Gubio Soares Campos

Outbreak of Exanthematous Illness Associated with Zika, Chikungunya, and Dengue Viruses, Salvador, Brazil

To the Editor: Zika virus (ZIKV) has been recognized as an emerging mosquito-borne flavivirus since outbreaks were reported from Yap Island in 2007 (1), French Polynesia in 2013 (2), and Cook Island and New Caledonia in 2014 (3). It has joined dengue virus (DENV) and chikungunya virus (CHIKV) as global public health threats (4). ZIKV infection typically causes a self-limited dengue-like illness characterized by exanthema, low-grade fever, conjunctivitis, and arthralgia, and an increase in rates of Guillain-Barre syndrome have been observed during ZIKV outbreaks (5). In Brazil, clusters of cases of acute exanthematous illness have been reported from various regions since late 2014, and in April 2015, ZIKV was identified as the etiologic agent (6). In May 2015, the Brazilian Ministry of Health recognized circulation of ZIKV in Brazil. We report epidemiologic findings for an ongoing outbreak of acute exanthematous illness in the population of Salvador, the third largest city in Brazil. The Salvador Epidemiologic Surveillance Office (ESO) was first alerted to cases of an acute exanthematous illness early in 2015. Reporting of cases increased during March, and in April the ESO established 10 public emergency health centers in Salvador as sentinel units for systematic surveillance of patients with acute exanthematous illness of unknown cause. The units searched retrospectively for suspected cases by review of medical charts of patients treated since February 15, continued with prospective case detection, and submitted weekly reports of identified cases to the ESO. During February 15−June 25, a total of 14,835 cases of an indeterminate acute exanthematous illness were reported from the 12 sanitary districts in Salvador. The overall attack rate was 5.5 cases/1,000 persons (4.6 cases/1,000 men and 6.3 cases/1,000 women, 8.2 cases/1,000 children 40 years of age). The epidemic curve peaked in the first week of May, which was 1 week after molecular diagnosis of ZIKV in 8 patients residing ≈50 km from Salvador and during a period of intense media coverage of the outbreak (Figure) (6). Reporting of suspected dengue cases in Salvador did not vary substantially from that in other years and was >5 times lower: 2,630 cases, of which 165/366 (45.1%) were positive for dengue IgM, 20/590 (3.4%) positive for dengue virus nonstructural protein 1, and 1/11 (9.1%) positive for dengue virus by reverse transcription PCR (Figure). During the same period, 58 cases of suspected chikungunya were reported and 24 patients with suspected Guillain-Barre syndrome were hospitalized. Figure Reported cases of indeterminate acute exanthematous illness and suspected dengue fever in Salvador, Brazil, by date of medical care, February 15−June 25, 2015. Letters indicate specific events. A) February 15: systematic reporting of cases of ... The median age of case-patients was 26 years (interquartile range 11–39 years), but all age groups were affected, which is a pattern typical of spread of new microorganisms (or subtypes) in a susceptible population. Median duration of symptoms at time of medical attention was 1 day (interquartile range 0–3 days). All patients had exanthema and most (12,711/14,093 [90.2%]) had pruritus. Fever (4,841/13,786, 35.1%), arthralgia (278/1,048 [26.5%]), headache (3,446/13,503 [25.6%]), and myalgia (223/1,033 [21.6%]) were less common. Serum samples from some patients were examined for rubella IgM (2/200, 1.0% positive), rubella IgG (15/18, 83.3% positive), measles IgM (0/11, 0% positive), dengue nonstructural protein 1 (3/185, 1.6% positive), dengue IgM (17/80, 21.3% positive), parvovirus B19 IgM (0/1, 0% positive), and parvovirus B19 IgG (1/1, 100% positive). Reverse transcription PCR was performed on 58 serum samples stored at −20°C and confirmed ZIKV in 3 (5.2%) samples, CHIKV in 3 (5.2%) samples, DENV type 3 in 1 (1.7%) sample, and DENV type 4 in 1 (1.7%) sample. Identification of ZIKV, CHIKV and DENV as etiologic agents of acute exanthematous illness suggests that these 3 Aedes spp. mosquito−transmitted viruses were co-circulating in Salvador and highlights the challenge in clinically differentiating these infections during outbreaks. Although we were not able to determine the specific incidence of each virus, the low frequency of fever and arthralgia, which are indicators of dengue and chikungunya, point to ZIKV as the probable cause of several of the reported cases. Furthermore, laboratory-confirmed cases of infection with ZIKV were simultaneously identified in other cities within metropolitan Salvador (6,7) and in other states in Brazil (8). Low diagnosis of ZIKV infection is likely because viremia levels among infected patients appear to be low (9). The spread of ZIKV represents an additional challenge for public health systems, particularly because of the risk for concurrent transmission of DENV and CHIKV by the same vectors, Ae. aegypti and Ae. albopictus mosquitoes, which are abundant throughout tropical and subtropical regions. To date, the largest outbreak of chikungunya in Brazil occurred in 2014 in Feira de Santana, Bahia, ≈100 km from Salvador, where dengue is also prevalent (10). This report illustrates the potential for explosive simultaneous outbreaks of ZIKV, CHIKV, and DENV in the Western Hemisphere and the increasing public health effects of Aedes spp. mosquitoes as vectors. The apparent increase in reports of Guillain-Barre syndrome during the outbreak deserves further investigation to elucidate whether this syndrome is associated with ZIKV infection. Public health authorities in Brazil and neighboring countries should plan accordingly.

