Clinical Trial Details
— Status: Completed
Administrative data
NCT number |
NCT03199547 |
Other study ID # |
SCC 1532 |
Secondary ID |
|
Status |
Completed |
Phase |
Phase 3
|
First received |
|
Last updated |
|
Start date |
October 21, 2017 |
Est. completion date |
May 31, 2021 |
Study information
Verified date |
March 2022 |
Source |
London School of Hygiene and Tropical Medicine |
Contact |
n/a |
Is FDA regulated |
No |
Health authority |
|
Study type |
Interventional
|
Clinical Trial Summary
Though maternal and neonatal health are high priority areas for international development,
maternal and neonatal mortality remain unacceptably high. Worldwide there are 1 million
maternal and 4 million neonatal deaths every year and half of them occur in sub-Saharan
Africa.
Post-partum and neonatal severe bacterial infections, namely sepsis, are leading causes of
maternal and neonatal deaths in sub-Saharan Africa. Newborns can be infected during labour -
when passing through the birth canal - and also during the first days/weeks of life, as a
consequence of the close physical contact with the mother, when the latter carriers bacteria.
As the mother is an important source of bacterial transmission to the newborn, treating
mothers with antibiotics during labour should decrease their bacterial carriage and therefore
lower transmission to the newborn. As carriage is a necessary step towards severe disease,
this intervention should in turn result in the lower occurrence of severe bacterial disease
and mortality during the neonatal period.
In many high-income countries, pregnant women are screened during pregnancy for vaginal
carriage of Group B Streptococcus, the bacteria responsible for the vast majority of neonatal
sepsis in the developed world. If women are carriers, they are treated with intravenous
antibiotics during labour to decrease the risk of severe disease to their off-spring.
Although this intervention has been successful in developed countries, infrastructure and
resource limitations in regions like sub-Saharan Africa prevent both screening and use of
intravenous antibiotics. Also, in Africa several bacterial pathogens are responsible for
neonatal sepsis and the antibiotics needed in the continent should cover a wider number of
bacteria; and ideally cover also bacteria responsible for severe post-partum disease in the
mother.
We will conduct a large trial in West Africa, The Gambia and Burkina Faso, with the main
objective of determining if a single dose of an oral antibiotic given to women during labour
decreases newborn mortality. The trial will also assess the effect of the antibiotic on
lowering newborns and maternal hospitalization during the first week's post-partum. We have
selected an antibiotic (azithromycin) that in sub-Saharan Africa has already been used for
elimination of other prevalent diseases such as trachoma. This antibiotic is safe, requires a
single oral administration, has no special storage requirements and has the potential to
eliminate most of the bacteria commonly causing severe disease in newborns and post-partum
women in the continent. Very important this antibiotic is not widely used in clinical care in
the continent, and therefore, any temporal increase of resistance induced by the intervention
should not have implications on current treatment guidelines.
Before going to the large trial proposed here (12,000 women to be recruited), we have
generated robust preliminary data on the effect of the intervention in a proof-of-concept
trial conducted in The Gambia (829 women and their offspring recruited). We found that in
fact, babies born from mothers who had taken this antibiotic during labour were less likely
to carry bacteria that can potentially cause severe disease. These babies were also three
times less likely to have bacterial skin infections or umbilical infections, both highly
common among African newborns. Besides, fever or mastitis (again both very common in the
region) during the post-partum period were four times lower among mothers who had taken the
antibiotic during labour. Such trial confirmed our hypothesis of impact on bacterial
transmission but it was too small to assess the effect of the antibiotic on mortality and
hospitalizations. The preliminary trial also showed that women from the azithromycin group
were less likely to need antibiotics for treatment infections during the puerperal period,
decreasing then the pressure on the scarcity of antibiotics available in the continent.
The advantages of our approach are its simplicity, low cost and the possibility of protecting
both mothers and babies with the same intervention.
