Hostname: page-component-cd9895bd7-7cvxr Total loading time: 0 Render date: 2024-12-27T13:39:01.949Z Has data issue: false hasContentIssue false

Zika virus epidemiology: from Uganda to world pandemic, an update

Published online by Cambridge University Press:  14 March 2018

C. Talero-Gutiérrez*
Affiliation:
Neuroscience Unit. Neuroscience Research Group (NeURos), Escuela de Medicina y Ciencias de la Salud, Universidad del Rosario, Bogotá D.C. 111211, Colombia
A. Rivera-Molina
Affiliation:
Neuroscience Undergraduate Research Group (NeURos), Escuela de Medicina y Ciencias de la Salud, Universidad del Rosario, Bogotá D.C., Colombia
C. Pérez-Pavajeau
Affiliation:
Neuroscience Undergraduate Research Group (NeURos), Escuela de Medicina y Ciencias de la Salud, Universidad del Rosario, Bogotá D.C., Colombia
I. Ossa-Ospina
Affiliation:
Neuroscience Undergraduate Research Group (NeURos), Escuela de Medicina y Ciencias de la Salud, Universidad del Rosario, Bogotá D.C., Colombia
C. Santos-García
Affiliation:
Neuroscience Undergraduate Research Group (NeURos), Escuela de Medicina y Ciencias de la Salud, Universidad del Rosario, Bogotá D.C., Colombia
M. C. Rojas-Anaya
Affiliation:
Neuroscience Undergraduate Research Group (NeURos), Escuela de Medicina y Ciencias de la Salud, Universidad del Rosario, Bogotá D.C., Colombia
A. de-la-Torre
Affiliation:
Immunology Department, Escuela de Medicina y Ciencias de la Salud, Neuroscience Research Group (NeURos), Universidad del Rosario, Bogotá D.C., Colombia
*
Author for correspondence: C. Talero-Gutiérrez, E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Zika virus (ZIKV) infection is an emergent worldwide public health problem. Historically, 84 countries have reported vector-borne ZIKV transmission, 61 of which report on-going transmission. It is a Flavivirus transmitted through arthropods belonging to the Aedes genus. Since 2015, ZIKV infections have increased dramatically; with 1.3 million people infected during 2015 in Brazil alone. This paper's objective is to highlight the conjectural epidemiological points of the virus’ dissemination. The digital archives Pubmed, MEDLINE, EMBASE and Cochrane were searched for papers that assessed aspects of ZIKV transmission and epidemiology. The first isolation occurred in Uganda in 1947. Since then, important outbreaks were documented globally. Consequently, an emergent public health problem arose from a rapidly increasing incidence and its association with the development of neurological diseases such as microcephaly and Guillain–Barré syndrome. Key factors in the successful containment of outbreaks include surveillance of mosquitos in the neighbourhood, an early mosquito control treatment, an assertive information campaign, and the involvement of the local population and healthcare workers. As such, while ZIKV seems to be spreading globally in a similar manner to other arboviruses, such as Dengue and Chikungunya viruses, it can also be rapidly contained due to the pre-existing availability of necessary resources and regulatory tools as control measures. This review aims to provide a description of those characteristics of ZIKV infection that may be useful in the construction of effective outbreak control strategies.

Type
Review
Copyright
Copyright © Cambridge University Press 2018 

Introduction

Zika virus (ZIKV) infection is an emergent public health problem around the world. According to the latest situational report of the World Health Organization (WHO), cases with evidence of vector-borne ZIKV transmission have been reported throughout history in 84 countries and territories worldwide [1]. On 1 February 2016, the WHO declared ZIKV a public health emergency of international concern, responding to multiple reports of microcephaly and neurological disorders [2]. Indeed, clinical complications following ZIKV infection are notably neurological, as the virus manifests a predilection for the central nervous system (CNS). This neurotropism is explained by previous animal experiments, which show that ZIKV breaks the protection of the blood–brain barrier, entering the CNS and causing the characteristic neurological features [Reference Del Carpio-Orantes3, Reference Nunes4].

ZIKV is a Flavivirus of the same family of the West Nile and Yellow Fever viruses. It is transmitted by arthropods belonging to the Aedes genus, especially Ae. aegypti and Ae. polynesisiensis [Reference Oehler5]. Infection by ZIKV carrying mosquito, Aedes aegypti, has been associated with neurological complications such as microcephaly and Guillain–Barré syndrome (GBS) [Reference Oehler5]. These associations were initially made by case reports of GBS in French Polynesia, describing symptoms similar to the axonal subtype in evaluated patients as a consequence of ZIKV infection [Reference Oehler5]. Additionally, other neurological complications such as microcephaly in newborns from ZIKV infected mothers have been associated with the virus [Reference Aziz6, Reference Brasil7].

The importance of surveillance is highlighted by the fact that ZIKV infections have risen dramatically since 2015, with an estimated 1.3 million people infected during a 9-month period in Brazil alone [8]. Also, the virus’ neurotoxicity constitutes a major health issue due to a possible increase in microcephaly and GBS cases around the globe. Such enormous public health implications call for an urgent understanding of the origin, mode of transmission, behaviour, spreading pattern, and diagnosis of the ZIKV, which will be further studied in this review.

A great deal of epidemiological, clinical and molecular evidence regarding ZIKV has been produced and has been reviewed in a highly focused fashion elsewhere [Reference Li9Reference Jamali Moghadam14]. However, the aim of this paper is to provide public health officials and policymakers with a succinct overview of the evidence that may inform the development of effective control and prevention strategies.

Methods

A literature search was conducted using the digital archives Pubmed, MEDLINE, EMBASE and Cochrane. The following MeSH terms were used: ‘Zika Virus Infection’, ‘Epidemiology’, ‘Public Health’, ‘Microcephaly’, ‘Social Determinants of Health’ and ‘Zika Virus Infection’, with varied subheadings as ‘clinical manifestations’, ‘animal models’ and ‘diagnosis’. All literature reviews, original papers and case reports that issued epidemiological aspects of ZIKV origin, mode of transmission, behaviour and pattern of spread were included. Additionally, epidemiological reports of WHO, CDC, ECDC and other public health organisations were assessed for this paper. The aim of this search strategy was to find literature which could describe the historical landmarks of the disease's spread, the consequences of that spread, and potential control strategies.

