Sentinel Enhanced Dengue Surveillance System — Puerto Rico, 2012–2022

Surveillance Summaries / May 30, 2024 / 73(3);1–29

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Zachary J. Madewell, PhD1; Alfonso C. Hernandez-Romieu, MD1; Joshua M. Wong, MD1; Laura D. Zambrano, PhD1; Hannah R. Volkman, PhD1; Janice Perez-Padilla, MPH1; Dania M. Rodriguez, MS1; Olga Lorenzi, MS1; Carla Espinet, MPH1; Jorge Munoz-Jordan, PhD1; Verónica M. Frasqueri-Quintana, MPH2; Vanessa Rivera-Amill, PhD2; Luisa I. Alvarado-Domenech, MD2; Diego Sainz, MD3; Jorge Bertran, MD3; Gabriela Paz-Bailey, MD, PhD1; Laura E. Adams, DVM1 (View author affiliations)

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Abstract

Problem/Condition: Dengue is the most prevalent mosquitoborne viral illness worldwide and is endemic in Puerto Rico. Dengue’s clinical spectrum can range from mild, undifferentiated febrile illness to hemorrhagic manifestations, shock, multiorgan failure, and death in severe cases. The disease presentation is nonspecific; therefore, various other illnesses (e.g., arboviral and respiratory pathogens) can cause similar clinical symptoms. Enhanced surveillance is necessary to determine disease prevalence, to characterize the epidemiology of severe disease, and to evaluate diagnostic and treatment practices to improve patient outcomes. The Sentinel Enhanced Dengue Surveillance System (SEDSS) was established to monitor trends of dengue and dengue-like acute febrile illnesses (AFIs), characterize the clinical course of disease, and serve as an early warning system for viral infections with epidemic potential.

Reporting Period: May 2012–December 2022.

Description of System: SEDSS conducts enhanced surveillance for dengue and other relevant AFIs in Puerto Rico. This report includes aggregated data collected from May 2012 through December 2022. SEDSS was launched in May 2012 with patients with AFIs from five health care facilities enrolled. The facilities included two emergency departments in tertiary acute care hospitals in the San Juan-Caguas-Guaynabo metropolitan area and Ponce, two secondary acute care hospitals in Carolina and Guayama, and one outpatient acute care clinic in Ponce. Patients arriving at any SEDSS site were eligible for enrollment if they reported having fever within the past 7 days. During the Zika epidemic (June 2016–June 2018), patients were eligible for enrollment if they had either rash and conjunctivitis, rash and arthralgia, or fever. Eligibility was expanded in April 2020 to include reported cough or shortness of breath within the past 14 days. Blood, urine, nasopharyngeal, and oropharyngeal specimens were collected at enrollment from all participants who consented. Diagnostic testing for dengue virus (DENV) serotypes 1–4, chikungunya virus, Zika virus, influenza A and B viruses, SARS-CoV-2, and five other respiratory viruses was performed by the CDC laboratory in San Juan.

Results: During May 2012–December 2022, a total of 43,608 participants with diagnosed AFI were enrolled in SEDSS; a majority of participants (45.0%) were from Ponce. During the surveillance period, there were 1,432 confirmed or probable cases of dengue, 2,293 confirmed or probable cases of chikungunya, and 1,918 confirmed or probable cases of Zika. The epidemic curves of the three arboviruses indicate dengue is endemic; outbreaks of chikungunya and Zika were sporadic, with case counts peaking in late 2014 and 2016, respectively. The majority of commonly identified respiratory pathogens were influenza A virus (3,756), SARS-CoV-2 (1,586), human adenovirus (1,550), respiratory syncytial virus (1,489), influenza B virus (1,430), and human parainfluenza virus type 1 or 3 (1,401). A total of 5,502 participants had confirmed or probable arbovirus infection, 11,922 had confirmed respiratory virus infection, and 26,503 had AFI without any of the arboviruses or respiratory viruses examined.

Interpretation: Dengue is endemic in Puerto Rico; however, incidence rates varied widely during the reporting period, with the last notable outbreak occurring during 2012–2013. DENV-1 was the predominant virus during the surveillance period; sporadic cases of DENV-4 also were reported. Puerto Rico experienced large outbreaks of chikungunya that peaked in 2014 and of Zika that peaked in 2016; few cases of both viruses have been reported since. Influenza A and respiratory syncytial virus seasonality patterns are distinct, with respiratory syncytial virus incidence typically reaching its annual peak a few weeks before influenza A. The emergence of SARS-CoV-2 led to a reduction in the circulation of other acute respiratory viruses.

