|Year : 2023 | Volume
| Issue : 1 | Page : 20-31
The effectiveness of prenatal care programs on reducing preterm birth in socioeconomically disadvantaged women: A systematic review and meta-analysis
Solmaz Mohammadi1, Kobra Shojaei2, Elham Maraghi3, Zahra Motaghi4
1 Student Research Committee, School of Nursing and Midwifery, Shahroud University of Medical Sciences, Shahroud, Iran
2 Department of Obstetrics and Gynecology, Fertility, Infertility and Perinatology Research Center, Ahvaz Jundishapur University of Medical Sciences, Ahvaz, Iran
3 Department of Biostatistics and Epidemiology, Faculty of Public Health, Ahvaz Jundishapur University of Medical Sciences, Ahvaz, Iran
4 Reproductive Health Department, School of Nursing and Midwifery, Shahroud University of Medical Sciences, Shahroud, Iran
|Date of Submission||20-Feb-2022|
|Date of Decision||06-Sep-2022|
|Date of Acceptance||21-Sep-2022|
|Date of Web Publication||27-Jan-2023|
Reproductive Health Department, School of Nursing and Midwifery, Shahroud University of Medical Sciences, Shahroud
Source of Support: None, Conflict of Interest: None
Background: Preterm Birth (PTB) is one of the leading causes of infant morbidity and mortality. Prenatal care is an effective way to improve pregnancy outcomes but there is limited evidence of effective interventions to improve perinatal outcomes in disadvantaged pregnant women. This review was conducted with the aim to assess the effectiveness of prenatal care programs in reducing PTB in socioeconomically disadvantaged women. Materials and Methods: We searched the Scopus, PubMed, Web of Science, and Cochrane Library databases from January 1, 1990 to August 31, 2021. The inclusion criteria included clinical trials and cohort studies focusing on prenatal care in deprived women with the primary outcome of PTB (< 37 weeks). Risk of bias was assessed using the Cochrane Collaboration's tool for assessing risk of bias and the Newcastle–Ottawa Scale. Heterogeneity was evaluated using the Q test and I2 statistics. The pooled odds ratio was calculated using random-effects models. Results: In total, 14 articles covering 22,526 women were included in the meta-analysis. Interventions/exposures included group prenatal care, home visits, psychosomatic programs, integrated intervention on socio-behavioral risk factors, and behavioral intervention through education, social support, joint management, and multidisciplinary care. The pooled results showed that all types of interventions/exposure were associated with a reduction in the risk of PTB [OR = 0.86; 95% confidence interval: (0.64, 1.16); I2 = 79.42%]. Conclusions: Alternative models of prenatal care reduce PTB in socioeconomically disadvantaged women compared with standard care. The limited number of studies may affect the power of this study.
Keywords: Meta-analysis, prenatal care, preterm birth, program evaluation, socioeconomic factors
|How to cite this article:|
Mohammadi S, Shojaei K, Maraghi E, Motaghi Z. The effectiveness of prenatal care programs on reducing preterm birth in socioeconomically disadvantaged women: A systematic review and meta-analysis. Iranian J Nursing Midwifery Res 2023;28:20-31
|How to cite this URL:|
Mohammadi S, Shojaei K, Maraghi E, Motaghi Z. The effectiveness of prenatal care programs on reducing preterm birth in socioeconomically disadvantaged women: A systematic review and meta-analysis. Iranian J Nursing Midwifery Res [serial online] 2023 [cited 2023 Mar 20];28:20-31. Available from: https://www.ijnmrjournal.net/text.asp?2023/28/1/20/368513
| Introduction|| |
Preterm Labor (PTL) is defined as regular uterine contractions and cervical changes that begin before 37 weeks of gestation. Almost 50% of PTL will lead to Preterm Birth (PTB). About 90% of PTB occurs in developing countries, 85% of which occurs in Africa and Asia. Moreover, 0.9 million cases of PTB are reported in Latin America. PTB is one of the leading causes of infant morbidity and mortality. PTB is related to a wide range of problems for the infant, including cerebral palsy, sensory impairment, learning disabilities, and respiratory illness. PTB imposes a significant burden on the healthcare system due to the longer and more intensive hospitalization of the infant. The cost of caring for these babies is significantly higher than that of caring for term babies. The costs and outcomes of infancy vary based on Gestational Age (GA). According to the evidence, a one- to two-week increase in GA can reduce neonatal complications and treatment, and care costs. PTB is also related to the inadequacy of maternal mental health, rise in average hospital stays, and re-hospitalization of the mother, and her care and treatment costs, which are not considered in the study of the burden of PTB. PTB is a multifactorial complication in the development of which a combination of individual-behavioral and psychological, environmental, genetic, and biological factors play a role. There is a high prevalence of perinatal poor outcomes and death among low-income women, homeless individuals, prisoners, asylum seekers, refugees, and ethnic minorities, known as vulnerable clusters. The results of a meta-analysis in the UK showed that regional and individual deprivation are associated with neonatal complications (birth weight and neonatal death). Although prenatal care is an effective way to improve pregnancy results, care interventions during this period have not been completely evaluated, and there is limited evidence of effective interventions in improving perinatal outcomes for vulnerable pregnant women. The National Health Service Clinical (NICE) Guidelines in the UK identified gaps in evidence of effective prenatal care services for women with complex social conditions and called for a reorganization of services to improve care.
