Assessment of measles immunity among infants in Maputo City, Mozambique

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Study Justification:
– The study aims to assess the presence of measles antibodies among infants in Maputo City, Mozambique.
– The study also aims to evaluate the effectiveness of the current measles immunization policy in the context of the current epidemiological scenario.
– The findings of this study will provide valuable information for policymakers and health authorities to re-evaluate and potentially adjust the measles vaccination schedule in Mozambique.
Study Highlights:
– The study was conducted in Maputo City, the capital of Mozambique, with a population of 1.5 million people.
– The study included six- and nine-month-old children and their mothers.
– Measles-specific antibodies were screened in oral fluid samples collected from the participants.
– The study found that 82.4% of children lost maternal antibodies by six months, indicating a need for vaccination.
– 30.5% of nine-month-old children had antibodies in oral fluid before vaccination, suggesting contact with the wild-type measles virus.
– The seroconversion rate after vaccination was 84.2%, indicating a good response to the vaccine.
Recommendations for Lay Reader:
– The study suggests that the current measles immunization policy in Mozambique needs to be re-evaluated.
– It is recommended to consider adjusting the measles vaccination schedule based on the findings of this study.
– The study highlights the importance of measles vaccination for infants to protect them from the disease.
Recommendations for Policy Maker:
– The study recommends re-evaluating the effectiveness of the current measles immunization policy in Mozambique.
– Based on the findings, policymakers should consider adjusting the measles vaccination schedule to ensure optimal protection for infants.
– It is important to prioritize measles vaccination campaigns and ensure high coverage to prevent the transmission of the wild-type measles virus.
Key Role Players:
– Ministry of Health (MoH) in Mozambique
– Mozambican Health Bioethics Committee
– Health-centres in Maputo City
– General hospital in Maputo City
– Researchers and scientists involved in the study
Cost Items for Planning Recommendations:
– Vaccine procurement and distribution
– Training and capacity building for healthcare workers
– Public awareness campaigns and communication materials
– Monitoring and evaluation activities
– Research and data collection expenses
– Laboratory testing and analysis
– Administrative and logistical support

The strength of evidence for this abstract is 7 out of 10.
The evidence in the abstract is moderately strong. The study provides data on measles immunity among infants in Maputo City, Mozambique. The study design is cross-sectional, which limits the ability to establish causality. However, the study includes a large sample size and uses a non-invasive method to assess measles antibodies. The study also reports a high seroconversion rate after vaccination. To improve the strength of the evidence, future studies could consider using a longitudinal design to establish causality and include a control group for comparison.

Background. The optimum age for measles vaccination varies from country to country and thus a standardized vaccination schedule is controversial. While the increase in measles vaccination coverage has produced significant changes in the epidemiology of infection, vaccination schedules have not been adjusted. Instead, measures to cut wild-type virus transmission through mass vaccination campaigns have been instituted. This study estimates the presence of measles antibodies among six- and nine-month-old children and assesses the current vaccination seroconversion by using a non invasive method in Maputo City, Mozambique. Methods. Six- and nine-month old children and their mothers were screened in a cross-sectional study for measles-specific antibodies in oral fluid. All vaccinated children were invited for a follow-up visit 15 days after immunization to assess seroconversion Results. 82.4% of the children lost maternal antibodies by six months. Most children were antibody-positive post-vaccination at nine months, although 30.5 % of nine month old children had antibodies in oral fluid before vaccination. We suggest that these pre-vaccination antibodies are due to contact with wild-type of measles virus. The observed seroconversion rate after vaccination was 84.2% Conclusion. These data indicate a need to re-evaluate the effectiveness of the measles immunization policy in the current epidemiological scenario. © 2008 Jani et al; licensee BioMed Central Ltd.