First isolation: Uganda

ZIKV was first isolated in April 1947 from a pyrexial sentinel rhesus monkey native to the Zika forest in Uganda, in an attempt to study yellow fever [Reference Dick, Kitchen and Haddow15]. The second isolation took place in January 1948, this time from a pool of Aedes africanus mosquitoes obtained in the same forest [Reference Lanciotti16]. Due to its being native to Zika forest, this newfound virus became known as the ‘Zika virus’ [Reference Dick, Kitchen and Haddow15]. The first report of a human infection of ZIKV occurred in Uganda in 1964, in which a European man developed a 5-day febrile syndrome with myalgia and maculopapular rash, that was eventually confirmed by convalescent and acute serum samples that showed neutralising ZIKV antibodies [Reference Beckham17]. Throughout the 1960s and 1970s, multiple ZIKV human isolates were obtained, confirming infections in several Asian and African countries (Egypt, Nigeria, Uganda, India, Malaysia, Indonesia, Pakistan, Thailand, North Vietnam and the Philippines) [Reference Dick, Kitchen and Haddow15Reference Rabaan18]. Non-structural gene 5 (NS5) sequencing demonstrated the existence of three lineages of ZIKV which originated infections in East Africa, West Africa and Asia [Reference Chibueze11]. Nonetheless, the first sample of human ZIKV infection outside of Africa and Asia was identified in 2007, in Yap Island in the Federated States of Micronesia, Oceania [Reference Dick, Kitchen and Haddow15Reference Rabaan18].

First outbreak: French Polynesia and association with neurological affections

The previous largest documented ZIKV outbreak took place in French Polynesia in 2013 [Reference Rabaan18]. It was during this Zika outbreak, alongside types 1 and 3 Dengue fever co-epidemics, that the first associated cases of GBS following a ZIKV infection were recorded [8]. This was reported in a case–control study in French Polynesia that took place between October 2013 and April 2014, which found a possible association between ZIKV and GBS [Reference Cao-Lormeau19]. There were two control groups: control group 1 (n = 98), containing patients who presented at the hospital with non-febrile illness; and control group 2 (n = 70), containing patients with acute ZIKV disease and no neurological symptoms. A total of 42 cases of GBS showed electrophysiological findings consistent with acute motor axonal neuropathy (AMAN) and exhibited a rapidly evolving pathology [Reference Cao-Lormeau19]. This study found an odds ratio for GBS of 34.1, with a wide but significant confidence interval (CI) (5.8, Inf). Likewise, research by Salinas et al. and Styczynski et al., found odds ratios of 4.6 (95% CI 1.1–19.0) and 6.45 (95%CI 1.88–22.10), further reinforcing the association between ZKV and GBS and confirming the early results from the Polynesian studies [Reference Salinas20, Reference Styczynski21].

Zika and microcephaly in French Polynesia

A retrospective study in French Polynesia found an increasing number of microcephaly cases during the 2013 and 2014 outbreaks. In 2013, four cases were reported (up from a base of three in the previous year). The following year, in 2014, this had increased to 13 cases. Out of those 13 cases, amniotic fluid tests were only possible in six patients, four of which were positive for ZIKV using PCR [Reference Jouannic22]. The estimated risk of microcephaly after ZIKV infection in the first trimester of pregnancy was 95 per 10 000 women infected. Nonetheless, the prevalence was two per 10 000 neonates [Reference Cauchemez23]. The risk period for microcephaly in this study was found to be the first trimester of pregnancy, and therefore prevention measures should be strengthened during this period. Finally, although the prevalence of microcephaly in the French Polynesia was 1%, which seems low, the growing population infected with ZIKV makes this risk increasingly noteworthy [Reference Cauchemez23]. Due to the potential effects of infection by ZIKV on pregnant women, physicians should consider the evaluation of cerebral abnormalities in the foetus during the second trimester of pregnancy of women living in ZIKV endemic zones [Reference Jouannic22].

The pandemic arrives to America: Brazil, Zika and nervous system affections

The latest outbreak documented occurred in Brazil close to the end of 2014, with between 0.4 and 1.3 million people estimated to have been infected during 2015 [1]. There are several theories as to how the disease arrived in the South American country. A two-step protocol DNA analysis of the virus showed its similarity with the Asian lineage, therefore suggesting its arrival during the 2014 FIFA World Cup tournament, held in June and July of that year, and also from the Va'a World Sprint Championship canoe race, held the following August [Reference Younger12, Reference Al-Qahtani24, Reference Faye25]. The explanation of the disease's arrival during the football tournament seems to be imprecise, as no Zika-endemic Pacific countries were participants [Reference Wikan and Smith26]. Even so, it is possible that spectators from Zika-endemic countries might have been present [Reference Wikan and Smith26]. The canoe race, on the other hand, included participants from four Pacific countries in which ZIKV was circulating: French Polynesia, New Caledonia, Cook Islands and Easter Island [Reference Musso27]. In either case, the outbreak is generally assumed to be a consequence of such sporting events [Reference Musso27]. Other researchers from Canada, Brazil, UK and USA published a study suggesting the virus entered Brazil in 2013 through someone infected in that year's Zika epidemic in French Polynesia or from another Zika-endemic country [Reference Vogel28]. This theory is also supported by the increase in air travel from Zika-endemic areas to Brazil by almost 50% during 2013 and by mathematical modelling of the outbreak [Reference Vogel28, Reference Massad29]. The growing number of infected people by local transmission made it necessary for Brazil to report ZIKV as a noteworthy disease in 2016 [2]. Additionally, GBS was temporally and geographically associated with the presence of ZIKV in Brazil, Colombia, El Salvador, Martinique, Panama, Puerto Rico, Suriname and Venezuela [Reference Broutet30, Reference Song31]. In contrast to the AMAN subtype found in patients in French Polynesia, case reports in Latin America suggest AIDP as the predominant subtype in this region [Reference Anaya32].