Due to the absence of sufficient evidence on the effectiveness of prenatal care programs in improving pregnancy outcomes in deprived women, this study was conducted with the aim to find the best available evidence on the effectiveness of prenatal care interventions in reducing PTB among women deprived of socioeconomic status.
| Materials and Methods|| |
The present study was part of a multistage mixed-method study that investigated perinatal care programs for women with high-risk pregnancies in Iran, which was conducted based on the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) statement. Based on the standard defined in the Cochrane Handbook for Systematic Reviews of Interventions, the two researchers separately performed a comprehensive search in four major databases including PubMed, Scopus, Web of Science, and the Cochrane Library. To search the texts, keywords were determined. The keywords were obtained by searching for related articles, asking questions from experts, and referring to the MeSH search on PubMed. Then, the search strategy was determined based on the keywords [Table 1]. Determinants of socioeconomic status (education, occupation, income, and residence type) were used to identify low-income pregnant women. The socioeconomic disadvantage was defined by the study authors. We utilized a search strategy that combined keywords related to the outcomes, intervention/exposure, and populations of interest. To review the gray literature, a search was conducted in the gray literature section of the Web of Science database. Moreover, to enter as much relevant data as possible, after the initial evaluation of the abstract, the references to the found articles were examined. All databases were reviewed from January 1, 1990, to August 31, 2021.
The studies were qualified if they met the subsequent criteria: (i) Population: Poor pregnant women (socioeconomically disadvantaged) and living in deprived areas; (ii) Intervention/exposure: Non-pharmacological interventions (including providing any health services, social and clinical care, and educational interventions as a complement to routine prenatal care); (iii) Control group: Standard or routine care; (iv) Primary outcome: PTB (<37 weeks gestation); (v) Secondary Outcomes: Low-birth weight (LBW: Weight <2500 grams), Apgar <7 in the first and fifth minute, hospitalization in NICU, premature neonatal death (<28 days), instrumental delivery, and cesarean section; (vi) Study design: Clinical trial and cohort with at least one comparison group; (vii) Language: English language articles. The exclusion criteria included inaccessibility to the full text of the article, protocol articles, guideline reports, and interventions focusing on labor/birth or the preconception period.
All retrieved articles were entered into Endnote X8 via electronic databases and a manual search. After removing duplicate studies, the two researchers separately reviewed the titles and abstracts of possibly eligible articles based on the prescribed inclusion criteria. To extract data, including the name of the first author, year, country, target group, type of intervention, sample size, desired outcome, and the conclusion, an electronic form was used. Data extraction was performed independently by two researchers. Any disagreements in the choice of articles and data extraction were resolved by the third researcher.
Risk of bias in the clinical trials was evaluated using the Cochrane Collaboration's tool for assessing risk of bias and the inclusion criteria which included random sequence generation, allocation concealment, blinding of participants and personnel, blinding of outcome assessment, incomplete outcome data, selective reporting, and other bias. Each item was evaluated as low-risk, unclear-risk, or high-risk. To appraise the selection bias, the primary and secondary outcomes (or main objective of the study) reported in the protocol (if any) were compared with the final reported results of each study.
One of the most commonly used scales for appraising quality and the risk of bias in observational studies is the Newcastle-Ottawa Scale (NOS). This scale includes three domains, including selecting study groups (4 stars), comparing groups (2 stars), and determining the amount of exposure and results (3 stars). The maximum score for these three dimensions is 9 points. The total scores were classified into the three following groups: very high risk of bias (0 to 3 stars), high risk of bias (4 to 6 stars), and low risk of bias (7 to 9 stars).
