How accurate are modelled birth and pregnancy estimates? Comparison of four models using high resolution maternal health census data in southern Mozambique

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Study Justification:
– The study aims to investigate the accuracy of global demographic distribution datasets at subnational levels in southern Mozambique.
– It addresses the need to assess the quality and access to healthcare services at subnational levels, despite improvements in national maternal and perinatal mortality rates.
– The study aligns with the Sustainable Development Goals’ emphasis on subnational monitoring of maternal and perinatal health progress.
Study Highlights:
– Four models were compared using high-resolution maternal health census data.
– The models’ prediction errors were lower at higher administrative unit levels.
– Improving spatial resolution and accuracy of input data had a more significant impact at higher administrative unit levels.
– The study validated the importance of spatial resolution and accuracy of maternal and perinatal health data in estimating pregnancies and live births.
Study Recommendations:
– More data collection techniques, such as comprehensive censuses like the CLIP project, are needed to improve the availability of datasets for populated areas.
– Projects should take advantage of mapping tools to fill gaps in data availability.
– The study suggests the need for ongoing efforts to improve the accuracy and resolution of demographic distribution datasets at subnational levels.
Key Role Players:
– Researchers and data analysts
– Government health departments
– Non-governmental organizations (NGOs)
– Community health workers
– Data collection teams
Cost Items for Planning Recommendations:
– Data collection equipment and materials
– Training and capacity building for data collection teams
– Transportation and logistics for data collection
– Data analysis software and tools
– Communication and dissemination of findings
– Monitoring and evaluation of data collection efforts

The strength of evidence for this abstract is 7 out of 10.
The evidence in the abstract is moderately strong. The study used specific data from the Community Level Intervention for Pre-eclampsia (CLIP) project and compared four models to assess the accuracy of global demographic distribution datasets. The analysis involved comparing prediction errors at different administrative unit levels. The study highlighted the impact of spatial resolution and accuracy of maternal and perinatal health data in modeling estimates of pregnancies and live births. To improve the evidence, the study could have included a larger sample size and conducted a more comprehensive data collection technique. Additionally, the study could have provided more details on the limitations and potential biases of the models used.

Background Existence of inequalities in quality and access to healthcare services at subnational levels has been identified despite a decline in maternal and perinatal mortality rates at national levels, leading to the need to investigate such conditions using geographical analysis. The need to assess the accuracy of global demographic distribution datasets at all subnational levels arises from the current emphasis on subnational monitoring of maternal and perinatal health progress, by the new targets stated in the Sustainable Development Goals. Methods The analysis involved comparison of four models generated using Worldpop methods, incorporating region-specific input data, as measured through the Community Level Intervention for Pre-eclampsia (CLIP) project. Normalised root mean square error was used to determine and compare the models’ prediction errors at different administrative unit levels. Results The models’ prediction errors are lower at higher administrative unit levels. All datasets showed the same pattern for both the live birth and pregnancy estimates. The effect of improving spatial resolution and accuracy of input data was more prominent at higher administrative unit levels. Conclusion The validation successfully highlighted the impact of spatial resolution and accuracy of maternal and perinatal health data in modelling estimates of pregnancies and live births. There is a need for more data collection techniques that conduct comprehensive censuses like the CLIP project. It is also imperative for such projects to take advantage of the power of mapping tools at their disposal to fill the gaps in the availability of datasets for populated areas.

