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History, epidemiology and diagnostics of dengue in the American and Brazilian contexts: a review

Abstract

Dengue virus (DENV), an arbovirus transmitted by mosquitoes, has become a major threat to American human life, reaching approximately 23 million cases from 1980 to 2017. Brazil is among the countries most affected by this terrible viral disease, with 13.6 million cases. DENV has four different serotypes, DENV1-4, which show a broad clinical spectrum. Dengue creates a staggering epidemiological and economic burden for endemic countries. Without a specific therapy and with a commercial vaccine that presents some problems relative to its full effectiveness, initiatives to improve vector control strategies, early disease diagnostics and the development of vaccines and antiviral drugs are priorities. In this study, we present the probable origins of dengue in America and the trajectories of its spread. Overall, dengue diagnostics are costly, making the monitoring of dengue epidemiology more difficult and affecting physicians’ therapeutic decisions regarding dengue patients, especially in developing countries. This review also highlights some recent and important findings regarding dengue in Brazil and the Americas. We also summarize the existing DENV polymerase chain reaction (PCR) diagnostic tests to provide an improved reference since these tests are useful and accurate at discriminating DENV from other flaviviruses that co-circulate in the Americas. Additionally, these DENV PCR assays ensure virus serotyping, enabling epidemiologic monitoring.

Background

Dengue is a disease caused by an arbovirus. This term refers to arthropod-borne viruses, as defined by the World Health Organization (WHO). Dengue virus (DENV) belongs to the family Flaviviridae and the genus Flavivirus and has four different serotypes (DENV1-4) [1, 2]. This pathogen is an enveloped virus with icosahedral symmetry and a diameter of approximately 50 nm [3, 4]. DENV has a genome consisting of a single positive-polarity RNA strand approximately 10.8 kb in length with an open reading frame that encodes a single polyprotein that is cleaved into the capsid (C), membrane (M), and envelope (E) structural proteins and eight non-structural (NS) proteins, NS1, NS2A, NS2B, NS3, NS4A, NS2K, NS4B and NS5. Structural glycoprotein E is responsible for cell recognition and for promoting entry, which is mediated by a fusion process between the viral envelope and the cell membrane, while the NS proteins aid viral genome replication [2, 3, 5].

Dengue fever (DF) has been well studied because it is a systemic and dynamic infection with a broad clinical spectrum that includes serious and non-serious clinical manifestations. This infection can evolve in phases: a feverish, critical phase with hemorrhagic fever symptoms, known as dengue hemorrhagic fever (DHF), and dengue shock syndrome (DSS). Both phases are considered complications, and uncomplicated cases are characterized by mild, spontaneous or induced manifestations, defined by thrombocytopenia (platelet count < 100,000/mm3) followed by a recovery phase [6].

No effective therapy for dengue exists. Treatment is purely symptomatic, requiring a high level of patient care; patients can be hospitalized to facilitate fluid replacement and blood transfusion when indicated [7]. Severe cases occur in approximately 500,000 people/year and present a mortality rate of up to 10% for hospitalized patients and 30% for non-hospitalized patients [5, 8].

DENV and other arboviruses that co-circulate in the Americas, such as Zika virus (ZIKV), yellow fever virus (YFV) and chikungunya virus (CHIKV), are transmitted by mosquito species of genus Aedes [9,10,11], particularly Aedes aegypti in the Americas [12].

Dengue in the Americas has an endemo-epidemic pattern with outbreaks every three to five years. Based on the epidemiological patterns of the disease, mainly determined by the reported circulation of the DENVs and the main vector, Brathwaite Dick et al. [13] documented four important time periods of dengue incidence in the Americas from 1600 to 2010. In the Americas, 1 million cases occurred in the 1980s, and 4.7 million cases occurred from 2000 to 2007 [13].

The main objective of this review is to show that the trend toward elevated dengue incidence and number of deaths was even higher in the period 2011–2017, than that in the period 2001–2010. This review aims to provide the reader with knowledge of the disease trajectory, prevention mechanisms and disease etiology, as dengue has become a major public health problem in the Americas, especially in Brazil from 2011 to 2017. Increasingly intense efforts are being made to seek effective vaccines and antiviral agents that can prevent and control this infection. Major problems are the sensitivity and cost of diagnostic tests, which hamper the immediate treatment of symptoms, as well as the high costs of healthcare for dengue patients and the epidemiological monitoring of the disease.

A brief history of dengue in the Americas

Historically, it has not been determined when DENV first appeared in human populations, mainly because the disease is often asymptomatic and is therefore not diagnosed [2]. The earliest record of dengue comes from a Chinese medical encyclopedia dating back to 992 BC [14]. Moreover, before the end of the 18th century, intermittent epidemics of a specific disease with a strong similarity to dengue occurred in Asia and the Americas; therefore, there is a hypothesis that between the 19th and 20th centuries, the virus probably spread throughout the tropics and subtropics [1].

The trajectory of dengue outbreaks in the Americas was characterized by Brathwaite Dick et al. [13], who described an outbreak history from 1600 to 2010 that was categorized into four phases: introduction of dengue in the Americas (1600–1946), continental plan for the eradication of Ae. aegypti (1947–1970) marked by the successful eradication of the mosquito in 18 continental countries, Ae. aegypti reinfestation (1971–1999) caused by the failure of the mosquito eradication program, and increased dispersion of Ae. aegypti and DENV circulation (2000–2010) characterized by a marked increase in the number of outbreaks [13, 15].

In the Americas, a new outbreak during the period 2011–2017 was coincidentally observed after the great movement of people caused by four global sporting events: the 2011 Pan-American Games in Guadalajara (Mexico), the 2013 Confederations Cup, the 2014 World Cup and the 2016 Olympics, all of them in Brazil. This outbreak was reflected in the dengue mortality rate [16].

Considering data from the Pan-American Health Organization (PAHO) [17], a total of 1,073,978 cases of dengue, 19,450 severe dengue cases and 758 deaths were reported in the Americas at the end of 2011, with an average dengue incidence of 113 cases/100,000 inhabitants [18]. Despite the historical increase in the dengue case number reported in 2011, the number of cases, severe dengue cases, and deaths were reduced by approximately 45% compared to those in 2010. However, the case fatality rate (CFR) maintained the same value (0.07%). The Southern Cone subregion reported a total of 796,548 cases, contributing 71% of the total cases. Surprisingly, Brazil contributed 95% of the total number of cases in this region (756,720 reported cases).