This study was conducted in Maputo City, the capital of Mozambique, which has an estimated population of 1.5 million people. Health services in Maputo are organized in three districts, each served by several health-centres and a general hospital. Health-centres offer a free health program for all children under the age of five-years. The program includes immunization, growth monitoring and nutritional rehabilitation. Subjects were recruited at the Xipamanine health-centre and the 1° de Junho health-centre located in the urban districts number four and two of Maputo City. The urban districts number four and two have 300,703 and 534,744 inhabitants and reported measles vaccine coverage of 80% and 83%, respectively (district midterm reports to MoH, unpublished document, 2005). The study was performed between June and September 2005, just before the 2005 measles national mass vaccination campaign. According to the EPI schedule in Mozambique, children are routinely immunized with a single dose of standard titre measles vaccine at nine months of age. At the time when the study was conducted, the measles vaccine in use was based on Edmonston-Zagreb strain (E-Z). Mothers of six-month-old children coming for growth monitoring and of nine-month-old children visiting the health-centre for measles immunization were invited to participate in the study. All children and their respective mothers were screened in a cross-sectional study for measles-specific antibodies in oral fluid. Additionally, all children at nine-months of age were invited to donate a second specimen of oral fluid during a follow-up visit 15 days after vaccination. This study was approved by the Mozambican Health Bioethics Committee. Informed consent was obtained by a signature or finger print from mothers after explaining the project aims, the procedures for data and specimen collection, and the need to return for post-vaccination control among those vaccinated. Data was collected using a structured questionnaire. The age of each child was calculated from the date of birth recorded on the Road-to-Health Card. The age of the mother was based on her verbal statement. A birth was considered to be premature if the baby was born at less than 37 weeks of gestation. This information was collected from the mother’s Pregnancy-Monitoring Card. A baby with a birth weight less than 2,500 grams was defined as having low-birth-weight. This information was collected from the Road-to-Health Card. On admission, the children were weighed (grams) and measured (centimetres). The anthropometric indices weight-for-age, height-for-age and weight-for-height were compared with mean Z-scores to access the nutritional status of the children. Minus two Z-scores were used as cut-off values for low height-for-age, weight-for-age and weight-for-height indices. The immunization status of the mothers was confirmed by the Road-to-Health Card when possible. A verbal history of immunization of the mother with no card for confirmation was categorized as a “history of immunization”. Mothers with no knowledge of their past immunization were classified as having an “unknown” status. A past history of measles disease in the infant and in the mother was collected by verbal history using the World Health Organization case definition [18]. The mother’s reproductive history was collected from the last gestation Pregnancy-Monitoring Card retained by the mother. Verbal information was not considered. Oral fluid was collected using the OraSure device (OraSure Technologies, Bethlehem, PA, USA). The collection device consists of a 3 cm × 1 cm flat pad of absorbent material supported by a 10 cm plastic stick. This device is supplied with a tube containing transport buffer and a preservative [19,20]. The absorbent pad was moved gently 4–10 times along the gums and left stationary between the lower gum and buccal membrane for a minimum of two minutes or until the pad was saturated with oral fluid. Thereafter, the collection device was placed in the pre-coded tube containing the buffer. The pads with oral fluid samples were transported to the laboratory at the Instituto Nacional de Saúde every day. There, tubes were centrifuged at 2000 rpm for five minutes. The fluid was then transferred into a screw-capped vial and stored at -20°C until testing. Oral fluid specimens were screened for measles-specific IgG and IgM using the MicroImmune® test (MicroImmune Ltd, UK). Both assays are capture EIAs and clasiify antibody status as positive, negative and borderline. The IgM test has a reported sensitivity and specificity of 100.0% (95% CI 85.2–100.0) and 96.6% (95% CI 90.7–99.3), respectively [17]. The sensitivity and specificity of the IgG assay are 97.5% (95% CI 96.1–98.3) and 86.7% (95% CI 78.4–91.5), respectively [16,21]. Proportions and chi-square were used as a statistical test at a 5% significance level. The differences in mothers’ ages were assessed by one way analysis of variance. Statistical procedures were performed using the Statistical Package for the Social Sciences (SPSS) version 15.0. Seroconversion was expressed as the proportion of seronegative children before vaccination who became positive for measles-specific antibody (IgM and IgG) 15 days after vaccination. The statistical difference in the proportions was compared using chi-square test with a 5% significance level. Samples with borderline results were excluded from this analysis.

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

1. Mobile clinics: Implementing mobile clinics that can travel to different areas within Maputo City, especially in underserved or remote areas, to provide maternal health services including immunizations, growth monitoring, and nutritional rehabilitation.

2. Community health workers: Training and deploying community health workers who can provide education, support, and basic healthcare services to pregnant women and new mothers in their own communities.

3. Telemedicine: Utilizing telemedicine technology to connect pregnant women and new mothers with healthcare professionals remotely, allowing them to receive medical advice, counseling, and support without having to travel to a healthcare facility.

4. Health education campaigns: Conducting targeted health education campaigns to raise awareness about the importance of maternal health, including the benefits of immunization, and addressing any misconceptions or concerns that may exist within the community.

5. Improving vaccine supply chain: Implementing strategies to ensure a consistent and reliable supply of vaccines, including proper storage and distribution, to ensure that all eligible pregnant women and new mothers have access to measles vaccination.

