Acceptability and Potential Effectiveness of eHealth Tools for Training Primary Health Workers from Nigeria at Scale: Mixed Methods, Uncontrolled Before-and-After Study

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Study Justification:
– In-service training of frontline health workers (FHWs) in primary health care facilities is important for improving healthcare delivery.
– Traditional training methods are expensive and require FHWs to leave their posts in rural areas.
– This study aims to determine the feasibility and acceptability of using digital health tools, specifically video training (VTR), to provide in-service training at scale without interrupting health services.
Study Highlights:
– A mixed methods design, including an uncontrolled before-and-after evaluation, was used.
– The VTR intervention was delivered to FHWs in 3 states of Nigeria.
– The study found that FHWs’ knowledge and confidence in delivering maternal, newborn, and child health (MNCH) services significantly improved after the intervention.
– Stakeholder interviews indicated wide acceptance of VTR as an important tool for enhancing training quality and improving health outcomes.
– The study identified barriers to adoption, such as poor electricity supply and internet connection, as well as FHWs’ workload.
Study Recommendations:
– Further research is needed to explore the translation of this digital health approach for training FHWs in low-resource settings.
– The study highlights the need to address barriers to adoption, such as improving electricity supply and internet connectivity.
– Policy makers should consider the cost-effectiveness of implementing VTR interventions and providing access to technology and training contents.
Key Role Players:
– Frontline health workers (FHWs)
– Facility managers
– Policy makers
– Research team
– Intervention support staff
Cost Items for Planning Recommendations:
– Improving electricity supply
– Enhancing internet connectivity
– Providing tablet computers with VTR apps
– Developing and hosting educational videos
– Training FHWs on using eHealth interventions
– Monitoring and evaluation of the intervention
Please note that the cost items provided are examples and not actual cost estimates. The actual cost will depend on various factors and should be determined through detailed planning and budgeting.

The strength of evidence for this abstract is 7 out of 10.
The evidence in the abstract is based on a mixed methods, uncontrolled before-and-after study. The study included a sample size of 328 frontline health workers in Nigeria and examined changes in their knowledge and confidence in delivering maternal, newborn, and child health (MNCH) services through a pre- and posttest survey. The study found a mean increase of 17 percentage points in test scores after the intervention. Stakeholder interviews also indicated wide acceptance of the digital health tool. However, the study design lacks a control group, which limits the ability to establish causality. To improve the evidence, future research could include a randomized controlled trial with a larger sample size and longer follow-up period to assess the sustained impact of the intervention.

