Plasmodium falciparum mutant haplotype infection during pregnancy associated with reduced birthweight, Tanzania

Emerging Infectious Diseases, Volume 19, No. 9, Year 2013

Interpretation

Intermittent preventive treatment during pregnancy with sulfadoxine-pyrimethamine (IPTp-SP) is a key strategy in the control of pregnancy-associated malaria. However, this strategy is compromised by widespread drug resistance from single-nucleotide polymorphisms in the Plasmodium falciparum dihydrofolate reductase and dihydropteroate synthetase genes. During September 2008-October 2010, we monitored a cohort of 924 pregnant women in an area of Tanzania with declining malaria transmission. P. falciparum parasites were genotyped, and the effect of infecting haplotypes on birthweight was assessed. Of the genotyped parasites, 9.3%, 46.3%, and 44.4% had quadruple or less, quintuple, and sextuple mutated haplotypes, respectively. Mutant haplotypes were unrelated to SP doses. Compared with infections with the less-mutated haplotypes, infections with the sextuple haplotype mutation were associated with lower (359 g) birthweights. Continued use of the suboptimal IPTp-SP regimen should be reevaluated, and alternative strategies (e.g., intermittent screening and treatment or intermittent treatment with safe and effective alternative drugs) should be evaluated. The study was conducted during September 2008–October 2010 in Korogwe District in the Tanga Region of northeastern Tanzania, where P. falciparum is the predominant malaria-causing species. A prospective cohort of 924 pregnant women was monitored from first attendance at the antenatal clinic through delivery. The study has been described in detail (22–24). In brief, pregnant women with a gestational age of <24 weeks, as estimated by using ultrasound, were enrolled if they had lived in Korogwe District for >6 months and were willing to give birth at Korogwe District Hospital. Study participants attended 3 additional prescheduled antenatal visits at weeks 26, 30, and 36 of pregnancy, and they were attended to by a study nurse/clinician. Obstetric history and maternal anthropometric measurements were recorded for all women (23). A venous blood sample was collected at each antenatal clinic visit, and venous and placental blood samples were collected at the time of delivery. All blood samples were tested for malaria parasites by using a rapid diagnostic test (RDT) (Parascreen, Zephyr Biomedicals, Goa, India; Paracheck Pf, Orchid Biomedical Systems, Mumbai, India; or ParaHIT-f, Span Diagnostics Ltd, Surat, India) and by microscopy. Blood smears for women with negative RDT results were examined retrospectively, whereas those for women with positive RDT results were examined immediately if deemed necessary by the study physician for a treatment decision (25). Parasite density was determined as the number of asexual stage parasites/200 leukocytes (500 leukocytes if <10 parasites) and converted to the number per microliter, as described (22,25); >100 fields were double-examined before a blood smear was declared negative. Women with positive RDT results were treated with the antimalarial drug artemether-lumefantrine (Coartem Dispersible, Norvatis Corporation, Suffern, New York, USA) or with quinine. For infections occurring during the first trimester of pregnancy, quinine sulfate–coated tablets (ELYS Chemical Industries Ltd, Nairobi, Kenya) were used, and for severe cases, quinine dihydrochloride injection (Vital Healthcare PVT Ltd, Mumbai, India) was used. Two doses of IPTp-SP (Sulphadar, Shelys Pharmaceutical Ltd, Dar es Salaam, Tanzania) were given >1 month apart as directly observed treatment; each dose contained 1,500 mg of sulfadoxine and 75 mg of pyrimethamine. Women with a gestational age of >20 weeks at enrollment were given the first IPTp-SP dose at the study-inclusion visit and the second dose during the third trimester. Women with a gestational age of <20 weeks at enrollment were given the first dose at 20 weeks of gestation. Women who had received IPTp-SP before study inclusion but earlier than recommended by the World Health Organization (i.e., after quickening in the second trimester) received a second dose after 20 weeks of gestation, and a third dose was given in the third trimester. Use of SP from private pharmacies/drug shops for malaria treatment before and after study inclusion was also documented. All study participants were provided with a voucher for procuring insecticide-treated nets. EDTA-preserved venous blood was used to estimate hemoglobin levels (KX-21N Automated Hematology Analyzer, Sysmex, Kobe, Japan). Live newborns whose birthweights were measured by using a spring scale (Fazzini, Vimodrone, Italy) with an accuracy of <50 g or a digital strain gauge scale (ADE, Hamburg, Germany) with an accuracy of <10 g within 24 h of delivery were included in the birthweight analysis. Newborns with severe malformations, twins, and those born to women with preeclampsia were excluded from analyses because these conditions can severely affect birthweight (23). EDTA-preserved blood (50 μL) was spotted on Whatman number 3 filter paper (VWR– Bie & Berntsen, Herlev, Denmark), dried at room temperature, and stored in separate zip-lock bags. DNA was extracted by using the Chelex 100 method, as described (26). The DNA supernatant was transferred to a 96-well PCR plate and stored at −20°C until use. The parasite DNA was amplified by outer and nested P. falciparum–specific PCRs, as described (27); the products were analyzed by electrophoresis in 1.5% ethidium bromide–stained gel, as described (22). To determine the multiplicity of infections, block 2 of the merozoite surface protein 2 domain was amplified by using fluorescent PCR (28). The results were analyzed by using GeneScan software, version 3.7 (Applied Biosystems, Naerum, Denmark). Parasite DNA was amplified by outer and nested PCR with specific primers targeting the Pfdhfr and Pfdhps genes, as described (29). Single-nucleotide polymorphisms (SNPs) in the Pfdhfr and Pfdhps genes were identified by using a sequence-specific oligonucleotide probe ELISA technique, as described (29) with minor modifications. In brief, we used sequence-specific oligonucleotide probes targeting Pfdhfr codons c50/51 CI/CN, c59 (C/R), c108 (S/N/T), and c164 (I/L) and Pfdhps codons c436/437 (AA/AG/SA/SG/FG), c540 (K/E), c581 (A/G), and c613 (A/S). Individual SNPs were combined to deduce the different infecting mutant haplotypes. We double-entered and validated data in Microsoft Access version 2007 (Redmond, WA, USA). Statistical analyses were conducted by using Stata version 10 (StataCorp, College Station, TX, USA) deploying parametric and nonparametric methods, as appropriate. The effect of infecting allelic haplotypes on birthweights was investigated by using multiple linear regression and dichotomized (as 6 and <6 SNPs) to infecting haplotypes; variables with a p<0.20 in univariate analysis were included in the multivariate models. By using a stepwise backward elimination approach, we obtained final models including only variables with a p<0.10. A 2-sided p-value of <0.05 was considered significant. Final models included only women without missing values.

