Background
Group B
Streptococcus (GBS) is recognized as a leading cause of neonatal morbidity and mortality around the world [
1‐
4]. The incidence varies significantly by region. A systematic review and meta-analysis reported an estimated global incidence of GBS in infants <3 months old of 0.53 per 1000 live births (95% confidence interval [CI] 0.44–0.62) [
5]. The incidence was highest in Africa, with 1.21 per 1000 live births, followed by the Americas (0.67 per 1000 live births) and Europe (0.57 per 1000 live births) [
5]. Southeast Asia had the lowest incidence, at 0.02 per 1000 live births [
5]. However, data from Asia are very limited and the disease burden in Mainland China remains unclear [
5,
6].
The Center for Disease Control and Prevention (CDC) in US has issued a perinatal disease prevention strategy in 1996 with two revisions in 2002 and 2010 suggesting universal culture-based screening of pregnant women and intrapartum antibiotic prophylaxis (IAP) for GBS colonized women as an approach for neonatal GBS prevention. The implementation of the guidelines decreased the incidence of early-onset GBS disease (EOD; occurring in infants <7 days old) from 1.7 per 1000 live births in 1993 to 0.25 per 1000 live births by 2014 [
7‐
9]. Specific guidelines such as IAP for GBS prevention are lacking in China and only few hospitals strictly follow the guideline issued by the US CDC. The three study hospitals did not implement IAP during the studying period.
Our previous study, the first prospective observational study conducted in Mainland China, showed an incidence of GBS of 0.28 per 1000 live births (95% CI 0.08–1.03, 2/7061 subjects) [
10]. However, this 6-month study included only two urban hospitals [
10]. To obtain more precise incidences of invasive GBS in Guangdong province, we retrospectively collected data of cases with culture-confirmed invasive GBS disease among <3 months old infants from three large urban tertiary hospitals for 2011–2014. This study was to investigate the epidemiology of GBS infections in south China and to provide evidence for developing preventive interventions and the introduction of GBS vaccines in the future.
Methods
Study design
This retrospective study was conducted within three large urban tertiary hospitals in Guangdong (Guangzhou Women & Children’s Medical Center, Guangdong Provincial Maternity & Children’s Hospital, and Zhongshan Boai Hospital) from Jan 2011 to Dec 2014. Skilled attendants in these hospitals provide maternity services to pregnancies, intensive care units in these hospitals also provide neonatal and pediatric medical services. This study was approved by the local ethical committees of three study hospitals.
Data collection
GBS cases were identified from the microbiology laboratory databases of the studying hospitals. All of the study hospitals used automated enrichment culture methods to identify GBS. A GBS case was defined as a < 3 months old infant with a confirmed positive GBS culture from a sterile sample accompanied any of clinical signs or symptoms of sepsis, meningitis or pneumonia. EOD was defined as isolation of GBS from the infants within the first 6 days after birth, and late-onset disease (LOD) was defined as isolation of GBS from the infants 7–89 days after birth. Only culture-confirmed GBS cases born in the studying hospitals were included for the estimation of incidence and evaluation of clinical outcomes at discharge e.g. survived, survived with sequelae and died. The medical records of GBS cases were reviewed and extracted. The numbers of live births per year between 2011 and 2014 were provided by the statistical departments of studying hospitals.
