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Explaining the impact of mHealth on maternal and child health care in low- and middle-income countries: a realist synthesis

Abstract

Background

Despite the growing global application of mobile health (mHealth) technology in maternal and child health, contextual factors, and mechanisms by which interventional outcomes are generated, have not been subjected to a systematic examination. In this study, we sought to uncover context, mechanisms, and outcome elements of various mHealth interventions based on implementation and evaluation studies to formulate theories or models explicating how mHealth interventions work (or not) both for health care providers and for pregnant women and mothers.

Method

We undertook a realist synthesis. An electronic search of five online databases (PubMed/Medline, Google Scholar, Scopus, Academic Search Premier and Health Systems Evidence) was performed. Using appropriate Boolean phrases terms and selection procedures, 32 articles were identified. A theory-driven approach, narrative synthesis, was applied to synthesize the data. Thematic content analysis was used to delineate elements of the intervention, including its context, actors, mechanisms, and outcomes. Abduction and retroduction were applied using a realist evaluation heuristic tool to formulate generative theories.

Results

We formulated two configurational models illustrating how and why mHealth impacts implementation and uptake of maternal and child health care. Implementation-related mechanisms include buy-in from health care providers, perceived support of health care providers’ motivation and perceived ease of use and usefulness. These mechanisms are influenced by adaptive health system conditions including organization, resource availability, policy implementation dynamics, experience with technology, network infrastructure and connectivity. For pregnant women and mothers, mechanisms that trigger mHealth use and consequently uptake of maternal and child health care include perceived satisfaction, motivation and positive psychological support. Information overload was identified as a potential negative mechanism impacting the uptake of maternal and child health care. These mechanisms are influenced by health system conditions, socio-cultural characteristics, socio-economic and demographics characteristics, network infrastructure and connectivity and awareness.

Conclusion

Models developed in this study provide a detailed understanding of implementation and uptake of mHealth interventions and how and why they impact maternal and child health care in low- and middle-income countries. These models provide a foundation for the ‘white box’ of theory-driven evaluation of mHealth interventions and can improve rollout and implementation where required.

Peer Review reports

Background

The potential for mobile health (mHealth) to enhance healthcare utilization, promote affordability and support accountability of health care in low-and middle-income countries (LMICs) is supported by the near-universal availability of mobile phones with increasing coverage in many LMICs [1, 2]. mHealth is described as an element of electronic health used for the provision of healthcare services using information and communication technology [3]. mHealth offers a personalized and interactive tool aimed at promoting healthcare access and awareness [4, 5]. mHealth also has the potential to strengthen public sector care for optimal management of chronic conditions and improvement of maternal and child health (MCH) care [6,7,8]. In addition to promoting health education among patients and reducing waiting times and costs of healthcare, mHealth enhances patient support, providing a system for emergency response and monitoring [7].

Potential challenges faced by mHealth interventions have been highlighted in previous studies [9, 10]. One-way mobile phone messaging is the most common type of mHealth communication used in LMICs [9]. A limitation of this approach, however, is that patients only receive messages and cannot interact with health care providers (HCPs) in real-time. Factors influencing mHealth interventions at individual level include users’ intentions, skills, attitudes, perceived norms, self-efficacy, literacy levels and proficiency in the use of mobile devices such as smartphones [9, 10]. Systems-related factors affecting the use of mHealth interventions include unsuitable implementation context, poor internet infrastructure, unreliable power supplies and frequent power outages.

Systematic reviews support the value of mHealth applications as an effective tool to improve MCH related outcomes, suggesting that it can be a key step towards achieving the Sustainable Development Goals (SDGs), in particular SDG 3 [8, 11] mHealth has shown to facilitate utilization of MCH services, increase clinic attendance and promote health-seeking behavior [12]. mHealth also supports regular immunization and exclusive breastfeeding by targeting behavioral change [8, 13].

Hackett et al., established that mHealth is significantly associated with MCH outcomes [14, 15]. While outcomes-based evaluation of mHealth interventions can offer insight into their performance, replicating findings across socio-demographic and geographical boundaries becomes challenging because mHealth interventions take on different forms. Having a functional understanding of how and why these interventions work (or not) can offer better implementation prospects. We sought to respond to this need by exploring and conceptualizing contextual elements and mechanisms that interact to explain observed effects of mHealth interventions on the uptake of MCH care in LMICs. We aimed to formulate models explicating how mHealth interventions work for HCPs and pregnant women and mothers by uncovering context, mechanisms and outcome elements in implementation and evaluation studies of mHealth interventions in MCH care in LMICs [3].

Material and methods

Our study was informed by the critical realist understanding of generative causality as conceptualized by Pawson and Tilley [16]. To address the question: ‘What works, for whom, why, in what situation, and how?’ with regards to intervention, programs and policies. They proposed the formula Context (C) + Mechanism (M) (resource + reasoning) = Outcome (O) to express the relationship between context, mechanism and outcomes to explicate how interventions lead to behavior change or sustenance. According to this formula, O is a product of M in a specific C [16], and theories or models can be formulated, tested, confirmed and modified using a context-mechanism-outcome configuration (CMOc) [17]. Some implementation scientists have suggested modifications of the CMOc heuristic to improve its explanatory power [18, 19]. Marchal et al. [20] and Mukumbang et al. [21] proposed adding “intervention” (I) modalities and relevant “actors” (A) to the CMO configuration based on the fact that interventions (I) can only work when adopted by actors (A). Based on this modification, generative understanding postulates that “outcome (O) is produced by mechanism (M) activated in context (C) through actors (A) when interventions (I) are executed” [3, 22]. Models developed in this study were achieved by formulating Intervention-Context-Actors-Mechanism-Outcome (ICAMO) configurations (Table 1).