AI Digest

Study Justification:

– The study aimed to assess the effect of Plasmodium falciparum mutant haplotype infection during pregnancy on birthweight.
– This is important because intermittent preventive treatment during pregnancy with sulfadoxine-pyrimethamine (IPTp-SP) is a key strategy in controlling pregnancy-associated malaria, but drug resistance is compromising its effectiveness.
– Understanding the impact of mutant haplotypes on birthweight can inform the evaluation of alternative strategies for preventing malaria during pregnancy.

Study Highlights:

– The study was conducted in Korogwe District, Tanzania, from September 2008 to October 2010.
– A cohort of 924 pregnant women was monitored from their first antenatal clinic visit until delivery.
– P. falciparum parasites were genotyped, and the effect of infecting haplotypes on birthweight was assessed.
– Of the genotyped parasites, 9.3% had quadruple or less mutated haplotypes, 46.3% had quintuple mutated haplotypes, and 44.4% had sextuple mutated haplotypes.
– Mutant haplotypes were not related to the doses of IPTp-SP received.
– Infections with the sextuple haplotype mutation were associated with lower birthweights (359 g less) compared to infections with less-mutated haplotypes.

Recommendations for Lay Reader and Policy Maker:

– The continued use of the suboptimal IPTp-SP regimen should be reevaluated.
– Alternative strategies, such as intermittent screening and treatment or intermittent treatment with safe and effective alternative drugs, should be evaluated.
– These recommendations aim to improve the control of pregnancy-associated malaria and reduce the impact on birthweight.