Figure 1 shows the study sites in southern Mozambique. Data were collected in parts of the two provinces of Gaza and Maputo. The administrative unit divisions shown in the insert are the neighbourhood units (referred to as admin 5 units in this paper). The CLIP study represents a household census of all households in 12 villages with WRA (12–49 years) conducted from March to October 2014 in Maputo and Gaza provinces of southern Mozambique. The regions had to contain a minimum population of 25 000 inhabitants that would result in at least one maternal death per year as per data from the 2007 national census.33 34 The inclusion criterion for the WRA was having lived in the household for more than 30 days prior to the date of the census and having the intention to live in the household as a permanent resident for at least 6 months following the census.33 A total of 50 493 households and 80 483 WRA (mean age 26.9 years) were surveyed. Admin 5 level data for age-specific number of WRA, pregnancies and live births and GPS coordinates of the households with WRA were collected as part of the baseline work for the CLIP trial.33 Admin 5 boundaries were generated by creating Thiessen polygons around GPS points with the same neighbourhood name. Higher level administrative boundaries (admins 4, 3, 2 and 1) were then derived from these lower level data and the corresponding age structure data (http://www.ine.gov.mz/estatisticas/estatisticas-demograficas-e-indicadores-sociais/populacao/relatorio-de-indicadores-distritais-2007) joined to each layer. To the authors’ knowledge, the CLIP data on pregnancies and live births is the most granular dataset there is in this region of Mozambique. We also anticipate that due to the rigorous attempts to identify all WRA, by visiting all households in the study area, the data are likely the most accurate representation of pregnancies and livebirths in the study area, hence the choice to use the data as part of data creation and comparison processes. Study sites, Maputo and Gaza provinces in Southern Mozambique. Two models of live births and pregnancies were created, using admin 5 level data and the other using admin 3 level data. Births and pregnancy datasets were generated using Worldpop methods highlighted in James et al,35 with the addition of region-specific data as obtained through the CLIP project, including ASFRs, births-to-pregnancy ratios and number of births, pregnancies and WRA. Spreadsheets of ASFRs for admin 3 and admin 5 were generated by dividing age-specific births by age-specific WRA, while the pregnancy-to-birth multiplier was created for the study region by dividing the total number of pregnancies by total births for each admin 5 unit (and admin 3) and averaging the multipliers to get a value for the whole region. The Worldpop adjusted 2010–2015 population dataset36 was clipped to the extent of the study region and used in the generation of the age-specific WRA raster layers. These region-specific births and pregnancy datasets were created at varying spatial scales to determine the effect of input spatial resolution on model performance. To eliminate the error introduced by inaccurate census data, the births raster dataset was adjusted by multiplying it by the CLIP births raster at each admin 5. This step ensured the error in the adjusted births dataset would be due to disaggregation only. The three datasets used to create the WRA dataset were created using census data, which as stated above, can be inaccurate. The ASFR dataset used is the CLIP dataset, hence the dataset that needs adjusting is the WRA dataset, which can be adjusted by adjusting the births dataset. Adjusting this dataset was a method used to eliminate the error due to inaccurate input census data. The adjustment factor was computed using the formula below: The adjusted births dataset becomes: This was possible because the ASFR values used to create the dataset were computed from the CLIP data, meaning that adjusting the dataset using the number of births at each admin 5 unit resulted in adjusting the WRA computed using the age structure data and the Worldpop population dataset. This meant that the error in the resulting dataset was due to disaggregation. The process of recreating the datasets is shown in figure 2. Data generation process for model comparison. CLIP, Community Level Intervention for Pre-eclampsia. The analysis involved comparison of four models: (1) CLIP model only (thematic maps with corresponding values for live births and pregnancies generated from the household survey); (2) admin 5 Worldpop-CLIP model (Worldpop methods incorporating region-specific input data at admin 5 level, as measured through the CLIP project); (3) admin 3 Worldpop-CLIP model (Worldpop methods incorporating region-specific input data at admin 3 level, as measured through the CLIP project) and (4) Worldpop-only model, using standardised input data as published through the Worldpop project.29 To quantify the impact of the model performance on actual births/pregnancy estimates, we converted the Worldpop model outputs to centroid points of the 1 km grids and joined them to admin 5 polygons, by summing the values of the centroid points falling within each polygon, to generate admin 5 polygons with the corresponding values of estimates of live births. This resulted in a thematic map of estimated live births and pregnancies, aggregated to admin 5 level. The CLIP values of births and pregnancies in the excel sheet were also joined to the polygon, resulting in a layer with the following attributes: Name of admin 5-unit, Model 1 (CLIP only) births, Model 1 (CLIP only) pregnancies, Model 2 (Admin 5 Worldpop-CLIP) births. Model 2 (Admin 5 Worldpop-CLIP) pregnancies, Model 3 (Admin 3 Worldpop-CLIP) births, Model 3 (Admin 3 Worldpop-CLIP) pregnancies, Model 4 (Worldpop), births and Model 4 (Worldpop) pregnancies. For these analyses, we compared modelled birth outputs, as pregnancy outputs are dependent on birth estimates. These polygons were dissolved into admin 4 level polygons, creating a map of localities with the corresponding births and pregnancy values of each admin 4 unit for all models. The same was done to create a map of admin 3 units with corresponding values of live births. The process is shown in figure 3. Data preparation process for validation. CLIP, Community Level Intervention for Pre-eclampsia. To compare model prediction errors, we computed the root mean square error (RMSE) across the three administrative unit levels. To enable cross dataset and administrative unit comparison of the prediction errors, the normalised root mean square error (NRMSE) was used. The formulae for both error statistics is shown below: where ei is the difference between the ith observed (O) and predicted (P) value (Pi-Oi) and n is the number of units. where O− is the mean of the observed values. To determine the impact of input data on model performance, we calculated the difference in NRMSE between model 4 and models 2 and 3. The percentage decrease in prediction error was calculated by dividing the differences by the NRMSE of model 4 at different administrative unit levels and expressing it as a percentage. To quantify the contribution of spatial resolution to the prediction error (expressed as a percentage), the differences in percentage error decrease between models 2 and 3 were averaged. This average percentage value was translated as the proportion of the prediction error due to spatial resolution of input data. Each head of the household and WRA who participated provided informed consent and this was confirmed by their signature or fingerprint prior to data collection.33

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Based on the provided information, here are some potential innovations that can be used to improve access to maternal health:

1. Mobile Health (mHealth) Applications: Develop and implement mobile applications that provide pregnant women and new mothers with access to important maternal health information, such as prenatal care guidelines, nutrition advice, and reminders for medical appointments.