Table 1 Definition of the concepts in the ICAMO heuristic

Figure 1 shows a tentative conceptual model developed a priori based on existing literature on mHealth and MCH. This was achieved through abductive thinking – the inventive thinking required to imagine the existence of such mechanisms to ‘suggest’ the most likely possible explanation. The model suggests that when HCPs (A) are educated on mHealth interventions and trained on how to use programme resources (I), their perceived support will motivate (M), encourage (M) and improve their self-efficacy (M), in turn improving MCH care (O). Regarding to program users, the framework proposes that health educational and reminder messages of MCH (I) will sensitize, motivate (M) and encourage (M) pregnant women and mothers (A) to routinely use MCH care, such as emergency obstetric care, facility births (O) and early initiation of antiretroviral therapy for HIV positive women (O). We adopted a realist synthesis approach based on Pawson’s practical steps for conducting realist reviews [25], which include five stages, now addressed subsequently.

Fig. 1
figure 1

Tentative program theory of mHealth programs

Stage 1: clarifying the scope of the review

The purpose of the review is to determine how, why, for whom and under which conditions mHealth supports MCH care in LMICs. Initial scanning of the literature and expertise of the research team helped to define the research questions: 1) What mechanisms and contextual factors lead to the implementation and uptake of MCH care? 2) How do those mechanisms and contextual factors interact to explain implementation and uptake of MCH care?

Stage 2: searching for relevant evidence

Five electronic databases (PubMed/Medline, Google Scholar, Scopus, Academic Search Premier and Health Systems Evidence) were searched for articles published between June 2008 and December 2018 using the following Boolean combinations: [“mHealth” AND “maternal health”], [“mobile phone” AND “maternal health” AND “child health”], [“mHealth AND “maternal health services”], [mHealth PRE/15 maternal] and [mHealth PRE/15 maternal AND child AND health]. A total of 813 records were identified.

Inclusion criteria were: peer-reviewed articles, published in English, published between January 2008 and June 2018 studies conducted in LMICs; studies targeting pregnant women, mothers with new babies and HCPs, including community health workers (CHWs). We considered cross-sectional, cohort, case-control and experimental studies, as well as randomized control trials.

Non-full text papers, technical reports, special reports, brief communications, presentation of scenarios or training workshops, editorial comments, non mHealth applications, telemedicine and other eHealth programme applications were excluded. Studies published before January 2008 were excluded as mHealth interventions were not common before that time.

Stage 3: study selection and appraising quality of evidence

From 813 records in the database searches, 747 duplicates and non-relevant titles and abstracts were removed. Of the remaining 66 articles, 14 systematic reviews were also excluded. Fifty-two (n = 52) full-text articles were screened for potential inclusion and twenty (n = 20) were excluded for various reasons, yielding 32 articles (Fig. 2).

Fig. 2
figure 2

PRISMA diagram illustrating the study selection process

Quality assessment was performed for each article using a research evidence appraisal tool [26] (Supplementary File 1). Eight of the 32 articles were of high quality and 24 were classified as having good or moderate quality. Results from these studies could thus provide relevant and credible information towards challenging or enhancing the initial theory.

Stage 4: extracting the data

Data were extracted and organized through a process of note-taking, annotation and conceptualization using the following headings: name of authors, year of publication and study setting or country; summary of the study aim; intervention, context, actors, mechanisms, and outcomes (Supplementary File 2).

Stage 5: synthesizing evidence and concluding a process of reasoning

The narrative synthesis (NS) approach informed the process of collating, summarizing and reporting the results [27]. NS proposes a theory-driven approach to data synthesis and is compatible with the philosophical assumptions guiding theory formulation in realist evaluation [28]. NS relies on application of various methods of inference making through the use of words and text [27]. To this end, NS is applied in reviews addressing several questions with research evidence in the context of studies that strive to inform policy and practice [27]. Four interrelated steps are involved in NS: (i) Theory development of how interventions work: (ii) development of a preliminary synthesis of results; (iii) exploring associations in the data; and, (iv) assessment of the rigor of the synthesis.

Step 1. Theory development of how interventions work

According to Arial et al. [29], a thinking framework herein referred to as initial programme theory, is required as a first step to continuously test and revise our understanding of how mHealth interventions could improve MCH outcomes [30]. This initial program theory – an assumption of how the program should work – guides the process of operationalizing mechanisms into theories or models at the end of synthesis (see Fig. 1).

Step 2. Development of preliminary synthesis of results

We applied a deductive thematic analysis to extract data [31, 32] based on the concepts outlined in the ICAMO heuristic tool [33] and used an inductive approach to code constructs within each concept (Supplementary File 2). We identified relevant aspects of interventions (I), context factors (C), mechanisms (M) and outcomes (O) related to delivery of mHealth programs for CHWs and HCPs, and pregnant women and mothers.

Step 3. Exploring associations in the data

The realist evaluation approach [17, 34] informed the process of constructing the explanatory model. Three different methods were employed to establish associations of the extracted ICAMO themes: retroductive inferencing, counterfactual thinking and configuration mapping. We applied retroductive inferencing to explore the relationship between the themes of the ICAMO heuristic tool. Retroductive inferencing is a mechanism-focused analytical approach used to reconstruct the basic conditions of phenomena, based on available data (abductive reasoning). Counterfactual thinking was applied to argue towards transfactual conditions – the existence of powers, potentials and liabilities which cause the outcomes [31]. We then mapped possible explanations based on the data through the process of configurational mapping – a process of organizing and representing knowledge by linking and specifying relationships between variables.