Background: The in-service training of frontline health workers (FHWs) in primary health care facilities plays an important role in improving the standard of health care delivery. However, it is often expensive and requires FHWs to leave their posts in rural areas to attend courses in urban centers. This study reports the implementation of a digital health tool for providing video training (VTR) on maternal, newborn, and child health (MNCH) care to provide in-service training at scale without interrupting health services. The VTR intervention was supported by satellite communications technology and existing 3G mobile networks. Objective: This study aims to determine the feasibility and acceptability of these digital health tools and their potential effectiveness in improving clinical knowledge, attitudes, and practices related to MNCH care. Methods: A mixed methods design, including an uncontrolled pre- and postquantitative evaluation, was adopted. From October 2017 to May 2018, a VTR mobile intervention was delivered to FHWs in 3 states of Nigeria. We examined changes in workers’ knowledge and confidence in delivering MNCH services through a pre- and posttest survey. Stakeholders’ experiences with the intervention were explored through semistructured interviews that drew on the technology acceptance model to frame contextual factors that shaped the intervention’s acceptability and usability in the work environment. Results: In total, 328 FHWs completed both pre- and posttests. FHWs achieved a mean pretest score of 51% (95% CI 48%-54%) and mean posttest score of 69% (95% CI 66%-72%), reflecting, after adjusting for key covariates, a mean increase between the pre- and posttest of 17 percentage points (95% CI 15-19; P80% power to detect an overall increase of 20 percentage points between the pre- and posttest scores, assuming the most conservative overall prescore of 50%, using a two-sided hypothesis test with a significance level of 0.05 and assuming a modest, typical design effect of 1.5, in the absence of any comparable or pilot data, and 10% loss to follow-up. To describe the characteristics of FHWs and health facilities in our study sample, we produced relevant descriptive statistics. To estimate the change in the overall FHW test score results between the pre- and posttests, we first fitted a multilevel linear regression model with the outcome of test score (including both pre- and posttest scores for every FHW with complete data) and fixed effects for the test period (pre- or posttest), gender (male or female), staff type (CHEW or nurses and midwives [merged due to low sample sizes]), facility type (PHC or comprehensive health centers, or health post and basic health centers [merged due to low sample sizes]), facility SatCom status (yes or no), state (Ondo, FCT, or Kano), and the number of days between FHWs’ pre- and posttests. The model also included a random intercept for individual FHWs to account for the repeated outcomes within individuals (ie, the pre- and posttest scores) and a separate random intercept for health facilities to account for any clustering effects at the health facility level. Using the fitted model, we then estimated the overall mean pre- and posttest scores, and the overall posttest minus pretest change in test scores (ie, the estimated change from before to after the intervention), along with the associated 95% CI and P values of these means. The means were based on estimated marginal means, also known as least-squares means or adjusted means, as calculated from the fitted model. The estimated marginal means assume a balanced population across all covariates, and when estimating them, we set the only numerical variable in the model (days between pre- and posttest) to its mean value across the sample. We then estimated test score results within the following mutually exclusive sets of subgroups: (1) male or female FHWs; (2) CHEWs, or nurses and midwives; (3) FHWs in PHCs, or FHWs in comprehensive health centers or FHWs in health posts and basic health centers; (4) FHWs in facilities with SatCom available or FHWs in facilities without the availability of SatCom; and (5) FHWs based in facilities located in Ondo, FCT, or Kano states. To calculate these results, for each set of subgroups, we fitted the same multilevel linear regression model described above, but with an additional term for the interaction between the test period (pre or post) and the relevant categorical variable defining the relevant set of subgroups (eg, gender for male or female FHWs). Using each of these models, we then estimated the pre- and posttest scores and the posttest minus pretest change in the test score for each subgroup, along with the associated 95% CI and P values. Within each set of subgroups, we then explored whether the observed changes in test scores between the pre- and posttest periods differed between each subgroup (eg, male vs female FHWs). To do this, we used the same models with interaction terms described above to calculate the differences in estimated test score changes (from pre to post) between the relevant subgroups, taking one subgroup within each set as the reference or comparison group, along with their associated 95% CI and P values (again based on estimated marginal means). Finally, we also calculated adjusted overall posttest scores and their 95% CI for each separate topic covered by the test, by repeatedly fitting multilevel linear regression models with outcomes of each topic-specific posttest score, in turn, and independent variables and random intercepts that were the same as described above for the overall primary outcome analysis, excluding a variable for the test period. For all analyses, we excluded observations (FHWs) if they were missing any outcome or required covariate data (ie, complete case analyses). We calculated CI and P values based on t statistics using the Kenward–Roger degrees of freedom approximation. We checked for adherence or violation of model assumptions using the standard range of residual and influence plots for multilevel linear regression models, but found no issues. All results were calculated using R version 3.5.2 statistical software (R Foundation for Statistical Computing) [22], with all models fitted using the lme4 package [23], and all estimated marginal means calculated using the emmeans package [24]. To assess the acceptability and feasibility of using the VTR mobile education intervention, we conducted face-to-face semistructured qualitative interviews with 34 participants in 3 states—12 FHWs, 12 facility managers, and 10 policy makers. Participants were recruited between February 19 and March 9, 2018. Interviews were conducted by 4 medical doctors (KO, AA, OD, and RMY) and a sociologist (DA), who were trained in qualitative interviewing techniques. Only 1 of the 5 data collectors was a female (OD). The research staff provided study information sheets to potential participants to help them understand the objectives of and decide whether to participate in the study. Participants were given at least 24 hours to express interest in participating in the study. Interview guides (Multimedia Appendix 2) were pretested before they were administered to the field. Interviews, which lasted about 30 minutes each, were conducted in a private setting in the workplace of respondents, audio-recorded, transcribed verbatim, and where appropriate, translated into English for analysis. The framework approach was used for analysis, while allowing for the emergence of new themes. The framework analysis involves the stages of familiarization with data, coding (done by the 5 interviewers above), indexing and charting, mapping, and interpretation [25]. The analysis was performed manually. We drew on the technology acceptance model (TAM) to help explain stakeholders’ acceptance and use of VTR Mobile intervention in the workplace environment [26]. The TAM proposes that an individual’s acceptability of (ie, intent to use) and use behavior (ie, actual use) of a technology is determined by two variables. These are the perceived usefulness of the technology to enhance job performance, and the perceived ease of use of the technology, that is, the effort needed to learn and use a given technology. An individual’s motivation to use an emerging technology is higher if the technology is easy to use. The TAM also proposes that factors such as an individual’s understanding of a technology and organizational support measures have positive effects on the perception of usefulness and adoption of technology. Approval for the study was granted by the University of Leeds School of Medicine Research Ethics Committee (MREC16-178) and the Ondo State Government Ministry of Health (AD.4693 Vol. II/109), the Kano State Ministry of Health (MOH/Off/797/T1/350), and the Federal Capital Health Research Ethics Committee (FHREC/2017/01/42/12-05-17).