Zika and microcephaly in Brazil

The first association with microcephaly in Brazil occurred during September 2015, as the number of newborns with the disease increased in correlation with ZIKV-infected pregnant women. The prevalence of microcephaly in involved outbreak states was 2.8 infants per 10 000 live births, with more than 4000 suspected cases reported in February 2016. Between November 2015 and July 2016, some 8301 cases of microcephaly were documented in Brazil [Reference Jouannic22, Reference Anaya32]. Reports also showed a rapidly increasing spread over South and Central America from October 2015 onward [33].

In the Americas, 20 countries have confirmed a total of 2311 cases of ZIKV infection and association with congenital syndromes [Reference Musso27]. A study in Brazil identified 343 pregnant women who were expecting delivery by the 31 July 2016, of whom 134 were positive for ZIKV. The results showed nine foetal deaths: five miscarriages in the first trimester, two miscarriages in the second trimester, and two stillbirths in the third trimester. Adverse outcomes after ZIKV infection occurred regardless of the timing of the pregnancy. From the ones that tested positive for ZIKV, 46.4% had adverse outcomes. In contrast, 11.5% of the cohort that tested negative for ZIKV developed adverse outcomes. The outcomes constituted 9% for restriction in growth and 4% for microcephaly. These results demonstrate that ZIKV infection during pregnancy is a severe risk for the development of microcephaly in foetuses [8].

The presence of clusters of microcephaly alongside other neurological disorders related to ZIKV was sufficient for the declaration of a Public Health Emergency of International Concern (PHEIC) by the WHO on the 1 February 2016 [2]. High incidences of microcephaly and GBS have been observed in populations in which Zika outbreaks have occurred. In turn, laboratory evidence from both in vitro and animal models support the plausibility of a link between these conditions and ZIKV infection. However, the specific pathophysiological mechanism remains unclear [Reference Nunes4, 33Reference Miner35].

Zika and other clinical manifestations around the world

Approximately 80% of patients infected with ZIKV are asymptomatic [Reference Jamali Moghadam14]. Hospitalisations are uncommon, and death is rare [Reference Paixão36]. However, these features are not pathognomonic for the disease as they may also be present in other Flaviviridae infections and therefore cannot be relied upon in isolation for diagnosis [Reference Wong, Poon and Wong37].

The incubation period is between 2 and 14 days [Reference Chan38], with clinical manifestations consisting of: low fever (<38.5 °C), headache, retro-orbital pain, bilateral non-purulent conjunctivitis, maculopapular rash, arthralgia with oedema on extremities, anorexia and occasionally abdominal symptoms such as diarrhoea and pain [Reference Ioos39, Reference Chang40]. Symptoms that may aid a clinical practitioner in differential diagnosis are conjunctivitis and limb oedema, which manifest more commonly after ZIKV infection in comparison to Dengue virus (DENV) and Chikungunya infection. Hepatomegaly, leukopenia and thrombocytopenia are also less common in ZIKV than in DENV [Reference Ioos39].

In 2016, sensorineural hearing loss was reported in a case of congenital ZIKV, implicating a possible complication other than microcephaly in newborns [Reference de Leal41]. Additionally, a prospective case study in Colombia and Venezuela including 43 patients found that babies born with ZIKV infection presented optic disc abnormalities, optical nerve hypoplasia, glaucoma, pigment mottling and chorioretinal atrophy with a predilection for the macula [Reference Yepez42]. Intrauterine and neonatal death may also occur [Reference Li9]. In fact, Chauchemez et al. reported, in a retrospective study, eight cases of microcephaly, five of which were aborted and three were born [Reference Song31].

The clinical spectrum of ZIKV infection remains a matter of investigation. Other manifestations have been reported such as: ocular flutter, meningoencephalitis, haematospermia, hearing difficulties, subcutaneous bleeding and acute myelitis [Reference Song31, Reference Carteaux43Reference Karam45].

Diagnosis

Diagnosis of ZIKV infection is based on three pillars: first, the evaluation of clinical symptoms; second, the finding of an epidemiological association between infection and endemic zones; and third, confirmation by serological and molecular laboratory findings [Reference Sharma46]. However, each of the pillars alone does not suffice to diagnose ZIKV infection, as the virus is very similar in structure, clinical features and geographical location to another flavivirus, especially Dengue, and togavirus like Chikungunya [Reference Wong, Poon and Wong37, Reference Lee, Kim and Shin47]. The gold standard for diagnosis is a real-time PCR (RT–PCR) on body fluids chosen depending on each patient's characteristics [Reference Li9, Reference Ferreira48]. ZIKV can be found in semen, saliva, blood, cerebrospinal fluid, amniotic fluid and urine. Serum samples should be taken no more than 10 days after symptom onset, as identification of the ZIKV RNA becomes more difficult. Nevertheless, ZIKV infection during pregnancy is associated with prolonged viraemia and the virus has been detected in the serum of pregnant women up to 53 days post-exposure [Reference Meaney-Delman49]. Saliva samples may also be taken within this range of time with an increased rate of molecular detection of the virus. However, it is especially used in patients with whom serum samples are difficult to take, such as the paediatric population [Reference Li9]. On the other hand, new investigations regarding urine samples of infected individuals have shown positivity for ZIKV RNA after ten days of symptom onset. This discovery brings an essential tool for diagnosis in cases in which obtaining samples is not possible within ten days of symptom onset [Reference Gourinat50]. Finally, diagnosis of ZIKV infection in newborns or aborted foetuses can be achieved by confirming viral RNA (vRNA) in their brain or serum and mother's placenta [Reference Song31], with a positive RT–PCR result being conclusive for ZIKV diagnosis. If results are negative, serum antibodies and IgM ELISA should be collected to confirm or discard the diagnosis [Reference Lee, Kim and Shin47]. Importance of early diagnosis lies in ZIKV's sexual transmission, foetal health problems and neurological complications that can be prevented [Reference Li9].