Key Role Players:

– Researchers and scientists specializing in malaria and maternal health.
– Healthcare providers and clinicians involved in antenatal care and delivery.
– Policy makers and government officials responsible for healthcare and malaria control programs.
– Community health workers and educators who can disseminate information and implement interventions.

Cost Items for Planning Recommendations:

– Research funding for evaluating alternative strategies and conducting further studies.
– Training and capacity building for healthcare providers and community health workers.
– Procurement and distribution of alternative drugs for intermittent treatment.
– Monitoring and evaluation of the implemented interventions.
– Education and awareness campaigns for pregnant women and the community.
– Infrastructure and equipment for screening and treatment programs.
– Data management and analysis systems for monitoring and reporting.

Strength of Evidence

N/A

Abstract

The study was conducted during September 2008–October 2010 in Korogwe District in the Tanga Region of northeastern Tanzania, where P. falciparum is the predominant malaria-causing species. A prospective cohort of 924 pregnant women was monitored from first attendance at the antenatal clinic through delivery. The study has been described in detail (22–24). In brief, pregnant women with a gestational age of 6 months and were willing to give birth at Korogwe District Hospital. Study participants attended 3 additional prescheduled antenatal visits at weeks 26, 30, and 36 of pregnancy, and they were attended to by a study nurse/clinician. Obstetric history and maternal anthropometric measurements were recorded for all women (23). A venous blood sample was collected at each antenatal clinic visit, and venous and placental blood samples were collected at the time of delivery. All blood samples were tested for malaria parasites by using a rapid diagnostic test (RDT) (Parascreen, Zephyr Biomedicals, Goa, India; Paracheck Pf, Orchid Biomedical Systems, Mumbai, India; or ParaHIT-f, Span Diagnostics Ltd, Surat, India) and by microscopy. Blood smears for women with negative RDT results were examined retrospectively, whereas those for women with positive RDT results were examined immediately if deemed necessary by the study physician for a treatment decision (25). Parasite density was determined as the number of asexual stage parasites/200 leukocytes (500 leukocytes if 100 fields were double-examined before a blood smear was declared negative. Women with positive RDT results were treated with the antimalarial drug artemether-lumefantrine (Coartem Dispersible, Norvatis Corporation, Suffern, New York, USA) or with quinine. For infections occurring during the first trimester of pregnancy, quinine sulfate–coated tablets (ELYS Chemical Industries Ltd, Nairobi, Kenya) were used, and for severe cases, quinine dihydrochloride injection (Vital Healthcare PVT Ltd, Mumbai, India) was used. Two doses of IPTp-SP (Sulphadar, Shelys Pharmaceutical Ltd, Dar es Salaam, Tanzania) were given >1 month apart as directly observed treatment; each dose contained 1,500 mg of sulfadoxine and 75 mg of pyrimethamine. Women with a gestational age of >20 weeks at enrollment were given the first IPTp-SP dose at the study-inclusion visit and the second dose during the third trimester. Women with a gestational age of <20 weeks at enrollment were given the first dose at 20 weeks of gestation. Women who had received IPTp-SP before study inclusion but earlier than recommended by the World Health Organization (i.e., after quickening in the second trimester) received a second dose after 20 weeks of gestation, and a third dose was given in the third trimester. Use of SP from private pharmacies/drug shops for malaria treatment before and after study inclusion was also documented. All study participants were provided with a voucher for procuring insecticide-treated nets. EDTA-preserved venous blood was used to estimate hemoglobin levels (KX-21N Automated Hematology Analyzer, Sysmex, Kobe, Japan). Live newborns whose birthweights were measured by using a spring scale (Fazzini, Vimodrone, Italy) with an accuracy of <50 g or a digital strain gauge scale (ADE, Hamburg, Germany) with an accuracy of <10 g within 24 h of delivery were included in the birthweight analysis. Newborns with severe malformations, twins, and those born to women with preeclampsia were excluded from analyses because these conditions can severely affect birthweight (23). EDTA-preserved blood (50 μL) was spotted on Whatman number 3 filter paper (VWR– Bie & Berntsen, Herlev, Denmark), dried at room temperature, and stored in separate zip-lock bags. DNA was extracted by using the Chelex 100 method, as described (26). The DNA supernatant was transferred to a 96-well PCR plate and stored at −20°C until use. The parasite DNA was amplified by outer and nested P. falciparum–specific PCRs, as described (27); the products were analyzed by electrophoresis in 1.5% ethidium bromide–stained gel, as described (22). To determine the multiplicity of infections, block 2 of the merozoite surface protein 2 domain was amplified by using fluorescent PCR (28). The results were analyzed by using GeneScan software, version 3.7 (Applied Biosystems, Naerum, Denmark). Parasite DNA was amplified by outer and nested PCR with specific primers targeting the Pfdhfr and Pfdhps genes, as described (29). Single-nucleotide polymorphisms (SNPs) in the Pfdhfr and Pfdhps genes were identified by using a sequence-specific oligonucleotide probe ELISA technique, as described (29) with minor modifications. In brief, we used sequence-specific oligonucleotide probes targeting Pfdhfr codons c50/51 CI/CN, c59 (C/R), c108 (S/N/T), and c164 (I/L) and Pfdhps codons c436/437 (AA/AG/SA/SG/FG), c540 (K/E), c581 (A/G), and c613 (A/S). Individual SNPs were combined to deduce the different infecting mutant haplotypes. We double-entered and validated data in Microsoft Access version 2007 (Redmond, WA, USA). Statistical analyses were conducted by using Stata version 10 (StataCorp, College Station, TX, USA) deploying parametric and nonparametric methods, as appropriate. The effect of infecting allelic haplotypes on birthweights was investigated by using multiple linear regression and dichotomized (as 6 and <6 SNPs) to infecting haplotypes; variables with a p<0.20 in univariate analysis were included in the multivariate models. By using a stepwise backward elimination approach, we obtained final models including only variables with a p<0.10. A 2-sided p-value of <0.05 was considered significant. Final models included only women without missing values.

