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Breastfeeding and maternal cardiovascular risk factors and outcomes: A systematic review

  • Binh Nguyen ,

    Roles Conceptualization, Data curation, Formal analysis, Investigation, Methodology, Visualization, Writing – original draft, Writing – review & editing

    thanh-binh.nguyen-duy@sydney.edu.au

    Affiliation Prevention Research Collaboration, Sydney School of Public Health, Faculty of Medicine, The University of Sydney, Camperdown, New South Wales, Australia

  • Kai Jin,

    Roles Conceptualization, Formal analysis, Writing – original draft

    Affiliation Sydney Nursing School, Charles Perkins Centre, The University of Sydney, Camperdown, New South Wales, Australia

  • Ding Ding

    Roles Conceptualization, Methodology, Supervision, Visualization, Writing – original draft, Writing – review & editing

    Affiliation Prevention Research Collaboration, Sydney School of Public Health, Faculty of Medicine, The University of Sydney, Camperdown, New South Wales, Australia

Abstract

Background

There is growing evidence that breastfeeding has short- and long-term cardiovascular health benefits for mothers. The objectives of this systematic review were to examine the association between breastfeeding and maternal cardiovascular risk factors and outcomes that have not previously been synthesized systematically, including metabolic syndrome, hypertension and cardiovascular disease.

Methods and findings

This systematic review meets PRISMA guidelines. The MEDLINE, EMBASE and CINAHL databases were systematically searched for relevant publications of any study design from the earliest publication date to March 2016. The reference lists from selected articles were reviewed, and forward and backward referencing were conducted. The methodological quality of reviewed articles was appraised using validated checklists.

Twenty-one studies meeting the inclusion criteria examined the association between self-reported breastfeeding and one or more of the following outcomes: metabolic syndrome/metabolic risk factors (n = 10), inflammatory markers/adipokines (n = 2), hypertension (n = 7), subclinical cardiovascular disease (n = 2), prevalence/incidence of cardiovascular disease (n = 3) and cardiovascular disease mortality (n = 2). Overall, 19 studies (10 cross-sectional/retrospective, 9 prospective) reported significant protective effects of breastfeeding, nine studies (3 cross-sectional/retrospective, 5 prospective, 1 cluster randomized controlled trial) reported non-significant findings and none reported detrimental effects of breastfeeding. In most studies reporting significant associations, breastfeeding remained associated with both short- and long-term maternal cardiovascular health risk factors/outcomes, even after covariate adjustment. Findings from several studies suggested that the effects of breastfeeding may diminish with age and a dose-response association between breastfeeding and several metabolic risk factors. However, further longitudinal studies, including studies that measure exclusive breastfeeding, are needed to confirm these findings.

Conclusions

The evidence from this review suggests that breastfeeding is associated with cardiovascular health benefits. However, results should be interpreted with caution as the evidence gathered for each individual outcome was limited by the small number of observational studies. Additional prospective studies are needed.

PROSPERO registration number

CRD42016047766.

Introduction

Cardiovascular disease is the leading cause of death among women globally [1] and lifestyle-related factors play a key role in its prevention. Considerable attention has been given to more conventional risk factors such as obesity, physical inactivity and an unhealthy diet. However, other modifiable behaviours, such as breastfeeding, should be considered and incorporated in the development of potential strategies to prevent cardiovascular disease.

While the importance of breastfeeding is well recognized for infant and child health, there is growing interest in maternal health outcomes. Breastfeeding has favourable short-term effects on maternal metabolic health, including lipid homeostasis [24], glucose homeostasis and insulin sensitivity [5,6]. Evidence from observational studies is accumulating for an association between breastfeeding and longer-term maternal cardiovascular risk factors such as hypertension [7,8], type 2 diabetes [9,10], obesity [11], and metabolic syndrome [MS] [12]. Breastfeeding has also been linked to cardiovascular disease incidence [13] and mortality [14].