Step 4. Assessment of the rigor of the synthesis

To assess robustness, we applied transparency, accuracy, purposively, utility, propriety, accessibility, and specificity (TAPUPAS) criteria (Table 2), an appraisal tool developed by Pawson et al. [35] to appraise the articles for relevance and to add more strength to the appraisal tool to assess the quality of the study (Supplementary File 1). Two study authors (EMK and FCM) applied judgmental rationality – the ability to evaluate different positions as being better or worse – to map ICAMO elements using Vensim® software [36] . This was achieved through discursive and iterative consultation among the researchers until consensus was reached.

Table 2 TAPUPAS criteria

Results

Thirty-two (32) studies from different geographic areas were identified: sub-Sahara Africa (21), Asia Pacific (10) and Latin America (1) (Supplementary File 2). Following the initial program theory (Fig. 1), findings are presented for HCPs and pregnant women and mothers. Out of the 32 studies, 20 contributed to the development of a model for HCPs, while 29 contributed to the model for pregnant women and mothers. We used Supplementary File 2 to extract data from the selected articles and the thematic analysis of the data are presented in Tables 3 and 4.

Table 3 Thematic representation of ICAMO element of HCPs
Table 4 Thematic representation of the ICAMO element of pregnant women and mothers

For more details on thematic analysis (Supplementary File 2, Tables 3 and 4).

Implementation of mHealth by CHWs and HCPs

Table 3 presents the themes used to map the HCPs ICAMO (Fig. 3), which shows an explanatory model of how and why HCPs implement mHealth interventions (or not).

Fig. 3
figure 3

Configuration model on how and why mHealth works for HCPs

The first aspect of mHealth interventions is that it offers ‘communication platform’ (I) [37,38,39,40,41,42, 45, 54]. This is influenced by ‘health system organization’(C) [5, 37, 45], their ‘experience with technology’(C) [37, 41], HCPs’ socio-demographic characteristics (C) [54] and availability of internet infrastructure (C) [50]. Having a functional ‘communication platform’ motivates (M+) [38] HCPs to ‘improve their performance of health care’ (O+) [38, 50], which increases the quality of MCH care (O+) [38]. Also, the communication platform improves ‘perceived ease of use and usefulness of mHealth’(M+) [46, 47], which also improves their performance of health care (O+) [47].

The second relevant aspect of mHealth interventions relates to their ability to offer a ‘data management platform’ (I) [14, 45, 46, 48, 51]. The importance of data management platform is influenced by health system organization (C) [14, 45] and experience with technology (C) [41]. Having a functional data management platform improves perceived support of HCPs (M+) [51], resulting in improved HCPs’ performance of health care (O+) [51]. Also, the data management platform facilitates the perceived ease of use and usefulness of mHealth (M+) [46, 47], leading to improved HCPs’ performance of health care (O+) [46, 47].

Another important aspect of mHealth interventions for /HCPs is that these offer an environment of ‘decision-making support and guidelines’ (I) [50,51,52,53]. Decision-making support and guidelines are influenced by ‘health system organization’(C) [50, 52] socio-demographic characteristics (C), and ‘availability of internet infrastructure’(C) [50]. Having decision-making support systems and guidelines motivate HCPs (M+) [50, 53], thus improving performance of health care (O+) [50, 53] and quality of MCH care (O+) [53]. Finally, decision-making support and guidelines improve perceived support (M+) [51] and result in improved performance [51] and hence the quality of MCH care (O+).

Uptake and outcomes of mHealth for pregnant women and mothers

Table 4 presents relevant themes used to develop the ICAMO model for pregnant women and mothers while Fig. 4 presents a model illustrating how and why various aspects of mHealth interventions work for pregnant women and mothers.

Fig. 4
figure 4

Configuration model of how and why mHealth works for pregnant women and mothers

The first important aspect of the uptake of mHealth interventions by pregnant women and mothers is the reminder messages system (I) [37, 50, 52, 55,56,57,58,59,60]. This aspect is influenced by socioeconomic and demographics characteristics (C) [37, 50, 52, 55,56,57, 59]; health system and political clout [37], and technical aspects of mobile phone services (C) [50, 55, 56, 58]. Having reminder message systems improve ‘positive psychological support’(M+) [37, 50, 52, 58,59,60] and ‘perceived satisfaction of care’ (M+) [56, 60], resulting in improved health-seeking behavior (O+) [37, 50, 52].

mHealth interventions also provide a communication platform (I) for pregnant women and mothers [5, 14, 15, 38, 42, 43, 45, 46, 49, 50, 59, 61,62,63,64,65], which is influenced by socio-cultural practices and norms (C) [14, 64], socio-economic and demographics characteristics (C) [14, 15, 42, 46, 50, 59, 62, 64, 65], health system and political clout (C) [5, 38, 43, 45, 49, 61, 63] and technical aspects of mobile phone services (C) [15, 61, 63]. The communication platform improves ‘positive psychological support’(M+) [14, 38, 42, 43, 45, 46, 50, 59, 61, 64, 65], thereby improving health-seeking behavior (O+) [14, 42, 45, 59, 61]. For instance, when users are educated about MCH care, their capabilities to make healthy choices are enhanced, which motivates them to seek medical care on time [64]. Nevertheless, perceived information overload (M-) can result in decreased visits to health facilities based on desensitization, as pregnant women and mothers who have access to more information online and on their mobile phone may become complacent with using health facilities (O-) [15].

mHealth interventions also offer a ‘consultation platform with HCPs (I) [39, 48, 51], which is influenced by socio-cultural practices (C) [51], health system and political clout [39, 48], and technical aspects of mobile phone services (C) [39]. The consultation platform improves perceived satisfaction of care (M+) [14, 48] and health-seeking behavior (O+) [39, 51].