Public Health Action: SEDSS is the only site-based enhanced surveillance system designed to gather information on AFI cases in Puerto Rico. This report illustrates that SEDSS can be adapted to detect dengue, Zika, chikungunya, COVID-19, and influenza outbreaks, along with other seasonal acute respiratory viruses, underscoring the importance of recognizing signs and symptoms of relevant diseases and understanding transmission dynamics among these viruses. This report also describes fluctuations in disease incidence, highlighting the value of active surveillance, testing for a panel of acute respiratory viruses, and the importance of flexible and responsive surveillance systems in addressing evolving public health challenges. Various vector control strategies and vaccines are being considered or implemented in Puerto Rico, and data from ongoing trials and SEDSS might be integrated to better understand epidemiologic factors underlying transmission and risk mitigation approaches. Data from SEDSS might guide sampling strategies and implementation of future trials to prevent arbovirus transmission, particularly during the expansion of SEDSS throughout the island to improve geographic representation.

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Introduction

Dengue is an acute febrile viral illness transmitted by Aedes spp. mosquitoes and caused by four closely related dengue virus serotypes (DENV 1–4). DENV causes an estimated 390 million infections (1) and 40,500 deaths worldwide each year (2). In contrast to data suggesting that the prevalence of most communicable diseases is declining worldwide, dengue incidence and disease prevalence have been increasing over time, measured both by disability-adjusted life years and mortality attributed to dengue (24). The increased prevalence is most pronounced in Southeast Asia; dengue remains endemic in Puerto Rico, where large outbreaks typically occur in cycles of 3–7 years (5). The most recent epidemic in Puerto Rico occurred during 2012–2013, dominated by DENV-1; sporadic cases of DENV-4 also occurred. During 2010–2020, dengue was associated with approximately 30,000 confirmed and probable cases, including 584 severe cases, approximately 10,000 hospitalizations, and 68 deaths islandwide (6). The southern region of Puerto Rico, which includes Ponce, has historically had a higher incidence of dengue. Ponce is the fourth largest municipality on the island and experienced a substantial proportion of dengue cases during the 2012–2013 epidemic (7).

Suspected dengue cases have historically been reported to the Passive Dengue Surveillance System (PDSS), a system jointly managed by CDC and the Puerto Rico Department of Health (PRDH). These cases were reported based on clinical suspicion, followed by laboratory confirmation by PRDH. PDSS faces certain challenges (e.g., underreporting, limited testing of suspected cases, and incomplete clinical data), highlighting the need for complementary and timely surveillance methods. Dengue presents diagnostic challenges because its nonspecific symptoms overlap with those of other acute febrile illnesses (AFIs), emphasizing the need for reliable diagnostic tests. Surveillance systems are often limited by underdiagnosis and underreporting, thereby missing cases. In 2012, CDC transferred the operational responsibility of PDSS to PRDH and established the Sentinel Enhanced Dengue Surveillance System (SEDSS), a site-based active surveillance system used to monitor acute febrile and respiratory illnesses within certain emergency departments (EDs) (810). SEDSS was designed to diagnose and characterize dengue infections, along with arboviral and other respiratory viruses, accompanied by comprehensive demographic, syndromic, and clinical data. SEDSS addresses these challenges through enhanced surveillance and by providing comprehensive diagnostic testing for all patients with AFIs, allowing for capture of the full spectrum of case and disease prevalence. Since May 2012, SEDSS has demonstrated its adaptability, expanding its scope to cover emerging pathogens such as chikungunya virus (CHIKV) in 2014, Zika virus (ZIKV) in 2016, and SARS-CoV-2 in 2020. This real-time tracking capability has positioned SEDSS as a flexible and responsive sentinel system, and this report represents the first comprehensive summary of SEDSS data, marking a milestone in the reporting of these surveillance findings.

This report summarizes arboviral and respiratory illnesses among patients with AFIs seeking care at SEDSS sites from May 5, 2012, through December 31, 2022, and describes large outbreaks of dengue, chikungunya, Zika, and COVID-19 that occurred at different points during the surveillance period. This report also characterizes the relative prevalence of dengue warning signs and severe dengue in different age groups among laboratory-confirmed cases.

