Strengthening intrapartum and immediate newborn care to reduce morbidity and mortality of preterm infants born in health facilities in Migori County, Kenya and Busoga Region, Uganda: A study protocol for a randomized controlled trial

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Study Justification:
– Preterm birth and its complications are major contributors to neonatal and under-5 mortality.
– Most neonatal deaths in Kenya and Uganda occur during the intrapartum and immediate postnatal period.
– This study aims to implement and evaluate a package of interventions to improve care for preterm infants during this critical period.
Study Highlights:
– Pair-matched, cluster randomized controlled trial across 20 health facilities in Eastern Uganda and Western Kenya.
– Intervention facilities receive four components: strengthening of data collection, modified Safe Childbirth Checklist, PRONTO simulation training, and quality improvement support.
– Control facilities receive data strengthening and introduction of the modified checklist.
– Primary outcome is 28-day mortality rate among preterm infants.
Study Recommendations:
– Strengthen personnel and facility capacity to respond to preterm labor and delivery.
– Improve care for preterm infants during the intrapartum and immediate postnatal period.
Key Role Players:
– Facility leadership, nurses, and health record staff.
– PRONTO mentors/trainers.
– Quality improvement teams.
Cost Items for Planning Recommendations:
– Training and mentoring costs for PRONTO mentors/trainers.
– Data strengthening activities.
– Implementation of the modified Safe Childbirth Checklist.
– Quality improvement initiatives.
– Monitoring and evaluation activities.
– Data collection and analysis.
– Communication and dissemination of findings.
Please note that the provided information is a summary of the study protocol and does not include actual cost estimates.

The strength of evidence for this abstract is 8 out of 10.
The evidence in the abstract is strong because it describes a pair-matched, cluster randomized controlled trial with a clear study protocol and intervention components. The primary outcome is clearly defined, and the study aims to improve care for preterm infants in health facilities. To improve the evidence, the abstract could provide more details on the sample size calculation and statistical analysis plan.

Background: Preterm birth (birth before 37 weeks of gestation) and its complications are the leading contributors to neonatal and under-5 mortality. The majority of neonatal deaths in Kenya and Uganda occur during the intrapartum and immediate postnatal period. This paper describes our study protocol for implementing and evaluating a package of facility-based interventions to improve care during this critical window. Methods/design: This is a pair-matched, cluster randomized controlled trial across 20 facilities in Eastern Uganda and Western Kenya. The intervention facilities receive four components: (1) strengthening of routine data collection and data use activities; (2) implementation of the WHO Safe Childbirth Checklist modified for preterm birth; (3) PRONTO simulation training and mentoring to strengthen intrapartum and immediate newborn care; and (4) support of quality improvement teams. The control facilities receive both data strengthening and introduction of the modified checklist. The primary outcome for this study is 28-day mortality rate among preterm infants. The denominator will include all live births and fresh stillbirths weighing greater than 1000 g and less than 2500 g; all live births and fresh stillbirths weighing between 2501 and 3000 g with a documented gestational age less than 37 weeks. Discussion: The results of this study will inform interventions to improve personnel and facility capacity to respond to preterm labor and delivery, as well as care for the preterm infant.

