Impact of mothers’ schistosomiasis status during gestation on children’s IgG antibody responses to routine vaccines 2 years later and anti-schistosome and anti-malarial responses by neonates in western Kenya

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Study Justification:
This study aimed to investigate the impact of mothers’ schistosomiasis status during pregnancy on their children’s immune responses to routine vaccines and their susceptibility to schistosomes and malaria. The study aimed to provide additional data to the ongoing discussions on the potential consequences of parasitic infections on immune responsiveness and vaccine efficacy.
Highlights:
– The study enrolled 99 pregnant women in western Kenya and determined their schistosomiasis and malaria infection status.
– At 2 years of age, the children’s IgG antibody levels to tetanus, diphtheria, and measles antigens were measured using a multiplex assay.
– The study found that mothers’ infections with either malaria or schistosomiasis did not impact the antibody responses of their children to tetanus and diphtheria antigens.
– However, children born to schistosomiasis-positive mothers had lower levels of anti-measles antibodies and a lower proportion of them developed protective levels of antibodies to measles antigen.
– The study also found that a percentage of the children acquired schistosomes and malaria during the first 2 years of life.
Recommendations:
Based on the findings of the study, the following recommendations can be made:
1. Further research is needed to understand the mechanisms behind the lower levels of anti-measles antibodies in children born to schistosomiasis-positive mothers.
2. Public health programs should consider the potential impact of maternal schistosomiasis on measles vaccine efficacy and explore strategies to improve the immune response in these children.
3. Continued monitoring and control efforts for schistosomiasis and malaria should be implemented to reduce the risk of infection in children.
Key Role Players:
To address the recommendations, the following key role players are needed:
1. Researchers and scientists to conduct further studies on the mechanisms of immune response and vaccine efficacy in children born to schistosomiasis-positive mothers.
2. Public health officials and policymakers to incorporate the findings of this study into vaccination programs and develop strategies to improve vaccine efficacy in high-risk populations.
3. Healthcare providers to educate pregnant women about the potential impact of parasitic infections on their children’s immune responses and the importance of preventive measures.
Cost Items:
While the actual cost is not provided, the following cost items should be considered in planning the recommendations:
1. Research funding for further studies on immune response and vaccine efficacy.
2. Implementation costs for incorporating the findings into vaccination programs, including training healthcare providers and updating educational materials.
3. Costs associated with monitoring and control efforts for schistosomiasis and malaria, such as diagnostic tests, treatment, and preventive measures.

The strength of evidence for this abstract is 7 out of 10.
The evidence in the abstract is rated 7 because it presents findings from a longitudinal serologic study conducted over a 4-year period. The study enrolled 99 pregnant women in western Kenya and monitored their children’s antibody responses to routine vaccines and parasite antigens. The study provides data on the impact of maternal schistosomiasis infection on children’s antibody responses to vaccines and suggests that children born to S. mansoni-positive mothers had lower levels of anti-measles antibodies. The study also reports on the acquisition of schistosomes and falciparum malaria by the children. The evidence is based on a relatively large sample size and includes statistical analyses. However, the abstract does not provide specific details about the study design, methods, or statistical tests used, which could be improved to enhance the clarity and transparency of the findings.

The potential consequences of parasitic infections on a person’s immune responsiveness to unrelated antigens are often conjectured upon in relationship to allergic responses and autoimmune diseases. These considerations sometimes extend to whether parasitic infection of pregnant women can influence the outcomes of responses by their offspring to the immunizations administered during national Expanded Programs of Immunization. To provide additional data to these discussions, we have enrolled 99 close-to-term pregnant women in western Kenya and determined their Schistosoma mansoni and Plasmodium falciparum infection status. At 2 years of age, when the initial immunization schedule was complete, we determined their children’s IgG antibody levels to tetanus toxoid, diphtheria toxoid, and measles nucleoprotein (N-protein) antigens using a multiplex assay. We also monitored antibody responses during the children’s first 2 years of life to P. falciparum MSP119 (PfMSP119), S. mansoni Soluble Egg Antigen (SEA), Ascaris suum hemoglobin (AsHb), and Strongyloides stercoralis (SsNIE). Mothers’ infections with either P. falciparum or S. mansoni had no impact on the level of antibody responses of their offspring or the proportion of offspring that developed protective levels of antibodies to either tetanus or diphtheria antigens at 2 years of age. However, children born of S. mansoni-positive mothers and immunized for measles at 9 months of age had significantly lower levels of anti-measles N-protein antibodies when they were 2 years old (p = 0.007) and a lower proportion of these children (62.5 vs. 90.2%, OR = 0.18, 95% CI = 0.04-0.68, p = 0.011) were considered positive for measles N-protein antibodies. Decreased levels of measles antibodies may render these children more susceptible to measles infection than children whose mothers did not have schistosomiasis. None of the children demonstrated responses to AsHb or SsNIE during the study period. Anti-SEA and anti-PfMSP119 responses suggested that 6 and 70% of the children acquired schistosomes and falciparum malaria, respectively, during the first 2 years of life.