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Methods

Surveillance Sites and Procedures

Data for this enhanced surveillance study were collected from patients with AFIs from hospitals participating in SEDSS from 2012 to 2022. Data collection adhered to a protocol approved by institutional review boards at CDC, Auxilio Mutuo, and Ponce Medical School Foundation with informed consent obtained from all participants. Recruitment for SEDSS began in May 2012 with two tertiary care facilities, two secondary care facilities, and one outpatient acute care clinic. During 2012–2015, SEDSS included three sites: 1) Saint Luke’s Episcopal Hospital (SLEH) in Ponce (SLEH-Ponce), a tertiary acute care hospital with 425 beds, an average of 50,000 patient visits per year, and 11,000 overall inpatient admissions per year; 2) SLEH-Guayama, a secondary acute care hospital with 116 beds, 40,000 patient visits per year, and 6,000 overall inpatient admissions per year; and 3) Hospital de La Universidad de Puerto Rico (UPR) in Carolina (UPR-Carolina), a secondary acute care teaching hospital with 250 beds, 55,000 medical visits per year, and 10,000 overall inpatient admissions per year (911). SLEH-Guayama participated from February 2013 to September 2015, UPR-Carolina operated from July 2013 to August 2015, and SLEH-Ponce continued participation through 2022. In 2016, Centro de Emergencia y Medicina Integrada (CEMI), an outpatient acute care clinic in Ponce registering approximately 1,700 annual clinic visits and 3,000 admissions joined the network. In November 2018, Auxilio Mutuo Hospital, a tertiary care facility in the San Juan-Caguas-Guaynabo metropolitan area (San Juan metro area) with 497 beds, 33,000 patient visits per year, and 8,000 overall inpatient admissions per year, was incorporated. The expansion to the San Juan metro area enhanced geographic representativeness, allowing the surveillance system to cover a broader and more diverse population within Puerto Rico.

Informational posters were available in hospital waiting rooms and hallways to inform the community about SEDSS. Potential participants were identified by triage nurses as any patient with an AFI defined by the presence of fever ≥100.4°F (≥38.0°C) for temperatures measured orally, ≥99.5°F (≥37.5°C) for temperatures measured rectally, and ≥101.3°F (≥38.5°C) for temperatures measured axillary at the time of triage or chief complaint of having a fever within the past 7 days. During the Zika epidemic (June 2016–June 2018), patients were eligible for enrollment in SEDSS if they visited a SEDSS site with either rash and conjunctivitis, rash and arthralgia, or fever (12). These criteria were applicable specifically during the Zika epidemic period to enhance Zika surveillance and are no longer part of the current eligibility criteria. Beginning in April 2020, patients reporting cough or dyspnea within the past 14 days (with or without fever) also were eligible for enrollment to better capture respiratory viruses (9). No age groups were excluded, although infants were only eligible for enrollment if they visited the hospital after their initial discharge after birth. All patients meeting the inclusion criteria were invited to participate in the study using convenience sampling. If a patient was incapacitated at the time of triage because of acute illness, the patient was only asked to participate after stabilization. All participants received an informational sheet about SEDSS and were enrolled after providing informed consent.

Data Collection

Data from SEDSS were collected through patient interview and medical record review at intake during patient enrollment on a case investigation form (CIF) and approximately 7–14 days later on a convalescent sample processing form (CSPF). The CIF included demographic information (e.g., name, age, sex, pregnancy status, and contact information), comorbidities (e.g., diabetes, hypertension, asthma, chronic kidney disease, and immunodeficiency), and clinical features (e.g., onset date, vital signs, signs, and symptoms). The CSPF contained comparable information to the CIF but added the date of the second specimen collection and indicators of AFI severity (e.g., hospitalizations and other clinic visits). Data were originally collected using paper copies of the CIF and CSPF and were transitioned to electronic data in 2020 using the Research Electronic Data Capture (REDCap) system (REDCap Consortium; version 5.20.11) (13,14).