Statistical calculations were performed using Stata software (version 16; StataCorp, College Station, TX, USA). In the analysis of the effect of group prenatal care on PTB compared to conventional care, the odds ratio (OR) index was used. The OR logarithm was used in each study to combine the results of the studies. Heterogeneity between studies was determined using Cochran's test and the I2 index. Heterogeneity was considered significant if I2 >50%.
The OR was measured from the crude data of each study with a 95% Confidence Interval (CI). Data from the single studies were pooled using the random-effects models, regardless of whether there was evidence of statistical heterogeneity or not. This approach also leads to a more conservative estimate of the effect size. All p values <0.05 were regarded as significant.
To conduct the research, written permission was obtained from the ethics committee of Shahroud University of Medical Sciences, Shahroud, Iran (Approval ID: IR.SHMU.REC.1399.123).
| Results|| |
The results of this research included 16 articles on 23619 women with socioeconomic deprivation [Table 1]. Studies were omitted for various reasons, including lack of perinatal outcomes, intervention before pregnancy, during labor, drug interventions, lack of a control group, type of study (descriptive-analytical and review), etc., [Figure 1].
|Figure 1: The PRISMA flow diagram of studies included and excluded in each review. PRISMA: Preferred Reporting Items for Systematic Reviews and Meta-Analyses; RCT: Randomized controlled trials|
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Finally, 16 studies were included in the systematic review, including 7 cohort studies (retrospective, prospective, and combined) and 9 Randomized Controlled Trials (RCTs) [Table 2]. In total, 14 studies involving 22,526 participants entered the meta-analysis section. Of the studies included, 11 were performed in the United States, 2 in Australia, 1 in Ireland, and 1 in South Africa, and 1 multicenter study was conducted in France and Spain. Moreover, 1 study was of low quality, 8 studies were of medium quality, and 8 studies were of high quality [Table 3] and [Table 4]. The control group was standard or routine in all care studies. The interventions/exposures include group prenatal care (4 cohort studies and 1 RCT), midwifery group practice (1 cohort study), a home visit (3 RCTs), psychosomatic program (1 RCT), integrated intervention on socio-behavioral risk factors (1 RCT), behavioral intervention care through education (1 RCT), social support program (2 RCTs), joint management (1 cohort study), and multidisciplinary care (1 cohort study) [Table 1].
|Table 2: Characteristics of each study and effectiveness of antenatal care programs|
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|Table 3: Risk of bias assessment in randomized controlled trials based on the Cochrane guidelines*|
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|Table 4: Risk of bias assessment of the cohort studies included based on the Newcastle-Ottawa Scale (NOS)|
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Random effects meta-analysis showed that all types of interventions/exposures were associated with a reduction in risk of PTB [OR = 0.86; 95%CI: (0.64, 1.16); I2 = 79.42%] [Figure 2].
|Figure 2: Forest plot of effects of interventions versus standard care on preterm birth|
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Group prenatal care
The three cohort studies by Picklesimer et al., Jacobs, Gareau et al., and a clinical trial by Ickovics et al. regarding the evaluation of the effectiveness of group prenatal care in low-income pregnant women showed that this intervention was effective in decreasing preterm delivery (P = 0.050). Nevertheless, the cohort study by Ickovics et al. showed that the intervention failed in clinics that served low-income women, especially minority women, because of the potential risk of selection bias.
The cohort studies by Gareau et al. and Ickovics et al. showed that LBW in the prenatal care group was lower than standard care, while in the clinical trial by Ickovic et al. no such result was observed.
The cohort study by Gareau et al. indicated that group prenatal intervention would reduce admissions to the NICU, while the cohort study by Picklesimer et al. and the clinical trial by Ickovics et al. did not reach such a conclusion.
Midwifery group practice
Gao et al., in their cohort studies, found that group midwifery care was ineffective in reducing PTB (18.5% v 20.6%; p = 0.400), LBW (6.4% v 9.9%; p = 0.625), and cesarean section rates (p = 0.466) in pregnant women native to remote areas of Australia.
Doyle et al., in their clinical trial, found that home care by skilled educators did not lead to a difference in neonatal outcomes, including preterm delivery (7.5% vs. 7.3%; OR = 1.01; 95% CI: 0.35 to 2.91, p = 0.490), birth weight (3302 ± 631 vs. 3268 ± 617 grams (g); p = 0.305), and caesarean section (25.0% vs. 15.1%; OR = 0.53, 95% CI: 0.27 to 1.07; p < 0.05) among unemployed pregnant women living in Dublin, Ireland, is above usual and does not lead to early school dropout.