Transmission

The rapid spread of the pathogen occurs due to diverse transmission pathways; however, the primary mode of transmission is mosquito-borne [51]. A sylvatic transmission cycle involves nonhuman primates and forest species of Aedes mosquitoes. In urban and suburban environments, ZIKV is transmitted in a cycle of human–mosquito–human bites by two species of the Aedes subgenus: Ae. aegypti and Ae. albopictus. The vectors usually bite humans during daytime, and can be found both inside and outside houses. Ae. aegypti mosquitoes are spread extensively in the Americas (excluding Chile), where the climatic conditions are appropriate for vector breeding. This is partially responsible for the ZIKV epidemic reported since 2015. Ae. albopictus is distributed in regions with cooler temperatures, such as New York and Chicago in northern USA and in parts of southern Europe [Reference Song31]. The Aedes mosquito species are found widely around the world, and in consequence, the likelihood of the outbreak to spread to new countries remains high [Reference Aziz6, Reference Petersen52]. Furthermore, climate change must be accounted for, as it expands vectorial capacity [Reference Liu-Helmersson53]. Species distribution modelling techniques have predicted that, due to the broadly tropical and sub-tropical regions worldwide with suitable environmental conditions, which also have a larger susceptible human population, there is a high risk of introducing and establishing new autochthonous transmission [Reference Song31]. Some studies also assess the possible competence of Culex species as a vector. However, due to conflicting results, additional evidence is needed to confirm these preliminary findings [54].

Substantial evidence also exists of non-vector transmission. Transplacental transmission during pregnancy (from mother to foetus) has been identified by detection of ZIKV RNA in the amniotic fluid of mothers whose children show cerebral abnormalities in ultrasonography, as well as the identification of the virus in brain tissues and placentas of children born with microcephaly. Peripartum transmission was documented in two infants: in one case the child exhibited symptoms, while the other was asymptomatic [Reference Besnard55]. ZIKV RNA load has also been identified in breast milk, with much higher loads as compared with serum, which represents a risk of viral transmission while breastfeeding [Reference Dupont-Rouzeyrol56]. Between the 16 October 2016 and 9 March 2017, 13 countries reported sexual transmission of the ZIKV [57]. These reports comprise probable transmission from male to female, and male to male, through vaginal, anal and oral sexual intercourse [Reference Harrower58]. The virus can be passed from an infected person before their symptoms start, while they are symptomatic and after their symptoms end [51]. So far, the maximum documented virus time of survival in semen of symptomatic men is 125 days [Reference Paz-Bailey59]. Further evidence is needed, but the virus may also be passed by someone infected, who never develops symptoms [Reference Moghadas60]. Multiple reports of blood transfusion transmission cases in Brazil have been published [Reference Motta61Reference Slavov63]. In spite of testing positive for vRNA, four probable cases of transfusion transmission did not develop symptoms compatible with the virus [Reference Motta61, Reference Barjas-Castro62]. Previous to the current outbreak, four documented cases of infection were known to have occurred through laboratory exposure [51]. Direct transmission can happen through the skin or mucous membranes, although it is uncommon [Reference Wikan and Smith26]. Finally, one case of an Australian man bitten by a monkey in Indonesia, and who subsequently developed ZIKV 5 days after the incident, led to speculation of this as a potential route of transmission [Reference Leung64]. However, it is still undetermined due to the possibility of his also being bitten by a mosquito during his stay [Reference Leung64].

Between January 2015 and 9 March 2017, 70 countries and territories have reported evidence of mosquito-borne transmission of the virus according to the ECDC; 13 countries have reported evidence of person-to-person transmission of the virus, via a sexual route [57]. Moreover, 31 countries have reported microcephaly and other CNS malformations in newborns potentially associated with ZIKV infection [57]. Four additional countries – Saint Martin, Bolivia, Trinidad and Tobago and Curaçao – have reported GBS associated with ZIKV infection [57].

Insights from mathematical models

Mathematical models of ZIKV transmission dynamics reaffirm the importance of a variety of public health strategies. Massad et al. devised a model which combined data from the transmission dynamics of ZIKV in French Polynesia with travel data [Reference Massad29]. This mathematical model predicted an expected incidence which closely matched that of the observed weekly cases and added to the growing body of evidence suggesting French Polynesia as the source of the infection. With regards to the timing of the infection, the model predicted a date of introduction of the disease that preceded the sporting events of 2014. The need for constant epidemiological vigilance is highlighted by this finding since the disease was most likely introduced before the large international gatherings that took place.

Other models suggest that public health interventions must be both effective and enduring in order to control the spread of the disease. The agent-based model proposed by Moghadas et al. considered the transmissibility of asymptomatic infection, producing lower estimates of the contribution of sexual transmission than previous deterministic models [Reference Moghadas60]. This agrees with the model proposed by Maxian et al., in which sexual transmission was considered to be of little importance in high-transmission scenarios [Reference Maxian65]. However, control of sexual transmission is not unimportant, since the model by Moghadas et al. also predicts second waves of infection if the asymptomatic transmission is not addressed [Reference Moghadas60].

The direct impact of vector control strategies has also been studied. Analysis of a local outbreak in the Miami-Dade County by Marini et al. suggested that a reduction in mosquito abundance of 50% before the introduction of the virus could have prevented 51.5% of the cases [Reference Marini66]. Wang et al. predicted that the continued release of male and female Wolbachia-containing mosquitos could have had a dramatic effect on the spread of the disease in Brazil [Reference Wang67]. Of note, this measure was only effective if implemented in the long-term, with little impact if implemented only at the onset.

ZIKV in animal models

As the Zika epidemic progresses, the study of its pathogenesis has gained great interest in the medical community. Development of numerous animal-based models to understand its pathophysiology, its action in pregnancy and foetal development, as well as the possibility of developing a vaccine and a treatment, are on the cutting-edge of science. The most often used models for these investigations have been the murine models (both immunocompetent and immunosuppressed), guinea-pigs and non-human primates [Reference Bierle68].