Description:
other data elements, such as eligibility criteria or outcome measures. (Limit: 32,000
characters) Project title: Pre-delivery administration of azithromycin to prevent neonatal
sepsis and death: a phase III double-blind randomized clinical trial Acronym: PregnAnZI-2
LIST OF INVESTIGATORS
Chief Investigator:
Dr Anna Roca, PhD MRC Unit The Gambia PO Box 273 Banjul The Gambia, West Africa aroca@mrc.gm
Co-Investigators:
Prof Umberto D'Alessandro Director - MRC Unit The Gambia PO Box 273 Banjul The Gambia, West
Africa udalessandro@mrc.gm
Dr Christian Bottomley PhD Trial Statistician London School of Hygiene and Tropical Medicine
London Christian.bottomley@lshtm.ac.uk
Dr Halidou Tinto PhD Site PI Burkina Faso Clinical Research Unit of Nanoro Burkina Faso
tintohalidou@yahoo.fr
Clinical Trial Coordinators:
Dr Bully Camara MD MRC Unit The Gambia PO Box 273 Banjul The Gambia, West Africa +2204495917
Dr Marc Tahita Clinical Research Unit of Nanoro Burkina Faso BACKGROUND AND RATIONALE
Neonatal and maternal sepsis are major contributors to the high burden of mortality in
sub-Saharan Africa (SSA). Bacterial infections are leading causes of neonatal deaths,
representing 1 out of 3 deaths in this age group (1).
Neonatal sepsis is the consequence of bacterial infection during early life. Newborns may be
infected during labour (through the birth canal) or during the first days/weeks of life, when
they may become infected because of the close physical contact with the mother, if the latter
carries bacteria (i.e. in the nasopharyngeal tract), a common occurrence in resource-limited
settings, particularly in SSA. Streptococcus pneumoniae and group A Streptococcus are
important in the late neonatal period (from the second week of life), while group B
Streptococcus (GBS), Staphylococcus aureus and Escherichia coli occur often in both the early
and late neonatal periods (2).
AZI is a semi-synthetic azalide macrolide that is structurally related to erythromycin but
has a broader spectrum of antibacterial activity, improved tissue penetration and a more
favourable pharmacokinetic profile (3). Azithromycin is a cheap, wide spectrum, oral
antibiotic that is safe to use in mothers and newborns, does not require special storage
conditions, and can be delivered at the most peripheral level of care.
Between 2013 and 2015, we conducted as first proof-of-concept, a double-blind randomized
trial on the effect of 2g of AZI administered to Gambian women in labour on maternal and
neonatal bacterial carriage (4). The primary endpoint was bacterial carriage at day 6 in the
newborn (i.e. S.aureus, GBS or S.pneumoniae). The rationale for the study was that this
intervention would decrease bacterial carriage of the study bacteria both, in the mother and
the newborn and consequently the risk of invasive bacterial disease or sepsis. We found that
the intervention substantially reduced the prevalence of carriage of each of these three
bacteria, both in the newborn and the mother, during the entire neonatal/puerperal period
(4).
Figure 1. Prevalence of nasopharyngeal bacterial carriage during the neonatal period.
(a) Newborn (b) Mother1
1 Maternal nasopharyngeal swab at day 0: collected before the intervention was given.
Our study also showed that women in the AZI group had a lower prevalence of the study
bacteria in the breast milk during the entire neonatal period (day 6: 9.6% vs 21.9%, RR=0.44,
p<0.001) and in the vaginal tract (8-10 days: 13.2% vs 24.2% RR=0.55 - p<0.001).
Although the study was not designed to evaluate clinical endpoints, prevalence of these
endpoints decreased significantly in the AZI group (5). The use of antibiotics, and the
occurrence of fever, mastitis and puerperal infections were significantly lower in the AZI
group (Table 1). Newborns in the intervention group had fewer infections (skin infections,
umbilical infections, ear infections, conjunctivitis or mild sepsis) during the neonatal
period (Table 2). There were also fewer neonatal deaths due to severe infections in the AZI
group (0.4% versus 1.4% excluding neonates with severe congenital malformations).
Table 1. Clinical endpoints and antibiotic use of study women during the puerperal period.