Kemp et al. found that despite the home nurse visit program was associated with increased duration of breastfeeding, maternal satisfaction, and mental development of children in pregnant women in disadvantaged areas of Sydney, it had no effect on PTB (OR = 1.96; 95% CI: 0.60 to 4.74) and LBW (OR = 3.22; 95% CI: 0.65 to 15.9). In this study, in addition to living in deprived areas, other socio-behavioral and psychological risk factors, such as being under 19 years of age, an Edinburgh Postnatal Depression Scale score of above 10, lack of social support, lack of psychological and practical support, initiation of prenatal care later than 20 weeks, present substance abuse, a history of domestic violence in the mother, and a history of child abuse in the mother's childhood, were found to affect the efficiency of the intervention.
Kitzman et al. also showed that home nurse visits were ineffective in reducing PTB (OR = 0.8; 95% CI: 0.60 to 1.20) and LBW (OR = 1.10, 95% CI: 0.80 to 1.60 (in low-income and single, pregnant women in Tennessee, Memphis.
In a clinical study, Collado et al. documented that a new care program based on Thorne's psychosomatic approach (focusing on emotions, body awareness, building a personal delivery model, and attachment) was effective in reducing PTB (4% vs. 22.4%; p = 0.003) and LBW (3019,01 ± 668,83 g; p = 0.010) among low-income pregnant women before 20 weeks of gestation and at moderate to high risk of postpartum depression.
The behavioral intervention focused on education
The Collaborative Pregnancy Prevention Group (1997), in its multicenter clinical trial in a low-income population, studied behavior-care intervention with a focus on educating the patient about the symptoms of PTL with additional visits. Due to the significant heterogeneity of the effects of the program in different centers, this intervention cannot be recommended for the prevention of preterm delivery (15.4% vs. 11.9%).
Integrated intervention on socio-behavioral risk factors
Subramanian et al. in their study showed that an integrated intervention on socio-behavioral risk factors (including a behavior change meta-theoretical model and self-help guide to quit smoking + group therapy, cognitive-behavioral therapy to treat depression + a visit program at home + individual counseling sessions) is not effective in reducing adverse pregnancy and fetal outcomes such as preterm delivery (14.5% vs. 15%), LBW (12.8% vs. 14.6%), cesarean section (28.7% vs. 28.1%), and hospitalization (12.2% vs. 15.5%) in the NICU. This study illustrates that the biomedical aspect plays a greater role in causing negative outcomes in low-income pregnant women than the psychosocial aspect. Thus, early diagnosis and management of previous hypertension, diabetes, and PTB in low-income women may reduce health disparities in birth outcomes.
Rothberg and Lits reported that psychosocial support programs (telephone support + home visits by a social worker or professional nurse) were ineffective in reducing PTL (10.8% vs. 20.5%; p = 0.200).
The clinical trial by Moore et al. also showed no significant beneficial effect on preterm delivery but indicated a more beneficial effect in a subgroup of 19-year-old black women (RR = 0.56; 95% CI (0.38-0.84); p = 0.004). As it is not clear whether the subgroup analysis was pre-defined based on age and ethnic group, the subgroup analysis was considered unlikely.
Rothberg and Lits reported a reduction in LBW, especially in African-American women, as a result of a social support program, but Moore et al. reported no differences in LBW between the intervention group (telephone support by a nurse) and the control group (usual care).
Comprehensive multidisciplinary care
Reece et al. evaluated comprehensive multidisciplinary care, which included psychosocial counseling and care, nutritional counseling, health education, social, and medical services, contact with community-based organizations, and follow-up of missed visits. They reported it to be effective in reducing PTB (4.2% vs. 12%; p < 0.005) and LBW (5.2% vs. 11%; p < 0.05). Despite its methodological limitations, this intervention can be considered as promising.
Jackson et al. compared nurse-midwife joint care registered with a gynecologist at a birth center to traditional physician-based care. Although it is associated with more spontaneous vaginal examinations (MD = 14.9; 95% CI: 11.5 to 18.3), it does not cause a difference in PTB (MD = 0.2; 95% CI: –1.7 to 2.1) and LBW (MD = 0.5; 95% CI:–1.7 to 2.70).
| Discussion|| |
The objective of this study was to assess the efficiency of interventions focused on prenatal care to diminish preterm delivery in socioeconomically disadvantaged women. We found that interventions were associated with lower rates of PTB. Of the studies included in this systematic review, 11 were conducted in the United States. Although adverse outcomes of pregnancy and birth due to socioeconomic inequalities exist around the world, Western countries such as the United States and the United Kingdom (UK) are showing a growing rate of adverse outcomes in women and children with poorer socioeconomic backgrounds. This inequality has a mostly ethnic foundation in the United States and a “social class” foundation in the UK. Therefore, interventions to address this disparity have recently become an eminent feature of health systems in the United States and UK, and researchers recommend the assessment and comparison of the various models of health care in this regard.