In the final epidemiological week (EW) of 2012, a total of 1,162,998 cases had been recorded in the entire continent, at an average incidence of 120.7 cases/100,000 inhabitants [18]. The data exceeded the total number of cases reported in 2011, with a great increase (approximately 60%) in the total number of severe cases (32,408) and a slight increase (approximately 7%) in the total number of deaths (807) compared to the year 2011. The Southern Cone subregion reported a total of 639,348 cases, contributing 54% of the total cases. Brazil again contributed 93% of the total number of cases in this region (594,593 reported cases).

By the end of 2013, there was an increase in the number of cases; 2,384,234 cases of dengue and 1,403 deaths were reported. The average incidence of dengue was 245 cases/100,000 inhabitants [18]. However, it is important to emphasize that although there was an increase in the number of dengue cases, the total number of severe cases (37,692) and the CFR remained close to the values observed in 2012. The Southern Cone subregion reported a total of 1,627,453 cases, contributing 68% of the total cases. Again, Brazil contributed of the highest number of cases in this region, 1,473,645 cases, contributing 90% of the total cases.

In 2014, there was a decrease in the total cases of dengue to 1,171,029; 15,744 severe dengue cases and 803 deaths were reported. The average incidence of dengue was 194 cases/100,000 inhabitants [18]. Despite the historical increase in the number of reported cases of this disease, an approximately 50% reduction in the number of cases, severe dengue cases, and deaths was reported in 2014 compared to the year 2013. However, the CFR maintained the same value (0.06%).

In 2015, there was an increase in the number of cases; a total of 2,430,178 dengue cases with 1354 deaths were recorded in the entire continent, for an average incidence of 245 cases/100,000 inhabitants [18]. The recorded data exceeded the total number of cases reported in 2014. However, it is important to emphasize that despite the increase in the number of cases, the total number of severe cases (12,824) and the CFR (0.05) remained well below the values observed during 2014. Additionally, Brazil, Colombia and Mexico reported the simultaneous co-circulation of all four serotypes of DENV. The Southern Cone subregion reported a total of 1,054,188 cases, contributing 87% of the total cases on the continent, followed by the Andean subregion and the North and Central America subregion, contributing 6% of the total cases. Brazil contributed 85% of the total number of cases on the continent (896,059 reported cases).

In 2016, there was a decrease in the number of cases; a total of 2,168,146 cases of dengue, 4,366 severe dengue cases and 903 deaths were reported, for a CFR of 0.04%. The average incidence of dengue was 219 cases/100,000 inhabitants [18]. The Southern Cone subregion reported a total of 1,651,575 cases, and Brazil contributed 91% of the total number of cases (1,502,933 reported cases).

In 2017, despite the historical decrease in the reported number of cases of this disease, a total of 577,697 cases, 4,366 severe dengue cases and 903 deaths were reported, and the CFR was maintained at 0.05%. The average incidence of dengue was 58.02 cases/100,000 inhabitants [18]. Brazil, Colombia and Guatemala reported the simultaneous co-circulation of all four serotypes of DENV. The Southern Cone subregion reported a total of 254,453 cases, contributing 43% of the total cases, and Brazil contributed 99% of the total number of reported cases (252,054 cases). Brazil also reported the co-circulation of other arboviruses, such as CHIKV, ZIKV and YFV.

It is important to emphasize that in the 2011–2017 period, there was a significant increase (approximately 30%) in the number of dengue cases, totaling 10,851,043 compared with the 2001–2010 period, which had a total number of 7,641,334 dengue cases [17]. When compared to the previous decades (1980–2017), this last seven-year period contributed 47% of the total number of cases. In according PAHO data the dengue incidence rates over the decades (1980–2017) [18], and the dengue mortality rates of countries and territories in the Americas in the same period, showing that mortality rates were significant over the last ten years (2007–2017) [16].

History of dengue in Brazil

The earliest reference to dengue in Brazil was made during the colonial period. The first case was described in the city of Recife, Brazil, in 1685. Seven years later, in Salvador, a dengue epidemic led to 2000 deaths. The 1846 dengue outbreak was also considered an epidemic, reaching several states, such as Rio de Janeiro and São Paulo. Between 1846 and 1916, São Paulo was hit by several dengue epidemics [19].

At the beginning of the 20th century, Oswaldo Cruz implemented a mosquito control program that lasted for many years. The great challenge of the time was the yellow fever epidemic [7, 19].

Aedes aegypti was eradicated in Brazil in the 1950s, but it returned in the 1980s. Since the first epidemic of dengue in Roraima, Ae. aegypti has persisted in Brazil to the present [7]. During the Roraima epidemic, serotypes DENV1 and 4 were isolated. In 1986, a dengue epidemic arose in Rio de Janeiro and in some urban areas of Northeast Brazil, with DENV1 dissemination and reports of more than 50,000 cases. In 1990, DENV2 was introduced in Rio de Janeiro, reaching several areas of Southeast Brazil. In 1998, a pandemic of more than 500,000 cases occurred in Brazil [7]. The virus spread throughout the country, with the highest number of cases being reported in Northeast Brazil. In 2000, DENV3 was isolated in Rio de Janeiro, and a new dengue epidemic occurred between 2001 and 2003. Several southern states were affected by dengue for the first time, with most cases occurring in people over 15 years of age. In fact, the disease generally affects young adults due to increased exposure, although it may also occur in children [7, 19]. The number of dengue cases and incidence/100,000 inhabitants in different Federative Units (FU) from regions of Brazil from 2011 to 2017 are summarized in Additional file 1: Table S1 (see also Fig. 1). The pattern of dengue endemo-epidemic outbreaks occurring every three to five years was maintained in Brazil until 2010 [13], when it changed to every two years (Additional file 1: Table S1), perhaps because of the movement of people for global sport events in the country.