Recent murine models have shown potential for determining neurovirulence of different ZIKV strains. A recent study on immunocompetent CD1/ICR murine models showed an 80–100% age-independent mortality rate after intracranial inoculation of MR766 – a 1947 Ugandan ZIKV prototype strain [Reference Duggal69]. It is important to underline that the route of inoculation was definitive for the initiation of disease. While the intra-peritoneal inoculation route did not show any symptoms of the disease, the intracranial route showed affection of the CNS confirmed by histopathology. Widespread variations have been observed, with inflammatory changes in the cerebral cortex showing mixed leptomeningeal and parenchymal inflammation with extensive glial proliferation and neuronal cell death [Reference Song31, Reference Duggal69]. Other studies have shown neuronal degeneration, softening, infiltration of round cells, infiltration of Crowdy Type A bodies and encephalitis in post-mortem histopathological studies of murine brains infected with the virus [Reference Boorman and Porterfield70]. Regarding other clinical manifestations, no mice showed any retinal changes [Reference Duggal69]. Similarly, a study showing intracranial inoculation of 35-day-old immunocompetent mice with this same prototype demonstrated signs of disease during a 5–15-day time-lapse after inoculation [Reference Maxian65].

Guinea-pigs have also been used to understand the course of other transplacental viral infections. ZIKV studies on guinea-pigs have shown low viraemia on non-pregnant animals [Reference Bierle68]. No viraemia was detected on pregnant guinea-pigs or their pup's blood, plasma or tissues, or other weight manifestations. However, antibodies were found in pups and their mothers, thereby posing immunocompetent guinea-pigs as an ideal model for the ZIKV-associated immune response but not ideal for the pathogenesis of complications of ZIKV infection [Reference Bierle68].

Experiments in macaques have shown that neutralising antibodies are produced in response to the injection of ZIKV RNA into plasma [Reference Dudley71]. This protects the organism from further infection and permits the development of specific T-cell response against the virus. Short-term viraemia follows infection in non-pregnant macaques, which usually resolves 10 days post-infection. However, infections in pregnant macaques show a more prolonged viraemia. ZIKV has been identified in macaque blood up to 57 days post-infection [Reference Dudley71]. Finally, an important finding on rhesus monkey models was that despite blood clearance of vRNA, the virus was still detected in saliva, urine and in cerebrospinal fluid, indicating the presence of ZIKV in some tissues at low levels [Reference Shankar, Patil and Skariyachan72]. The vRNA was also found in the brain, eye and placenta of foetal tissues of macaques during pregnancy [Reference Nguyen73].

Social determinants of disease

All illnesses are immersed in a context that determines in an extensive manner the characteristics of the disease's course. The transmission of the ZIKV, for example, partly depends on conditions which perpetuate the vector cycle. This includes standing water reservoirs where eggs laid by the mosquito can find an optimal environment to develop, such as buckets, rainwater gathered in puddles, pools, drums, flower pots, empty cans, etc. [Reference Aziz6, Reference Petersen52]. Rapid urbanisation in conditions of extreme poverty contributes to deforestation, exposing populations to different vectors and pathogens with greater frequency. Furthermore, despite widespread exposure to the vector in endemic areas, evidence has shown that poverty and inequality are factors that make people more vulnerable to develop ZIKV-related microcephaly (as shown in the economically deprived northeast region of Brazil) [Reference Possas74]. This social determinant of disease relates to the lack of basic services, in particular the persistent absence of water services, as well as problems with the establishment of sewage, residue collection and the use and disposal of non-biodegradable material [75]. Finally, phenomena such as population growth, migration, uncontrolled urbanisation and poverty belts in cities facilitate vector breeding and the perpetuation of the disease cycle [Reference Possas74, 75].

Lessons learned

On 18 November 2016, the Director-General of the International Health Regulations (IHR) accepted the recommendations of the Emergency Committee and declared the end of the Public Health Emergency of International Concern (PHEIC) [76]. However, ZIKV infection and its complications are still a concern for public health. Despite a decline in cases of ZIKV infection registered in many territories, the virus continues to spread geographically to areas where vectors are found [1]. Therefore, in order to prevent the establishment of new transmission chains, it is necessary to undertake several strategic public health interventions:

  • Intensify vector-control measures and the strategic intervention in public health risk communication, community engagement activities, personal protection against mosquitoes and appropriate advice for the caregivers of those affected [1].

  • Surveillance needs to be assured through an optimal preparedness plan by local, national, and international authorities, as well as mosquito control professionals and national laboratories. A documented example of the success of such plans occurred in the Chikungunya outbreak in Montpellier, France 2014 [Reference Delisle77]. The outbreak was rapidly contained thanks to a prompt attribution of responsibilities, an aggressive communication campaign, and continued vector control interventions. This included the use of general measures to avoid mosquito bites, as well as the use of disinfectants to which the virus is vulnerable such as 1% sodium hypochlorite, 70% ethanol or 6% hydrogen peroxide, among others [Reference Delisle77, Reference Müller and Harms78].

  • The screening of TORCH, dengue and other arboviruses during pregnancy, taking into account that the synergic potential is given by the presence of immunity and/or seropositivity of another virus can cause atypical presentations of the disease or absence of the symptoms, as well as an extension of the spectrum of the maternal–foetal presentation [Reference Coyne and Lazear79].

  • Enable the ‘massification’ of education, in particular regarding the epidemiology of the disease and the general measures that must be taken to prevent transmission by the public health authorities of each country [Reference Chang40]. Regarding travellers, it is important to take into account the differential diagnosis of other travel-related illnesses, the use of measures to avoid mosquito bites and the fact that travellers who plan to become pregnant soon should refrain from travelling to areas where the transmission of the ZIKV may be active.

Conclusion

ZIKV outbreaks produce devastating and lasting effects in the regions in which they occur [80]. Despite the danger having seemingly abated, for now, authorities should not be apathetic. The geographical spread of the virus and the severity of its diverse health complications, coupled with increasing cross-border travel and climate change increase the habitable environments for vectors. Therefore, it is imperative that the international public health community and national policymakers make use of this window of opportunity to put in place appropriate measures before another – possibly worse – outbreak occurs. They can do so by taking advantage of pre-existing regulatory and public health infrastructure [Reference Younger12]. Early vector control, an assertive information campaign, and the involvement of the local population and healthcare workers are key factors in the successful containment of outbreaks.