This longitudinal serologic study was conducted in western Kenya over a 4-year period, between 2013 and 2017. We enrolled late-term pregnant women and followed their children for 2 years for antibody responses to parasite antigens and standard immunizations. Pregnant women were diagnosed for malaria, soil-transmitted helminths (STH; A. lumbricoides; Trichuris trichiura, and hookworm), and schistosomiasis. Blood samples were collected from mothers, and from babies at or near birth, and subsequently until 2 years of age (see below). Pregnant women were recruited from the antenatal clinics at several county hospitals which were selected based on the average number of pregnant women visiting the facility, nearness of the facility to the Kenya Medical Research Institute (KEMRI) in Kisian, Kenya, and to represent multiple categorical levels of the hospitals. The six study hospitals used were: Jaramogi Oginga Odinga teaching and referral hospital (the largest facility in Kisumu offering comprehensive services in the region—level 5), Kisumu sub-county hospital (level 4), Port Florence and Ober Kamoth health centers (level 3), Usoma and Rota dispensaries (level 2). All the facilities used are government funded except Port Florence, which is private. Pregnant women who were in their third trimester (34–37 weeks gestation) were screened for eligibility and asked to participate in the study. Those who consented filled out a questionnaire and donated a single blood sample and three stool specimens collected on consecutive days. The name, detailed address, and phone number of each consented participant was recorded at the time of enrollment to facilitate home based follow-up of their child until 24 months postpartum. Each woman was assigned a unique study number that was then consistent with that of her child throughout the study. Pregnant women who were smear-positive for malaria were treated according to Kenya Ministry of Health guidelines. Mothers infected with schistosomes or intestinal helminths were treated soon after delivery. The objective of the study was explained in detail to all enrolled pregnant mothers in the local language (Luo) in the presence of community midwives who were not part of the study. Witnessed written informed consent was obtained from each subject for themselves and for their unborn child to participate over the entire 2-year follow-up period. A copy of the signed consent form was given to each enrollee and another copy was kept in a locked cabinet with restricted access in the offices of the KEMRI, Centre for Global Research at Kisian, in Kisumu County. Only infants born at term, defined as a gestational age of 37–42 weeks, were included in this study. When twins were born, both were enrolled in the study. Before birth, each mother was confirmed to have been provided with a vaccination clinic booklet that was to be used to record and track vaccination history of the infant and the health status of both the mother and child. In accordance with KEPI, infants were vaccinated with BCG vaccine at birth; 3 doses of [diphtheria, pertussis, tetanus (DPT)] vaccine, at 6, 10, and 14 weeks; oral polio vaccine (OPV) at or within 2 weeks of birth and 6, 10, 14 weeks; and measles vaccine at 9 months. BCG, DPT, OPV, and measles vaccines, all of which were recommended and pre-qualified by WHO, were manufactured by Serum Institute of India PVT, Hadapsar, India. Vaccine manufacturers provided the study product but had no role in the conduct of the study, analysis of the data, or preparation of this report. These vaccines were provided free-of-charge by the Ministry of Health officials through the Division of Vaccines and Immunization under KEPI. All immunizations were recorded on an infant birth vaccination clinic booklet brought by the mother and all dates of vaccinations were verified for all children by our field study team. The research protocol was approved by the Scientific Steering Committee of the Kenya Medical Research Institute (SSC-KEMRI), KEMRI/Scientific Ethical Review Unit (Protocol No. 2303) and the Institutional Review Board at the University of Georgia (Protocol No. 00004091). The Centers for Disease Control and Prevention (CDC) also reviewed the