Fig. 1
figure 1

Dengue incidence associated with DENV serotypes in Brazil from 2010 to 2016. Bars: dengue incidence per 100,000 inhabitants related to the left Y-axis. Lines: DENV serotype percentage observed in samples analyzed by LACENs related to the right Y-axis. Calculations were performed for each region for every year using data available from the Brazilian Ministry of Health. 2010 data: up to the 9th week of monitoring. 2016 data: up to the 27th week of monitoring

Serotypes circulating in Brazil in the 21st century

The monitoring of dengue cases is performed using suspected blood samples through viral isolation followed by the gold standard polymerase chain reaction (PCR) assay [18] used in Brazilian State Central Reference Laboratories (LACENs) for serotyping, allowing evaluation of circulating DENV serotypes. Monitoring reports demonstrated that DENV3 predominated in several Brazilian FU between 2002 and 2006. From 2007 to 2009, a shift was observed, and DENV2 replaced DENV3 as the predominant serotype. This change led to epidemics in several FU, with a rise in severe cases among individuals under 15 years old [7]. The monitoring of circulating serotypes throughout 2009 revealed a new change in the predominant serotype, with a significant recirculation in DENV1, which became the predominant serotype in the FU of Roraima, Mato Grosso do Sul and Piauí beginning in 2008 [7].

In 2010, DENV monitoring in Brazil indicated the circulation of the DENV1, DENV2 and DENV3 serotypes (Fig. 1). However, notably, compared with the other serotypes, DENV1 had the highest incidence in Brazil, except for the Northeast region (which had fewer than 200 cases/100,000 inhabitants) (Fig. 1). This serotype probably directly affected the epidemiological FU situation with epidemic occurrence [7].

The recirculation of DENV1 was a potentially dangerous situation as it could lead to a large disease outbreak in the Brazilian FU since most of the population had never been in contact with this serotype before; DENV1 appeared before the first decade of the 21st century. With DENV2 circulation, an increase in the proportion of severe cases of the disease was also observed, particularly in children and adolescents, including a higher demand for hospital admissions [7]. Indeed, data available from Brazilian Government surveillance agencies revealed that an increase in DENV1 serotype was reported in 2010 and the following years, with a similar increasing pattern of dengue incidence (Fig. 1). The repercussions of DENV1 recirculation should be monitored closely by dengue surveillance at all levels of the health system because this event could cause serious epidemic disease due to the low circulation of this serotype in recent decades [7].

On July 30, 2010, the first suspected case of the DENV4 serotype was collected by the Roraima LACEN, and the sample was sent to the Evandro Chagas Institute (ECI) in accordance with the protocol established by the Ministry of Health. This finding was significant because since DENV4 was identified 28 years ago in Brazil, this serotype had not been observed or detected for a long period. The ECI confirmed a total of three DENV4 dengue cases in Roraima, located in the North Brazilian region (Fig. 2) [20]. Furthermore, during the DENV1 outbreak in March 2011, seven patients with the DENV4 serotype were detected in Niterói City in Rio de Janeiro, indicating the co-circulation of DENV1 and 4 in Brazil [21]. The presence of DENV4 provided the risk not only for the development of more severe manifestations (such as DHF) in people previously infected with DENV1, 2 or 3 but also the possibility of increasing cases in subsequent years. Indeed, except for the Southern region, all the other Brazilian regions presented a rapid increase in DENV4 serotype incidence with a new reduction from 2014 (Fig. 1).

Fig. 2
figure 2

Total probable dengue cases per region of Brazil associated with serotyped samples. Bars: total probable cases related to the left Y-axis. Lines: total serotyped samples related to the right Y-axis. Calculations were performed for each region for every year using data available from the Brazilian Ministry of Health. 2010 data: up to the 9th week of monitoring. 2016 data: up to the 27th week of monitoring

In 2015, a new recurrence of DENV2 was observed, especially in the Northeast region, leading to 1365 cases of severe dengue fever and 18,619 cases of DF in Brazil. Despite the increase in DENV2 serotype infections compared to the same period in 2015, DENV2 represented 6.4% of the total of 2,204,000 cases of the disease registered between January and June 2016. During the same period, 318 deaths related to dengue were confirmed. The data from the last Epidemiological Bulletin of the Ministry of Health showed that by the 49th EW of 2016, 826 cases of severe dengue fever and 8166 dengue fever cases had been confirmed [22]. In the same period in 2015, there were 1680 cases of severe dengue fever and 21,155 cases of dengue fever [22, 23].

The 2016 bulletin confirmed 609 deaths by dengue, representing 6.8% of the total cases. Although the number of dengue deaths was lower in 2016 than in 2015, 972 deaths were confirmed. The data also highlight that 2016 had the second-highest number of dengue cases in Brazil since 1990, when data began to be recorded in Brazil, followed only by 2015 [23]. Notably, as a percentage of the total number of cases, 2015 deaths were lower (4.3% of total cases) than those of 2016. This finding is possibly related to the high number of people infected with DENV1 who may have also become infected with DENV2 in recent years (Fig. 2), increasing the number of serious cases. Once infected by one serotype, a patient is immune only to that specific serotype; however, there is an increased risk of presenting a more severe manifestation of the disease during a second infection with another serotype [23]. Currently, all four serotypes circulate throughout the year in Brazil. When the detection of one serotype increases in a certain region, the effect is usually regional and could remain limited to that region, depending on both the geographic location and the population movement in the area (for example, if many individuals commute to the city for work). Furthermore, epidemics sometimes target regions that were unaffected by the last epidemics of a certain serotype, so that the population is susceptible but the municipalities around it are not susceptible.

Laboratory monitoring is vital for the assessment of circulating serotypes, which provides Brazilian Government agencies with important data to establish strategies focused on combating dengue through vector control aiming to minimize potential disease outbreaks. Figure 2 shows that the increase in dengue serotyping is proportional to the number of cases of dengue reported in different regions, although the serotyping percentage is still lower compared with the total cases. A maximum 7% of total dengue cases were serotyped from 2010 to 2016; this insufficient serotyping percentage clearly underestimates the actual number of cases of dengue that occurs in Brazil (Fig. 3) [7, 19, 22, 24,25,26,27,28,29] making it difficult to monitor DENV throughout the country. After 2010, some strategies such as laboratory accreditation (LACENs) and greater funding were adopted to further expand the dengue serotyping coverage. Despite the investment, these efforts were not sufficient to increase the percentage beyond 7%, considering the elevated number of dengue cases that occurred in Brazil in 2015 and 2016 (Fig. 3).