To date, there have been several systematic reviews examining the association between breastfeeding and cardiovascular risk factors such as postpartum weight change, body composition and type 2 diabetes [1518]. Findings from these reviews suggest that breastfeeding may be associated with a reduced risk of type 2 diabetes [16,18] while the associations with postpartum weight change and body composition are unclear [15,17,18]. To our knowledge, the evidence for an association between breastfeeding and other cardiovascular risk factors and outcomes such as MS, hypertension and cardiovascular disease, has not been systematically summarized. With growing evidence suggesting that breastfeeding has both short- and long-term effects on maternal cardiovascular health outcomes, it is important to evaluate whether breastfeeding can be a modifiable risk factor for cardiovascular disease in parous women and whether lactation has long-term beneficial effects for maternal cardiovascular health.

Therefore, the objectives of this systematic review were to summarize the relationship of breastfeeding with maternal cardiovascular risk factors and outcomes that have not previously been reviewed systematically and to synthesize the findings that have been recently evaluated systematically. Reviewing this evidence systematically can provide valuable information for future guidelines and strategies for cardiovascular disease prevention.

Methods

Details of the protocol for this systematic review were registered with the International Prospective Register of Systematic Reviews (PROSPERO; registration number CRD42016047766) and can be accessed at http://www.crd.york.ac.uk/PROSPERO/display_record.asp?ID=CRD42016047766. This systematic review meets Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines (S1 Checklist) [19].

Search strategy

The electronic databases MEDLINE, EMBASE and CINAHL were searched for relevant publications, from the earliest publication date to March 2016, using multiple subject headings and text words in combination (S1 Table). Additional articles were identified through backward and forward reference searching. Authors of published conference abstracts were contacted to identify any corresponding full text publications. Only full text publications of studies on humans and published in English were considered.

Inclusion criteria and study selection

Articles of any study design (e.g. cross-sectional/retrospective, prospective cohort, cluster randomized controlled trial [RCT]) were included in this systematic review if they investigated the association of breastfeeding with any maternal cardiovascular risk factor and/or cardiovascular outcome of a biological nature. Possible cardiovascular risk factors included: weight change, body mass index (BMI), waist circumference, body composition (e.g. visceral adiposity), hypertension, type 2 diabetes mellitus, hyperlipidemia, MS/risk factors and inflammatory markers. Studies on lifestyle risk factors, such as smoking, physical inactivity and an unhealthy diet, were not considered. Cardiovascular outcomes included subclinical and clinical cardiovascular disease prevalence, incidence and mortality. All study time periods, definitions of breastfeeding (whether exclusive or complemented by other foods) and studies that involved women with any menopausal status were accepted. Studies were excluded if they had a small sample size (defined arbitrarily as <100 participants) and if they examined risk factors/outcomes relating only to: the breastfed child, cancer, and pregnancy complications (e.g. gestational diabetes mellitus, pre-eclampsia and pre-term delivery). Two reviewers (BN and KJ) independently screened the titles and abstracts of retrieved articles to assess study eligibility. Any disagreement or uncertainty was resolved through discussion. The same reviewers reviewed the full text articles that met the inclusion criteria or with uncertain eligibility. Any disagreement was resolved by consensus. Although systematic reviews were not included among the selected studies, recent systematic reviews were identified and summarized for several outcomes of interest (postpartum weight change, body composition and type 2 diabetes) [1518]. Studies involving maternal outcomes of interest that had not been previously systematically assessed were reviewed (MS/metabolic risk factors, hypertension, inflammatory markers, adipokines, subclinical cardiovascular disease, and cardiovascular disease prevalence, incidence and mortality).

Quality assessment and data extraction

One reviewer (BN) assessed the methodological quality of cross-sectional/retrospective and prospective cohort studies by using an adapted 15-item checklist derived from checklists for the reporting of observational studies (S2 Table) [20]. The single cluster RCT trial was appraised against a quality assessment checklist based on a tool developed by the Cochrane collaboration for assessing risk of bias in randomized studies [21] and relating to the following criteria: random sequence generation, allocation concealment, blinding of participants and personnel, blinding of outcome assessment, completeness of outcome data, accurate outcome reporting and other sources of bias addressed. For each study, an overall study quality rating was allocated based on the total number of individual criteria met or addressed. Studies were rated as: “low quality” if ≤1/3 of individual criteria were met, “medium quality” if >1/3-≤2/3 of individual criteria were met and “high quality” if >2/3 of criteria were met. Five articles (~25%) were randomly selected from the included studies and independently appraised by the second reviewer (KJ). The overall agreement rate between both authors for the quality rating of these five articles was 100%.