This study is a pair-matched, cluster randomized controlled trial (CRCT) among 20 public sector health facilities in the Busoga Region of Uganda (four facilities) and in Migori County, Kenya (16 facilities, including 14 public facilities and two not-for-profit missionary hospitals). The full intervention package (data strengthening (DS), modified Safe Childbirth Checklist (mSCC), PRONTO provider training, and quality improvement (QI)) will be introduced to 10 facilities (intervention arm); the remaining 10 facilities will receive DS + mSCC (control arm) (Fig. 1). All facilities will begin with DS + mSCC intervention components in order to capture preliminary data for baseline and facility matching, as well as to standardize definitions of key indicators related to GA and newborn outcomes. Roll-out of mSCC and support will differ between the control and intervention sites, in that the latter will receive additional mSCC mentorship and support through synergies with PRONTO and QI. The intervention package will be delivered at the facility level, while outcomes will be measured at both an individual and facility level. Schematic of the study design In addition to the 10 pairs of matched facilities, three referral hospitals to which the respective sub-county or district hospitals send their high-risk deliveries will receive the full intervention package. While these three referral hospitals are not included in the randomization scheme, cases referred in from any one of the 20 facilities will be included in the primary outcome analysis. The study regions of Migori County, Kenya and Busoga Region, Uganda were selected based on in-country stakeholder input. Prematurity burden and presence of synergistic parallel maternal/newborn research or implementation studies were considered. Health facilities were asked to participate in this study by in-country partners. Formal approval from facility leadership was obtained before any activities commenced. Given that facilities were not selected from a target population of hospitals, the intervention effects should be interpreted as impact evaluation of the intervention package implemented at the said facilities. A complete list of all facilities can be found at the clinical trial registration (ClinicalTrials.gov, ID: {“type”:”clinical-trial”,”attrs”:{“text”:”NCT03112018″,”term_id”:”NCT03112018″}}NCT03112018). The Busoga Region of Eastern Uganda contains approximately three million people, or 10% of Uganda’s population, with over 80% of residents living on less than US$1 per day [21]. The estimated preterm birth rate for Uganda is 13.57% and the neonatal mortality rate is 21 per 1000 live births [3, 4]. Our selected six health facilities include approximately 22,000 deliveries per year, with 9000 deliveries from the four hospitals pair-matched in this study. Migori County, located in southwestern Kenya, has a population of approximately 917,170, wherein 43% of the population lives below the poverty line [21]. The estimated preterm birth rate for Kenya is 12.30% and the neonatal mortality rate is 23 per 1000 live births [3, 4]. Our 17 selected Migori County health facilities include approximately 10,000 deliveries per year, with 7500 deliveries at pair-matched sites. In all facilities, women accessing delivery care services who are admitted for labor will be eligible for this study. Anonymized data on all deliveries will be extracted from maternity registers. For follow-up, mothers of newborns who are discharged alive and born less than 2500 g or between 2501 g and 3000 g while also being identified as less than 37 weeks by recorded GA in the maternity register are being asked to participate in this study and approached for consent for follow-up for 28-day outcome. These inclusion parameters were selected based on baseline data showing a poor correlation between birthweight and reported GA in the maternity register. Women or newborns from enrolled sites who are referred to one of the three referral facilities will remain in the study. Their outcomes will be allocated to the facility to which the woman first presented. Healthcare workers providing labor and delivery and immediate newborn care services at referral, control, and intervention facilities will participate in DS initial and refresher workshops, DQAs, as well as initial instruction and minimal refreshers or reorientation on use of the mSCC. Intervention sites will have ongoing support for mSCC utilization, in addition to the other reinforcing intervention components, PRONTO and QI. Healthcare providers in intervention facilities who provide consent for PRONTO simulation trainings will also be enrolled as study participants to ascertain changes in knowledge and practices. Facility staff in the intervention facilities will be organized into QI teams to develop and implement QI programs. Ten intervention sites and the three referral-level hospitals will receive an intervention package comprising DS + mSCC + PRONTO + QI, while the remaining 10 control facilities will receive DS + mSCC. Each intervention component is described in detail below. The intervention package is designed to strengthen and reinforce EBPs, as well as improve teamwork, communication, respectful maternity care and data use. All study activities consist of known interventions or strategies. There are no experimental interventions that would directly impact patient safety. Improvements in measurement and data use in the study sites are critical to establishing baseline measures and achieving and demonstrating reductions in the burden of preterm birth. Therefore, we will begin our study by strengthening existing data collection processes in health facilities, introducing standard tools to improve GA assessment, and reviewing standardization of indicators based on national guidelines. We will also