Consideration of the social determinants of health suggests that urban planners play a key role in the prevention of outbreaks and in the amelioration of the disease's spread. There is evidence of how integrated prevention can improve the public health response to arbovirus outbreaks and successfully contain the spread. Responsible urbanisation schemes including adequate water and waste management and sustainable urban development that avoids encroaching on vector habitats are key strategies that fall outside of the scope of health authorities. This highlights the need for an interdisciplinary approach to the control and prevention of the ZIKV spread.

Authors contributions

Talero-Gutierrez participated in research conception/design, analysis and interpretation, manuscript preparation and final approval. Rivera-Molina participated in research conception/design, data acquisition, analysis and interpretation, manuscript preparation and final approval. Pérez-Pavajeau participated in research conception/design, data acquisition, analysis and interpretation, manuscript preparation and final approval. Ossa-Ospina participated in research conception/design, data acquisition, analysis and interpretation, manuscript preparation and final approval. Santos-García participated in research conception/design, data acquisition, analysis and interpretation, manuscript preparation and final approval. Rojas-Anaya participated in research conception/design, data acquisition, analysis and interpretation, manuscript preparation and final approval. de-la-Torre participated in analysis and interpretation, manuscript preparation and final approval, critical reviewing and expert advisory of the study.

Funding

None of the authors received any kind of funding for this paper.

Declaration of Interest

There is no actual or potential financial or other conflict of interest related to the submitted manuscript.