MATERNAL Azithromycin (N=414) Placebo (N=415) RR(95%CI) p-value Maternal infections n(%) n(%)
Mastitis 6(1.4) 21(5.1) 0.29(0.12,0.70) 0.005 Puerperal sepsis 4(1.0) 5(1.2) 0.80(0.22,2.97)
1 Related infections 3(0.7) 9(2.2) 0.33(0.09,1.23) 0.143 Others 2(0.5) 5(1.2) 0.40(0.08,2.06)
0.451 Any of above 17(4.1) 38(9.2) 0.45(0.26,0.78) 0.005 Fever 8(1.9) 24(5.8) 0.33(0.15,0.74)
0.006 Use of antibiotic (for clinical care) 25(6.0) 42 (10.1) 0.58(0.36,0.94) 0.031 Table 2.
Clinical endpoints and antibiotic use of study children during the neonatal period.
NEONATES Azithromycin (N=419) Placebo (N=424) RR(95%C) p-value Neonatal infections n(%) n(%)
Skin infection 13(3.1) 27(6.4) 0.49(0.25,0.93) 0.034 Umbilical infection 1(0.2) 4(0.9)
0.25(0.03,2.25) 0.374 Conjunctivitis 37(8.8) 45(10.6) 0.83(0.55,1.26) 0.417 Otitis 3(0.7)
5(1.2) 0.61(0.15,2.52) 0.725 Oral infection 12(2.9) 13(3.1) 0.93(0.43,2.02) 1 Sepsis 18(4.3)
15(3.5) 1.21(0.62,2.38) 0.598 Meningitis 0(0.0) 1(0.2) NA 1 Pneumonia 3(0.7) 4(0.9)
0.76(0.17,3.37) 1 Any of above 76(18.1) 101(23.8) 0.76(0.58,0.99) 0.052 Fever 54(12.9)
43(10.1) 1.27(0.87,1.85) 0.235 Use of any antibiotic (for clinical care) 43(10.1) 42(10.0)
0.99(0.66,1.5) 1 The time point when the endpoints occurred during the follow-up period are
summarized in Figure 2 below.
Figure 2. Proportion of mothers and newborns infected at different points during the follow
up.
p-values from the log-rank test (mothers p=0.001, newborns p=0.04) AZI was safe for both the
mothers and the newborns. Hypertrophic pyloric stenosis (HPS) was not observed in any of the
study children during the 2-month follow up period (4).
Azithromycin is a cheap, wide spectrum, oral antibiotic that is safe to use in mothers and
newborns, does not require special storage conditions, and can be delivered at the most
peripheral level of care.
In the trial presented here, we want to assess the impact of using AZI during labour on
neonatal mortality as well as maternal and neonatal sepsis and infant growth. If successful,
this simple intervention could be easily implemented through the health system at the most
peripheral level of care. It has the potential to achieve wide coverage in SSA where low-cost
interventions aiming at reducing neonatal mortality are urgently needed. In addition, the
intervention should concomitantly protect women and newborns. Azithromycin resistance will
also be monitored as the former trial showed high rates of AZI resistance for S. aureus.
However, AZI is not widely used in SSA for clinical treatment and therefore any short-term
resistance arising from the intervention would have little impact on clinical care.
References
1. Lawn JE, Cousens S, Zupan J et al. (2005) 4 million neonatal deaths: When? Where? Why?
Lancet 365: 891-900. S0140-6736(05)71048-5.
2. Sigauque B, Roca A, Mandomando I et al (2009) Community-acquired bacteremia among
children admitted to a rural hospital in Mozambique. Pediatr Infect Dis J 28: 108-113.
3. Chico RM, Chandramohan D (2011) Azithromycin plus chloroquine: combination therapy for
protection against malaria and sexually transmitted infections in pregnancy. Expert Opin
Drug Metab Toxicol 7: 1153-1167.
4. Roca A, Oluwalana C, Bojang A et al (2016). Oral azithromycin given during labour
decreases bacterial carriage in the mother and their offspring: a double-blind
randomized trial. Clin Microbiol Infect. Jun;22(6):565.
5. Oluwalana C, Camara B, Bottomley C, et al (2017). Azithromycin in labor lowers clinical
infections in mothers and newborns: a double-blind trial. Pediatrics; 139(2).