work with in-country stakeholders to develop and iterate a Data Dashboard to improve data use and dissemination of our study data (Table 1). Components of data strengthening DS initial training will include review of these components with facility clinical leadership, health records officers and district staff, followed by site trainings with maternity nurses and health record staff. Refresher DS trainings will be offered as needed during the course of the study. Intermittent DQAs will be implemented every 6–12 months to collect data on specific DHIS-related indicators to assess gaps between reported and actual indicators (e.g., errors in transcription) across all control and intervention facilities. This process will also help identify barriers in the reporting processes and flow. Each country team will modify the WHO Safe Childbirth Checklist in order to adhere to their national guidelines. It will be adapted to the local setting and modified to emphasize identification of preterm labor and care of the preterm infant. Specifically, we will incorporate additional elements focused on GA assessment and documentation, prematurity-related intrapartum/immediate postnatal care practices (e.g., use of magnesium sulfate, antenatal corticosteroids, immediate skin to skin, etc.). We will also include an additional pause point at initial presentation or triage (i.e., before a woman is admitted for labor), as well as prompts focused on ascertaining additional maternal demographic information, clinical risk factors and history. Each country’s mSCC will be piloted in order to optimize content and roll-out. The mSCC will be introduced during initial DS activities at all study sites. It is intended to serve as both a decision aid for providers of key EBPs, as well as a data source for the study. An mSCC will be included in the maternity inpatient record for each woman in all control and intervention facilities. After piloting, study data staff will review all maternity charts of cases eligible for follow-up each month and abstract a selected number of essential data variables. Study personnel will also monitor mSCC completeness and uptake by each of the five pause points either by convenience or purposive sampling. These data will be displayed on the Data Dashboard quarterly, and will allow the study teams to tailor the mSCC approach depending on uptake and use. The Kenya-Uganda unified PRONTO emergency obstetric and neonatal care simulation training will emphasize the identification, triage, and management of preterm labor and birth with a curriculum specifically adapted for this context. It will include strengthening preterm labor identification with more accurate GA assessments, intrapartum care, and immediate management of fragile infants. The training also emphasizes identification and management of preeclampsia, chorioamnionitis, and other conditions related to preterm birth. The mSCC will be integrated into all PRONTO clinical activities to provide facility staff with continued opportunities to reinforce its use. Any change ideas that arise from these PRONTO activities will be integrated into QI efforts. Selection of PRONTO mentors/trainers will be conducted in each country, with an initial pool of up to 15 candidates from which we will select the 5–10 highest performing trainers. Due to the overlapping clinical and curricular content between the two countries, refreshers will be conducted as joint facilitator training for the Kenyan mentors and Ugandan trainers. However, the training mode of delivery will vary between Kenya and Uganda. Kenya will utilize an in situ mentoring program whereby each intervention facility will receive high-intensity/4-day per week mentorship and a pair of mentors will rotate among intervention sites during the study duration. They will spend a combined total of 9–12 weeks at each intervention facility over the study duration and visits will include bedside mentoring, video-recorded, in situ simulations, knowledge reviews, skills stations, teamwork activities, and mSCC support. In Uganda, a high-intensity/shorter modular strategy will be used. A modular-based training program will be paired with 2-day-long in-situ simulation refresher and training visits. Modules and refresher/training visits will be spread out during the study period, and will similarly amount to approximately 6 weeks of mentorship. Thus, while the mode of delivery for training in each country will be different, provider teams in each country will receive approximately 56–58 h of PRONTO-based instruction using the same curriculum. Each facility in the intervention arm will have a designated QI team comprising facility leadership, nurses, and health record staff (five to seven people). If teams have been trained previously through other QI efforts, we will revitalize and support these ongoing efforts in intervention sites. Otherwise, we will offer foundational training in QI methods. These teams will carry out Plan-Do-Study-Act cycles which include identification of a problem or bottleneck in the facility, implementation of solutions, tracking of the outcomes of the changes, and implementation or adjustment based on the results. QI teams across facilities (known collectively as the QI collaborative) will also participate in a learning session every 3 to 6 months to discuss core learnings and QI indicators. QI indicators will be chosen by each country and will focus on EBPs expected to result in decreased neonatal mortality among preterm infants, such as uptake of Kangaroo Mother Care, antenatal corticosteroid provision, and breastfeeding. At these learning sessions, QI teams across facilities will be able to share progress on QI indicators, lessons learned, and best practices. Elements of the package, namely PRONTO, the Data Dashboard and the mSCC, will be integrated