We combined the tentative programme theory (Fig. 1), the HCPs model (Fig. 3), and the pregnant women and mothers model (Fig. 4) to create a mHealth program theory (Fig. 5), which portrays how adoption of mHealth programs by HCPs and pregnant women and mothers’ influences performance and quality of health care among HCPs and health-seeking behaviors among pregnant women and mothers. We identified that performance and quality of service by HCPs (O+) were influenced by four different mechanisms: (1) Buy-in from HCPs (M+), explaining that HCPs’ engagement with mHealth impacted their performance. (2) Perceived support of HCPs, which shows how the perceived support of HCPs such as quality of training, resources, and administrative support help HCPs to perform their task and improve the relationship between HCPs and community. (3) Motivation (M+), reflecting how mHealth encourages HCPs to be more active in their task and how knowledge acquisition and skills improve self-efficacy and confidence. (4) Ease of use and usefulness of mHealth (M+), which shows how the quality of training is received, resource availability, administrative support, knowledge and skills gained helped to improve their tasks such as data collection and data management.

Fig. 5
figure 5

Program theory of mHealth programs and MCH

In addition, four mechanisms explained how the mHealth program influences health-seeking behavior among pregnant women and mothers including: (1) Perceived satisfaction (M+), explaining how perceived privacy, confidentiality and support from HCPs can influence health-seeking behaviors. (2) Motivation (M+), reflection of how information and education received through mHealth act as a stimulus for health-seeking behaviors. (3) Positive psychological support (M+), reflecting how knowledge gained improved self-efficacy, confidence, empowered and motivated pregnant women and mothers can impact on health-seeking behaviors. (4) Information overload and sensitization (M-), reflecting how accessing MCH information has positive or negative effect as pregnant women and mothers may become complacent to using health facilities once they can access this through their mobile phones [15].

The model shows that improved performance and quality of health care by HCPs (O+) have an impact on the mechanisms activated by pregnant women and mothers to produce the outcomes.

Discussion

The present realist synthesis analyzed 32 articles describing eight intervention modalities used to implement mHealth programs for HCPs, pregnant women and mothers in LMICs, namely mHealth programs, training and support of HCPs, communication platform, data management platform, decision support and guidelines (for HCPs), mHealth messages sent to HCPs, reminder messages system, communication platform, consultation platform (for pregnant women and mothers). Our findings are supported by many other studies [44, 46, 48, 59].

This review unearthed theoretical models explicating how the adoption of mHealth program by HCPs, pregnant women and mothers can improve MCH. Our findings on the two models ICAMO resume that improved delivery of mHealth program, performance of care, and quality of health care by HCPs (O+) will influence the perceived satisfaction, motivation and psychological support (M+) of pregnant women and mothers (A) that will in turn influence on their overall health-seeking behaviors (O+). Our finding that context influences adoption of mHealth by HCPs concurs with those of Abejirinde et al. [48], which showed that mHealth empowered HCPs to adopt and use mHealth in contexts where it aligns to with needs, workload, training and skills. Perceived usefulness and ease of use of mHealth encouraged HCPs with skills and confidence, perceived usefulness related to design and technical concerns, cost, time, privacy, ease of use, security issues, risk-benefit assessment, experience with technology and contact with colleagues and patients [67, 68].

Our model is supported by Azhar and Dhillon [68] that identified behavioral intent, self-efficacy, social influence, attitude and perceived privacy threat as factors that influenced successful use of mHealth applications for self-care [68]. Moreover, our model is supported by a systematic review by Aker et al. that found that users’ perceived platform quality, perceived satisfaction of care, perceived quality interaction and outcomes, influence users’ uptake of mHealth for health care [69]. Our findings are supported by a realist-informed document review that identified empowerment, perceived quality of MCH care, encouragement, motivation, and knowledge acquisition as the main mechanisms driving the implementation and uptake of MCH care through the MomConnect program [70].

How does our model compare to relevant existing frameworks?

The Fogg Behavior Model (FBM) [71] is a psychological model which proposes that for a targeted behavior to occur, presence of the following is needed in tandem for a target behavior: Ample motivation, ability and an active trigger. The Fit between Individual, Task and Technology (FITT) framework explains the degree to which technology’s functionality matches task requirements and individuals abilities to use technology to perform tasks [72]. The Technology Acceptance Model (TAM) seeks to explain users’ adoption or rejection of information technology by focusing on two theoretical constructs: perceived ease of use and usefulness [73]. According to TAM, if potential users believe an application is useful, they may at the same time believe that the system is easy or not easy to use, which makes the performance of benefit of usage outweigh the effort of using the application [73].

We found that FBM, FITT and TAM identified constructs that could be considered by realists as mechanisms to explain how mHealth interventions work. For instance, the FBM model revealed user motivation as central for how mHealth interventions work, whereas the FITT model highlights the perceived ease of use as central mechanism of how mHealth interventions work. The TAM model on the other hand, reveals perceived ease of use and usefulness as central ingredients to intervention uptake. While using theoretical frameworks in mHealth evaluation has been found beneficial to inform best practices [74], these models are limited in their explanatory power, because they largely ignore contextual elements in triggering identified mechanisms. Our ICAMO models thus not only identify further mechanisms and relevant contextual elements but also illustrate how contextual factors could impact on intervention modalities to activate mechanisms that produce outcomes. In this way, our models do not only provide evidence of how and why mHealth interventions work or not, but also context-linked explanatory theories to inform implementation and rollout of mHealth interventions to ensure conducive health systems and programmatic conditions that increase the chances of uptake among users.