Predominance of Rotavirus Genotype G9 during the 1999, 2000, and 2002 Seasons among Hospitalized Children in the City of Salvador, Bahia, Brazil: Implications for Future Vaccine Strategies

ABSTRACT Two hundred eight of 648 (32%) diarrheal stool samples collected from hospitalized children under 5 years of age during a 3-year period (1999, 2000, and 2002) in the city of Salvador, in the state of Bahia, Brazil, were rotavirus positive. One hundred sixty-four of 208 (78.8%) rotavirus-positive samples had genotype G9 specificity, predominantly in association with P[8]. Other specificities detected were G1 (12.0%) and G4 (1.4%). Viruses with G2, G3, or P[4] specificity were not detected. Rotavirus genotype G9 predominated during each of the three seasons studied; it represented 89.2% of rotavirus strains detected in 1999, 85.3% in 2000, and 74.5% in 2002. G1 viruses (the globally most common G type) have a unique epidemiological characteristic of maintaining predominance during multiple consecutive rotavirus seasons. We have shown in this study for the first time that the G9 viruses also have a similar epidemiological characteristic, albeit for a shorter period of surveillance. The next generation of rotavirus vaccines will need to provide adequate protection against disease caused by G9 viruses.

Distribution of hepatitis B virus genotypes among patients with chronic infection

Abstract: Hepatitis B virus (HBV) can be classified into at least eight genotypes, A–H. We evaluated the distribution HBV genotypes among patients with chronic infection.