2. Telemedicine: Establish telemedicine programs that allow pregnant women in remote or underserved areas to consult with healthcare professionals through video calls or phone consultations. This can help address the shortage of healthcare providers in certain regions.

3. Community Health Workers: Train and deploy community health workers who can provide basic maternal health services, education, and support to pregnant women and new mothers in their communities. These workers can help bridge the gap between healthcare facilities and the community.

4. Maternal Health Vouchers: Implement voucher programs that provide pregnant women with financial assistance to access maternal health services, including prenatal care, delivery, and postnatal care. This can help reduce financial barriers to accessing healthcare.

5. Transportation Solutions: Develop innovative transportation solutions, such as mobile clinics or ambulances, to ensure that pregnant women can easily reach healthcare facilities for prenatal care, delivery, and emergency obstetric care.

6. Data Collection and Analysis: Improve data collection methods and use advanced analytics to accurately estimate birth and pregnancy rates at subnational levels. This can help identify areas with low access to maternal health services and inform targeted interventions.

7. Public-Private Partnerships: Foster collaborations between public and private sectors to improve access to maternal health services. This can involve leveraging private sector resources, expertise, and technology to expand healthcare infrastructure and services.

8. Maternal Health Education: Develop and implement comprehensive maternal health education programs that target women, families, and communities. These programs can raise awareness about the importance of prenatal care, safe delivery practices, and postnatal care.

9. Maternal Health Financing: Explore innovative financing mechanisms, such as microinsurance or community-based health financing, to ensure that pregnant women have access to affordable and quality maternal health services.

10. Quality Improvement Initiatives: Implement quality improvement initiatives in healthcare facilities to enhance the quality of maternal health services, including training healthcare providers, improving infrastructure, and ensuring the availability of essential medical supplies and equipment.
AI Innovations Description
Based on the provided description, the recommendation to improve access to maternal health would be to implement comprehensive census projects, similar to the Community Level Intervention for Pre-eclampsia (CLIP) project, in order to collect accurate and granular data on pregnancies and live births. These projects should aim to visit all households in the study area to identify all women of reproductive age (WRA) and collect data on pregnancies and live births. Additionally, mapping tools should be utilized to fill gaps in the availability of datasets for populated areas. By improving the spatial resolution and accuracy of maternal and perinatal health data, more accurate estimates can be generated, which can help identify and address inequalities in access to healthcare services at subnational levels.
AI Innovations Methodology
Based on the provided description, here are some potential recommendations to improve access to maternal health:

1. Increase data collection techniques: Conduct comprehensive censuses like the CLIP project to gather more accurate and granular data on pregnancies and live births in the study area. This will help in identifying gaps in maternal and perinatal health and enable targeted interventions.

2. Improve spatial resolution and accuracy of input data: Use mapping tools and technologies to enhance the spatial resolution and accuracy of maternal and perinatal health data. This will provide a more detailed understanding of the distribution of healthcare services and help in identifying areas with limited access.

3. Implement subnational monitoring: Emphasize subnational monitoring of maternal and perinatal health progress to identify and address inequalities in quality and access to healthcare services at the local level. This will enable targeted interventions and resource allocation based on specific needs of different regions.

4. Utilize innovative models: Explore the use of innovative models, such as the Worldpop methods, to generate estimates and predictions related to maternal health. These models can incorporate region-specific input data and help in simulating the impact of different interventions on improving access to maternal health.

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

1. Define the indicators: Identify key indicators that reflect access to maternal health, such as the number of healthcare facilities, distance to the nearest facility, availability of skilled healthcare providers, and utilization rates of maternal health services.

2. Collect baseline data: Gather baseline data on the identified indicators in the study area. This can be done through surveys, interviews, and data collection from relevant sources such as health facilities and government records.

3. Develop a simulation model: Create a simulation model that incorporates the baseline data and the recommended innovations. This model should consider factors such as population distribution, healthcare infrastructure, and resource allocation.

4. Define scenarios: Define different scenarios based on the recommended innovations. For example, one scenario could involve increasing the number of healthcare facilities in underserved areas, while another scenario could focus on improving the training and deployment of skilled healthcare providers.

5. Simulate the impact: Run the simulation model for each scenario and analyze the results. Assess the changes in the identified indicators and evaluate the impact of the recommended innovations on improving access to maternal health.

6. Validate the results: Validate the simulation results by comparing them with real-world data and feedback from stakeholders. This will help ensure the accuracy and reliability of the simulation model.

7. Refine and iterate: Based on the validation and feedback, refine the simulation model and repeat the simulation process if necessary. Continuously iterate and improve the model to enhance its accuracy and effectiveness in simulating the impact of different interventions on improving access to maternal health.

By following this methodology, policymakers and healthcare providers can gain insights into the potential impact of different innovations on improving access to maternal health. This can inform decision-making and resource allocation to effectively address the identified gaps and inequalities in maternal healthcare.

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