protocol; CDC personnel were considered not to be engaged because they had no contact with study participants or access to personal identifiers. All subjects provided written informed consent in accordance with the Declaration of Helsinki. Maternal venous blood was collected at the time of the neonate’s first bleed, at or a few days after birth. Subsequent blood collections from children were at 6 and 20 weeks and 9, 12, 18, and 24 months of age. At least 400 µL of heel prick or finger blood was collected by capillary blood collection using lithium heparin anticoagulant (Kabe Labortechnik GMBH, Germany). Blood was centrifuged to isolate the plasma fraction from the cell pellet and plasma specimens were stored at −20°C. Antibody assays were performed at the same time after all plasmas were collected. Detection and enumeration of S. mansoni eggs were determined by Kato Katz fecal examination (12) based on two slides from each of the three stool samples collected from women upon enrollment. Intensity of infection was obtained for S. mansoni as eggs per gram of feces (epg) and the presence or absence of eggs of the three STH was recorded. Blood from all pregnant women was examined for malaria parasites. Thick and thin blood smears were prepared, stained with 10% Giemsa for 15 min, and examined by light microscopy for Plasmodium-infected erythrocytes. At least 200 microscope fields were scanned before a smear was considered as negative. Children were not assayed for malaria parasites in their blood, nor were they evaluated by stool examination for schistosome infection. Fluorescent bead–based multiplex bead immunoassays were performed using Luminex technology (Luminex Corp., Austin, TX, USA) to analyze plasma antibody levels to multiple antigens from mothers and infants. Expression and purification of S. stercoralis NIE (SsNIE) (13) and P. falciparum 19-kDa subunit of Merozoite Surface Protein 1 (MSP119) (14) antigens as fusion proteins with Schistosoma japonicum glutathione-S-transferase (GST) have been described (15, 16). Recombinant GST with no fusion partner was also expressed and purified as previously described (17) for use as a negative control in the multiplex assays. The conditions for coupling these antigens to the beads have been described (16) as has coupling of S. mansoni soluble egg antigen (SEA) (18). Native hemoglobin Ascaris suum hemoglobin (AsHb) purified from A. suum worms was a kind gift of Peter Geldhof (Ghent University, Belgium) (19, 20). SEA and AsHb were coupled to SeroMap microsphere beads (Luminex Corp., Austin, TX, USA) in phosphate-buffered saline (PBS) at pH 7.2 using 120 µg protein for 12.5 × 106 beads as previously described (18). The following antigens were purchased from commercial sources: tetanus toxoid (Massachusetts Biological Laboratories, Boston, MA, USA), diphtheria toxoid from Corynebacterium diphtheriae (List Biological Laboratories, Campbell, CA, USA), and recombinant measles nucleoprotein (MV-N, Meridian Life Sciences, Memphis, TN, USA) (21). Tetanus toxoid was coupled to SeroMap beads as previously described (16). Diphtheria toxoid was coupled in buffer containing 50 mM 2-N-morpholinoethanesulfonic acid (MES) at pH 5.0 with 0.85% NaCl using 60 µg of protein per 12.5 × 106 beads in 1 mL final volume. Measles nucleoprotein (N-protein) was partially purified by MonoQ column chromatography (GE Healthcare, Piscataway, NJ, USA) and coupled to beads in buffer containing 50 mM MES/NaCl buffer at pH 5.0 using 6 µg of protein per 12.5 × 106 beads in 1 mL final volume. Test plasma samples were diluted 1:400 in PBS buffer (pH 7.2) containing 0.3% Tween 20, 0.02% sodium azide, 0.5% casein, 0.5% polyvinyl alcohol, 0.8% polyvinylpyrrolidone, and 3 µg/mL Escherichia coli extract (15, 18, 22). Multiplex bead assays for total IgG antibodies were performed as previously described (15, 23). Each assay plate included a buffer only blank, as well as positive and negative controls, and all samples were tested in duplicate. Data were collected using a BioPlex 200 instrument with BioPlex Manager version 6.1.1 software (BioRad, Hercules, CA, USA). Responses are reported as the average of the median fluorescent intensity minus background for the duplicate