Strengths and limitations

Understanding the influence of mHealth by focusing on mechanisms and contextual factors through which outcomes are generated, is relevant because more information can be obtained about why mHealth interventions work or not and what triggers observed outcomes. Lack of information on how mHealth interventions work may encumber understanding of challenges and justifications for the implementation of successful mHealth programs, as well as its limitations.

A limitation of this review is that only six databases were searched and that search terms were restricted to LMICs, which could potentially bias the findings. The review also relied only on open access articles or those accessible through the electronic database and search engines published in English, which could have resulted in missing important studies on mHealth interventions for MCH care. Most articles did not conceptualize notions of context and mechanisms as understood in a realist philosophical sense. Thus, strict identification of these concepts needed further interpretation (abduction thinking) by the authors. Published studies on MCH-allied mHealth programs are growing, but have been inadequate in evaluating context and mechanisms by which outcomes are generated. More research is needed to evaluate mHealth using realist methods by comparing higher and LMICs.

Conclusion

This review unearthed theoretical models explicating utilization of mHealth by HCPs and pregnant women and mothers. The models developed in the study provide detailed understanding of the uptake of mHealth interventions and how they enhance MCH care in LMICs. Our findings suggest that mHealth programs can shift the pattern of health care utilization and can be applied by policymakers to inform implementation strategies for mHealth programs in LMICs. By making explicit ICAMO configurations that are associated with success and failure of mHealth programs, policymakers can be informed on critical aspects that can inform scale-up of mHealth interventions. ICAMO models can yield important insights into potential policy changes that need to be enacted for mHealth interventions to be successful at scale. These models provide a foundation for the ‘white box’ of theory-driven evaluation of mHealth interventions and hence improve implementation where required.

Availability of data and materials

The dataset(s) supporting the conclusions of this article is (are) included within the article (and its additional file(s).

Abbreviations

ANC/PNC:

Antenatal and postnatal care

CHWs:

Community Health Workers

CMOc:

Context-mechanism-outcome configuration

FITT:

Fit between individual, task and technology

HCPs:

Healthcare providers

LMICs:

Lower- and Middle-Income Countries

MCH:

Mother and Child Health

mHealth:

mobile Health

NS:

Narrative synthesis

ICAMO:

Intervention-context-actors-mechanism-outcomes

TAM:

Technology acceptance model

RCT:

Randomized controlled trials

SDGs:

Sustainable development goals

SMS:

Short messaging services

References

  1. Majeed-Ariss R, Hall AG, McDonagh J, Fallon D, Swallow V. Mobile phone and tablet apps to support young people’s management of their physical long-term conditions: a systematic review protocol. JMIR Res Protoc. 2015;4(2):e40.

    Article  PubMed  PubMed Central  Google Scholar 

  2. Abejirinde IOO, Ilozumba O, Marchal B, et al. Mobile health and the performance of maternal health care workers in low- and middle-income countries: a realist review. Int J Care Coord. 2018;21:73–86.

    PubMed  PubMed Central  Google Scholar 

  3. Kabongo EM, Mukumbang FC, Delobelle P, et al. Understanding the influence of the MomConnect programe on antenatal and postnatal care service utilisation in two south African provinces: a realist evaluation protocol. BMJ Open. 2019;9:1–9.

    Article  Google Scholar 

  4. Akter S, Ray P. mHealth - an ultimate platform to serve the Unserved. Yearb Med Inform. 2018;19:94–100.

    Google Scholar 

  5. Ruton H, Musabyimana A, Gaju E, et al. The impact of an mHealth monitoring system on health care utilization by mothers and children: an evaluation using routine health information in Rwanda. Health Policy Plan. 2018;33:920–7.

    Article  PubMed  PubMed Central  Google Scholar 

  6. Martínez-Pérez B, De La Torre-Díez I, López-Coronado M. Mobile health applications for the most prevalent conditions by the World Health Organization: review and analysis. J Med Internet Res. 2013;15(6):e120.

    Article  PubMed  PubMed Central  Google Scholar 

  7. Sondaal S, Browne JL, Amoakoh-coleman M, et al. Assessing the effect of mHealth interventions in improving maternal and neonatal Care in low- and Middle-Income Countries : a systematic review. Plos One. 2016;11:1–26.

    Article  CAS  Google Scholar 

  8. Feroz A, Perveen S, Aftab W. Role of mHealth applications for improving antenatal and postnatal care in low and middle income countries: a systematic review. BMC Health Serv Res. 2017;17(1):1–1.

    Article  Google Scholar 

  9. Mbuthia F, Reid M, Fichardt A. MHealth communication to strengthen postnatal care in rural areas: a systematic review. BMC Pregnancy Childbirth. 2019;19:1–10.

    Article  Google Scholar 

  10. Manyati TK, Mutsau M. A systematic review of the factors that hinder the scale up of mobile health technologies in antenatal care programmes in sub-Saharan Africa. African J Sci Technol Innov Dev. 2021;13(1):125–31.

  11. Amoakoh-Coleman M, Borgstein AB, Sondaal SF, Grobbee DE, Miltenburg AS, Verwijs M, Ansah EK, Browne JL, Klipstein-Grobusch K. Effectiveness of mHealth interventions targeting health care workers to improve pregnancy outcomes in low-and middle-income countries: a systematic review. J Med Internet Res. 2016;18(8):e226.

    Article  PubMed  PubMed Central  Google Scholar 

  12. Sondaal SF, Browne JL, Amoakoh-Coleman M, Borgstein A, Miltenburg AS, Verwijs M, Klipstein-Grobusch K. Assessing the effect of mHealth interventions in improving maternal and neonatal care in low-and middle-income countries: a systematic review. Plos One. 2016;11(5):e0154664.

