Neonatal mortality in HIV-exposed infants born to women receiving combination antiretroviral therapy in rural Uganda

Journal of Tropical Pediatrics, Volume 59, No. 6, Year 2013

Interprétation

As human immunodeficiency virus (HIV)-infected women gain access to combination antiretroviral therapy throughout sub-Saharan Africa, a growing number of infants are being born HIV-exposed but uninfected. Data about neonatal mortality and the impact of premature delivery, in this population are limited. We describe the 28-day mortality outcomes in a cohort of HIV-exposed infants who had ultrasound-confirmed gestational age in rural Uganda. There were 13 deaths among 351 infants, including 9 deaths in the perinatal period. Premature delivery was a strong predictor of mortality. The prevention of HIV transmission to infants is now possible in rural low-resource settings but the frequency of neonatal death among HIV-exposed infants remains extremely high, calling for new comprehensive interventions to reduce mortality in this growing population. © The Author [2013]. Published by Oxford University Press. All rights reserved. This study included infants born in a randomized clinical trial of HIV-infected pregnant women who were enrolled between 15 December 2009 and 25 November 2012 in the rural town of Tororo, Uganda ({“type”:”clinical-trial”,”attrs”:{“text”:”NCT00993031″,”term_id”:”NCT00993031″}}NCT00993031). Ethical approval for the study was obtained from the Uganda National Council of Science and Technology, the Research and Ethics Committee of the School of Medicine at Makerere University and the Committee on Human Research at the University of California, San Francisco. Informed written consent for participation was obtained from all study participants at enrollment. ART-naïve women between 12 and 28 weeks gestation were randomized to receive either lopinavir-ritonavir- or efavirenz-based ART. All women received insecticide-treated bed nets and daily trimethoprim-sulfamethoxazole for prevention of opportunistic infections, and a standard prenatal care package of a safe water vessel, multivitamins and condoms as per standard of care for HIV-infected pregnant women in Uganda. GA was established using LMP and sonographic biometry (biparietal diameter, head circumference, abdominal circumference, femur length). Estimated date of delivery was based on LMP if the biometry was concordant within 7, 14 and 21 days in the first, second and third trimester, respectively, and based on ultrasound if LMP and biometry were not concordant. Women were encouraged to deliver at Tororo General Hospital (TGH), the district referral hospital. Midwives conducted deliveries and oxygen was available for resuscitation. Infants were seen every 2 weeks in the study clinic. Infants received zidovudine (AZT) prophylaxis after delivery in accordance with Ugandan Ministry of Health Guidelines, which changed during the course of the study. Seventy-six infants received AZT for 7 days, while 275 infants received AZT for 6 weeks after delivery. All infants had HIV DNA polymerase chain reaction (PCR) (Roche Amplicor HIV-1 DNA, v. 1.5) testing at birth. Maternal medical and obstetrical history was collected at enrollment. Women were followed in the study clinic for all clinical care, including monthly routine visits. Delivery data were collected by study physicians who reviewed the medical record as recorded by the hospital staff. Infants were weighed on a calibrated scale within 12 h of delivery. Infants were followed every 2 weeks for the first month after delivery. This analysis included all neonatal deaths occurring within the first 28 days of life. Causes of neonatal deaths were determined by two pediatricians blinded to maternal study intervention arm and categorized according to criteria established by Lawn et al. [12]. The primary outcome was neonatal death, defined as the death of a live-born infant within 28 days of birth. Perinatal death, defined as the death of a live-born infant within 7 days of life was also examined. Low birth weight (LBW) was defined as <2500 g at birth. Prematurity, or preterm birth, was defined as any infant born before 37 weeks of gestation. Infants were included in this analysis if they were born alive, and had either died or reached 28 days of life at the time of analysis. No infants were lost to follow-up. Continuous (GA, duration of ART from enrollment to delivery, maternal age, CD4 count at enrollment), dichotomous (LBW, twin gestation, infant sex, location of delivery, treatment arm) and ordinal (gravidity, 1- and 5-min Apgar scores) variables were evaluated as predictors in univariate. Adjusted odds ratios were estimated using a multivariate logistic regression model that included all predictors significant in univariate analysis. Data analysis was conducted using Stata version 9 (StataCorp LP, TX, US).