GBS strain analysis
For suspected cases, blood and/or cerebrospinal fluid (CSF) samples were taken into culture bottles and sent to laboratories according to operation manuals of blood culture system (BD Bactec™ 9210 or BioMerieux Bact/ALERT). The
Streptococcus genus was identified using Gram stain, colony morphology, haemolysis, and a catalase test. API 20STREP, an automated identification panel for Gram-positive bacteria, was then employed (VITEK 2 COMPACT, BioMerieux, France). GBS isolates from culture-confirmed cases born elsewhere but transferred to the studying hospitals for medical treatment after delivery also were enrolled into strain analysis. Antimicrobial susceptibility to penicillin, ceftriaxone, vancomycin, linezolid, ofloxacin, sulfamethoxazole, tetracycline, erythromycin, clindamycin, was examined using the AST-GP67 (VITEK 2 COMPACT) or manual Kirby-Bauer disc diffusion, as per interpretive standards established by the Clinical and Laboratory Standards Institute (US) [
11]. GBS isolates were recovered in trypticase soy agar supplemented with 5% sheep blood. Lancefield serotyping was performed using a Strep-B-Latex® rapid latex agglutination test kit (Statens Serum Institute, Hillerød, Denmark) according to the manufacturer’s instructions. Multi-locus sequence typing (MLST) was performed by sequencing the internal fragments of seven house-keeping genes (
adhP,
pheS,
atr,
glnA,
sdhA,
glcK and
tkt). PCR products were purified and sequenced in both directions by BGI Tech Solutions Co.,Ltd.. Alleles and sequence types (STs) were determined using the
S. agalactiae MLST website (
http://pubmlst.org/sagalactiae/).
Statistical analysis
The incidence per 1000 live births was calculated by dividing the total number of confirmed GBS cases born in the studying hospitals by the total number of infants born in the studying hospitals and multiplying by 1000. For both the incidence and mortality, 95% confidence intervals (CI) were calculated using the Wilson interval method. The percentage changes were used to compare the incidences in each calendar year during the period of this study. The mortality rate was defined as the percentage (%) of the GBS cases born in studying hospitals, in which the infants died before discharge. The collected strains isolated from GBS cases born in the studying hospitals or elsewhere were enrolled for further analyses of serotyping, MLST and antimicrobial susceptibility. Serotype distribution is described as a frequency distribution (number and percentage). All analyses were completed with SPSS 19.0 (IBM Corp., Armonk, NY, US), and P < 0.05 was considered statistically significant.
Discussion
GBS is an important cause of neonatal sepsis and meningitis. Considerable demographic variation exists in terms of incidence and other disease burden indicators [
5,
6]. The overall incidence of invasive neonatal GBS disease (0.55 per 1000 live births, 95% CI 0.44–0.69) in Guangdong between 2011 and 2014, was close to the global average estimation (0.53 per 1000 live births, 95% CI 0.44–0.62) [
5]. However the incidence rate in this study is much higher than which was suggested in our previous short-term observation [
10] and in other Asian countries with the incidences rate 0.14–0.41 per 1000 live births [
12,
13]. Furthermore, GBS in EOD increased markedly from 2011 to 2014, reaching 0.58 per 1000 live births. The overall incidence of EOD (0.39 per 1000 live births, 95% CI 0.29–0.51) was higher than that from studies with any IAP (0.23 per 1000 live births) and lower than that from studies with no IAP (0.75 per 1000 live births) [
5]. IAP was not implemented in these three hospitals during the study period. Hence, the possible reason about the incidence of LOD was more stable than EOD include: Firstly, some LOD cases might go to other hospitals rather than the studying hospitals if they moved elsewhere; doctors paid more attention to the GBS identification over time so that the blood/CSF samples could be taken more timely than before. Secondly, the clinical symptoms of LOD mostly present as neurological sequelae. Therefore, the blood and cerebrospinal fluid from patients with similar symptoms are routinely examined for the presence of bacteria in these samples. However, the symptoms of EOD are similar to respiratory infections which may be treated with broad-spectrum antibiotics before blood culture examination. After introducing the tighten regulations of antibiotic usage gradually in the study hospitals since 2012, more blood samples from potential bacteria-infected patients were examined and more GBS infection from EOD patients were identified. This may reflect the realistic situation of GBS infections especially in EOD incidences. The growing number of sterile samples were sent to the laboratory for bacterial examination using the same experimental facilities under the same examining standard in study hospitals over the studying period [
14]. The increasing GBS infection rate was identified and suggested that GBS is an important pathogen of invasive neonatal infections and increases the threat to neonatal health in Guangdong in south China.