    Article  PubMed  PubMed Central  CAS  Google Scholar 

  13. Colaci D, Chaudhri S, Vasan A. mHealth interventions in low-income countries to address maternal health: a systematic review. Ann Glob Heal. 2016;82:922–35.

    Article  Google Scholar 

  14. Hackett K, Lafleur C, Nyella P, Ginsburg O, Lou W, Sellen D. Impact of smartphone-assisted prenatal home visits on women’s use of facility delivery: results from a cluster-randomized trial in rural Tanzania. Plos One. 2018;13(6):e0199400.

    Article  PubMed  PubMed Central  CAS  Google Scholar 

  15. Obasola OI, Mabawonku IM. Women’s use of information and communication technology in accessing maternal and child health information in Nigeria. African J Libr Arch Inf Sci. 2017;27:1–15.

    Google Scholar 

  16. Mukumbang FC, Van Belle S, Marchal B, et al. Realist evaluation of the antiretroviral treatment adherence club programme in selected primary healthcare facilities in the metropolitan area of Western Cape Province, South Africa: a study protocol. BMJ Open. 2016;6:e009977–88.

    Article  PubMed  PubMed Central  Google Scholar 

  17. Pawson R, Tilley N. Realistic evaluation. London: sage; 1997.

  18. Dalkin SM, Greenhalgh J, Jones D, Cunningham B, Lhussier M. What’s in a mechanism? Development of a key concept in realist evaluation. Implement Sci. 2015;10(1):1–7.

    Article  Google Scholar 

  19. Mukumbang FC, Marchal B, Van Belle S, van Wyk B. A realist approach to eliciting the initial programme theory of the antiretroviral treatment adherence club intervention in the Western Cape Province, South Africa. BMC medical research methodology. 2018 Dec;18(1):1–6.Mukumbang FC, Marchal B, Belle S Van, et al. A realist approach to eliciting the initial programme theory of the antiretroviral treatment adherence club intervention in the Western Cape Province , South Africa. BMC Med Res Methodol. 2018;18:47.

    Article  PubMed  PubMed Central  Google Scholar 

  20. Marchal B, van Belle BTCS, Josefien van Olmen B, et al. Is realist evaluation keeping its promise? A review of published empirical studies in the field of health systems research review of realist evaluations in health systems researchEvaluation. Evaluation. 2012;18:192–212.

    Article  Google Scholar 

  21. Mukumbang FC, Van Wyk B, Van Belle S, et al. Unravelling how and why the antiretroviral adherence Club intervention works (or not) in a public health facility: a realist explanatory theory-building case study. Plos One. 2019;14:1–26.

    Article  CAS  Google Scholar 

  22. Mukumbang FC, van Wyk B, Sara van Wyk BM. At this [ adherence ] club , we are a family now ’: A realist theory-testing case study of the antiretroviral treatment adherence club , South Africa. South Afr J HIV Med. 2015;20:1–14.

    Google Scholar 

  23. Pawson R, Tilley N. Realistic evaluation. Sage London Publ. 2004:1–36.

  24. Mukumbang FC, Marchal B, Van Belle S, van Wyk B. Unearthing how, why, for whom and under what health system conditions the antiretroviral treatment adherence club intervention in South Africa works: a realist theory refining approach. BMC Health Serv Res. 2018;18(1):1–15.

    Article  Google Scholar 

  25. Pawson R, Greenhalgh T, Harvey G, Walshe K. Realist synthesis: an introduction. Manchester: ESRC Research Methods Programme, University of Manchester; 2004. p. 1–55.

    Google Scholar 

  26. Petticrew M, Roberts H. Systematic reviews in the social sciences: A practical guide. Wiley; 2008.

  27. Popay J, Roberts H, Sowden A, Petticrew M, Arai L, Rodgers M, Britten N, Roen K, Duffy S. Guidance on the conduct of narrative synthesis in systematic reviews. A product from the ESRC methods programme Version. 2006;1:b92.

  28. Mukumbang FC, Van Belle S, Marchal B, van Wyk B. An exploration of group-based HIV/AIDS treatment and care models in sub-Saharan Africa using a realist evaluation (intervention-context-actor-mechanism-outcome) heuristic tool: a systematic review. Implement Sci. 2017;12(1):1–20.

    Article  Google Scholar 

  29. Arai L, Britten N, Popay J, et al. Testing methodological developments in the conduct of narrative synthesis: a demonstration review of research on the implementation of smoke alarm interventions. Evid Policy. 2007;3:361–83.

    Article  Google Scholar 

  30. Peters DH. The application of systems thinking in health: why use systems thinking? Health Res Policy Syst. 2014;12(1):1–6.

    Article  Google Scholar 

  31. Eastwood JG, Jalaludin BB, Kemp LA. Realist explanatory theory building method for social epidemiology: a protocol for a mixed method multilevel study of neighbourhood context and postnatal depression. SpringerPlus. 2014;3(1):1–2.

    Article  Google Scholar 

  32. Doi L, Jepson R, Cheyne H. A realist evaluation of an antenatal programme to change drinking behaviour of pregnant women. Midwifery. 2015;31:965–72.

    Article  PubMed  PubMed Central  Google Scholar 

  33. Marchal B, van Belle S, van Olmen J, et al. Is realist evaluation keeping its promise? A review of published empirical studies in the field of health systems research. Evaluation. 2012;18:192–212.

    Article  Google Scholar 

  34. Wong G, Westhorp G, Manzano A, Greenhalgh J, Jagosh J, Greenhalgh T. RAMESES II reporting standards for realist evaluations. BMC Med. 2016;14(1):1–8.