The following data were extracted from each article: study design, country in which the study was conducted, cohort/study designation, sample size, brief participant description, age range, mean follow-up or period, type of outcome measure(s), breastfeeding comparison categories, effect sizes (most commonly reported as odds ratios or relative risks with 95% confidence intervals) and covariates adjusted for. The expected direction of each association was hypothesized based on existing literature and coded as: + (significant association in the hypothesized direction),–(significant association not in the hypothesized direction), 0 (non-significant association). Due to the heterogeneous nature of the studies and limited number of studies for each outcome of interest, only a qualitative analysis of included studies was conducted.

Breastfeeding terms and categories

In this review, the terms breastfeeding and lactation are used interchangeably. Breastfeeding was self-reported in all included studies. Lactation history refers to any reported history (usually ≥1 month) of breastfeeding (ever vs. never). Lactation duration is the reported length of time a woman breastfed a child. Exclusive lactation duration is the length of time a woman exclusively breastfed a child before introducing complementary foods. Lifetime lactation duration is the cumulative amount of time a woman reportedly breastfed across all pregnancies and average lactation duration is the average amount of time a woman breastfed each child.

Results

Selection of studies

The study selection process is shown in Fig 1. The literature searches yielded 581 unique citations, of which 37 were identified as potentially relevant. Following full text review, 16 studies were excluded based on small sample size or if they related to outcomes of interest that had been recently reviewed in retrieved systematic reviews (i.e., adiposity, body composition, and type 2 diabetes). Twenty-one articles examining the association between breastfeeding and one or more of the following outcomes were included for review: MS/metabolic risk factors (n = 10), hypertension (n = 7), inflammatory markers/adipokines (n = 2), subclinical cardiovascular disease (n = 2), prevalence/incidence of cardiovascular disease (n = 3) and cardiovascular disease mortality (n = 2).

Critical appraisal

Out of 21 included papers, 16 (76%) were rated as high quality and 5 (24%) as medium quality (S3 and S4 Tables). Although most quality assessment criteria were adequately addressed, many observational studies failed to describe the reliability (n = 15) and/or validity (n = 12) of the breastfeeding measure and the number of participants with missing data for the exposure/outcome of interest (n = 6).

Study characteristics

Tables 15 provide details of reviewed studies. Nearly all papers (95%) were published in the last decade. Of the 21 included studies, 9 were cross-sectional/retrospective [2230], 10 were prospective [7,8,1214,3135], 1 reported both cross-sectional/retrospective and prospective data [36], and 1 was a cluster RCT [37]. More than half of the studies were conducted in the United States (US) (n = 11), with the remaining conducted in Europe (n = 4), Asia (n = 5), and Australia (n = 1). Sample sizes ranged from 297 to 267,400 participants (median = 6,914) and the age of participants varied between 18 and 89 years of age. In prospective studies, participants were followed up between 3 and 20 years. Breastfeeding was assessed mainly by self-administered questionnaires (16/21 studies) and also by interviewer-administered questionnaires (6/21 studies). Study outcomes were mostly measured, although several were self-reported.

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Table 1. Summary of included studies with metabolic syndrome as the outcome.

https://doi.org/10.1371/journal.pone.0187923.t001

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Table 2. Summary of included studies with metabolic risk factors as the outcome.

https://doi.org/10.1371/journal.pone.0187923.t002

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Table 3. Summary of included studies with hypertension as the outcome.

https://doi.org/10.1371/journal.pone.0187923.t003

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Table 4. Summary of included studies with inflammatory markers, adipokines and subclinical cardiovascular disease as the outcomes.

https://doi.org/10.1371/journal.pone.0187923.t004

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Table 5. Summary of included studies with cardiovascular disease as the outcome.

https://doi.org/10.1371/journal.pone.0187923.t005

Association between breastfeeding and maternal cardiovascular risk factors and outcomes

Weight change/body composition.