with QI efforts. First, the Data Dashboard will help generate specific visual data to inform facility teams on progress and remaining performance gaps with respect to QI indicators and selected EBPs. Second, areas of possible improvement that arise through PRONTO mentorship and simulation will be shared with QI teams. Lastly, the mSCC may serve as a data source to document QI indicators. The approach for roll-out of the intervention package will be as follows: Figure 2 depicts the schedule of enrollment, interventions, and assessments to be conducted. Standard Protocol Items: Recommendations for Interventional Trials (SPIRIT) Figure The primary outcome for this study is 28-day mortality rate among preterm infants. For this primary analysis, the denominator will include: This outcome will be measured by comparing mortality rates of preterm infants at 28 days after delivery across the intervention and control arms to determine the effect of the package of facility-level interventions. The upper limit of 3000 g (which is coupled to a documented GA of less than 37 weeks) was agreed upon based on INTERGROWTH-21st standards. At this weight, we assume that we will capture 90% and 97% of < 34-week infants and 60% and 70% of  1000 g or > 28 weeks’ gestation) [6]. However, data on infants with signs of life born weighing < 1000 g will be followed for secondary data analyses, including outcomes at 28 days of life. Selected secondary outcomes are listed in Table 2.We include additional information as to how they will be measured and how often during the study duration. Select secondary outcomes GA gestational age, DQA data quality assessment, EBP evidence-based practice, mSCC Modified Safe Childbirth Checklist, QI quality improvement For the primary outcome, existing facility-based registers will be used as primary data sources. Data entry into registries is conducted by facility care providers, as part of existing routine data collection. Information in these registries will then be extracted by study personnel. Study staff will visit each facility at least once per month to collect routine facility data from register reviews. All data will be uploaded via Open Data Kit via tablet or laptop. For preterm babies discharged alive from hospital, mothers will be consented to be followed up by phone at 28 days following delivery. Consent of eligible mothers and their newborns will take place prior to discharge or referral. Contact information will be derived from consent forms, and from the mSCC as needed. Outcomes will be determined by targeted follow-up of study participants via phone call. Where phone calls are insufficient to trace mothers, the Kenya team will engage with community health volunteers and Uganda will employ community outreach nurses to seek out mothers. Study personnel in each country will collect data from maternity registers on a monthly basis. In addition to reviewing the quality of records, they will also generate summary reports for data sharing among the research team and facility leads. Routine indicators and process indicators for QI cycles will be collected and displayed on a Data Dashboard accessible to study staff, intervention and referral health facility staff, and county health authorities. While these Data Dashboard displays will be customized to different audiences, all of the data included will be aggregate, and no individual data will be displayed. The mSCC will be distributed to facilities and fixed into the patient charts in readiness for use by the healthcare providers. Staff will be adequately trained on the use of the checklist and regular reinforcement conducted as scheduled at intervention sites. Study staff will review all maternity charts for newborns who meet our eligibility criteria. Each month, they will abstract key data from eligible admissions from the mSCC in order to compile coverage indicators for key interventions and EBPs. Uptake and completeness of the mSCC will also be determined. To measure changes in knowledge through training and mentoring, we will conduct evaluations in the form of pre- and post-knowledge tests of PRONTO-trained midwives, nurses, and physicians before and after each training session and periodically during mentoring visits. These evaluations will be adapted to the local context based on previously developed knowledge assessment tools used by PRONTO. To evaluate the impact of PRONTO’s on-site simulation training program, we will collect video-recordings of simulated birth scenarios and debriefs conducted in participating hospitals led by PRONTO-trained mentors/trainers. These videos will be coded using Studiocode™ software to create scores based on how often EBPs are practiced in simulation and if this changes over time. We will track process indicators of these QI cycles, such as number of projects started, number of goals reached, and amount of change detected by the QI team in studying their implementation. We will implement a QI documentation journal for the sites. QI teams will also track key EBPs, such as Kangaroo Care uptake, and track their progress against it. Data from registries will be collected using a secure database via the Open Data Kit data entry platform and hosted on a secure server. Data will be reviewed for accuracy and completeness by a data manager before entry, and the data entry system will include automated range and logic checks to identify any data entry mistakes before they are saved. All devices used for data entry (laptops or tablets) will be encrypted and password protected. The research team and stakeholders will have access to aggregate data across facilities through the Data Dashboard. For example, each facility will have access to their own data including 28-day outcome, but stratified data by control and intervention data will not be shared. Moreover, only