Résumé de l’IA

Study Justification:

– The study aims to address the limited data on neonatal mortality and the impact of premature delivery in HIV-exposed infants born to women receiving combination antiretroviral therapy in rural Uganda.
– It highlights the need for comprehensive interventions to reduce neonatal mortality in this growing population.

Study Highlights:

– The study included 351 HIV-exposed infants in rural Uganda.
– There were 13 deaths among the infants, including 9 deaths in the perinatal period.
– Premature delivery was found to be a strong predictor of mortality.
– The study emphasizes the possibility of preventing HIV transmission to infants in low-resource settings but highlights the high frequency of neonatal death among HIV-exposed infants.

Recommendations for Lay Reader and Policy Maker:

– Implement comprehensive interventions to reduce neonatal mortality in HIV-exposed infants, with a focus on addressing premature delivery.
– Improve access to and utilization of antenatal care services for HIV-infected pregnant women.
– Strengthen healthcare facilities in rural areas to provide adequate prenatal and neonatal care.
– Enhance the availability of resources for resuscitation and treatment of neonates in rural hospitals.
– Promote awareness and education about the importance of early detection and treatment of HIV in pregnant women.

Key Role Players:

– Ministry of Health: Responsible for policy development and implementation of interventions to reduce neonatal mortality in HIV-exposed infants.
– Healthcare Providers: Including doctors, nurses, and midwives, who play a crucial role in providing prenatal and neonatal care.
– Community Health Workers: Involved in community outreach and education to promote antenatal care and HIV prevention.
– Non-Governmental Organizations (NGOs): Provide support and resources for healthcare facilities and community-based interventions.

Cost Items for Planning Recommendations:

– Strengthening healthcare facilities: Budget for infrastructure improvements, equipment, and supplies.
– Training healthcare providers: Allocate funds for training programs on prenatal and neonatal care.
– Community outreach and education: Allocate resources for awareness campaigns and training of community health workers.
– Antenatal care services: Budget for increased access to antenatal care, including HIV testing and counseling.
– Resuscitation and treatment resources: Allocate funds for the availability of oxygen and necessary medications in rural hospitals.

Force de la preuve

The strength of evidence for this abstract is 7 out of 10.
The evidence in the abstract is moderately strong. The study includes a cohort of HIV-exposed infants with ultrasound-confirmed gestational age in rural Uganda. The study design is a randomized clinical trial, which adds to the strength of the evidence. However, the sample size is relatively small (351 infants) and the study only focuses on neonatal mortality outcomes within the first 28 days of life. To improve the strength of the evidence, future studies could consider increasing the sample size and extending the follow-up period to assess long-term outcomes. Additionally, conducting a multicenter study could enhance the generalizability of the findings.