wells (MFI-BKG). Samples having a coefficient of variation of >15% between the duplicate wells for >3 positive antibody responses were repeated. All samples collected from one child were assayed on the same plate to minimize potential impacts caused by variability in assay performance. Cutoffs for the responses to the vaccine antigens were determined using reference standards TE-3 (tetanus) and 10/262 (diphtheria) purchased from National Institute for Biological Standards and Control in the Hertfordshire, UK. Twofold serial dilutions were performed, and a log–log plot used to fit a line to the data below the response plateau. Correlations were all consistently high. Median fluorescence intensity (MFI) cutoffs were as follows: diphtheria cutoff for complete protection = 0.1 IU/mL = 4,103 MFI-BKG (24, 25); tetanus cutoff for protection = 10 mIU/mL = 43 MFI-BKG (16, 26). The choice of measles N-protein assay cutoff was based on a receiver-operating characteristic curve analysis of 140 sera comparing multiplex bead assay to the “gold standard” plaque reduction neutralization assay, a live virus infection assay that measures all classes of virus-neutralizing immunoglobulin. The 149 MFI-BKG cutoff value calculated at the CDC in Atlanta, GA, USA, was translated to the data generated at KEMRI using a twofold serial dilution standard curve that was run at both locations. The resulting measles N-protein assay cutoff for the KEMRI BioPlex 200 instrument was 67 MFI-BKG units. The optimal cutoff points for positive antibody levels against PfMSP1 were determined by assigning all mothers’ responses in this holoendemic area as positive and all children’s responses at 20 weeks of age as negative and calculating an ROC curve and J-Index (GraphPad Prism version 6 for Windows, San Diego, CA, USA). The cutoff for anti-SEA antibodies was determined by using the mixture model reported in Cutoff Finder using R (27). The final dataset used for analysis was comprised of mother/neonate pairs for which the mother and her neonate were concordant for either presence or absence of anti-SEA IgG and for mother/neonate pairs where the mother’s plasma contained anti-SEA IgG and her stool specimens were positive for S. mansoni eggs. Egg-negative mothers were Kato Katz-negative but could be anti-SEA IgG antibody negative or positive with a consistent antibody response in the neonate. Mothers in this category were assumed either to be: (a) uninfected; (b) previously infected; or (c) infected with low eggs per gram feces below the Kato Katz limit of detection. Mother/neonate pairs for which the mother and her neonate were discordant for the presence of any anti-SEA IgG (i.e., one member of the pair had specific antibody and the other was completely negative) were deemed to be mistakenly matched during data collection or entry and were, therefore, excluded from final analyses. Data were cleaned and analyzed using IBM SPSS Statistics for Windows, Version 24.0 (IBM Corp., Armonk, NY, USA). GraphPad Prism version 6 for Windows (La Jolla California) was used for statistical analyses as well as for graph preparation. Characteristics of the participating mothers were summarized using descriptive statistics. Anemia was categorized using WHO-recommended cutoffs (28) adjusted by age and altitude with the following hemoglobin values: normal (>11.1 g/dL), mild (10.2–11.1 g/dL), moderate (7.2–10.1 g/dL), and severe (<7.2 g/dL). Correlations between a mother’s and her infant’s antibody levels at birth were examined using Spearman’s correlation test and simple linear regression. Antibody levels were log-transformed due to skewed distribution. The Mann–Whitney U test was used to compare vaccine antibody responses in S. mansoni egg positive and negative mothers. To determine whether an infant reached a protective antibody level, the following cutoffs were used: diphtheria: 4,103 MFI (mean fluorescence intensity) minus background, tetanus: 43 MFI minus background, and Measles: 67 MFI minus background. Chi square analysis was used to determine whether the proportion of vaccine-protected infants differed between S. mansoni egg positive and negative mothers. Tests were considered statistically significant at p < 0.05.