Research has also shown more obstetric interventions such as induction of labor, instrumental delivery, epidural anesthesia, and cesarean section in socially disadvantaged women in high-income countries, which are associated with poor pregnancy outcomes. Of the 16 studies included in this systematic review, 1 study had poor internal validity and the rest had acceptable internal validity (good and moderate). There was a wide range of variation in the types of interventions evaluated in the studies. Some studies did not target a decrease in preterm delivery, but indicated it as a consequence. The question, therefore, arises as to whether these studies were robust enough to identify differences in the resulting improvement, including decreased preterm delivery. The follow-up periods of the studies were also considerably different. Despite numerous risk factors for participants in some studies, data analysis was not performed by adjusting the effect of confounders. Our findings show that one type of intervention is unlikely to be significantly superior to another, but a combination of interventions may have a better effect. However, some interventions were effective. Among the interventions evaluated in this study, group prenatal care was effective in reducing preterm delivery. Nevertheless, due to the limited number of studies, quality of evidence, small sample size in some primary studies, and variability in the number of sessions, duration of each session, and follow-up time, these results should be interpreted with caution. The results of a meta-analysis also indicated that group prenatal care (compared to standard care) was not related to a reduced rate of preterm delivery and hospitalization in the NICU, or beginning of breastfeeding overall, or with the type of study (subgroup analysis). Nevertheless, subgroup analysis of this study shows that group prenatal care in low-income women of color is related to a decrease of 3 PTBs per 100 live births. This is a potentially significant result because the rate of PTB in African American women is approximately twice as high as in white women, even after controlling for factors such as socioeconomic status. One feasible interpretation of improved outcomes in African-American women is the provision of social support, coping strategies, and tension reduction via group prenatal care.
As suggested in a systematic review that assessed group prenatal care in women with high-risk pregnancies with behavior-social and biomedical risk factors, further high-quality, well-controlled studies are needed to confirm the effectiveness of group prenatal care in improving the outcomes and costs of pregnancy-related care. Consistent with previous reviews,,, studies with adequate internal validity, the present review has shown that prenatal visits at home do not reduce PTB. The number of home visits (average: 5 times), home visits by an expert compared to an unprofessional, and the characteristics of the participants may be effective in improving pregnancy outcomes. Developing a standard home visit plan for a specific cultural environment with specific characteristics (start time, frequency, intensity, and content) remains a critical issue for healthcare providers. In addition, home visits can be implemented via a mixture of in-situ handbooks and mobile information technology (such as distance nursing).
In this study, social support for women with socioeconomic deprivation reduced PTB. The results of a systematic review and meta-analysis also showed that programs that provide additional social support during pregnancy are unlikely to have a significant impact on the proportion of LBW, PTB, stillbirths, or neonatal death. The results of another systematic review showed that continued midwife-led support for women with mixed levels of risk during pregnancy and childbirth is associated with a reduction in PTB (RR = 0.76; 95% CI: 0.64 to 0.91), but has no impact on LBW (RR = 0.96; 95% CI: 0.82 to 1.13).
Although this study has provided us with the key knowledge that there is some existing evidence of the effectiveness of alternative models of prenatal care in reducing PTB in socioeconomically disadvantaged women compared with standard care, it has also helped to identify that this is an area where further research is needed. However, the limited number of studies and the quality of the evidence may affect the power of this study, so interpretation of the results should be done with caution.
| Conclusion|| |
A random-effects meta-analysis showed that all types of interventions were associated with a reduction in the risk of PTB. Given the limited number of studies and the quality of the evidence, these findings need to be interpreted with great caution. Randomized trials are needed to obtain more conclusive evidence about how to reduce preterm delivery and negative perinatal outcomes.
The current study was approved by Shahroud University of Medical Sciences, Shahroud, Iran, as a Ph.D. thesis. The authors would like to convey their gratitude to the Research Surrogate of Shahroud University of Medical Sciences (code: 860).
Financial support and sponsorship
Shahroud University of Medical Sciences
Conflicts of interest
Nothing to declare.
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[Figure 1], [Figure 2]
[Table 1], [Table 2], [Table 3], [Table 4]