The recommendation based on the study is to develop and implement eHealth tools, specifically video training (VTR) on maternal, newborn, and child health (MNCH) care, to provide in-service training for frontline health workers (FHWs) in primary health care facilities. This digital health tool can be delivered through computer tablets with a VTR app, enabling FHWs in rural areas to access high-quality training videos and learning content without the need to travel to urban centers for training. The VTR intervention can be supported by satellite communications technology and existing 3G mobile networks to ensure connectivity.

To implement this recommendation, the following steps can be taken:

1. Develop a comprehensive curriculum: Collaborate with relevant stakeholders, including state ministries of health and experts in obstetrics and gynecology, to develop a curriculum that covers key MNCH topics. Ensure that the curriculum aligns with federal government and WHO guidelines for maternal and child health.

2. Create high-quality training videos: Partner with organizations like Medical Aid Films and Global Health Media Project to develop educational videos that provide clear educational content and engage clinical scenarios focused on MNCH care. These videos should be accessible through the VTR app.

3. Provide training and support: Train FHWs on how to use the eHealth intervention, including the VTR app and tablet computers. Provide ongoing technical support to address any issues or challenges faced by the FHWs during the training process.

4. Ensure connectivity: Establish a reliable internet connection in rural primary health care facilities, either through existing 3G mobile networks or satellite communications technology. This will enable FHWs to access the VTR app and other online learning resources.

5. Monitor and evaluate: Continuously monitor the implementation of the eHealth intervention and evaluate its impact on FHWs’ knowledge, attitudes, and practices related to MNCH care. Collect data on test scores, user feedback, and health outcomes to assess the effectiveness of the intervention.

6. Address barriers: Identify and address barriers to the adoption of the eHealth intervention, such as poor electricity supply and poor internet connection. Explore solutions, such as alternative power sources and infrastructure improvements, to ensure uninterrupted access to the VTR app.

7. Scale up the intervention: Based on the positive results and feedback, consider scaling up the eHealth intervention to reach a larger number of FHWs in rural areas. Collaborate with government agencies, non-profit organizations, and other stakeholders to secure funding and support for the expansion of the intervention.

By implementing these recommendations, access to maternal health can be improved by providing cost-effective and scalable training opportunities for FHWs in rural areas, ultimately leading to better health outcomes for mothers and children.
AI Innovations Description
The recommendation based on the study is to develop and implement eHealth tools, specifically video training (VTR) on maternal, newborn, and child health (MNCH) care, to provide in-service training for frontline health workers (FHWs) in primary health care facilities. This digital health tool can be delivered through computer tablets with a VTR app, enabling FHWs in rural areas to access high-quality training videos and learning content without the need to travel to urban centers for training. The VTR intervention can be supported by satellite communications technology and existing 3G mobile networks to ensure connectivity.

The study found that the use of VTR mobile intervention significantly improved FHWs’ clinical knowledge, attitudes, and reported practices related to MNCH care. The mean increase in test scores between the pre- and posttest was 17 percentage points. Stakeholder interviews also indicated a wide acceptance of VTR mobile as an important tool for enhancing the quality of training and improving health outcomes.