TRIAL DESIGN
This is a multi-country phase III, double-blind, placebo-controlled, randomised trial in
which 12,500 women in labour will be randomised to receive either a single dose of 2g of
oral azithromycin or placebo (ratio 1:1). Pregnant women (age ≥16 years) will be
identified during antenatal clinic visits in several health facilities in The Gambia and
Burkina Faso; and will be asked to provide written informed consent. Recruitment will
take place when these women attend the study health facilities in labour.
INCLUSION AND EXCLUSION CRITERIA Pregnant women (age ≥16 years) will be identified
during antenatal clinic visits and asked to provide written informed consent. During
labour they will be screened and recruited unless they have any of the following
exclusion criteria: planned caesarean section, ante-partum haemorrhage, known allergy to
macrolides, confirmed intrauterine death or a known severe congenital malformation. The
randomisation number will only be assigned after the screening.
TRIAL OBJECTIVES
The primary objective of the study is to assess the effect of one oral dose of AZI (2g)
given to women in labour on neonatal sepsis and mortality (from birth to 28 days).
Deaths due to severe birth asphyxia (Apgar score <3 at 1 min); severe congenital
malformations and very low birth weight (VLBW) (<1.5Kg) will be excluded. Note: Those
deaths excluded from the primary objective are considered in some of the secondary
objectives below.
Secondary objectives of the trial include the effect of the intervention on other
clinical endpoints (for both neonates and mothers) and on microbiological endpoints
(prevalence of carriage and resistance of different bacterial pathogens):
(i) Neonates
a. Efficacy on clinical neonatal sepsis b. Efficacy on neonatal deaths, excluding those
due to severe birth asphyxia, severe congenital malformations or VLBW c. Efficacy on
severe birth asphyxia and associated deaths d. Efficacy on culture-confirmed neonatal
sepsis e. Efficacy on all cause-hospitalisation during the follow-up period (during the
first 28 days) f. Efficacy on sepsis and all cause mortality among VLBW g. Efficacy on
skin infection h. Efficacy on bacterial conjunctivitis i. Efficacy on umbilical cord
infections j. Efficacy on clinical malaria k. Efficacy in the use of antibiotics during
the neonatal period
(ii) Infants (Children of the first 1,000 mothers recruited per country followed-up to 1
year)
1. Efficacy on all cause-mortality
2. Efficacy on malnutrition - Height-for-age (HAZ), weight-for-age (WAZ),
weight-for-height (WHZ), body mass index-for-age, head circumference-for-age, and
MUAC for age (28 days; 6 and 12 months)
(iii) Mothers (up to 28 days) a. Efficacy on post-partum sepsis b. Efficacy on
post-partum mastitis c. Efficacy on post-partum malaria d. Efficacy on post-partum fever
e. Efficacy on use of post-partum antibiotics f. Efficacy on all post-partum
hospitalisations g. Efficacy on all post-partum mortality (iv) Microbiological
objectives (for hospitalised newborns)
1. Efficacy on prevalence of S. pneumoniae and Klebsiella spp in the nasopharynx
2. Efficacy on prevalence of E.coli and Pseudomonas spp in rectal swabs (RS)
3. Efficacy on prevalence of S. aureus, GBS, GAS in the oropharyngeal swabs
(v) Microbiological objectives (random selection of 250 participant pairs in each
country)
1. Efficacy on prevalence of S. pneumoniae and Klebsiella spp in the nasopharynx of
study infants at different time points.
2. Efficacy on prevalence of E. Coli, Klebsiella spp and Pseudomonas spp from RS
collected from infants at different time points.
3. Efficacy on prevalence of S. aureus, GBS and GAS in the oropharynx of infants at
different time points.
4. Efficacy on prevalence of S. aureus, GBS, GAS, E. coli, Pseudomonas spp and
Klebsiella in the breast milk of the study women at different time points.
5. Efficacy on prevalence of S. pneumoniae and Klebsiella spp in the nasopharynx of
study women one week after the intervention.
6. Efficacy on the prevalence of S. aureus, GBS and GAS in the oropharynx of study
women one week after the intervention.
7. Effect of the intervention onAZI, oxacillin and amoxicillin resistance among
isolates of S. aureus, GBS, GAS, S. pneumoniae, Klebsiella spp, E. coli and
Pseudomonasspp at different time points during the follow-up period.