Materials

N/A

Innovations

Innovations for the above recommendations could include:

1. Development of new antimalarial drugs: Researchers could focus on developing new drugs that are effective against Plasmodium falciparum mutant haplotypes and have a reduced risk of resistance. This could involve exploring novel drug targets or modifying existing drugs to overcome resistance.

2. Implementation of point-of-care diagnostic tests: Point-of-care diagnostic tests that can quickly and accurately detect malaria infections during pregnancy could be developed and implemented. These tests would enable healthcare providers to promptly diagnose and treat pregnant women with malaria, reducing the risk of adverse outcomes.

3. Use of alternative preventive measures: In addition to insecticide-treated nets, other preventive measures such as indoor residual spraying or the use of repellents could be explored to further reduce the risk of malaria infection during pregnancy.

4. Integration of maternal health and malaria control services: Strengthening the integration of maternal health and malaria control services could improve access to comprehensive care for pregnant women. This could involve training healthcare providers to provide both antenatal care and malaria prevention and treatment services.

5. Mobile health (mHealth) interventions: Leveraging mobile technology to deliver health education messages, reminders for antenatal care visits, and information on malaria prevention and treatment could improve awareness and adherence to recommended interventions among pregnant women.

6. Community-based interventions: Engaging communities through community health workers or community-based organizations could help raise awareness about malaria during pregnancy and promote the use of preventive measures. These interventions could also facilitate early detection and referral of pregnant women with malaria infections.

7. Strengthening health systems: Investing in the strengthening of health systems, including infrastructure, human resources, and supply chains, is crucial to ensure the effective implementation of interventions to improve access to maternal health and address the challenges posed by drug resistance.

It is important to note that these innovations are suggestions and would require further research, development, and evaluation to determine their feasibility and effectiveness in the context of Tanzania. Collaboration between researchers, policymakers, healthcare providers, and communities would be essential for successful implementation.

AI Innovations Description

Based on the information provided, the recommendation to improve access to maternal health and address the issue of reduced birthweight associated with Plasmodium falciparum mutant haplotype infection during pregnancy in Tanzania is as follows:

1. Reevaluate the continued use of the suboptimal IPTp-SP regimen: The study suggests that the current strategy of intermittent preventive treatment during pregnancy with sulfadoxine-pyrimethamine (IPTp-SP) may be compromised by widespread drug resistance. It is recommended to reassess the effectiveness of this regimen and explore alternative strategies.