To implement this recommendation, the following steps can be taken:

1. Develop a comprehensive curriculum: Collaborate with relevant stakeholders, including state ministries of health and experts in obstetrics and gynecology, to develop a curriculum that covers key MNCH topics. Ensure that the curriculum aligns with federal government and WHO guidelines for maternal and child health.

2. Create high-quality training videos: Partner with organizations like Medical Aid Films and Global Health Media Project to develop educational videos that provide clear educational content and engage clinical scenarios focused on MNCH care. These videos should be accessible through the VTR app.

3. Provide training and support: Train FHWs on how to use the eHealth intervention, including the VTR app and tablet computers. Provide ongoing technical support to address any issues or challenges faced by the FHWs during the training process.

4. Ensure connectivity: Establish a reliable internet connection in rural primary health care facilities, either through existing 3G mobile networks or satellite communications technology. This will enable FHWs to access the VTR app and other online learning resources.

5. Monitor and evaluate: Continuously monitor the implementation of the eHealth intervention and evaluate its impact on FHWs’ knowledge, attitudes, and practices related to MNCH care. Collect data on test scores, user feedback, and health outcomes to assess the effectiveness of the intervention.

6. Address barriers: Identify and address barriers to the adoption of the eHealth intervention, such as poor electricity supply and poor internet connection. Explore solutions, such as alternative power sources and infrastructure improvements, to ensure uninterrupted access to the VTR app.

7. Scale up the intervention: Based on the positive results and feedback, consider scaling up the eHealth intervention to reach a larger number of FHWs in rural areas. Collaborate with government agencies, non-profit organizations, and other stakeholders to secure funding and support for the expansion of the intervention.

By implementing these recommendations, access to maternal health can be improved by providing cost-effective and scalable training opportunities for FHWs in rural areas, ultimately leading to better health outcomes for mothers and children.
AI Innovations Methodology
To simulate the impact of the main recommendations on improving access to maternal health, a methodology could be developed as follows:

1. Define the target population: Identify the specific population that will benefit from the implementation of eHealth tools, such as frontline health workers (FHWs) in primary health care facilities in rural areas.

2. Collect baseline data: Gather data on the current knowledge, attitudes, and practices of FHWs related to maternal, newborn, and child health (MNCH) care. This can be done through surveys, interviews, or other data collection methods.

3. Develop a simulation model: Create a simulation model that represents the target population and incorporates the main recommendations, such as the implementation of video training (VTR) through computer tablets with a VTR app.

4. Implement the recommendations in the simulation model: Introduce the eHealth tools, including the VTR app, into the simulation model. This can be done by providing access to the training videos and learning content to the simulated FHWs in rural areas.

5. Simulate the impact: Run the simulation model to simulate the impact of the recommendations on FHWs’ knowledge, attitudes, and practices related to MNCH care. Measure the changes in test scores, attitudes, and reported practices based on the simulated implementation of the eHealth tools.

6. Analyze the results: Analyze the simulated data to determine the effectiveness of the recommendations in improving access to maternal health. Assess the changes in FHWs’ knowledge, attitudes, and practices and evaluate the impact on health outcomes.

7. Validate the simulation model: Validate the simulation model by comparing the simulated results with real-world data. This can be done by comparing the simulated changes in test scores, attitudes, and reported practices with the actual changes observed in the baseline data.

8. Refine the simulation model: Make adjustments to the simulation model based on the validation results. Fine-tune the model to ensure its accuracy and reliability in predicting the impact of the recommendations on improving access to maternal health.

9. Conduct sensitivity analyses: Perform sensitivity analyses to assess the robustness of the simulation results. Explore different scenarios and variables to understand the potential variations in the impact of the recommendations.

10. Communicate the findings: Summarize the simulation findings in a clear and concise manner. Present the results to stakeholders, policymakers, and other relevant parties to inform decision-making and facilitate the implementation of the recommendations.

By following this methodology, stakeholders can gain insights into the potential impact of implementing the recommendations on improving access to maternal health. The simulation results can inform the planning and decision-making processes, leading to more effective and targeted interventions for maternal health.

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