Abstrait

This study included infants born in a randomized clinical trial of HIV-infected pregnant women who were enrolled between 15 December 2009 and 25 November 2012 in the rural town of Tororo, Uganda ({“type”:”clinical-trial”,”attrs”:{“text”:”NCT00993031″,”term_id”:”NCT00993031″}}NCT00993031). Ethical approval for the study was obtained from the Uganda National Council of Science and Technology, the Research and Ethics Committee of the School of Medicine at Makerere University and the Committee on Human Research at the University of California, San Francisco. Informed written consent for participation was obtained from all study participants at enrollment. ART-naïve women between 12 and 28 weeks gestation were randomized to receive either lopinavir-ritonavir- or efavirenz-based ART. All women received insecticide-treated bed nets and daily trimethoprim-sulfamethoxazole for prevention of opportunistic infections, and a standard prenatal care package of a safe water vessel, multivitamins and condoms as per standard of care for HIV-infected pregnant women in Uganda. GA was established using LMP and sonographic biometry (biparietal diameter, head circumference, abdominal circumference, femur length). Estimated date of delivery was based on LMP if the biometry was concordant within 7, 14 and 21 days in the first, second and third trimester, respectively, and based on ultrasound if LMP and biometry were not concordant. Women were encouraged to deliver at Tororo General Hospital (TGH), the district referral hospital. Midwives conducted deliveries and oxygen was available for resuscitation. Infants were seen every 2 weeks in the study clinic. Infants received zidovudine (AZT) prophylaxis after delivery in accordance with Ugandan Ministry of Health Guidelines, which changed during the course of the study. Seventy-six infants received AZT for 7 days, while 275 infants received AZT for 6 weeks after delivery. All infants had HIV DNA polymerase chain reaction (PCR) (Roche Amplicor HIV-1 DNA, v. 1.5) testing at birth. Maternal medical and obstetrical history was collected at enrollment. Women were followed in the study clinic for all clinical care, including monthly routine visits. Delivery data were collected by study physicians who reviewed the medical record as recorded by the hospital staff. Infants were weighed on a calibrated scale within 12 h of delivery. Infants were followed every 2 weeks for the first month after delivery. This analysis included all neonatal deaths occurring within the first 28 days of life. Causes of neonatal deaths were determined by two pediatricians blinded to maternal study intervention arm and categorized according to criteria established by Lawn et al. [12]. The primary outcome was neonatal death, defined as the death of a live-born infant within 28 days of birth. Perinatal death, defined as the death of a live-born infant within 7 days of life was also examined. Low birth weight (LBW) was defined as <2500 g at birth. Prematurity, or preterm birth, was defined as any infant born before 37 weeks of gestation. Infants were included in this analysis if they were born alive, and had either died or reached 28 days of life at the time of analysis. No infants were lost to follow-up. Continuous (GA, duration of ART from enrollment to delivery, maternal age, CD4 count at enrollment), dichotomous (LBW, twin gestation, infant sex, location of delivery, treatment arm) and ordinal (gravidity, 1- and 5-min Apgar scores) variables were evaluated as predictors in univariate. Adjusted odds ratios were estimated using a multivariate logistic regression model that included all predictors significant in univariate analysis. Data analysis was conducted using Stata version 9 (StataCorp LP, TX, US).

Matériaux

N/A

Innovations

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

1. Telemedicine: Implementing telemedicine services can provide remote access to healthcare professionals for prenatal care, consultations, and monitoring, especially in rural areas where access to healthcare facilities is limited.

2. Mobile health (mHealth) applications: Developing mobile applications that provide pregnant women with information, reminders for appointments and medication, and access to educational resources can help improve maternal health outcomes.

3. Community health workers: Training and deploying community health workers who can provide basic prenatal care, education, and support to pregnant women in rural areas can help bridge the gap in access to maternal health services.

4. Transport services: Establishing reliable and affordable transportation services specifically for pregnant women in remote areas can ensure timely access to healthcare facilities for prenatal care, delivery, and emergency situations.

5. Maternal health clinics: Setting up dedicated maternal health clinics in rural areas can provide comprehensive prenatal care, delivery services, and postnatal care, making it easier for pregnant women to access the necessary healthcare services.

6. Mobile clinics: Utilizing mobile clinics equipped with medical professionals and necessary equipment to reach remote areas can provide prenatal care, screenings, and vaccinations to pregnant women who have limited access to healthcare facilities.

7. Health education programs: Implementing community-based health education programs that focus on maternal health, including prenatal care, nutrition, and hygiene practices, can empower women with knowledge and promote healthy behaviors during pregnancy.

8. Improved data collection and analysis: Enhancing data collection systems and conducting thorough analysis of maternal health data can help identify trends, gaps, and areas for improvement, leading to more targeted interventions and resource allocation.

These innovations can help address the challenges faced in improving access to maternal health, particularly in rural areas with limited resources and infrastructure.

AI Innovations Description

Based on the description provided, the following recommendation can be developed into an innovation to improve access to maternal health:

1. Implement comprehensive interventions to reduce neonatal mortality in HIV-exposed infants: Given the high frequency of neonatal death among HIV-exposed infants in rural low-resource settings, it is crucial to develop and implement comprehensive interventions specifically targeted at reducing neonatal mortality in this population. These interventions should focus on improving access to quality maternal healthcare services, including prenatal care, skilled birth attendance, and postnatal care.

2. Strengthen prenatal care services: Enhance prenatal care services by ensuring that all HIV-infected pregnant women have access to combination antiretroviral therapy (ART) and receive regular check-ups throughout their pregnancy. This includes providing ART-naïve women with lopinavir-ritonavir- or efavirenz-based ART, insecticide-treated bed nets, trimethoprim-sulfamethoxazole for prevention of opportunistic infections, and a standard prenatal care package.