Emergence of Congenital Zika Syndrome: Viewpoint From the Front Lines

Zika, a mosquito-borne flavivirus discovered in Uganda in 1947, remained obscure until its emergence in Micronesia in 2007. Six years later, it arrived in French Polynesia and other islands in the South Pacific (1). The virus was first detected in Brazil in early 2015 and has now spread throughout South and Central America and the Caribbean (2). Infection often remains unrecognized because it either is asymptomatic (75% to 80%) or has a nonspecific presentation of rash and fever. The first suggestion that Zika virus causes more than a self-limited illness was during the French Polynesian outbreak, when incidence of Guillain-Barr syndrome increased 20-fold (3). Likewise, a cluster of cases of this syndrome was identified in Brazil after the introduction of Zika virus (4). From July to September 2015, several months after the introduction of Zika virus into northeastern Brazil, obstetricians noticed an increased number of fetuses with congenital malformations during ultrasound screening. By October, the number of newborns with microcephaly had increased significantly in this area, according to birth registry data from previous years. Microcephaly had now increased in other regions along with the spread of Zika virus. To date, more than 4000 cases have been reported (Figures 1 and 2). Figure 1. Distribution of incident cases of microcephaly among Brazilian newborns, according to epidemiologic week and geographic region from 15 November 2015 to 16 January 2016. From the Brazilian Ministry of Health. Figure 2. Cumulative cases of microcephaly according to federal state from 15 November 2015 to 16 January 2016. From the Brazilian Ministry of Health. That Zika virus is the cause of the large number of microcephaly cases identified during the epidemic remains presumptive (5). Brazilian researchers first noted the viruss potential association with microcephaly when they investigated a newborn with this condition, who died soon after birth and was found to have detectable virus in tissues. Subsequently, Zika virus RNA was detected in additional cases of fetuses and stillbirths with congenital malformations (68). To date, the strongest evidence of the correlation between Zika virus and microcephaly is a circumstantial link between the spatial and temporal patterns of these infections and the appearance of microcephaly. In addition, this condition was retrospectively identified in infants born during the 2013 outbreak in French Polynesia. Despite these observations, investigators have not determined a definitive association between Zika virus and microcephaly cases in the Brazilian outbreak, most of which have been live-born infants. Our investigation is still in progress; however, we have gained insight into the scope and severity of microcephaly due to presumed congenital Zika syndrome (CZS), as well as challenges in confirming this association. Microcephaly is characterized by severe manifestations, such as marked cerebral atrophy and ventriculomegaly, extensive intracranial calcifications, simplified gyral patterns, dysgenesis of the corpus collosum, and cerebellar hypoplasia (Figure 3). Furthermore, CZS manifestations that extend beyond the central nervous system have been observed, including auditory impairment as well as ocular manifestations (9), such as focal pigment mottling and chorioretinal atrophy, which are distinct from other congenital conditions. Similar ocular lesions have been anecdotally identified in normocephalic newborns, suggesting that the overall burden may not be restricted to microcephaly cases. Figure 3. Computed tomography, reconstructed in the coronal oblique plane, of a newborn with microcephaly. Craniofacial dysmorphism, subcortical and basal ganglia calcifications, simplified gyral pattern, ventriculomegaly, and dysgenesis of the corpus callosum are seen. Although the apparent increase in microcephaly supports the assertion that Zika virus causes a distinct congenital syndrome, diagnostic limitations suggest caution in assuming a causal relationship. We have detected Zika virus RNA in only a fraction of microcephaly cases. Increased case ascertainment of microcephaly due to other causes has probably occurred contemporaneously. The inability to detect Zika virus in newborns with microcephaly may reflect compartmentalization of virus in tissues not sampled at the time of birth. Alternatively, intrauterine infections may be self-limited and Zika virus often cleared by birth. Screening approaches are essential for pregnant women who reside in impoverished regions where Zika virus has been recently introduced and who do not have access to ultrasonography and amniocentesis. Although detection is hampered by the extensive antigenic cross-reactivity with dengue and other circulating flaviviruses, a serologic test for prior intrauterine exposure to the virus in newborns is critically needednot only for diagnosis in pregnant women and newborns but also to identify individuals who have been infected with Zika virus and are presumably immune to reinfection. A more accurate IgG assay is essential to stratify risk in women of childbearing age and to facilitate targeted prenatal screening. Molecular detection is unlikely to be available in many regions, and infections are asymptomatic. Potential explanations for the recent explosion of Zika virus in the Pacific islands and the Americas and its continued spread are unclear but include recent genetic/phenotypic virus changes before or coincident with its disbursement beyond Asia. This could involve selection for enhanced infection of mosquito vectors, such as Aedes aegypti. Such vector-adaptive selection of more transmissible chikungunya virus strains has occurred since 2005. Other possibilities include selection for higher levels of human viremia in the urban cycle, which could increase the efficiency of transmission as well as enhance fetal infection. A simpler explanation is that the outbreaks began when, by chance, the virus was introduced into naive populations at the right time and place for initiation of the humanmosquito cycle. If the virus is able to establish endemic or enzootic circulation (as has been suggested as occurring in Asia on the basis of seroprevalence data) stable herd immunity may prevent future epidemics, as well as CZS in Brazil. Further, genetic, pathogenesis, and vector infection studies with diverse virus strains combined with improved surveillance and better, more affordable diagnostics that can be deployed even in remote, resource-limited settings, are needed to evaluate these hypotheses. Unfortunately, the immediate prospects for controlling the magnitude and spread of the current Zika virus epidemic are not promising. Until a vaccine is available, mosquito control and education of at-risk populations to reduce contact with the vector are the only short-term approaches available. These methods have had limited success for dengue and chikungunya viruses. Although recent advances in flavivirus vaccines may guide relatively rapid development of a Zika vaccine, availability is still probably years away. Treatment with a monoclonal antibody could also be developed quickly on the basis of promising past results with flaviviruses. However, systematic investigations of pregnant women and newborns will still be needed to determine the risk for transplacental infection and development of severe congenital sequelae that can, in turn, guide effective diagnostic and prevention efforts.

Coinfections of Zika and Chikungunya Viruses in Bahia, Brazil, Identified by Metagenomic Next-Generation Sequencing

ABSTRACT Metagenomic next-generation sequencing (mNGS) of samples from 15 patients with documented Zika virus (ZIKV) infection in Bahia, Brazil, from April 2015 to January 2016 identified coinfections with chikungunya virus (CHIKV) in 2 of 15 ZIKV-positive cases by PCR (13.3%). While generally nonspecific, the clinical presentation corresponding to these two CHIKV/ZIKV coinfections reflected infection by the virus present at a higher titer. Aside from CHIKV and ZIKV, coinfections of other viral pathogens were not detected. The mNGS approach is promising for differential diagnosis of acute febrile illness and identification of coinfections, although targeted arbovirus screening may be sufficient in the current ZIKV outbreak setting.