Fig. 3
figure 3

Serotyped samples (%) in several regions of Brazil from 2010 to 2016. The total percentage of serotyped samples was calculated in relation to the total probable cases observed in each region for every year using data available from the Brazilian Ministry of Health. 2010 data: up to the 9th week of monitoring. 2016 data: up to the 27th week of monitoring

Diagnosis of dengue virus

Dengue, a neglected tropical disease, was recognized as a major public health problem in June of 1999 by being formally included in the disease portfolio of the United Nations Development Programme/World Bank/World Health Organization Special Programme for Research and Training in Tropical Diseases by the Joint Coordination Council [30, 31]. The WHO recommends the use of serological methods for the diagnosis of DENVs to provide laboratory confirmation and the use of genomic techniques for the confirmatory test necessary to directly detect the virus. Currently, three basic steps in DENV detection are followed by most diagnostic laboratories: (i) isolation by animal cell culture; (ii) viral characterization by the detection of specific antigens (NS1 antigen capture enzyme-linked immunosorbent assay, ELISA) and the indirect detection of immunoglobulin M (IgM), IgG, and virus-specific antibodies in serum; and (iii) detection of the DENV genomic sequence using a nucleic acid amplification assay based on PCR, with reverse transcription (RT-PCR) and quantitative PCR (qPCR) being the appropriate tools for the identification and determination of different serotypes of dengue [6].

The Brazilian Ministry of Health recommends the use of the following protocol. All patients suspected of DF must be reported and have a blood sample collected for diagnostics. Up to eight days (preferably five) after the onset of symptoms, patient samples are processed for dengue using ELISA for NS1 detection and using qRT-PCR for the detection of DENV genome and serotyping. At 8 to 15 days after the onset of symptoms, the samples are assayed for IgM detection using ELISA. After 15 days, the sera are screened for IgG using ELISA. Dengue infection cannot be excluded in samples that are negative for the NS1 antigen and must be confirmed by IgM/IgG detection. Samples that are negative for dengue will be screened by RT-PCR for chikungunya and Zika virus and other pathogens for differential diagnosis [32]. In Brazil, the recommendation of the Ministry of Health is that all suspected dengue samples must be serotyped. The PCR protocol of Lanciotti et al. [33] is used for confirmation, which is considered the gold-standard protocol for the identification of serotypes by PCR and qPCR techniques.

Several methods based on PCR and qPCR techniques are available in the literature; Table 1 presents the main characteristics of some primers used in these works.

Table 1 PCR and qPCR primers

Chow et al. [34] described consensus primers for DENV PCR designed based on motifs conserved within the serine protease and RNA helicase domains encoded by the NS3 genes of dengue and other flaviviruses. However, the authors noted that this method still requires internal primers for the four serotypes of DENV to constitute a nested PCR. This strategy of using consensus primers in PCR depends on DNA sequencing techniques to identify which viral serotype is present in the sample and thus forms a complete molecular diagnostic protocol to characterize the epidemiology of dengue and other flavivirus infections. This protocol is therefore laborious and costly for the identification of DENV serotypes.

Chang et al. [35] presented primers for the nested PCR method for DENV. These primers were designed in the NS5 gene region encoding the viral RNA polymerase because this region is highly conserved in flaviviruses. These authors designed consensus primers and specific internal primers for serotyping, but the amplicons had sizes ranging from 411 to 761 bp, making them inappropriate for qPCR assays [36]. This protocol has a specificity of 89% for DENV serotypes and a sensitivity of 95% for DENV detection. Thus, diagnosis by this protocol still needs improvement.

Pierre et al. [37] proposed a universal single set of consensus primers for flaviviruses. The set was based on conserved elements in the NS5 protein and the 3' untranslated region (3' NC) of flavivirus RNA. Again, this method depends on post-amplification sequencing analysis to characterize the type of flavivirus.

Meiyu et al. [38] described a universal primer set, "DJS (+)/DJA (-)", which was designed for the NS1 gene, which is highly conserved in flaviviruses. Five specific internal primers were also developed based on published NS1 gene sequence data: four of them were for the dengue serotypes (DENV1-4), and one was for Japanese encephalitis virus (JEV). These primers were combined with DJA (-), thus forming five sets of internal primers to produce a hemi-nested assay. The results presented by the authors showed a sensitivity of the PCR assay of 84.6%, necessitating an improvement in the protocol to guarantee greater accuracy in the diagnosis of dengue.

Kuno et al. [39] described a cross-reactive primer set for flavivirus RT-PCR (FU1 and cFD3) with high efficiency to generate 1 kb DNA templates near the 3' terminal end of the flavivirus NS5 gene. The protocol described by the authors aimed to reduce the discrepancy between molecular and serological classifications. The union of these two methods improves discrimination among the members of the genus Flavivirus when the RT-PCR amplicon is used for genomic sequencing of the flavivirus.

Shu et al. [40] described a set of group primers and additional serotype-specific primers, which were designed against conserved sequences in the capsid protein (C) gene region and which can be used in RT-PCR and RT-qPCR (SYBR Green) protocols. The results presented by these authors showed a sensitivity of 83% for the SYBR Green-based RT-PCR method, demonstrating that the protocol has a sensitivity below the optimum range (90–110%) determined for the technique and indicating a need for improvement.

Johnson et al. [41] characterized a set of primers in different viral genes, which required three primers to identify each DENV serotype, that targeted the M, E and NS5 protein genes with a TaqMan assay. This method has the advantage of simultaneously identifying all four serotypes, either by using four different probes for each serotype or by using the same probe in separate assays. However, some disadvantages also exist: the cost of the protocol is high, and three primers are required for each viral serotype, two of which are fluorogenic probes for serotyping by RT-qPCR [42].