In this study the proportion of EOD (70%) is higher than that of LOD (30%). In other Asian countries such as Japan and Korea, reported that the LOD account for 75% (45/60) and 80% (125/157), respectively [
13,
15]. An important risk factor for EOD is GBS colonization of maternal vaginal and rectal sites during late pregnancy. No data about GBS colonization in Guangdong has been reported. A study conducted in the other Chinese city, Beijing, showed that 7.1% of pregnant women had GBS present in the vaginal-rectal tract [
16] which is lower than some developed countries (15–25%) [
17,
18]. Further study to explore the relationship between EOD and maternal GBS recto-vaginal colonization will be necessary in Guangdong in the future.
The overall mortality in the present study was 7.1% (95% CI 1.1–13.2%), which is lower than the global average with 9.6% (95% CI 7.5–11.8) [
5], 13.6% for EOD and 8.0% for LOD in Japan [
19], 6.2% in India [
20] and 20.7% for EOD and 7.2% for LOD in Korea [
15]. The administration of broad spectrum antibiotics and neonatal senior nursing interventions that were provided to suspected cases of sepsis may reduce the mortality rate in the studying hospitals. In addition, the relatively low mortality might be relevant with most of cases with a normal birth weight. The proportion of LOD cases with neurological sequelae was lower than the reported 25%–35% in other countries [
19,
21].
The studying hospitals provided effective anti-infection treatment for GBS cases in a timely manner and rehabilitation for cases with neurological signs, which are important to reduce the case fatality ratio and sequelae. In this study, the clinical isolated GBS strains are all susceptible to beta-lactam antibiotics including penicillin, ampicillin and cefazolin. Thus beta-lactam antibiotics are ideal to treat GBS diseases in the studying area. For the infants who are allergic to penicillin, considering high resistant rate to erythromycin and clindamycin (57.4% and 51.5%, respectively) in this study and the reported global increase in resistance to erythromycin and clindamycin over the last two decades [
22,
23], other antibiotics should be chosen. Furthermore, 95.6% of isolates resistant to tetracycline and 33.8% of isolates showed multi-drug resistance to lincosamides and macrolides. The antibiotics resistance had no correlation to any particular serotypes or MLSTs which suggested the ability of antibiotic-resistance in clinical GBS strains is universal and there is no barrier of antibiotic-resistance spreading between different serotypes or MLSTs. It is necessary to unremittingly observe the antibiotic resistance of GBS in Guangdong and a guideline for reasonable usage of antibiotics against GBS is desired.
Knowledge of the serotype is crucial to the development of serotype-based vaccines against GBS disease. Serotype distribution varies by country and region [
24,
25], with serotype III predominating worldwide [
5,
10,
26,
27]. It is well comparable to the results of our study. In this study, the percentage of serotype III was 77.9%, among these, 81.1% were caused by ST-17, which is higher than the similar study in Japan that half (50.0%) of the serotype III strains were ST17 [
28]. The use of potential GBS vaccines during pregnancy will not only overcome problems caused by IAP (e.g., no impact on LOD and antibiotic resistance), reducing the incidence and mortality of GBS disease [
17,
29]. The trivalent GBS vaccine covering serotypes Ia, Ib, and III was also well tolerated and induced capsular-specific antibody responses [
30], which are associated with 95.6% of GBS cases in the present study, 92.7% of GBS cases in Japan [
28] and approximately 79% of GBS cases globally [
5]. Furthermore, the serotyping in the present study indicated that a pentavalent conjugate vaccine covering serotypes Ia, Ib, II, III, and V could potentially prevent 100% of neonatal invasive GBS disease; these five capsular serotypes corresponded to 95% of invasive disease worldwide [
5]. The findings were also consistent with a recent study among pregnant women in Beijing, which reported that serotypes III, Ia, V, and Ib accounted for 91.3% of all serotyped isolates [
16].
All false-negative cases, spontaneous abortions and stillbirths caused by GBS infection might have been missed and not been included in this study. Furthermore, this study was conducted in three urban hospitals which are regarded as the best institutions for infant disease treatment in South China, it is difficult to monitor the outcomes and infections incidences after patients discharged from occasional visits. The prolonged studying period and expanded studying area will overcome the limitation of this study. Acquiring the duration and dosage of intrapartum antibiotics usage for GBS-colonized pregnant women in the course of delivery is necessary to include in the future study.