A 2014 systematic review by Neville et al., based on 37 prospective studies and eight retrospective studies, assessed the relationship between breastfeeding and changes in postpartum weight or body composition in mothers ≤2 years postpartum [17]. Most studies found little or no association between breastfeeding and either change in postpartum weight or maternal body composition.

In 2015, a systematic review conducted by Chowdury et al. [15] updated the review on postpartum weight change by Neville et al. [17] with five additional studies. The authors concluded that there were no clear associations between breastfeeding and postpartum weight change, with factors such as age, gestational weight gain and pre-pregnancy weight possibly confounding these relationships.

Type 2 diabetes.

In a 2014 review and meta-analysis based on six cohort studies, the longest duration of lifetime lactation was associated with a 32% reduction in relative risk of type 2 diabetes compared with the shortest duration [16]. This finding was in line with a later review of the same primary studies [15] and an earlier systematic review [18].

MS.

MS is a cluster of conditions which can increase the risk for diabetes and CVD. Table 1 describes studies with MS as the outcome. Five studies examined the association between breastfeeding and MS [12,2224,31]. Studies adhered to the National Cholesterol Education Program Adult Treatment Panel III criteria [38] to define MS, which is based on the presence of three of more of the following risk determinants: abdominal obesity, elevated triglyceride levels, reduced high-density lipoprotein cholesterol levels, elevated blood pressure, and elevated fasting glucose levels [38]. The findings from the three cross-sectional studies, conducted among women of different age categories, were mixed [2224]. One study from the US found a significant protective association of both lactation history and lifetime lactation duration with MS in a dose-response manner in middle-aged, parous premenopausal women from various ethnic backgrounds [22]. Another US study reported a significant association between lactation history and the prevalence of MS in parous women aged ≥20 years. However, this association was no longer significant after additional adjustment for BMI [23]. The third study did not find any association between lactation history and the prevalence of the MS in postmenopausal Korean women [24].

Both prospective studies found significant protective effects of lifetime lactation duration on incident MS [12,31]. One study following Iranian women over 9 years observed a significant association between 13–23 months lifetime lactation duration and higher incidence of MS compared with ≥24 months [31]. The other study showed that lifetime lactation duration of 6–9 and >9 months was significantly associated with a lower incidence of MS compared with 0–1 month lactation, among American women of reproductive age followed over a 20-year period [12].

Metabolic risk factors.

Table 2 provides a summary of studies with metabolic risk factors as the outcomes. Five studies (three cross-sectional/retrospective, two prospective) assessed the relation between breastfeeding and metabolic risk factors [25,26,32,33,36]. All three cross-sectional/retrospective studies reported a protective association of breastfeeding with metabolic risk factors [25,26,36]. One study involving Portuguese mothers who were examined at 4 years postpartum, showed that women who breastfed their child for >26 weeks were less likely to be obese and have and an adverse metabolic profile. However, there was no association between breastfeeding and excessive weight associated with a healthy metabolic profile [25]. Another cross-sectional/retrospective study found that lifetime lactation duration is associated in a dose-response fashion with a more favorable cardiovascular risk profile, including lipids, in a large sample of Norwegian mothers later in life [26]. Similarly, the third cross-sectional/retrospective study found a dose-response relationship between lifetime lactation duration and hyperlipidemia in a large sample of US mothers [36].

The findings from relatively small prospective studies were mixed [32,33]. One US prospective study examining 3-year changes in metabolic risk factors from pre-pregnancy to post-weaning showed that breastfeeding is associated with a more favorable metabolic risk profile in the postpartum period [32]. In contrast, the other US prospective study did not find any association between lactation duration and metabolic risk at 3 years postpartum after adjusting for pre-pregnancy BMI [33].

Hypertension.