    Article  CAS  Google Scholar 

  35. Pawson R, Barnes C, Boaz A, Grayson L, Long A. Types and quality of social care knowledge stage one: a classification of types of social care knowledge. Retrieved April 2003;2:2004. ESRC UK Centre for Evidence Based Policy and Practice PP1-16.

  36. Eberlein RL, Peterson DW. Understanding models with Vensim™. Eur J Oper Res. 1992;59(1):216–9.

    Article  Google Scholar 

  37. Kaewkungwal J, Singhasivanon P, Khamsiriwatchara A, Sawang S, Meankaew P, Wechsart A. Application of smart phone in “better border healthcare program”: a module for mother and child care. BMC Med Inform Decis Mak. 2010;10(1):1–2.

    Article  Google Scholar 

  38. Ngabo F, Nguimfack J, Nwaigwe F, et al. Designing and implementing an innovative SMS-based alert system (RapidSMS-MCH) to monitor pregnancy and reduce maternal and child deaths in Rwanda. Pan Afr Med J. 2012;13:1–15.

    Google Scholar 

  39. Ayiasi RM, Atuyambe LM, Kiguli J, et al. Use of mobile phone consultations during home visits by community health workers for maternal and newborn care: community experiences from Masindi and Kiryandongo districts, Uganda. BMC Public Health. 2015;15:1–14.

    Google Scholar 

  40. Modi D, Gopalan R, Shah S, Venkatraman S, Desai G, Desai S, Shah P. Development and formative evaluation of an innovative mHealth intervention for improving coverage of community-based maternal, newborn and child health services in rural areas of India. Glob Health Action. 2015;8(1):26769.

    Article  PubMed  Google Scholar 

  41. Kaphle S, Chaturvedi S, Chaudhuri I, Krishnan R, Lesh N. Adoption and usage of mHealth technology on quality and experience of care provided by frontline workers: observations from rural India. JMIR Mhealth Uhealth. 2015;3(2):e61.

    Article  PubMed  PubMed Central  Google Scholar 

  42. Tobe RG, Haque SE, Ikegami K, et al. Mobile-health tool to improve maternal and neonatal health care in Bangladesh: a cluster randomized controlled trial. BMC Pregnancy Childbirth. 2018;18:1–7.

    Article  Google Scholar 

  43. Balakrishnan R, Gopichandran V, Chaturvedi S, et al. Continuum of Care Services for Maternal and Child Health using mobile technology - a health system strengthening strategy in low and middle income countries. BMC Med Inform Decis Mak. 2016;16:1–8.

    Article  Google Scholar 

  44. Musabyimana A, Ruton H, Gaju E, Berhe A, Grépin KA, Ngenzi J, Nzabonimana E, Hategeka C, Law MR. Assessing the perspectives of users and beneficiaries of a community health worker mHealth tracking system for mothers and children in Rwanda. PloS one. 2018;13(6):1–12.

  45. Ilozumba O, Dieleman M, Kraamwinkel N, et al. ‘I am not telling. The mobile is telling’: factors influencing the outcomes of a community health worker mHealth intervention in India. Plos One. 2018;13:1–24.

    Article  CAS  Google Scholar 

  46. Asiki G, Newton R, Kibirige L, et al. Feasibility of using smartphones by village health workers for pregnancy registration and effectiveness of mobile phone text messages on reduction of homebirths in rural Uganda. Plos One. 2018;13:1–14.

    Article  CAS  Google Scholar 

  47. Mwendwa P. Assessing the fit of RapidSMS for maternal and new-born health: perspectives of community health workers in rural Rwanda. Dev Pract. 2016;26:38–51.

    Article  Google Scholar 

  48. Abejirinde IOO, Douwes R, Bardají A, et al. Pregnant women’s experiences with an integrated diagnostic and decision support device for antenatal care in Ghana. BMC Pregnancy Childbirth. 2018;18:1–11.

    Article  Google Scholar 

  49. McNabb M, Chukwu E, Ojo O, et al. Assessment of the quality of antenatal care services provided by health workers using a mobile phone decision support application in northern Nigeria: a pre/post-intervention study. PLoS One. 2015;10:1–12.

    Article  CAS  Google Scholar 

  50. Shiferaw S, Spigt M, Tekie M, et al. The effects of a locally developed mHealth intervention on delivery and postnatal care utilization; a prospective controlled evaluation among health centres in Ethiopia. Plos One. 2016;11:1–15.

    Article  CAS  Google Scholar 

  51. Hackett KM, Kazemi M, Sellen DW. Keeping secrets in the cloud: Mobile phones, data security and privacy within the context of pregnancy and childbirth in Tanzania. Soc Sci Med. 2018;211:190–7.

    Article  PubMed  Google Scholar 

  52. Atnafu A, Otto K, Herbst CH. The role of mHealth intervention on maternal and child health service delivery: findings from a randomized controlled field trial in rural Ethiopia. mHealth. 2017;3:39.

    Article  PubMed  PubMed Central  Google Scholar 

  53. Martinez B, Ixen EC, Hall-Clifford R, et al. MHealth intervention to improve the continuum of maternal and perinatal care in rural Guatemala: a pragmatic, randomized controlled feasibility trial. Reprod Health. 2018;15:1–12.

    Article  Google Scholar 

  54. Bigna JJR, Jacques J, Noubiap N, et al. Eff ect of mobile phone reminders on follow-up medical care of children exposed to or infected with HIV in Cameroon (MORE CARE): a multicentre, single-blind, factorial, randomised controlled trial. Lancet Infect Dis. 2014;14:600–8.