Ayers et al. [43] demonstrated consensus primers targeting a segment of the NS5 coding region to detect various flaviviruses. This protocol requires the sequencing of amplification products for the confirmation and identification of viral species. Protocol validation was performed, but the authors did not determine the sensitivity of the assay; additional research is required to ensure high sensitivity in further experiments.

Lanciotti et al. [33] described a hemi-nested protocol using primers located in the junction region of the capsid and premembrane (C-prM) genes of DENV; this is the most sensitive method described in the literature [44]. However, the authors reported false-negative PCR results using this protocol due to incompatibility between the dengue viral RNA sequence and the D1, D2 or TS sequences (Table 1). Based on this observation, Chien et al. [44] described modifications of the D1 (mD1) primers and replacement of the primers specific to DENV1, DENV2 and DENV4 by redesigned TS1 (rTS1) and TS4 (rTS4) and modified TS2 (mTS2), leading to primer efficiencies ranging from 72.60 to 89.20% for DENV1, from 70.90 to 96.40% for DENV2, and from 66.90 to 85.80% for DENV4. The TS3 efficiency was similar to that described by Lanciotti et al. [33] for DENV3.

In the Chien et al. [44] study, some modifications were also made to the primers described by Kuno et al. [39]. The consensus primers were redesigned, and internal primers were designed to be used in TaqMan RT-qPCR assays in a nested protocol, taking advantage of the Johnson et al. [41] protocol’s single pair of consensus primers and four oligonucleotides with specific fluorogenic probes to identify each DENV serotype. However, studies have shown that the sensitivity of C-prM is higher (100%) than that of NS5 (91%) [44].

Salles et al. [42] presented modifications to the primers used to detect DENV serotypes, as an update of Chien et al. [44] due to incompatibility between the dengue viral RNA sequence and the protocol. The modified protocol can use less-expensive and more common polymerase enzymes. The hemi-nested protocol was altered by replacing the mD1 primer with STD in the consensus primer region and replacing the mD1 primer with specific internal primers named STD1, STD2, STD3 and STD4 for serotyping. With these modifications, this protocol obtained better yields relative to primer efficiency, from 89.20 to 92.60% (STD1/rTS1) for DENV1, from 96.40 to 101.00% (STD2/mTS2) for DENV2, from 90.10 to 91.10% (STD3/TS3) for DENV3, and from 85.80 to 99.30% (STD4/rTS4) for DENV4.

In addition to the data summarized in Table 1, some commercial PCR kits exist, such as the CDC’s DENV1-4 RT-PCR assay kit and those from Geno-Sen, LifeRiver, RealStar and Simplexa. However, these kits are expensive and do not provide 100% sensitivity, making it difficult to use them in the Brazilian Unified Health System [41, 45].

Prevention and control of dengue in Brazil

The French pharmaceutical company Sanofi-Aventis, the world’s leading vaccine producer, has launched a commercial vaccine for the prevention of dengue fever called Dengvaxia. This pentavalent chimeric vaccine is derived from all four serotypes of DENV and YFV [46]. This vaccine has been licensed in several American countries: Mexico, Brazil, El Salvador, Costa Rica, Paraguay, Guatemala and Peru [47]. ANVISA (the Brazilian National Health Surveillance Agency) licensed Dengvaxia for Brazil in 2015 [48]. This vaccine presents some serious problems that call into question its full effectiveness [47]. In addition, this vaccine has a high cost, and further studies are needed to prove its efficacy [47]. In November 2017, ANVISA released a note recommending the non-use of the Dengvaxia vaccine in Brazil [49]. This study was based on the possibility that the Dengvaxia vaccine might increase the risk of severe disease in people who had never been exposed to DENV before. Since then, this vaccine has not been considered as a potential prevention tool. The Philippine Health Ministry halted Dengvaxia immunizations due to 14 deaths of children that were associated with vaccination [50]. In Brazil, the government decided to use Dengvaxia to vaccinate only individuals who are already seropositive [49].

In Brazil, all three government spheres (federal, state and municipality) share responsibility for dengue control. The federal level provides guidelines for vector control, allocates resources to the states and purchases insecticides and equipment, such as vehicles mounted with an ultra-low-volume sprayer to support chemical control. The states assist and supervise municipalities, acquire consumables and small equipment, such as nylon nets and lids for water tanks or mosquito traps, and gather information about the municipalities to notify the Health Ministry. The municipality is responsible for operations such as management of vector control professionals and actions, following central-level recommendations. In practice, this shared responsibility can reduce the efficiency of vector control; for example, decision-making processes can be bureaucratic and time-consuming [51].

The prospects of controlling dengue disease are not promising. The number of dengue cases increases in proportion with factors such as deforestation, poor sanitation and climate change [51]. Three out of four Brazilian municipalities are heavily infested with the mosquito Ae. aegypti. Reducing the density of Ae. aegypti, the main link in the transmission chain, remains a challenge. Under the coordination of the National Program for Dengue Control (PNCD) of the Ministry of Health, an International Meeting for Implementation of New Alternatives for Ae. aegypti Control was held in Brazil in February 2016 [52, 53]. Some vector control initiatives have been conducted. These efforts include re-emphasizing insecticide use, but most mosquito populations are resistant [52, 53]. Other initiatives, such as sterilizing mosquitoes by genetic modification or irradiation or even infecting mosquitoes with Wolbachia, have so far shown no success in vector control [52, 53]. Another form of prevention consists of an ongoing battle against water accumulation, which is conducive to the reproduction of the mosquitoes that transmit the disease. For this reason, periodic epidemiological surveillance and population awareness are necessary to control the reproduction of the mosquito vector by promoting actions such as the removal of water that accumulates in breeding sites [54]. This initiative can be efficient in the home, but much water accumulates in peridomicile environments in Brazil due to the precarious system of water supply, sewage and solid waste collection among others. These conditions favor the proliferation of the Ae. aegypti mosquito in cities, making it difficult or almost impossible to combat the vector [55].

Even with the government investing more than half a billion dollars each year in mosquito control, there has been no reduction in vector density that could limit or reduce the spread of dengue in a sustained way [56].