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

1. Mobile Health (mHealth) Solutions: Develop mobile applications or SMS-based platforms to provide pregnant women with information about maternal health, including the importance of immunizations and the potential impact of parasitic infections on their child’s immune responses.

2. Telemedicine: Implement telemedicine services to enable pregnant women in remote areas to access prenatal care and consultations with healthcare providers. This can help ensure that women receive appropriate care and guidance throughout their pregnancy.

3. Community Health Workers: Train and deploy community health workers who can educate pregnant women about the importance of immunizations and provide support and guidance during pregnancy. These workers can also help identify and refer women with parasitic infections for appropriate treatment.

4. Integrated Healthcare Services: Establish integrated healthcare services that combine maternal health services with parasitic infection screening and treatment. This can help ensure that pregnant women receive comprehensive care and address both their maternal health and parasitic infection needs.

5. Health Education Campaigns: Conduct targeted health education campaigns to raise awareness among pregnant women and their communities about the potential impact of parasitic infections on their child’s immune responses to routine vaccines. This can help increase demand for immunizations and encourage women to seek treatment for parasitic infections.

6. Improved Vaccine Delivery Systems: Explore innovative vaccine delivery systems, such as microneedle patches or needle-free injections, to improve the accessibility and acceptability of routine immunizations for pregnant women and their children.

7. Collaboration and Partnerships: Foster collaboration and partnerships between healthcare providers, researchers, policymakers, and community organizations to develop and implement innovative strategies for improving access to maternal health services and addressing the impact of parasitic infections on immune responses to vaccines.

It is important to note that these recommendations are based on the information provided and may need to be further evaluated and tailored to the specific context and needs of the target population.
AI Innovations Description
Based on the information provided, the study found that maternal schistosomiasis infection had no impact on the level of antibody responses or the proportion of offspring that developed protective levels of antibodies to tetanus or diphtheria antigens at 2 years of age. However, children born to S. mansoni-positive mothers and immunized for measles at 9 months of age had significantly lower levels of anti-measles N-protein antibodies when they were 2 years old. This suggests that decreased levels of measles antibodies may render these children more susceptible to measles infection than children whose mothers did not have schistosomiasis.

Based on these findings, a recommendation to improve access to maternal health and address this issue could be to implement targeted interventions for pregnant women in areas with high rates of schistosomiasis infection. These interventions could include regular screening and treatment for schistosomiasis during pregnancy, as well as education and awareness campaigns to promote the importance of immunizations and ensure that all children receive the recommended vaccines.

By addressing maternal schistosomiasis infection and ensuring that children receive adequate protection through immunizations, access to maternal health can be improved and the risk of measles infection can be reduced in these communities.
AI Innovations Methodology
Based on the provided description, the study aims to investigate the impact of maternal schistosomiasis infection during pregnancy on the immune response of their children to routine vaccines and parasitic infections. The study was conducted in western Kenya over a 4-year period, from 2013 to 2017. Late-term pregnant women were enrolled, and their children were followed for 2 years to assess antibody responses to parasite antigens and standard immunizations.

To improve access to maternal health, the following innovations could be considered:

1. Mobile Clinics: Implementing mobile clinics that can travel to remote areas, providing maternal health services and vaccinations to pregnant women who may not have easy access to healthcare facilities.

2. Telemedicine: Utilizing telemedicine platforms to provide virtual consultations and prenatal care to pregnant women in underserved areas. This can help overcome geographical barriers and improve access to healthcare professionals.

3. Community Health Workers: Training and deploying community health workers who can provide maternal health education, prenatal care, and vaccinations to pregnant women in their communities. This can help bridge the gap between healthcare facilities and remote areas.

4. Health Information Systems: Implementing robust health information systems that can track and monitor maternal health indicators, vaccination coverage, and parasitic infections. This can help identify areas with low access to maternal health services and target interventions accordingly.

To simulate the impact of these recommendations on improving access to maternal health, the following methodology can be used:

1. Baseline Data Collection: Collect data on the current state of maternal health access, including the number of healthcare facilities, their locations, and the percentage of pregnant women receiving prenatal care and vaccinations.

2. Intervention Implementation: Implement the recommended innovations, such as mobile clinics, telemedicine platforms, community health worker programs, and improved health information systems. Ensure proper training and resources are provided for successful implementation.

3. Data Monitoring: Continuously monitor and collect data on the utilization of the implemented interventions, including the number of pregnant women accessing maternal health services through mobile clinics or telemedicine, the coverage of prenatal care and vaccinations, and the impact on maternal and child health outcomes.

4. Comparative Analysis: Compare the data collected after the implementation of the interventions with the baseline data to assess the impact on improving access to maternal health. Analyze indicators such as the percentage of pregnant women receiving prenatal care and vaccinations, the reduction in geographical barriers, and the improvement in maternal and child health outcomes.

5. Evaluation and Adjustment: Evaluate the effectiveness of the implemented interventions and make adjustments as necessary. Identify any challenges or barriers to access and address them to further improve the impact of the interventions.

By following this methodology, it will be possible to simulate the impact of the recommended innovations on improving access to maternal health and assess their effectiveness in addressing the identified challenges.

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