6. Strengthening healthcare infrastructure: Investing in the improvement and expansion of healthcare facilities, particularly in underserved areas, to ensure that there are enough resources and capacity to provide quality maternal health services.

7. Public-private partnerships: Collaborating with private sector organizations, such as pharmaceutical companies or technology companies, to leverage their resources, expertise, and networks to improve access to maternal health services, including immunizations.

8. Data-driven decision making: Collecting and analyzing data on maternal health indicators, including vaccination coverage rates, to identify gaps and prioritize interventions that can improve access to maternal health services, including measles immunization.

9. Maternal health incentives: Implementing incentive programs, such as providing vouchers or financial incentives, to encourage pregnant women and new mothers to seek and receive maternal health services, including immunizations.

10. Policy advocacy: Advocating for policy changes at the national and local levels to prioritize maternal health and ensure that resources are allocated to improve access to maternal health services, including measles immunization.
AI Innovations Description
The recommendation that can be developed into an innovation to improve access to maternal health based on the study is to re-evaluate the effectiveness of the measles immunization policy in Mozambique. The study found that a significant number of nine-month-old children had measles antibodies before vaccination, indicating possible contact with the wild-type measles virus. This suggests that the current immunization schedule may not be adequately protecting children against measles.

To address this issue and improve access to maternal health, the following steps can be taken:

1. Conduct a comprehensive review of the current measles immunization policy in Mozambique, taking into account the findings of the study and the current epidemiological scenario.

2. Consider adjusting the vaccination schedule to ensure optimal protection against measles. This may involve administering the measles vaccine at an earlier age or providing additional booster doses.

3. Strengthen the monitoring and evaluation of measles vaccination coverage to ensure that all eligible children are receiving the vaccine.

4. Implement targeted vaccination campaigns in areas with low vaccination coverage or high measles transmission rates.

5. Improve public awareness and education about the importance of measles vaccination and the potential risks of not vaccinating.

6. Enhance the capacity of healthcare providers to administer and monitor measles vaccinations effectively.

By implementing these recommendations, Mozambique can improve access to maternal health by ensuring that children are adequately protected against measles, reducing the burden of the disease, and ultimately improving overall maternal and child health outcomes.
AI Innovations Methodology
Based on the provided information, here are some potential recommendations to improve access to maternal health:

1. Strengthening immunization programs: This study highlights the need to re-evaluate the effectiveness of the measles immunization policy in Mozambique. One recommendation could be to strengthen immunization programs by ensuring that all children receive the measles vaccine at the recommended age. This could involve improving vaccine supply chains, training healthcare workers, and raising awareness among parents about the importance of timely vaccination.

2. Enhancing antenatal care services: Antenatal care plays a crucial role in promoting maternal and child health. To improve access to maternal health, it is important to enhance antenatal care services. This could include increasing the number of healthcare facilities offering antenatal care, improving the quality of care provided, and promoting early and regular attendance by pregnant women.

3. Implementing community-based interventions: Community-based interventions can help improve access to maternal health services, especially in remote or underserved areas. These interventions could involve training community health workers to provide basic maternal health services, conducting outreach programs to raise awareness about maternal health, and establishing referral systems to ensure timely access to higher-level care when needed.

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

1. Define indicators: Identify key indicators that reflect access to maternal health, such as vaccination coverage, antenatal care attendance rates, and availability of skilled birth attendants. These indicators will be used to measure the impact of the recommendations.

2. Collect baseline data: Gather baseline data on the selected indicators before implementing the recommendations. This could involve conducting surveys, reviewing existing data sources, and analyzing relevant statistics.

3. Implement interventions: Implement the recommended interventions, such as strengthening immunization programs, enhancing antenatal care services, and implementing community-based interventions. Ensure that these interventions are implemented consistently and monitored closely.

4. Collect post-intervention data: After a sufficient period of time, collect post-intervention data on the selected indicators. This could involve conducting follow-up surveys, reviewing updated data sources, and analyzing relevant statistics.

5. Analyze and compare data: Compare the baseline and post-intervention data to assess the impact of the recommendations on improving access to maternal health. Use appropriate statistical methods to analyze the data and determine if there have been significant improvements in the selected indicators.

6. Evaluate and refine: Evaluate the results of the simulation and identify any areas that require further improvement. Refine the recommendations and interventions based on the findings to ensure continuous progress in improving access to maternal health.

By following this methodology, policymakers and healthcare professionals can assess the effectiveness of different interventions and make informed decisions to improve access to maternal health.

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