the study biostatistician and core team will have access to the unblinded dataset prior to study completion. Our primary analysis will combine data across our selected facilities in Kenya and Uganda. Since we will exclude the referral hospitals from our primary analysis, the project takes place in 20 facilities with an expected volume of 46,000 deliveries over 24 months. In an initial calculation, prior to baseline data collection, we assumed an average preterm birth rate of 12% and expected to see about 5500 preterm deliveries within this period. We assumed a 25% loss-to-follow-up rate for eligible cases. This yields at least 200 projected preterm deliveries per facility with known 28-day mortality outcome. Detectable effect sizes were estimated by standard t test procedures adjusted to account for the design effect due to clustering of outcomes within facilities to attain 80% power while maintaining type I error at 5%. At a 25% 2-year cumulative incidence of 28-day mortality across both countries in the absence of the intervention, this would allow us to detect a 25% reduction in cumulative incidence if the between-cluster outcome coefficient of variation is 0.2 or below. If this coefficient increases to 0.3, we would be powered to detect a 30% reduction. If it increases to 0.4, we would be powered to detect a 40% reduction. For the primary outcome, the analysis will contrast mortality at 28 days among preterm infants between the intervention and control groups. This will be performed using hierarchical, targeted maximum-likelihood estimation which accounts for within-cluster correlation by controlling for cluster-level covariates [23]. The baseline covariates we will measure for each facility include delivery volume, baseline neonatal mortality rate among preterm infants, preterm birth rate, and country. Additionally, targeted maximum-likelihood estimation will allow us to incorporate individual-level baseline covariate information (such as date of presentation, maternal age, parity/gravidity, HIV status, maternal and fetal complications at presentation, last menstrual period (LMP), infant birthweight, final diagnosis of newborn) in order to improve precision. We will directly incorporate knowledge of the pair-matched randomization scheme into estimation by making the targeting stage of this procedure a function of this known assignment mechanism. Primary outcome data analysis will be conducted in collaboration among in-country partners and UCSF. Secondary analyses will also be performed, in some cases contrasting secondary outcomes between the intervention and control groups, and in others contrasting these outcomes pre and post intervention within the intervention groups. Secondary analyses will primarily be descriptive, comparing means or proportions between groups, trends over time, composite scores as appropriate for each measure. Both primary and secondary analyses will be conducted in R or Stata. Process data including qualitative interviews or reports will be analyzed by hand or in Atlas ti, identifying and grouping themes that emerge. Additional analyses will be conducted for each intervention component. For example, PRONTO-related knowledge will be assessed against the standard guidelines for management. Simulation and debrief videos will be analyzed using Studiocode™ software which enables the systematic coding of videos to measure of changes in use of EBPs, as well as teamwork and communication techniques. Video analysis of simulation and debrief results will be shared with participants in the form of structured feedback to PRONTO mentors on their simulation and debriefing facilitation skills. In accordance with the Bill & Melinda Gates Foundation open-access policy, we will publish in open-access journals. The final trial dataset will be made publicly available after study completion once all datasets are cleaned and initial results are reported. We plan to disseminate evaluation findings to both internal and external stakeholders, including facility staff implementers, Ministries of Health policymakers, and the Bill & Melinda Gates Foundation. The intervention package is designed to strengthen and reinforce best EBPs, and all study activities consist of known interventions or strategies. There are no experimental interventions that would directly impact patient safety. Should any adverse events be reported, these will be immediately reported to study leadership and ethics committees. This proposal was submitted to KEMRI, Makerere University School of Public Health, and UCSF Scientific and Ethical Research Bodies for scientific and ethical approval before study initiation. This is an implementation science study and intervention components will be applied to facilities rather than individuals. In most cases, there will be no direct contact with the participants except for the 28-day follow-up. For the primary outcome, risks to participants will be minimized by the fact that facility registers and medical records will be used as the primary source of information and no identifiable information will be collected or used. Data abstraction from registers, medical records and the mSCC will be conducted in a private, confidential area of each facility. However, for 28-day follow-up among eligible newborns, mothers will be asked to provide written consent prior to discharge. No incentives will be provided, and women can opt out from participation. For providers in the intervention arm, both PRONTO mentors and mentees will be asked for written consent authorizing the use of knowledge tests and video data for analysis. While QI indicators and a change in direction of performance would be noted over the course of the study, QI team members and facility staff will not be asked for consent as no identifying individual data will be collected.