Table 3 describes studies with hypertension as the outcome. Seven studies examined the association between breastfeeding and hypertension [7,8,2628,36,37]. Breastfeeding was associated with lower odds of hypertension in all four cross-sectional/retrospective studies [2628,36]. Both lactation history and duration were associated with reduced odds of hypertension in middle-aged and older Chinese mothers [27]. Similarly, in a large sample of Australian women aged ≥45 years, lactation history was protective compared to parous women who never breastfed or nulliparous women [28]. Lifetime lactation duration of >6 months, or >3 months/child, was significantly associated with lower odds of hypertension, in women aged 45–64 years compared with parous women who did not breastfeed. The odds of hypertension decreased with longer breastfeeding durations and were mostly not significant in women ≥64 years. In another cross-sectional/retrospective study from Norway, while there were no clear associations in mothers ≥50 years, mothers aged <50 years who had never lactated had higher odds of hypertension than those who had lactated ≥24 months in their lifetime [26]. In contrast, lifetime lactation duration was significantly associated with lower odds of hypertension in postmenopausal US women ≥50 years [36].

Breastfeeding also appeared to be protective in two large prospective studies [7,8]. In a US cohort of parous women, those who did not breastfeed were more likely to develop hypertension compared with those who breastfed their first child for ≥12 months or exclusively breastfed their first child for ≥6 months [7]. Lactation history, lifetime lactation duration between 1–18 months and average lactation duration between 1–9 months were also protective among a large cohort of premenopausal Korean women followed for six years [8]. In a large cluster RCT from Belarus, despite greater breastfeeding duration and exclusivity achieved among breastfeeding mothers randomized to a breastfeeding promotion intervention compared to usual care, there was no significant difference in blood pressure between mothers receiving the intervention and those allocated to the usual care group. However, this was not an RCT of breastfeeding per se but of factors aimed at promoting breastfeeding behaviour. In addition, a marginally significant association was found between lactation duration and lower blood pressure at 11.5 years postpartum in observational analyses in the same sample regardless of treatment allocation [37].

Inflammatory markers and adipokines.

Table 4 provides a summary of studies with inflammatory markers, adipokines and subclinical cardiovascular disease as the outcomes. Only two papers from the same sample were identified [33,34]. In one paper, two inflammatory markers: C-reactive protein (CRP), commonly associated with cardiovascular health outcomes [39], and interleukin-6, a proinflammatory cytokine that induces the hepatic production of CRP [40], were examined, but neither was significantly related to lactation duration at 3 years postpartum among 175 women with fasting blood samples after adjusting for pre-pregnancy BMI [33]. The other paper [34] examined adipokines, which are cytokines secreted by adipose tissue that are involved in inflammatory responses and associated with metabolic disease risk [41]. At 3 years postpartum, longer lactation duration was associated with higher levels of ghrelin and peptide YY, both involved in appetite regulation and associated with reduced risk of metabolic disease [34].

Subclinical cardiovascular disease.

Early physiologic changes in vascular health such as calcified atherosclerotic plaques and increases in carotid adventitial diameter can be detected and identify patients at increased risk of future cardiovascular events [4244]. Two cross-sectional/retrospective studies from the US assessed the relationship between breastfeeding and subclinical cardiovascular disease [29,30]. Both studies have found non-breastfeeding mothers to be at increased risk of vascular changes associated with subsequent cardiovascular disease. Among premenopausal women assessed 4 to 12 years after delivery, mothers who never breastfed had larger carotid artery lumen and adventitial diameters, which are indicative of poorer cardiovascular health status, compared with mothers who breastfed all of their children for at least 3 months [29]. In another study involving an older sample of women between 45 to 58 years of age, the association between lactation and an increased adventitial diameter was not significant after adjustment for confounders. However, aortic calcification remained significantly associated with lactation duration [30]. McClure et al. [29] suggest that differences in the significance of findings between breastfeeding and adventitial diameter could be due to the younger age group and shorter time since pregnancy in their study.

Cardiovascular disease.

Table 5 describes studies with cardiovascular disease as the outcome. A few studies investigated the relationship between breastfeeding and cardiovascular disease, and found protective effects of breastfeeding [13,36]. One US study examined both the self-reported prevalence and incidence (confirmed by physician adjudication of medical records) of cardiovascular disease in a large sample of parous, postmenopausal women [36]. In that study, increasing lifetime lactation duration was significantly associated with a lower prevalence of cardiovascular disease, compared with never breastfeeding. In particular, women who breastfed ≥13 months in their lifetime and women aged 50–59 years who had breastfed ≥7 months, were less likely to have prevalent cardiovascular disease. Although women aged 60–69 years with 13–23 months of lifetime lactation had lower odds of prevalent cardiovascular disease than similar-aged women who had never breastfed, there were no significant associations observed in women aged 70–79 years [36].