Without vaccines, effective drugs, or sensitive diagnostic tests, the only available response to reduce disease severity and case fatality is clinical management through enhanced care supported by accessible, sensitive and specific useful diagnostic tests. These tools will help identify warning signs for severe disease and evidence-based criteria for the standardization of treatment procedures [57]. During epidemics, Brazil’s public health initiatives are aimed at increasing awareness of the signs and symptoms of the disease to facilitate the earlier arrival of health services to allow the early diagnosis and treatment of severe forms of dengue.

Conclusions

Without adequate prevention and treatment, the number of reported cases of dengue has increased in recent years in Brazil and the Americas. Considering these facts, the population is dependent on methods of prevention and the treatment of symptoms. For this reason, the Secretariat of Health Surveillance (SHS) must collect information from the data provided by sentinel laboratories, even if not all cases are confirmed due to diagnostic inefficiency and some must be discarded. Studies are necessary to increase the performance of the available diagnostic methods to guarantee accurate notifications by state health departments and municipalities. Finally, it is important to continue to support the research for more effective diagnosis and treatment of dengue and also for new methodologies of vector control and disease prevention.

Abbreviations

ANVISA:

National Health Surveillance Agency

C:

Capsid protein

CFR:

Case fatality rate

CHIKV:

Chikungunya virus

DENV:

Dengue virus

DENV1:

Dengue virus serotype 1

DENV2:

Dengue virus serotype 2

DENV3:

Dengue virus serotype 3

DENV4:

Dengue virus serotype 4

DF:

Dengue fever

DHF:

Dengue hemorrhagic fever

DSS:

Dengue shock syndrome

E:

Envelope proteins

ECI:

Evandro Chagas Institute

EW:

Epidemiological week

FU:

Federative Units

IgG:

Immunoglobulin G

IgM:

Immunoglobulin M

JEV:

Japanese encephalitis virus

LACENS:

Brazilian State Central Reference Laboratories

M:

Membrane protein

NS1, NS2A, NS2B, NS3, NS4A, NS2K, NS4B and NS5:

Non-structural proteins

PAHO:

Pan-American Health Organization

PCR:

Polymerase chain reaction

PNCD:

National Program For Dengue Control

qPCR:

quantitative PCR

RT-PCR:

Reverse transcription PCR

RT-qPCR:

RT-quantitative PCR

SHS:

Secretariat of Health Surveillance

SLEV:

Saint Louis encephalitis virus

TBEV:

Tick-borne encephalitis virus

WHO:

World Health Organization

WNV:

West Nile virus

YFV:

Yellow fever virus

ZIKV:

Zika virus

References

  1. Holmes EC, Twiddy SS. The origin, emergence and evolution genetics of dengue virus. Infect Genet Evol. 2003;3:19–28.

    Article  PubMed  Google Scholar 

  2. Mukhopadhyay S, Kuhn RJ, Rossmann MG. A structural perspective of the flavivirus life cycle. Nat Rev Microbiol. 2005;3:13–22.

    Article  CAS  PubMed  Google Scholar 

  3. Lindenbach BD, Thiel H-J, Rice CM. Fields virology. 5th ed. Philadelphia: Lippincott Williams & Wilkins Publishers; 2007. p. 1101–52.

    Google Scholar 

  4. Slonczewski JL, Foster JW. Microbiology: An evolving science, 2nd ed. New York: W. W. Norton and Company; 2010.

  5. Whitehead SS, Blaney JE, Durbin AP, Murphy BR. Prospects for a dengue virus vaccine. Nat Rev Microbiol. 2007;5:518–28.

    Article  CAS  PubMed  Google Scholar 

  6. World Health Organization. Dengue: guidelines for diagnosis, treatment, prevention and control. New edition. Geneva: World Health Organization; 2009. Available from: http://www.who.int/tdr/publications/documents/dengue-diagnosis.pdf.

  7. Ministério da Saúde. Secretaria de Vigilância em Saúde: Informe epidemiológico da dengue análise de situação e tendências. 2010. Available from: http://portalms.saude.gov.br/boletins-epidemiologicos. Accessed 8 Dec 2017.

  8. Gould EA, Soloman T. Pathogenic flaviviruses. Lancet. 2008;371:500–9.

    Article  CAS  PubMed  Google Scholar 

  9. Wang E, Ni H, Xu R, Barrett ADT, Watowich SJ, Gubler DJ, et al. Evolutionary relationships of endemic/epidemic and sylvatic dengue viruses. J Virol. 2000;74:3227–34.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  10. Ghosh D, Basu A. Present perspectives on flaviviral chemotherapy. Drug Discov Today. 2008;13:619–24.

    Article  CAS  PubMed  Google Scholar 

  11. Tchankouo-Nguetcheu S, Khun H, Pincet L, et al. Differential protein modulation in midguts of Aedes aegypti infected with chikungunya and dengue 2 viruses. PLoS One. 2010;5:13149.

    Article  Google Scholar 

  12. Halstead SB. Dengue. Lancet. 2007;370:1644–52.

    Article  PubMed  Google Scholar 

  13. Brathwaite Dick O, San Martín JL, Montoya RH, del Diego J, Zambrano B, Dayan GH. The history of dengue outbreaks in the Americas. Am J Trop Med Hyg. 2012;87(4):584–93.

    Article  PubMed  PubMed Central  Google Scholar 

  14. Gubler DJ. Dengue and dengue haemorrhagic fever. J Clin Microbiol. 1998;11:480–96.

    CAS  Google Scholar 

  15. San Martín JL, Brathwaite O, Zambrano B, Solórzano JO, Bouckenooghe A, Dayan GH, et al. The epidemiology of dengue in the Americas over the last three decades: a worrisome reality. Am J Trop Med Hyg. 2010;82:128–35.

    Article  PubMed  PubMed Central  Google Scholar 

  16. Pan American Health Organization. Dengue mortality rate for countries and territories of the Americas, 1990–2017. 2018. Available from: http://www.paho.org/data/index.php/en/mnu-topics/indicadores-dengue-en/dengue-nacional-en/253-dengue-mortalidad-tasa-en.html?showall=&start=2. Accessed 27 Feb 2018.

  17. Pan American Health Organization. Number of reported cases of dengue and dengue hemorrhagic fever (DHF), Region of the Americas (by country and subregion) 1980–2018. 2018. Available from: http://www.paho.org/data/index.php/en/mnu-topics/indicadores-dengue-en/dengue-nacional-en/252-dengue-pais-ano-en.html. Accessed 2 Feb 2018.