(vi) Clinico-microbiological sub-analysis (sub-group of approximately 4,000 for whom
pre-intervention recto-vaginal swab is collected during labour)
a. Efficacy of the intervention on neonataland maternal outcomes [see (i) and (iii)]
when women are carrying S. aureus, Klebsiella spp, Pseudomonas spp, GBS, GAS or E. coli
in the recto-vaginal tract.
Tolerability of AZI given during labour will be monitored for all recruited women.
Other aspects of the study such as Qualitative research and Health economics are not
included in the clinical trial protocol but a summary of the objectives are as follows:
(vii) Qualitative research: a. Perceptions and acceptability by pregnant women and the
study communities on the taking antibiotic during labour.
(viii) Health economics
a. Costs of delivering AZI during labour in a health facility. b. Cost of a newborn
death. c. Hospitalisation treatment costs. d. Disability Adjusted Life Year averted from
delivering the intervention. PARTICIPANTS AND SAMPLES We will recruit 12,500 women and
their newborns. Approximately half of this number of women will be recruited in The
Gambia and half in Burkina Faso. However, the recruitment will be competitive and if one
country does not reach the numbers within the time period expected, the other will
increase the recruitments.
Figure 3. Length of follow-up of study participants and visits.
*Visit at Day 0/1 (recruitment at the health facility and discharge from the health
facility) and visit at Day 28 is the same for all the study participants. The additional
active visits are only for participants included in one of the sub-studies.
All study participants will be followed for 28 days. During this follow-up period,
samples will be collected if they are hospitalized with suspicion of sepsis (mothers and
newborns). Clinical samples to conduct sepsis work up will be collected. For newborns
hospitalized with clinical suspicion of sepsis, we will also collect nasopharyngeal
swabs (NPS), oropharyngeal swabs (OPS) and rectal swabs (RS).
For 250 participant pairs recruited in the carriage sub-study. Samples will be collected
according to the table below.
Table 3. Samples collected from the participants included in the carriage sub-study.
Day 01 Day 6 (±2 days) Day 28 (±4 days) 4 Months (±2 weeks) Mother Recto-Vaginal swab X2
Nasopharyngeal swab X2 X Oropharyngeal swab X2 X Breast Milk X X X Newborn
Nasopharyngeal swab X3 X X X Oropharyngeal swabs X3 X X X Rectal swabs X3 X X X 1Samples
at day 0 will be collected at the health facilities. 2For the women, samples will be
collected before treatment; 3Within 4 hours after birth.
For infants of the first 1,000 mothers s participating in the anthropometrical
sub-study. These children will be followed for 1 year but no additional samples will be
collected. Anthropometric information will be collected during the additional visits at
6, 9 and 12 months; and information of AE will be collected.
CENTRES INVOLVED IN THE TRIAL
In The Gambia, we will conduct the trial at Bundung Maternal and Child Health Hospital
and Serrekunda Health Facility. Bundung Maternal and Child Health Hospital is where the
proof-of-concept trial was conducted. The hospital delivers approximately 5,000 babies
each year and is located on the Gambian coast, 15 km from the MRC The Gambia
headquarters. Pregnant women usually have 2-3 antenatal visits during the second and
third trimester and they are kept in the health centre for approximately 6 hours after
delivery. Serrekunda Health Facility is located approximately 15Km from both the Bundung
Maternal and Child Health Hospital and the MRC The Gambia headquarters. Approximately,
2,000 deliveries take place per year. In The Gambia, maternal mortality ratio is 461
deaths/100,000 live births (4) and infant mortality rate is above 50 deaths/1,000 live
births (5).
In Burkina Faso, the study will be carried out at the Clinical Research Unit of Nanoro
(CRUN) located in the rural central west region of the country. In 2013, the total
population of the Nanoro Health district was estimated at 158,127 people. There are 14
peripheral health facilities (covering 70 villages) around the referral hospital, all
with maternity and extended program of immunizations (EPI) services. Seven to 10 of
these health facilities will be part of the trial. The epidemiological profile of
diseases remains dominated by communicable infectious diseases. Maternal mortality rate
is 300 deaths/100,000 live births and infant mortality rate is 78.3 deaths/1,000 live
births. A Health and Demographic Surveillance System (HDSS), which covers a total
population of about 60,000 people in 24 villages (7 health facilities) was set up in
2009 by the CRUN within the Health district catchment area.