In that same study, lifetime lactation duration was not associated with incident cardiovascular disease in the overall sample followed for 7.9 years [36]. However, compared to similar-aged women who never breastfed, significant cardiovascular benefits were seen in women in the younger age group, but not in the older age groups. In another large US study involving middle-aged and elderly women, women with a lifetime lactation duration ≥12 months had a reduced risk of incident myocardial infarction (confirmed by physician review of medical records) compared with parous women who had never breastfed [13]. A stronger inverse association was observed for women with ≥23 months of lifetime lactation and for those with a birth in the last 30 years.

Two prospective studies assessed the association between breastfeeding and cardiovascular disease mortality ascertained from death registries [14,35]. Among a large sample of Chinese non-smoking textile workers followed between 1989 and 2000, lactation duration was not significantly associated with mortality from ischaemic or haemorrhagic stroke [35]. However, compared to parous women who never breastfed, women who breastfed appeared to have a lower risk of mortality from ischaemic heart disease. In another study from Norway, mothers aged <65 years that never breastfed had nearly three times the risk of death from cardiovascular disease over 15 years compared with mothers with a lifetime lactation duration ≥24 months [14]. There was evidence for a U-shaped association with women who breastfed 7–12 months having almost half the risk of women who breastfed ≥24 months in their lifetime. There were no significant associations in women 65 years and over.

Overall pattern of associations.

The pattern of associations across different outcomes is summarized in Table 6. Overall, 19 studies (10 cross-sectional/retrospective, 9 prospective) reported significant protective effects of breastfeeding, nine studies (3 cross-sectional/retrospective, 5 prospective, 1 cluster RCT) reported non-significant findings and none reported detrimental effects of breastfeeding. Ten out of thirteen associations reported in cross-sectional/retrospective studies suggested that breastfeeding was associated with significant cardiovascular benefits. Although the evidence was less convincing, nine out of fifteen associations reported in prospective studies also indicated beneficial effects of breastfeeding. Out of all cardiovascular risk factors and outcomes considered, the evidence for significant protective effects of breastfeeding was most convincing for hypertension, although the evidence was mainly based on cross-sectional/retrospective studies. Three-quarters of high quality studies [7, 12, 13, 14, 22, 26, 28, 29, 30, 32, 34, 36] and 80% of medium quality studies [8, 27, 31, 35] reported significant protective effects of breastfeeding.

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Table 6. Summary of expected direction of associationsa between breastfeeding and cardiovascular risk factors/outcomes.

https://doi.org/10.1371/journal.pone.0187923.t006

Discussion

This review synthesized the current evidence on the associations between breastfeeding and cardiovascular risk factors and outcomes, including MS, metabolic risk factors, hypertension, inflammatory markers, adipokines, subclinical cardiovascular disease and cardiovascular disease. Nearly all included studies were published in the last decade highlighting the rising interest in the maternal health benefits of breastfeeding. Overall, most studies reported significant protective effects of breastfeeding, several reported non-significant findings while there were no studies that reported detrimental effects of breastfeeding. The cardiovascular benefits of breastfeeding were present in most studies even after adjustment for multiple covariates, including socio-demographic, lifestyle factors (e.g. smoking, physical activity, dietary intake), BMI and parity. In addition, findings from included studies indicate that breastfeeding has favorable short-term and long-term cardiovascular health outcomes. Altogether, the evidence from medium-high quality studies suggests that breastfeeding is associated with several cardiovascular health benefits that can extend to later life, and supports health promotion strategies and interventions to increase breastfeeding. Notwithstanding, findings from this review should be interpreted with caution as the evidence gathered for each individual outcome is limited by the small number of observational studies. In particular, additional prospective studies of larger samples are needed.