  18. Pan American Health Organization. Distribution of dengue virus serotypes in the Americas, 1990–2017. 2018. Available from: http://www.paho.org/data/index.php/en/mnu-topics/indicadores-dengue-en/dengue-nacional-en/254-dengue-incidencia-en.html?showall=&start=3. Accessed 27 Feb 2018.

  19. Ministério da Saúde. Combate à dengue, histórico. 2010. Available from: http://combateaedes.saude.gov.br/pt/historico. Accessed 16 Aug 2017.

  20. O Globo. Portal G1 da Globo: Casos de dengue tipo 4 em Roraima são confirmados no pará. 2010. Available from: http://g1.globo.com/brasil/noticia/2010/08/casos-de-dengue-tipo-4-em-roraima-sao-confirmados-no-para.html. Accessed 12 Aug 2010.

  21. Campos RM, Veiga CS, Meneses MD, de Souza LM, Fernandes CA, Malirat V, et al. Emergence of dengue virus 4 genotypes II b and I in the city of Rio de Janeiro. J Clin Virol. 2013;56:86–8.

    Article  Google Scholar 

  22. SVS. Departamento de Vigilância Epidemiológica: Guia de vigilância. Epidemiológica: Secretaria de Vigilância em Saúde; 2016. Available from: http://portalms.saude.gov.br/boletins-epidemiologicos. Accessed 2 Nov 2017.

  23. SBMT. Avanço de vírus mais agressivo da dengue preocupa área da saúde: Sociedade Brasileira de Medicina Tropical; 2016. Available from: http://www.sbmt.org.br/portal/avanco-de-virus-mais-agressivo-da-dengue-preocupa-area-da-saude/. Accessed 15 Aug 2016.

  24. SVS. Departamento de Vigilância Epidemiológica: Guia de vigilância. Epidemiológica: Secretaria de Vigilância em Saúde; 2011. Available from: http://portalms.saude.gov.br/boletins-epidemiologicos. Accessed 2 Nov 2017.

  25. SVS. Departamento de Vigilância Epidemiológica: Guia de vigilância. Epidemiológica: Secretaria de Vigilância em Saúde; 2012. Available from: http://portalms.saude.gov.br/boletins-epidemiologicos. Accessed 2 Nov 2017.

  26. SVS. Departamento de Vigilância Epidemiológica: Guia de vigilância. Epidemiológica: Secretaria de Vigilância em Saúde; 2013. Available from: http://portalms.saude.gov.br/boletins-epidemiologicos. Accessed 2 Nov 2017.

  27. SVS. Departamento de Vigilância Epidemiológica: Guia de vigilância. Epidemiológica: Secretaria de Vigilância em Saúde; 2014. Available from: http://portalms.saude.gov.br/boletins-epidemiologicos. Accessed 2 Nov 2017.

  28. SVS. Departamento de Vigilância Epidemiológica: Guia de vigilância. Epidemiológica: Secretaria de Vigilância em Saúde; 2015. Available from: http://portalms.saude.gov.br/boletins-epidemiologicos. Accessed 2 Nov 2017.

  29. SVS. Departamento de Vigilância Epidemiológica: Guia de vigilância. Epidemiológica: Secretaria de Vigilância em Saúde; 2017. Available from: http://portalms.saude.gov.br/boletins-epidemiologicos. Accessed 2 Nov 2017.

  30. WHO. Dengue haemorrhagic fever: diagnosis, treatment prevention and control. 2nd ed. Geneva: World Health Organization; 1999.

    Google Scholar 

  31. Shu PY, Huang JH. Current advances in dengue diagnosis. Clin Diagn Lab Immunol. 2004;11:642–50.

    PubMed  PubMed Central  Google Scholar 

  32. Ministério da Saúde. Secretaria de Vigilância em Saúde. Departamento de Vigilância Epidemiológica: Dengue: diagnóstico e manejo clínico: criança. 2011. Available from: http://www.sbp.com.br/fileadmin/user_upload/pdfs/DENGUE_DIAGN%C3%93STICO_E_MANEJO_CL%C3%8DNICO_CRIAN%C3%87AS_2011_MINIST%C3%89RIO_DA_SA%C3%9ADE.pdf. Accessed 8 Feb 2018.

  33. Lanciotti RS, Calisher CH, Gubler DJ, Chang GJ, Vorndam AV. Rapid detection and typing of dengue viruses from clinical samples by using reverse transcriptase-polymerase chain reaction. J Clin Microbiol. 1992;30:545–51.

    CAS  PubMed  PubMed Central  Google Scholar 

  34. Chow VTK, Seah CLK, Chan YC. Use of NS3 consensus primers for the polymerase chain reaction amplification and sequencing of dengue viruses and other flaviviruses. Arch Virol. 1993;133:157–70.

    Article  CAS  PubMed  Google Scholar 

  35. Chang GJ, Trent DW, Vorndam AV, Vergne E, Kinney RM, Mitchell CJ. An integrated target sequence and signal amplification assay, reverse transcriptase-PCR-enzyme linked immunosorbent assay, to detect and characterize flaviviruses. J Clin Microbiol. 1994;32:477–83.

    CAS  PubMed  PubMed Central  Google Scholar 

  36. Thornton B, Basu C. Real-time PCR (qPCR) primer design using free online software. Biochem Mol Biol Educ. 2011;39:145–54.

    Article  CAS  PubMed  Google Scholar 

  37. Pierre V, Drouet MT, Deubel V. Identification of mosquito-borne flavivirus sequences using universal primers and reverse transcription/polymerase chain reaction. Res Virol. 1994;145:93–104.

    Article  CAS  PubMed  Google Scholar 

  38. Meiyu F, Huosheng C, Cuihua C, et al. Detection of flaviviruses by reverse transcriptase-polymerase chain reaction with the universal primer set. Microbiol Immunol. 1997;41:209–13.