    Article  PubMed  Google Scholar 

  55. Nie J, Unger JA, Thompson S, et al. Does mobile phone ownership predict better utilization of maternal and newborn health services? A cross-sectional study in Timor-Leste. BMC Pregnancy Childbirth. 2016;16:1–7.

    Article  Google Scholar 

  56. Kazi AM, Carmichael J-L, Hapanna GW, et al. Assessing Mobile phone access and perceptions for texting-based mHealth interventions among expectant mothers and child caregivers in remote regions of northern Kenya: a survey-based descriptive study. JMIR Public Heal Surveill. 2017;3(1):1–5.

  57. Coleman J, Bohlin KC, Thorson A, et al. Effectiveness of an SMS-based maternal mHealth intervention to improve clinical outcomes of HIV-positive pregnant women. AIDS Care. 2017;29:890–7.

    Article  PubMed  Google Scholar 

  58. Bangal VB, Borawake SK, Gavhane SP, Aher KH. Use of mobile phone for improvement in maternal health: a randomized control trial. Int J Reprod, Contracept Obstet Gynecol. 2017;6(12):5458–63.

    Article  Google Scholar 

  59. Skinner D, Delobelle P, Pappin M, Pieterse D, Esterhuizen TM, Barron P, Dudley L. User assessments and the use of information from MomConnect, a mobile phone text-based information service, by pregnant women and new mothers in South Africa. BMJ Glob Health. 2018;3(Suppl 2):1–6.

  60. Barron P, Peter J, LeFevre AE, Sebidi J, Bekker M, Allen R, Parsons AN, Benjamin P, Pillay Y. Mobile health messaging service and helpdesk for south African mothers (MomConnect): history, successes and challenges. BMJ Glob Health. 2018;3(Suppl 2):e000559.

    Article  PubMed  PubMed Central  Google Scholar 

  61. Feroz A, Rizvi N, Sayani S, Saleem S. Feasibility of mHealth intervention to improve uptake of antenatal and postnatal care services in peri-urban areas of Karachi: a qualitative exploratory study. J Hospit Manage Health Policy. 2017;4(1):1–11.

    Google Scholar 

  62. Jennings L, Omoni A, Akerele A, et al. Disparities in mobile phone access and maternal health service utilization in Nigeria: a population-based survey. Int J Med Inform. 2015;84:341–8.

    Article  PubMed  Google Scholar 

  63. Guerra-Reyes L, Christie VM, Prabhakar A, et al. Postpartum health information seeking using Mobile phones: experiences of low-income mothers. Matern Child Health J. 2016;20:13–21.

    Article  PubMed  PubMed Central  Google Scholar 

  64. Nyemba-Mudenda M, Chigona W. mHealth outcomes for pregnant mothers in Malawi: a capability perspective. Inf Technol Dev. 2018;24:245–78.

    Article  Google Scholar 

  65. Abekah-Nkrumah G, Guerriero M, Purohit P. ICTs and maternal healthcare utilization. Evidence from Ghana. Int J Soc Econ. 2014;41:518–41.

    Article  Google Scholar 

  66. Yamin F, Kaewkungwal J, Singhasivanon P, et al. Women’s perceptions of using mobile phones for maternal and child health support in Afghanistan: cross-sectional survey. J Med Internet Res. 2018;20:1–10.

    Google Scholar 

  67. Gagnon MP, Ngangue P, Payne-Gagnon J, et al. M-health adoption by healthcare professionals: a systematic review. J Am Med Informatics Assoc. 2016;23:212–20.

    Article  Google Scholar 

  68. Azhar FA, Bin DJS. A systematic review of factors influencing the effective use of mHealth apps for self-care, 2016 3rd Int Conf Comput Inf Sci ICCOINS 2016 - Proc; 2016. p. 191–6.

    Google Scholar 

  69. Akter S, D’Ambra J, Ray P. User perceived services quality of mHealth Services around the world, 18 th Eur Conf Inf Syst Pretoria, South Africa; 2010. p. 1–12.

    Google Scholar 

  70. Kabongo EM, Mukumbang FC, Delobelle P, Nicol E. Combining the theory of change and realist evaluation approaches to elicit an initial program theory of the MomConnect program in South Africa. BMC Med Res Methodol. 2020;20(1):1–1.

    Article  Google Scholar 

  71. Fogg BJ. A behavior model for persuasive design. In Proceedings of the 4th international Conference on Persuasive Technology. 2009;1-7.

  72. Goodhue DL, Thompson RL. Task-technology fit and individual performance. MIS quarterly. JTOR. 1995;19(2):213–36.

  73. Davis FD. Perceived usefulness, perceived ease of use, and user acceptance of information technology. MIS quarterly. JTOR. 1989;13(3):319–40.

  74. Bull S, Ezeanochie N. From Foucault to Freire through Facebook: toward an integrated theory of mHealth. Heal Educ Behav. 2016;43:399–411.

    Article  Google Scholar 

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The scoping review was developed by EMK, with support from FCM, PD and EN. All authors have read and approved the final manuscript.

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Supplementary Information

Additional file 1.

Research Evidence Extraction/appraisal tool. This tool assisted in assessing the quality of studies included in the review.

Additional file 2.

Part a) HCPs data charting, and Part b) pregnant women and mothers. This file provides two tables of information on ICAMO data extraction.

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Kabongo, E.M., Mukumbang, F.C., Delobelle, P. et al. Explaining the impact of mHealth on maternal and child health care in low- and middle-income countries: a realist synthesis. BMC Pregnancy Childbirth 21, 196 (2021). https://0-doi-org.brum.beds.ac.uk/10.1186/s12884-021-03684-x

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