The study protocol described aims to improve access to maternal health by implementing and evaluating a package of facility-based interventions to strengthen intrapartum and immediate newborn care for preterm infants in Kenya and Uganda. The interventions include:

1. Strengthening of routine data collection and data use activities: This involves improving the collection and use of data in health facilities to inform decision-making and improve the quality of care.

2. Implementation of the WHO Safe Childbirth Checklist modified for preterm birth: The checklist is a tool that guides healthcare providers in delivering evidence-based practices during childbirth. It will be adapted to focus on preterm labor and care of preterm infants.

3. PRONTO simulation training and mentoring: PRONTO is an emergency obstetric and neonatal care simulation training program. It will be used to train healthcare providers in identifying, triaging, and managing preterm labor and birth, as well as other conditions related to preterm birth.

4. Support of quality improvement teams: Quality improvement teams will be established in each facility to identify and address bottlenecks in the delivery of care. They will implement Plan-Do-Study-Act cycles to improve processes and outcomes.

These interventions will be implemented in 10 intervention facilities, while the remaining 10 facilities will receive data strengthening and the modified Safe Childbirth Checklist. The primary outcome of the study is the 28-day mortality rate among preterm infants.

The study will also involve data collection, analysis, and evaluation to assess the impact of the interventions on maternal and newborn outcomes. The findings of the study will inform interventions to improve personnel and facility capacity to respond to preterm labor and delivery, as well as care for preterm infants.
AI Innovations Description
The recommendation to improve access to maternal health in this study is to implement a package of facility-based interventions. These interventions include:

1. Strengthening routine data collection and data use activities: This involves improving the process of collecting and analyzing data related to maternal health. By strengthening data collection and use, healthcare providers can better understand the challenges and gaps in maternal health care and make informed decisions to improve access and quality of care.

2. Implementation of the WHO Safe Childbirth Checklist modified for preterm birth: The Safe Childbirth Checklist is a tool developed by the World Health Organization (WHO) to ensure that essential practices are followed during childbirth. In this study, the checklist is modified specifically for preterm birth to address the unique needs and challenges associated with preterm infants.

3. PRONTO simulation training and mentoring to strengthen intrapartum and immediate newborn care: PRONTO is an evidence-based simulation training program that focuses on improving the skills and knowledge of healthcare providers in managing complications during childbirth and caring for newborns. This training program uses realistic simulations to provide hands-on practice and feedback to healthcare providers.

4. Support of quality improvement teams: Quality improvement teams are established in each facility to identify and address gaps in the delivery of maternal health care. These teams work collaboratively to develop and implement strategies to improve the quality and safety of care provided to mothers and newborns.

By implementing these interventions, the study aims to improve the capacity of healthcare facilities to respond to preterm labor and delivery, as well as provide better care for preterm infants. The results of this study will inform future interventions and strategies to improve access to maternal health and reduce morbidity and mortality among preterm infants.
AI Innovations Methodology
Based on the provided description, the study protocol aims to implement and evaluate a package of facility-based interventions to improve care during the intrapartum and immediate postnatal period for preterm infants in Migori County, Kenya, and Busoga Region, Uganda. The interventions include strengthening routine data collection and data use activities, implementing the WHO Safe Childbirth Checklist modified for preterm birth, providing PRONTO simulation training and mentoring, and supporting quality improvement teams.

To simulate the impact of these recommendations on improving access to maternal health, a methodology could be developed as follows:

1. Define the objectives: Clearly state the specific objectives of the simulation study, such as assessing the impact of the interventions on reducing morbidity and mortality of preterm infants, improving healthcare provider knowledge and practices, and enhancing facility capacity to respond to preterm labor and delivery.

2. Identify the key variables: Determine the key variables that will be measured and analyzed in the simulation study. These may include 28-day mortality rate among preterm infants, preterm birth rate, neonatal mortality rate, adherence to evidence-based practices, healthcare provider knowledge and practices, and facility capacity indicators.

3. Collect baseline data: Gather baseline data on the identified variables before implementing the interventions. This may involve reviewing existing facility records, conducting surveys or interviews with healthcare providers, and assessing facility capacity through site visits.

4. Develop a simulation model: Create a mathematical or computational model that represents the healthcare system and the interactions between various factors influencing access to maternal health. The model should incorporate the interventions being studied and their potential impact on the key variables.

5. Define assumptions and parameters: Specify the assumptions and parameters that will be used in the simulation model. These may include the effectiveness of the interventions, the population size and characteristics, the duration of the study, and any other relevant factors.

6. Run the simulation: Use the developed model to simulate the impact of the interventions over the specified time period. This involves inputting the baseline data, applying the interventions, and observing the changes in the key variables.

7. Analyze the results: Analyze the simulation results to assess the impact of the interventions on improving access to maternal health. This may involve comparing the outcomes between the intervention and control groups, identifying trends over time, and evaluating the effectiveness of specific interventions.

8. Interpret the findings: Interpret the simulation findings in the context of the study objectives and the limitations of the simulation model. Discuss the implications of the results for improving access to maternal health and identify any areas for further research or intervention refinement.

9. Communicate the results: Present the simulation findings in a clear and concise manner, using appropriate visualizations and statistical analyses. Share the results with relevant stakeholders, such as healthcare providers, policymakers, and the research community, to inform decision-making and future interventions.

By following this methodology, researchers can simulate the impact of the recommended interventions on improving access to maternal health and gain insights into their potential effectiveness before implementing them in real-world settings.

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