Breastfeeding intensity and duration

For optimal child and maternal health benefits, the World Health Organization recommends exclusive breastfeeding for the first 6 months of life followed by two years or more of breastfeeding supplemented by complementary foods [45]. With the exception of four studies [7,33,34,37], most studies did not distinguish between exclusive breastfeeding, a measure of breastfeeding intensity, and breastfeeding supplemented by other foods. Several studies compared exclusive breastfeeding for ≥6 months with shorter durations of exclusive breastfeeding or non-exclusive breastfeeding, and found inconsistent associations with a range of cardiovascular outcomes [7,33,34,37]. Overall, additional studies that explore the association between exclusive breastfeeding and a range of short- and long-term cardiovascular health outcomes are needed.

Breastfeeding appears to be a protective factor for several maternal cardiovascular risk factors and outcomes, with evidence suggesting that increased duration may be associated with further benefits. Based on evidence from both cross-sectional/retrospective and prospective studies, benefits were reported for ≥24 months of lifetime lactation for most outcomes including metabolic risk factors [26,36], hypertension [28], the prevalence [36] and incidence of cardiovascular disease [13], and mortality from cardiovascular disease [14].

Dose-response

A dose-response relationship has been suggested between breastfeeding and various cardiovascular outcomes including MS, several metabolic risk factors, hypertension and the prevalence of cardiovascular disease. A cross-sectional/retrospective study among parous pre-menopausal women found a dose-response association between lifetime lactation duration and MS [22]. However, this relationship was modified by parity and protective effects of breastfeeding were no longer observed after four births. A prospective study also found dose-response effects of lifetime lactation duration up to >9 months on incident MS developed over a 20-year period [12]. In two large cross-sectional/retrospective studies involving parous women <50 years [26] and postmenopausal women [36], inverse dose-response associations were observed between lifetime lactation duration up to ≥24 months and several maternal cardiovascular risk factors including lipid levels [26,36], blood pressure [26,36], and the prevalence of cardiovascular disease [36].

Although findings from these studies suggest that there is a dose-response relationship between breastfeeding and metabolic risk factors, additional evidence is needed, particularly from longitudinal studies. The possibility of a U-shaped relationship between breastfeeding and cardiovascular mortality [14] should also be further investigated.

Short vs long-term outcomes

A previous systematic review has evaluated the relationship between breastfeeding and postpartum weight change and has found inconclusive evidence [17]. In our systematic review, lactation was associated with maternal improvements in metabolic risk factors from preconception to post-weaning in one prospective study [32] while no association was detected in another prospective study at 3 years postpartum [33]. However, an association between breastfeeding and adipokine levels at 3 years postpartum was reported in the latter cohort [34].

Meanwhile, evidence from cross-sectional/retrospective studies among middle-aged and older women suggests that breastfeeding may have protective effects in later life against hypertension [22,28], metabolic risk [26,36] and cardiovascular disease [36].

Findings from prospective studies suggest that breastfeeding may be protective against the incidence of: MS among young and middle-aged women followed for 9 [31] or 20 years [12], hypertension among young and middle-aged women after 6 years of follow-up [7,8], cardiovascular disease among middle-aged [13] and older women [36] followed between 8–12 years, mortality from ischaemic heart disease over a 10 year period [35] and mortality from cardiovascular disease in women of various ages followed for 15 years [14].

Age, time since last birth and menopause.

Findings from one cross-sectional/retrospective study [26] and a few prospective studies [14,28,36] suggest that the benefits from breastfeeding may diminish with age. In a large cross-sectional Norwegian study, significant associations between lifetime lactation duration and cardiovascular risk factors were observed in parous women <50 years. However, there were no clear associations in women >50 years [26]. Among three prospective studies, there were unclear associations with hypertension [28], the incidence of cardiovascular disease [36], or cardiovascular disease mortality [14] in women >60 [36] or >65 years of age [14,28]. Time since last birth may also have an effect on the association between breastfeeding and cardiovascular outcomes [13,26,36]. Among Norwegian mothers <50 years, the association between lifetime lactation duration and hypertension was attenuated after adjustment for time since last birth, while the association with metabolic risk factors remained similar [26]. In a large prospective cohort study, there was a stronger association between breastfeeding and incident myocardial infarction for women who gave birth in last the 30 years compared to women who had not [13]. Menopausal status may also influence the risk of cardiovascular disease. Among a large cohort of postmenopausal women, increasing lifetime lactation duration was associated with a lower prevalence of hypertension, diabetes, hyperlipidemia and cardiovascular disease [36]. There was also a significant association between breastfeeding and the incidence of cardiovascular disease among women between 50–59 years of age, but not among women >60 years [36]. Whether older age, increasing time since last birth and menopause attenuate the association between breastfeeding and cardiovascular risk factors and outcomes requires further investigation.