3. Improve gestational age determination: Accurate determination of gestational age is crucial for identifying high-risk pregnancies and providing appropriate care. Implement protocols to establish gestational age using both last menstrual period (LMP) and sonographic biometry, such as biparietal diameter, head circumference, abdominal circumference, and femur length. This will help identify premature deliveries, which have been identified as a strong predictor of mortality in HIV-exposed infants.

4. Enhance delivery and postnatal care: Strengthen delivery and postnatal care services by encouraging women to deliver at well-equipped healthcare facilities, such as district referral hospitals, where midwives can conduct deliveries and resuscitation equipment, including oxygen, is available. Ensure that infants receive zidovudine (AZT) prophylaxis after delivery in accordance with national guidelines and conduct regular follow-up visits to monitor the health of both the mother and the infant.

5. Conduct regular neonatal mortality assessments: Continuously monitor and assess neonatal mortality rates among HIV-exposed infants to identify any gaps or areas for improvement. This will help evaluate the effectiveness of the implemented interventions and guide future strategies to further reduce neonatal mortality in this population.

By implementing these recommendations, it is expected that access to maternal health will be improved, leading to a reduction in neonatal mortality among HIV-exposed infants in rural Uganda.

AI Innovations Methodology

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

1. Strengthening prenatal care: Implementing comprehensive prenatal care programs that include regular check-ups, screenings, and education for pregnant women can help identify and address potential health issues early on.

2. Improving transportation infrastructure: Enhancing transportation infrastructure in rural areas can help pregnant women reach healthcare facilities more easily and quickly, reducing delays in accessing maternal health services.

3. Increasing availability of skilled healthcare providers: Training and deploying more skilled healthcare providers, such as midwives and obstetricians, in rural areas can ensure that pregnant women have access to quality care during pregnancy, childbirth, and postpartum.

4. Enhancing community-based interventions: Implementing community-based interventions, such as mobile clinics and community health workers, can bring maternal health services closer to remote communities, improving access for pregnant women who may face geographical or social barriers.

To simulate the impact of these recommendations on improving access to maternal health, a methodology could include the following steps:

1. Define the target population: Identify the specific population that would benefit from the recommendations, such as pregnant women in rural areas of Uganda.

2. Collect baseline data: Gather data on the current state of access to maternal health services in the target population, including factors such as distance to healthcare facilities, availability of skilled providers, and utilization rates of prenatal care.

3. Develop a simulation model: Create a simulation model that incorporates the identified recommendations and their potential impact on improving access to maternal health. This model should consider factors such as the number of additional healthcare providers, changes in transportation infrastructure, and the implementation of community-based interventions.

4. Input data and parameters: Input the baseline data and parameters into the simulation model, including information on the target population, the recommendations being considered, and any assumptions or constraints.

5. Run simulations: Run multiple simulations using the model to simulate different scenarios and assess the potential impact of the recommendations on improving access to maternal health. This could include variations in the scale and effectiveness of the recommendations.

6. Analyze results: Analyze the simulation results to determine the potential outcomes of implementing the recommendations. This could include evaluating changes in access to maternal health services, such as reduced travel time to healthcare facilities or increased utilization of prenatal care.

7. Refine and validate the model: Refine the simulation model based on the analysis of the results and validate it against real-world data or expert opinions to ensure its accuracy and reliability.

8. Communicate findings: Present the findings of the simulation study, including the potential impact of the recommendations on improving access to maternal health, to relevant stakeholders and decision-makers. This can help inform policy and programmatic decisions to prioritize and implement the most effective interventions.

Auteur

Dima Health

Statistics:

Citations: 8

Identifiers:

DOI: 10.1093/tropej/fmt044

ISSN: 01426338

Research Areas:

Community Interventions, Environmental, Genetics and Genomics, Health System and Policy, Infectious Diseases, Maternal Access, Maternal and Child Health, Quality of Care, Technology and Innovations, Workforce

Study Countries:

Uganda

Study Design:

Cohort Study, Cross Sectional Study, randomised-control-trial

Study Approach:

Quantitative

Participants Gender:

Female

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