2. Evaluate alternative strategies: Consider implementing alternative strategies such as intermittent screening and treatment or intermittent treatment with safe and effective alternative drugs. These approaches may help overcome the challenges posed by drug resistance and improve maternal health outcomes.

3. Conduct further research: Conduct additional research to evaluate the efficacy and safety of alternative strategies. This could involve clinical trials or observational studies to assess the impact of different interventions on birthweight and maternal health.

4. Strengthen antenatal care services: Enhance antenatal care services to ensure early detection and management of malaria infections during pregnancy. This includes regular monitoring of pregnant women for malaria parasites, prompt diagnosis, and appropriate treatment.

5. Improve access to insecticide-treated nets: Provide pregnant women with insecticide-treated nets to prevent mosquito bites and reduce the risk of malaria infection during pregnancy.

6. Enhance health education and awareness: Increase awareness among pregnant women and healthcare providers about the risks of malaria during pregnancy and the importance of preventive measures. This can be achieved through health education campaigns, community outreach programs, and training for healthcare professionals.

7. Collaborate with international organizations and stakeholders: Collaborate with international organizations, such as the World Health Organization, and engage relevant stakeholders to support the implementation of innovative strategies and interventions to improve access to maternal health and address the challenges posed by drug resistance.

It is important to note that these recommendations are based on the specific findings and context of the study mentioned. Further analysis and consultation with experts in the field of maternal health and malaria control would be necessary to develop a comprehensive and tailored approach to address this issue.

AI Innovations Methodology

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

1. Data collection: Gather data on the current state of maternal health in Tanzania, including information on maternal mortality rates, birthweight outcomes, and access to antenatal care services. This data can be obtained from national health surveys, reports from the Ministry of Health, and other relevant sources.

2. Baseline assessment: Assess the current utilization of the suboptimal IPTp-SP regimen and its impact on birthweight outcomes. Evaluate the prevalence of Plasmodium falciparum mutant haplotype infection during pregnancy and its association with reduced birthweight. This assessment will provide a baseline against which the impact of the recommendations can be measured.

3. Modeling the impact: Use mathematical modeling techniques to simulate the potential impact of implementing the main recommendations. This can involve creating a model that incorporates factors such as the effectiveness of alternative strategies, the coverage of antenatal care services, and the use of insecticide-treated nets. The model should also consider the potential reduction in Plasmodium falciparum mutant haplotype infection and its effect on birthweight outcomes.

4. Sensitivity analysis: Conduct sensitivity analysis to assess the robustness of the model and the potential range of outcomes. This can involve varying key parameters, such as the effectiveness of alternative strategies and the coverage of interventions, to determine their impact on the results.

5. Evaluation of outcomes: Evaluate the outcomes of the simulation, including changes in birthweight outcomes, reduction in Plasmodium falciparum mutant haplotype infection, and improvements in access to maternal health services. Compare these outcomes to the baseline assessment to determine the effectiveness of the recommendations.

6. Policy implications: Based on the simulation results, provide recommendations for policy-makers and stakeholders on the implementation of the main recommendations. This can include suggestions for scaling up alternative strategies, improving access to antenatal care services, and strengthening health education and awareness programs.

It is important to note that the accuracy and reliability of the simulation results will depend on the quality of the data used and the assumptions made in the modeling process. Therefore, it is crucial to ensure that the data used is accurate and representative of the population of interest. Additionally, consulting with experts in the field of maternal health and malaria control can help validate the methodology and ensure its relevance to the Tanzanian context.

Authors & Co-Authors

Statistics:

Citations: 64

Authors: 14

Identifiers:

DOI: 10.3201/eid1909.130133

ISSN: 10806040

Research Areas:

Cancer, Genetics and Genomics, Health System and Policy, Infectious Diseases, Maternal and Child Health, Sexual and Reproductive Health, Social Determinants

Study Countries:

Kenya, Multi-Countries, Tanzania

Study Design:

Cohort Study

Study Approach:

Quantitative

Participants Gender:

Female