Potential mechanisms

Breastfeeding increases metabolic expenditure approximately by 480 calories/day [46]. Although the effects of breastfeeding on postpartum weight change remains inconclusive [15,17], breastfeeding may lower cardiovascular risk by mobilizing fat stores accumulated during pregnancy. Breastfeeding may also have favorable effects on glucose metabolism, glycemic control and lipid metabolism [26]. The “reset hypothesis” in which breastfeeding “resets” maternal metabolism after pregnancy by reversing visceral fat accumulation and increases in insulin resistance, lipid and triglyceride levels has been proposed [47]. Hormones associated with breastfeeding such as prolactin and oxytocin may also exert effects on maternal blood pressure [4850]. In addition, oxytocin may promote mother-child attachment and lead to reduced stress levels.

Methodological considerations

Several methodological issues should be considered in interpreting these findings. Observational studies are subject to residual confounding. Unmeasured confounders could include health-enhancing behaviors of breastfeeding mothers that distinguish them from non-breastfeeding mothers, and factors that influence breastfeeding initiation and duration such as pre-pregnancy BMI and pre-existing metabolic risk factors [5153]. Breastfeeding measures were self-reported and recall bias may have led to misclassification of a woman’s lactation history such as under- or over reporting of breastfeeding duration [54]. However, maternal recall of breastfeeding has been shown to be valid and reliable [55]. Differences in findings could be due to a number of factors that vary between studies including sample characteristics (e.g. country, setting), breastfeeding comparison categories, covariate adjustment and follow-up periods for prospective studies. Most included studies did not assess the exclusivity of breastfeeding, a measure of breastfeeding intensity. Temporal relationships could not be established from cross-sectional studies.

Strengths and limitations

The strengths of this review include systematic literature search, data extraction and summarization, an evaluation of the quality of included studies using established checklists, a range of maternal cardiovascular risk factors and outcomes examined, the inclusion of various breastfeeding comparison categories, the assessment of evidence relating to exclusive breastfeeding and dose-response relationship between breastfeeding and maternal outcomes, as well as a systematic and detailed approach in reporting findings. The limitations of this systematic review reflects limitations of the existing literature, such as a small number of prospective studies for each outcome of interest and methodological issues described above. Although the search terms used were comprehensive, there is a possibility that relevant studies were not identified by this systematic review.

Conclusion

Overall, the evidence from this systematic review suggests that breastfeeding is associated with maternal cardiovascular health benefits that extend from child-bearing years to later life. However, additional longitudinal research is needed to investigate the association between breastfeeding and specific cardiovascular risk factors and outcomes and to further inform the evidence base.

Supporting information

S1 Table. Search strategy used for MEDLINE, which was then adapted for EMBASE and CINAHL.

https://doi.org/10.1371/journal.pone.0187923.s002

(DOCX)

S2 Table. Quality assessment criteria adapted from a 15-item checklist used by Van Uffelen et al. [20].

https://doi.org/10.1371/journal.pone.0187923.s003

(DOCX)

S3 Table. Critical appraisal of included cross-sectional and prospective studies based on 15 quality assessment criteria.

https://doi.org/10.1371/journal.pone.0187923.s004

(DOCX)

S4 Table. Critical appraisal of single cluster randomized controlled trial [37] based on quality assessment checklist developed by the Cochrane collaboration for assessing risk of bias in randomized studies [21].

https://doi.org/10.1371/journal.pone.0187923.s005

(DOCX)

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