ALLOCATION OF PARTICIPANTS Randomisation lists based on permuted blocks will be created
independently for each country, and blister packs will be numbered according to the
list. The trial will comply with Good Clinical Practices (GCP).
RISK TO THE SAFETY OF THE TRIAL
1. Hyperpyloric stenosis (HPS). Azithromycin is associated with HPS in infants (6)
although it is uncertain in the context of azithromycin treated breast feeding
women (7). Typically, infants with HPS do not show any symptoms at birth but they
develop projectile vomiting and other metabolic abnormalities during the first few
weeks of life. Data generated in our pilot study showed that azithromycin reaches
the breast milk and traces are still detectable in samples collected at day 28 (8).
There is some evidence that HPS is less frequent in SSA (9). In our pilot study
none of the 419 children whose mother received azithromycin developed HPS (8).
Nevertheless, newborns will be carefully followed up for signs of HPS.
2. Azithromycin resistance. Azithromycin is not routinely used for clinical care in
SSA and has a wide antimicrobial spectrum (10). For these reasons it has been used
in several successful mass drug administration (MDA) campaigns, including trachoma
and yaws control and elimination (11;12), and in clinical trials for the prevention
of malaria in pregnancy and preterm births (13). Most studies have shown to varying
degrees that resistant bacteria can be selected after a single dose. Nevertheless,
in the absence of antibiotic pressure, resistance disappears due to the lower
fitness of resistant bacteria (14). Studies that have used azithromycin for MDA, in
which thousands of people were treated at the same time, have shown that
S.pneumoniae resistance is only maintained for more than a few months in
communities where the baseline prevalence of resistance is high (15). In The Gambia
azithromycin resistance after MDA for trachoma elimination reverted to baseline
levels 6 months after the intervention (16). In our pilot study, resistance of
S.aureus was high 28 days after treatment but decreased to baseline levels 12
months after treatment (Bojang et al in prep). As azithromycin is not used in
standard clinical care, there would be little selective pressure on resistant
bacteria. In addition, it is interesting to note that in our pilot trial women in
the azithromycin group used other antibiotics less often than women in the placebo
arm (2). This suggests that the intervention might decrease selective pressure on
the few antibiotics available for standard clinical care in the region. Resistance
to azithromycin and other antibiotics among the trial participants will be assessed
in the proposed study.
SAMPLE SIZE CALCULATION In our proof-of-concept trial, the prevalence of bacterial
carriage in the azithromycin group decreased by more than 50%, and there were 6 neonatal
deaths (1.4%) (primary endpoint as defined above) in the placebo arm compared to 2
(0.4%) in the azithromycin arm (70% reduction).
We assume that mortality in the placebo arm will be at least 1.4% - this is a
conservative estimate as in the proof-of-concept trial neonates were closely followed up
during the first week of life and this probably decreased the risk of death. Assuming
the intervention reduces neonatal mortality by 40%, we would need 5,800 women per arm to
show a significant difference at 80% power and 5% significance level. And allowing for
8% loss to follow-up, we would need to recruit a total of 12,500 women.
Up to two thirds of these women will be recruited in the Gambia, and the remainder will
be recruited in Burkina Faso, depending on the pace of recruitment in both countries.
Maternal and infant mortality rates in these two countries are similar. The sample size
would also provide reasonable power for the secondary endpoints of maternal and neonatal
infection, hospitalisation and antibiotic use, since their occurrence is higher than
neonatal death.
As during the trial we have observed a mortality of approxiamtely half of the expected,
we have modified the endpoint to a composite endpoint of mortality or sepsis. This
composite endpoint prevalence is approximately 2.1% of the total sample size. Assuming
the intervention reduces the endpoint by 28%, 12,000 participants gives us 80% power at
a 5% significance level to detect differences by study arm.