Zika virus infection induces mitosis abnormalities and apoptotic cell death of human neural progenitor cells

Zika virus (ZIKV) infection has been associated with severe complications both in the developing and adult nervous system. To investigate the deleterious effects of ZIKV infection, we used human neural progenitor cells (NPC), derived from induced pluripotent stem cells (iPSC). We found that NPC are highly susceptible to ZIKV and the infection results in cell death. ZIKV infection led to a marked reduction in cell proliferation, ultrastructural alterations and induction of autophagy. Induction of apoptosis of Sox2+ cells was demonstrated by activation of caspases 3/7, 8 and 9, and by ultrastructural and flow cytometry analyses. ZIKV-induced death of Sox2+ cells was prevented by incubation with the pan-caspase inhibitor, Z-VAD-FMK. By confocal microscopy analysis we found an increased number of cells with supernumerary centrosomes. Live imaging showed a significant increase in mitosis abnormalities, including multipolar spindle, chromosome laggards, micronuclei and death of progeny after cell division. FISH analysis for chromosomes 12 and 17 showed increased frequency of aneuploidy, such as monosomy, trisomy and polyploidy. Our study reinforces the link between ZIKV and abnormalities in the developing human brain, including microcephaly.

Distinct Zika Virus Lineage in Salvador, Bahia, Brazil.

Sequencing of isolates from patients in Bahia, Brazil, where most Zika virus cases in Brazil have been reported, resulted in 11 whole and partial Zika virus genomes. Phylogenetic analyses revealed a well-supported Bahia-specific Zika virus lineage, which indicates sustained Zika virus circulation in Salvador, Bahia’s capital city, since mid-2014.

Molecular detection and genetic diversity of norovirus in hospitalized young adults with acute gastroenteritis in Bahia, Brazil

The molecular epidemiology of a recent norovirus (NoV) outbreak in Brazil performed by comparative analysis with Genebank NoV sequences showed that the GII.4 strain was responsible for 72.5% of all NoV-positive cases (58/80). Other detected NoV strains included GII.3 (7/80; 8.8%) and GII.9 (8/80; 10%). This is the first outbreak reported in Bahia state, Brazil, during June–July of 2006, where NoV was identified as the principal etiologic agent in hospitalized young adults with acute gastroenteritis symptoms. These findings suggest that GII.4 is a predominant circulating genotype in NoV outbreaks in Brazil.

Neonatal encephalitis due to Chikungunya vertical transmission: First report in Brazil

Purpose To report the first case of Chikungunya encephalitis acquired in the perinatal period during the current outbreak in Brazil Methods Case report. Results A male neonate with 3500 g developed macular erythematous rash, hypoactivity and fever progressing to generalized seizures. His mother had experienced a disseminated rash and fever before delivery. EEG showed diffuse slowing and cranial NMR was suggestive of encephalitis. Rt-PCR for Chikungunya virus (CHIKV) was positive in cerebrospinal fluid (CSF), blood, urine and saliva. The newborn was discharged home with neurological improvement. Conclusion We report the first case of a perinatal CHIKV infection associated with a rapidly evolving encephalitis and an extensive dissemination of the virus as documented by positive rt-PCR results in CSF, blood, urine and saliva in the present outbreak in Brazil. In countries experiencing outbreaks of CHIKV infections, clinicians and neonatologists must be familiar with the possibility of the occurrence of neurologic complications and its possible consequences.

Molecular characterization of group A rotavirus isolates obtained from hospitalized children in Salvador, Bahia, Brazil

Rotavirus is a major cause of infectious diarrhea in infants and young children. The objective of this study was to characterize the genotypes of Human Rotavirus found in children hospitalized with acute diarrhea in the Pediatric Hospital Prof. Hosannah de Oliveira of the UFBA in Salvador, Bahia, Brazil, during the years of 1999, 2000 and 2002. Fecal samples were analyzed (n=358) by methods EIARA and SDS-PAGE for detection of Rotavirus. Positive samples of one or two of these methods (n=168) were submitted to RT-PCR and Multiplex-Nested PCR to determine genotypes G and P. A hundred sixty-eight (46.9%) samples were positive and 190 (53.1%) negative. Only 17 (4.7%) samples had divergent results. The distribution of genotypes G during the first year, showed that the genotype G9 was present in 96,8% of the analyzed samples, in the second year, it was responsible for 96% and in the third year, 88,1%. The characterization of genotypes P demonstrated that the genotype P1A[8] was the most outstanding in all years. In this study we discuss the benefit to control the genotypes of Rotavirus through the molecular characterization for the development of potential vaccines.