    Article  CAS  PubMed  Google Scholar 

  39. Kuno G. Universal diagnostic RT-PCR protocol for arboviruses. J Virol Methods. 1998;72:27–41.

    Article  CAS  PubMed  Google Scholar 

  40. Shu PY, Chang SF, Kuo YC, Yueh YY, Chien LJ, Sue CL, et al. Development of group and serotype-specific one-step SYBR Green I-based real-time reverse transcription-PCR assay for dengue virus. J Clin Microbiol. 2003;41:2408–16.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  41. Johnson BW, Russell BJ, Lanciotti RS. Serotype-specific detection of dengue viruses in a fourplex real-time reverse transcriptase PCR assay. J Clin Microbiol. 2005;43:4977–83.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  42. Salles TS, Sá-Guimaraes TE, Souza DFS, López SBG, Alvarenga ESL, et al. Quantitative dengue serotyping: the development of a higher performance method using SYBR Green assay. Arch Clin Microbiol. 2017;4:55.

    Google Scholar 

  43. Ayers M, Adachi D, Johnson G, et al. A single tube RT-PCR assay for the detection of mosquito-borne flavivirus. J Virol Methods. 2006;135:235–9.

    Article  CAS  PubMed  Google Scholar 

  44. Chien LJ, Liao TL, Shu PY, Huang JH, Gubler DJ, et al. Development of real-time reverse transcriptase PCR assays to detect and serotype dengue viruses. J Clin Microbiol. 2006;44:1295–304.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  45. Najioullah F, Viron F, Cesaire R. Evaluation of four commercial real-time RT-PCR kits for the detection of dengue viruses in clinical samples. Virol J. 2014;11:164.

    Article  PubMed  PubMed Central  Google Scholar 

  46. Villar L, Dayan GH, Arredondo-García JL, Rivera DM, Cunha R, Deseda C, et al. Efficacy of a tetravalent dengue vaccine in children in Latin America. N Engl J Med. 2015;11:164.

    Google Scholar 

  47. World Health Organization (WHO). Dengue vaccine: WHO position paper - July 2016. Wkly Epidemiol Rec. 2016;91:349–64.

  48. Diário Oficial da União, Brasília, DF, Brazil. 2015. Available from: https://www.jusbrasil.com.br/diarios/106783857/dou-suplemento-secao-1-28-12-2015-pg-4. Accessed 28 Dec 2015.

  49. Ouvidoria Anvisa: National Health Surveillance Agency. Manifestações envolvendo a aplicação da vacina contra a dengue. 2017. Available from: http://portal.anvisa.gov.br/documents/111522/3613595/Tema+de+Destaque++Novembro_Dezembro+2017/c64fc913-6b39-4e06-92d9-a485e1af174d. Accessed 31 Jan 2018.

  50. Reuters. Philippines says anti-dengue vaccine may be connected to three deaths. 2018. Available from: https://www.reuters.com/article/us-sanofi-dengue-philippines/philippines-says-anti-dengue-vaccine-may-be-connected-to-three-deaths-idUSKBN1FM0SP. Accessed 2 Feb 2018.

  51. Maciel-de-Freitas R, Valle D. Challenges encountered using standard vector control measures for dengue in Boa Vista, Brazil. Bull World Health Organ. 2014;92(9):685–9.

    Article  PubMed  PubMed Central  Google Scholar 

  52. Valle D, Pimenta DN, Cunha RV. Dengue: teorias e práticas. Rio de Janeiro: Editora Fiocruz; 2015.

    Book  Google Scholar 

  53. Valle D. Sem bala mágica: cidadania e participação social no controle de Aedes aegypti. Epidemiol Serv Saude. 2016;25:629–32.

    Article  PubMed  Google Scholar 

  54. Ministerio da Saúde. Dengue.org.br: Prevenção da dengue. 2011. Available from: http://www.dengue.org.br/dengue_prevenir.html. Accessed 20 Jan 2011.

  55. Ministerio da Saúde. Combate Dengue: como combater. 2011. Available from: http://combateaedes.saude.gov.br/pt/comocombater. Accessed 20 Jan 2011.

  56. Barreto ML, Teixeira MG, Bastos FI, Ximenes RAA, Barata RB, Rodrigues LC. Successes and failures in the control of infectious diseases in Brazil: social and environmental context, policies, interventions, and research needs. Lancet. 2011;377(9780):1877–89.

    Article  PubMed  Google Scholar 

  57. Kroeger A, Nathan M. Dengue: setting the global research agenda. Lancet. 2006;368:2193–5.

    Article  PubMed  Google Scholar 

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Acknowledgments

The authors Salles TS, Sa-Guimarães TE and Alvarenga ESL are recipients of a graduate fellowship from Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES).

Funding

This study was financially supported by the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), Instituto Nacional de Ciência e Tecnologia em Entomologia Molecular (INCT-EM/CNPq), and Fundação Carlos Chagas Filho de Amparo à Pesquisa do Estado do Rio de Janeiro (FAPERJ) -Edital: E-18/2015 pedido: 221797.

Author information

Authors and Affiliations

Authors

Contributions

TSS, TESG, ESLA, VGR, PFCS and CRS were involved in the search for papers and the drafting and editing of the manuscript. TSS, TESG and ESLA were involved in the drafting of the Background section. TSS, VGR and CRS were involved in the drafting of the A brief history of dengue section. TSS, TESG and ESLA were involved in the drafting of the History of dengue in Brazil section. TSS, PFCS and MDFM were involved in the drafting of the Diagnosis of dengue virus section. TSS, ESLA, and MFM were involved in the drafting of the prevention and control of dengue section. ACAM, MRS, DFF and MFM critically revised the manuscript, and TSS designed the tables. All the authors read and approved the final manuscript.

Corresponding author

Correspondence to Monica Ferreira Moreira.

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The authors declare that they have no competing interests.

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Additional file

Additional file 1:

Table S1. Cases of dengue. Brazil, major regions and federated units, 1990 to 2017. (DOCX 20 kb)

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Salles, T.S., da Encarnação Sá-Guimarães, T., de Alvarenga, E.S.L. et al. History, epidemiology and diagnostics of dengue in the American and Brazilian contexts: a review. Parasites Vectors 11, 264 (2018). https://0-doi-org.brum.beds.ac.uk/10.1186/s13071-018-2830-8

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