References

1.World Health Organization (2017) Zika Virus Microcephaly and Guillain-Barre Syndrome. Geneva, Switzerland: World Health Organization.Google Scholar
2.World Health Organization. WHO|WHO Statement on the First Meeting of the International Health Regulations (2005) (IHR 2005) Emergency Committee on Zika Virus and Observed Increase in Neurological Disorders and Neonatal Malformations. WHO. Available at http://www.who.int/mediacentre/news/statements/2016/1st-emergency-committee-zika/en/. Accessed 4 October 2017.Google Scholar
3.Del Carpio-Orantes, L (2016) [Zika, a neurotropic virus?]. Revista Medica Del Instituto Mexicano Del Seguro Social 54, 540543.Google Scholar
4.Nunes, ML, et al. (2016) Microcephaly and Zika virus: a clinical and epidemiological analysis of the current outbreak in Brazil. Jornal de Pediatria 92, 230240.CrossRefGoogle ScholarPubMed
5.Oehler, E, et al. (2014) Zika virus infection complicated by Guillain–Barré syndrome – case report, French Polynesia, December 2013. Eurosurveillance 19. Published online: 6 March 2014. doi: 10.2807/1560-7917. ES2014.19.9.20720.CrossRefGoogle ScholarPubMed
6.Aziz, H, et al. (2017) Zika virus: global health challenge, threat and current situation: Zika virus. Journal of Medical Virology 89, 943951.CrossRefGoogle ScholarPubMed
7.Brasil, P, et al. (2016) Zika virus infection in pregnant women in Rio de Janeiro. New England Journal of Medicine 375, 23212334.CrossRefGoogle ScholarPubMed
8.European Centre for Disease Prevention and Control (2016). Rapid Risk Assessment. Zika Virus Disease Epidemic. Sixth update, 20 May 2016. Stockholm: ECDC.Google Scholar
9.Li, R, et al. (2017) Zika virus infections, a review. Radiology of Infectious Diseases 4, 8893.CrossRefGoogle Scholar
10.Desai, SK, et al. (2017) Zika virus (ZIKV): a review of proposed mechanisms of transmission and associated congenital abnormalities. American Journal of Stem Cells 6, 1322.Google ScholarPubMed
11.Chibueze, EC, et al. (2017) Zika virus infection in pregnancy: a systematic review of disease course and complications. Reproductive Health 14, 1428.CrossRefGoogle Scholar
12.Younger, DS (2016) Epidemiology of Zika virus. Neurologic Clinics 34, 10491056.CrossRefGoogle ScholarPubMed
13.Grischott, F, et al. (2016) Non-vector-borne transmission of Zika virus: a systematic review. Travel Medicine and Infectious Disease 14, 313330.CrossRefGoogle ScholarPubMed
14.Jamali Moghadam, SR, et al. (2016) Zika virus: a review of literature. Asian Pacific Journal of Tropical Biomedicine 6, 989994.CrossRefGoogle Scholar
15.Dick, GW, Kitchen, S and Haddow, A (1952) Zika virus (I). isolations and serological specificity. Transactions of the Royal Society of Tropical Medicine and Hygiene 46, 509520.CrossRefGoogle ScholarPubMed
16.Lanciotti, RS, et al. (2008) Genetic and serologic properties of Zika virus associated with an epidemic, Yap State, Micronesia, 2007. Emerging Infectious Diseases 14, 12321239.CrossRefGoogle ScholarPubMed
17.Beckham, JD, et al. (2016) Zika virus as an emerging global pathogen: neurological complications of Zika virus. JAMA Neurology 73, 875.CrossRefGoogle ScholarPubMed
18.Rabaan, AA, et al. (2017) Overview of Zika infection, epidemiology, transmission and control measures. Journal of Infection and Public Health 10, 141149.CrossRefGoogle ScholarPubMed
19.Cao-Lormeau, V-M, et al. (2016) Guillain-Barré syndrome outbreak associated with Zika virus infection in French Polynesia: a case-control study. The Lancet 387, 15311539.CrossRefGoogle ScholarPubMed
20.Salinas, JL, et al. (2017) Zika virus disease-associated Guillain-Barré syndrome – Barranquilla, Colombia 2015–2016. Journal of the Neurological Sciences 381, 272277.CrossRefGoogle ScholarPubMed
21.Styczynski, AR, et al. (2017) Increased rates of Guillain-Barré syndrome associated with Zika virus outbreak in the Salvador metropolitan area, Brazil. PLoS Neglected Tropical Diseases 11, e0005869. doi: 10.1371/journal.pntd.0005869.CrossRefGoogle Scholar
22.Jouannic, J-M, et al. (2016) Zika virus infection in French Polynesia. The Lancet 387, 10511052.CrossRefGoogle ScholarPubMed
23.Cauchemez, S, et al. (2016) Association between Zika virus and microcephaly in French Polynesia, 2013–15: a retrospective study. The Lancet 387, 21252132.CrossRefGoogle ScholarPubMed
24.Al-Qahtani, AA, et al. (2016) Zika virus: a new pandemic threat. Journal of Infection in Developing Countries 10, 201207.CrossRefGoogle ScholarPubMed
25.Faye, O, et al. (2008) One-step RT-PCR for detection of Zika virus. Journal of Clinical Virology 43, 96101.CrossRefGoogle ScholarPubMed
26.Wikan, N and Smith, DR (2016) Zika virus: history of a newly emerging arbovirus. The Lancet Infectious Diseases 16, e119e126.CrossRefGoogle ScholarPubMed
27.Musso, D (2015) Zika virus transmission from French Polynesia to Brazil. Emerging Infectious Diseases 21, 18871887.CrossRefGoogle ScholarPubMed
28.Vogel, G (2016) Don't blame sports for Zika's spread. Science 351, 13771378.CrossRefGoogle Scholar
29.Massad, E, et al. (2017) On the origin and timing of Zika virus introduction in Brazil. Epidemiology and Infection 145, 23032312.CrossRefGoogle ScholarPubMed
30.Broutet, N, et al. (2016) Zika virus as a cause of neurologic disorders. New England Journal of Medicine 374, 15061509.CrossRefGoogle ScholarPubMed
31.Song, B-H, et al. (2017) Zika virus: history, epidemiology, transmission, and clinical presentation. Journal of Neuroimmunology 308, 5064.CrossRefGoogle ScholarPubMed
32.Anaya, J-M, et al. (2017) A comprehensive analysis and immunobiology of autoimmune neurological syndromes during the Zika virus outbreak in Cúcuta, Colombia. Journal of Autoimmunity 77, 123138.CrossRefGoogle ScholarPubMed
33.European Centre for Disease Prevention and Control (2016) Communicable Disease Threat Reports Report. Week 25, 19–25 June 2016. Stockholm: ECDC.Google Scholar
34.Krauer, F, et al. (2017) Zika virus infection as a cause of congenital brain abnormalities and Guillain-Barré Syndrome: systematic review. PLoS Medicine 14: e1002203. doi: 10.1371/journal.pmed.1002203.CrossRefGoogle ScholarPubMed
35.Miner, JJ, et al. (2016) Zika virus infection during pregnancy in mice causes placental damage and fetal demise. Cell 165, 10811091.CrossRefGoogle ScholarPubMed
36.Paixão, ES, et al. (2016) History, epidemiology, and clinical manifestations of Zika: a systematic review. American Journal of Public Health 106, 606612.CrossRefGoogle ScholarPubMed
37.Wong, SS-Y, Poon, RW-S and Wong, SC-Y (2016) Zika virus infection – the next wave after dengue? Journal of the Formosan Medical Association 115, 226242.CrossRefGoogle ScholarPubMed
38.Chan, JFW, et al. (2016) Zika fever and congenital Zika syndrome: an unexpected emerging arboviral disease. Journal of Infection 72, 507524.CrossRefGoogle ScholarPubMed
39.Ioos, S, et al. (2014) Current Zika virus epidemiology and recent epidemics. Médecine et Maladies Infectieuses 44, 302307.CrossRefGoogle ScholarPubMed
40.Chang, C, et al. (2016) The Zika outbreak of the 21st century. Journal of Autoimmunity 68, 113.CrossRefGoogle Scholar
41.de Leal, MC, et al. (2016) Sensorineural hearing loss in a case of congenital Zika virus. Brazilian Journal of Otorhinolaryngology. Published online: June 2016. doi: 10.1016/j.bjorl.2016.06.001.Google Scholar
42.Yepez, JB, et al. (2017) Ophthalmic manifestations of congenital Zika syndrome in Colombia and Venezuela. JAMA Ophthalmology 135, 440445.CrossRefGoogle ScholarPubMed
