate partner violence: Correlates and outcomes. Violence and victims 20: 483–497. pmid:16248486
  53. 53. Gracia E (2004) Unreported cases of domestic violence against women: towards an epidemiology of social silence, tolerance, and inhibition. Journal of Epidemiology and Community Health 58: 536–537. pmid:15194711
  54. 54. Ellsberg M, Heise L, Pena R, Agurto S, Winkvist A (2001) Researching Domestic Violence against Women: Methodological and Ethical Considerations. Studies in Family Planning 32: 1–16. pmid:11326453
  55. 55. Jewkes R, Watts C, Abrahams N, Penn-Kekana L, García-Moreno C (2000) Ethical and methodological issues in conducting research on gender-based violence in Southern Africa. Reproductive health matters 8: 93–103. pmid:11424273
  56. 56. Ellsberg M, Heise L (2002) Bearing witness: ethics in domestic violence research. The Lancet 359: 1599–1604. pmid:12047984
  57. 57. Abramsky T, Watts C, Garcia-Moreno C, Devries K, Kiss L, et al. (2011) What factors are associated with recent intimate partner violence? findings from the WHO multi-country study on women’s health and domestic violence. BMC Publ Health 11: 109.
  58. 58. Hernán MA, Hernandez-Diaz S, Robins JM (2004) A structural approach to selection bias. Epidemiology 15: 615–625. pmid:15308962
  59. 59. McNutt L-A, Wu C, Xue X, Hafner JP (2003) Estimating the Relative Risk in Cohort Studies and Clinical Trials of Common Outcomes. American Journal of Epidemiology 157: 940–943. pmid:12746247
  60. 60. Ioannidis JPA (2008) Interpretation of tests of heterogeneity and bias in meta-analysis. JEP Journal of Evaluation in Clinical Practice 14: 951–957. pmid:19018930
  61. 61. Thompson SG, Higgins JPT (2005) Can meta-analysis help target interventions at individuals most likely to benefit? The Lancet 365: 341–346. pmid:15664231
  62. 62. Baker W, White M, Cappelleri J, Kluger J, Coleman C (2009) Understanding heterogeneity in meta-analysis: the role of meta-regression. International Journal of Clinical Practice 63: 1426–1434. pmid:19769699
  63. 63. Borenstein M, Hedges LV, Higgins JP, Rothstein HR (2011) Introduction to meta-analysis: John Wiley & Sons.
  64. 64. Peters JL, Sutton AJ, Jones DR, Abrams KR, Rushton L (2006) Comparison of two methods to detect publication bias in meta-analysis. JAMA: the journal of the American Medical Association 295: 676–680. pmid:16467236
  65. 65. Hill AB (1965) The environment and disease: association or causation? Proceedings of the Royal Society of Medicine 58: 295–300. pmid:14283879
  66. 66. Schünemann H, Oxman A, Vist G, Higgins J, Deeks J, et al. (2011) Chapter 12: Interpreting results and drawing conclusions. In: JPT H, S G, editors. Cochrane Handbook for Systematic Reviews of Interventions Version 510 (updated March 2011): The Cochrane Collaboration.
  67. 67. Ely GE, Otis MD (2011) An examination of intimate partner violence and psychological stressors in adult abortion patients. Journal of interpersonal violence 26: 3248–3266. pmid:21282124
  68. 68. Fanslow J, Whitehead A, Silva M, Robinson E (2008) Contraceptive use and associations with intimate partner violence among a population-based sample of New Zealand women. Australian and New Zealand Journal of Obstetrics and Gynaecology 48: 83–89. pmid:18275577
  69. 69. Egger M, Schneider M, Smith GD (1998) Spurious precision? meta-analysis of observational studies. BMJ: British Medical Journal 316: 140. pmid:9462324
  70. 70. Hindin M, Kishor S, Ansara D (2008) Intimate partner violence among couples in 10 DHS countries: predictors and health outcomes. DHS Analytical Studies No 18. Calverton, Maryland, USA: Macro International Inc.
  71. 71. Alio AP, Daley EM, Nana PN, Duan J, Salihu HM (2009) Intimate partner violence and contraception use among women in Sub-Saharan Africa. International Journal of Gynecology & Obstetrics 107: 35–38. pmid:25625194
  72. 72. Weed DL (2000) Interpreting epidemiological evidence: how meta-analysis and causal inference methods are related. International Journal of Epidemiology 29: 387–390. pmid:10869307
  73. 73. Organization. WH (2013) Summary: responding to intimate partner violence and sexual violence against women: clinical and policy recommendations.
  74. 74. Chamberlain L, Levenson R (2013) Addressing Intimate Partner Violence, Reproductive and Sexual Coercion: A Guide for Obstetric, Gynecologic, Reproductive Health Care Settings.
  75. 75. Gynecologists ACoOa (2013) ACOG Committee opinion no. 554: Reproductive and sexual coercion. Obstetrics and Gynecology 121: 411–415. pmid:23344307
  76. 76. Padian NS, van der Straten A, Ramjee G, Chipato T, de Bruyn G, et al. (2007) Diaphragm and lubricant gel for prevention of HIV acquisition in southern African women: a randomised controlled trial. The Lancet 370: 251–261.