43.Carteaux, G, et al. (2016) Zika virus associated with meningoencephalitis. New England Journal of Medicine 374, 15951596.CrossRefGoogle ScholarPubMed
44.Mécharles, S, et al. (2016) Acute myelitis due to Zika virus infection. The Lancet 387, 1481.CrossRefGoogle ScholarPubMed
45.Karam, E, et al. (2017) Ocular flutter following Zika virus infection. Journal of NeuroVirology 23, 932934.CrossRefGoogle ScholarPubMed
46.Sharma, S, et al. (2017) Zika virus: a public health threat. Journal of Medical Virology 89, 16931699.CrossRefGoogle ScholarPubMed
47.Lee, H-J, Kim, YB and Shin, Y (2017) Advances in epidemiology, biology and laboratory diagnosis of Zika virus. Journal of Bacteriology and Virology 47, 113.CrossRefGoogle Scholar
48.Ferreira, MLB, et al. (2017) Guillain–Barré syndrome, acute disseminated encephalomyelitis and encephalitis associated with Zika virus infection in Brazil: detection of viral RNA and isolation of virus during late infection. The American Journal of Tropical Medicine and Hygiene 97, 14051409.CrossRefGoogle Scholar
49.Meaney-Delman, D, et al. (2016) Prolonged detection of Zika virus RNA in pregnant women. Obstetrics & Gynecology 128, 724730.CrossRefGoogle ScholarPubMed
50.Gourinat, A-C, et al. (2015) Detection of Zika virus in Urine. Emerging Infectious Diseases 21, 8486.CrossRefGoogle ScholarPubMed
51.Centers for Disease Control and Prevention (2014) Zika virus – transmission and risks. CDC. Available at https://www.cdc.gov/zika/transmission/index.html. Accessed 4 October 2017.Google Scholar
52.Petersen, E, et al. (2016) Rapid spread of Zika virus in the Americas – implications for public health preparedness for mass gatherings at the 2016 Brazil olympic games. International Journal of Infectious Diseases 44, 1115.CrossRefGoogle ScholarPubMed
53.Liu-Helmersson, J, et al. (2016) Climate change and Aedes vectors: 21st century projections for dengue transmission in Europe. EBioMedicine 7, 267277.CrossRefGoogle ScholarPubMed
54.European Centre for Disease Prevention and Control (2016) Rapid Risk Assessment. Zika Virus Disease Epidemic. Eigth update, 30 August 2016. Stockholm: ECDC.Google Scholar
55.Besnard, M, et al. (2014) Evidence of perinatal transmission of Zika virus, French Polynesia, December 2013 and February 2014. Eurosurveillance 19, 20751.CrossRefGoogle ScholarPubMed
56.Dupont-Rouzeyrol, M, et al. (2016) Infectious Zika viral particles in breastmilk. The Lancet 387, 1051.CrossRefGoogle ScholarPubMed
57.European Centre for Disease Prevention and Control (2017) Rapid Risk Assessment. Zika Virus Disease Epidemic. Tenth update, 4 April 2017. Stockholm: ECDC.Google Scholar
58.Harrower, J, et al. (2016) Sexual transmission of Zika virus and persistence in semen, New Zealand, 2016. Emerging Infectious Diseases 22, 18551857.CrossRefGoogle ScholarPubMed
59.Paz-Bailey, G, et al. (2017) Persistence of Zika virus in body fluids – preliminary report. The New England Journal of Medicine. Published online: 14 February 2017. doi: 10.1056/NEJMoa1613108.Google Scholar
60.Moghadas, SM, et al. (2017) Asymptomatic transmission and the dynamics of Zika infection. Scientific Reports 7. Published online: December 2017. doi: 10.1038/s41598-017-05013-9.CrossRefGoogle ScholarPubMed
61.Motta, IJF, et al. (2016) Evidence for transmission of Zika virus by platelet transfusion. New England Journal of Medicine 375, 11011103.CrossRefGoogle ScholarPubMed
62.Barjas-Castro, ML, et al. (2016) Probable transfusion-transmitted Zika virus in Brazil. Transfusion 56, 16841688.CrossRefGoogle ScholarPubMed
63.Slavov, SN, et al. (2017) Zika virus RNA detection in asymptomatic blood donors during an outbreak in the northeast region of São Paulo State, Brazil, 2016. Transfusion 57, 28972901.CrossRefGoogle Scholar
64.Leung, GHY, et al. (2015) Zika virus infection in Australia following a monkey bite in Indonesia. The Southeast Asian Journal of Tropical Medicine and Public Health 46, 460464.Google ScholarPubMed
65.Maxian, O, et al. (2017) Zika virus dynamics: when does sexual transmission matter? Epidemics 21, 4855.CrossRefGoogle ScholarPubMed
66.Marini, G, et al. (2017) First outbreak of Zika virus in the continental United States: a modelling analysis. Eurosurveillance 22. Published online: 14 September 2017. doi: 10.2807/1560-7917.ES.2017.22.37.30612.CrossRefGoogle ScholarPubMed
67.Wang, L, et al. (2017) Modeling the transmission and control of Zika in Brazil. Scientific Reports 7. Published online: December 2017. doi: 10.1038/s41598-017-07264-y.Google ScholarPubMed
68.Bierle, CJ, et al. (2017) Assessing Zika virus replication and the development of Zika-specific antibodies after a mid-gestation viral challenge in Guinea pigs. PLoS ONE 12: e0187720. doi: 10.1371/journal.pone.0187720.CrossRefGoogle ScholarPubMed
69.Duggal, NK, et al. (2017) Differential neurovirulence of African and Asian genotype Zika virus isolates in outbred immunocompetent mice. The American Journal of Tropical Medicine and Hygiene 97, 14101417.CrossRefGoogle ScholarPubMed
70.Boorman, JP and Porterfield, JS (1956) A simple technique for infection of mosquitoes with viruses; transmission of Zika virus. Transactions of the Royal Society of Tropical Medicine and Hygiene 50, 238242.CrossRefGoogle ScholarPubMed
71.Dudley, DM, et al. (2016) A rhesus macaque model of Asian-lineage Zika virus infection. Nature Communications 7, 1761. Published online: 28 June 2016. doi: 10.1038/ncomms12204.CrossRefGoogle ScholarPubMed
72.Shankar, A, Patil, AA and Skariyachan, S (2017) Recent perspectives on genome, transmission, clinical manifestation, diagnosis, therapeutic strategies, vaccine developments, and challenges of Zika virus research. Frontiers in Microbiology 8. Published online: 14 September 2017. doi: 10.3389/fmicb.2017.01761.CrossRefGoogle ScholarPubMed
73.Nguyen, SM, et al. (2017) Highly efficient maternal-fetal Zika virus transmission in pregnant rhesus macaques. PLoS Pathogens 13, e1006378. doi: 10.1371/journal.ppat.1006378.CrossRefGoogle ScholarPubMed
74.Possas, C (2016) Zika: what we do and do not know based on the experiences of Brazil. Epidemiology and Health 38, e2016023. doi: 10.4178/epih.e2016023.CrossRefGoogle Scholar
75.Panamerican Health Organization (2012) Situación Actual del Dengue. Informes de Progreso Sobre Asuntos Técnicos. Washington DC: Panamerican Health Organization, pp. 3134.Google Scholar
76.European Centre for Disease Prevention and Control (2016). Epidemiological Update: Outbreaks of Zika Virus and Complications Potentially Linked to the Zika Virus Infection, 24 November 2016. Available at http://ecdc.europa.eu/en/news-events/epidemiological-update-outbreaks-zika-virus-and-complications-potentially-linked-38. Accessed 29 December 2017.Google Scholar
77.Delisle, E, et al. (2015) Chikungunya outbreak in montpellier, France, September to October 2014. Euro Surveillance: Bulletin Europeen Sur Les Maladies Transmissibles. European Communicable Disease Bulletin 20, Published online: 30 April 2015.Google ScholarPubMed
78.Müller, JA and Harms, M (2016) Inactivation and environmental stability of Zika virus. Emerging Infectious Diseases 22, 16851687.CrossRefGoogle ScholarPubMed
79.Coyne, CB and Lazear, HM (2016) Zika virus – reigniting the TORCH. Nature Reviews Microbiology 14, 707.CrossRefGoogle ScholarPubMed
80.European Centre for Disease Prevention and Control (2016) Preparing for Zika in the EU. Stockholm: ECDC. doi: 10.2900/624835.Google Scholar