Inpatient medical data for participants with AFIs who were admitted to the hospital from SLEH-Ponce, SLEH-Guayama, and Auxilio Mutuo Hospital also were collected using a separate form (Hospital Admitted Abstraction Form) and entered into REDCap to collect key clinical indicators of disease severity and progression. For admitted patients, these data included information on extent and nature of hemorrhage, plasma leakage (e.g., ascites and pleural and cardiac effusions), hematologic indicators of increased intravascular permeability (e.g., hematocrit and serum albumin levels), additional blood pressure and heart rate measures to assess shock, and indicators of severe organ involvement (e.g., liver impairment, meningitis, and encephalitis) (15). These data were subsequently merged with data entered from the SEDSS CIF and CSPF forms using medical record numbers.

Sample Collection, Laboratory Procedures, and Case Confirmation

Blood, nasopharyngeal (NP), and oropharyngeal (OP) specimens were collected at enrollment from eligible participants. Additional blood samples (e.g., serum and whole blood) also were collected during the convalescent phase. Participants were required to provide at least one sample (blood, OP, or NP) to participate. All participants had molecular testing for dengue, chikungunya (December 2013–April 2020), and Zika (December 2015–April 2020) viruses for specimens collected within 7 days of symptom onset. Before March 2016, DENV was detected by the CDC DENV-1–4 Real-Time Reverse Transcription-Polymerase Chain Reaction (RT-PCR) Assay (16). During March 2016–April 2020, the CDC Trioplex Real-Time RT-PCR Assay was used to detect DENV, CHIKV, and ZIKV concurrently, followed by the CDC DENV-1–4 Real-Time RT-PCR Assay on any samples positive for DENV to determine serotype (17). After April 2020, the CDC DENV-1–4 Real Time RT-PCR Assay again was used as the primary assay to detect DENV. Serologic testing was done by immunoglobulin M (IgM) antibody capture enzyme-linked immunosorbent assay for anti-DENV, anti-CHIKV (December 2013–March 2019), and anti-ZIKV (December 2015–March 2019) antibodies for specimens collected >3 days after symptom onset (18). Molecular diagnostic testing of NP and OP specimens was done by RT-PCR on a panel of respiratory viruses including influenza A (IAV) and influenza B (IBV) viruses, human adenovirus (HAdV), respiratory syncytial virus (RSV), human metapneumovirus (HMPV), human parainfluenza virus (HPIV) types 1 and 3, seasonal human coronavirus (HCoV [229E, OC43, NL63, and HKU1]) (18,19), and for SARS-CoV-2. For SARS-CoV-2, the RT-PCR assays used included the CDC Real-Time RT-PCR Panel for tests performed before December 2021 and the CDC Influenza SARS-CoV-2 Multiplex Assay for tests performed in December 2021 and later (20,21). HCoV testing was conducted consistently from 2012 to 2014 but was discontinued because of the viruses’ low frequency. However, sporadic testing based on clinical suspicion or exposure to known cases might have occurred throughout the study period. Molecular and serologic results were used to classify participants as having confirmed or probable CHIKV, DENV, or ZIKV infection using established guidance (22,23) (Table 1).

Dengue warning signs and severe dengue were defined by the Pan American Health Organization (24), incorporating available clinical indicators from SEDSS intake and follow-up forms and abstracted inpatient medical records. Dengue warning signs were defined by abdominal pain or tenderness, persistent vomiting, pleural or pericardial effusion or ascites, mucosal bleeding, restlessness, or hepatomegaly (15). Severe dengue was defined as severe plasma leakage or shock, severe bleeding, or severe organ impairment (15).

Analysis

Descriptive frequencies of AFI cases were reported by selected characteristics, including year, days post onset, age group, sex, ED encounter, physician diagnosis, clinical disposition, and chronic conditions. These characteristics also were reported by arboviral infection status (confirmed and probable DENV, ZIKV, and CHIKV) and respiratory virus infection (confirmed IAV, IBV, RSV, HAdV, HPIV-1, HPIV-3, HMPV, HCoV, and SARS-CoV-2). Clinical characteristics were reported by age group for participants with confirmed or probable DENV, CHIKV, and ZIKV infections. A patient might have been enrolled in SEDSS more than one time over the course of the study. The denominator for this analysis was the number of unique patient visits. Arbovirus and acute respiratory virus infection data were aggregated into weekly infection counts and plotted by epidemiologic week and year over the surveillance period. The frequency of symptoms for dengue, chikungunya, and Zika cases, as well as the frequency of warning signs and indicators of severe dengue, were calculated. The proportion of AFI cases positive for arboviruses or acute respiratory viruses by municipality is presented using choropleth maps with 5% equal intervals. All analyses were done using R software (R Foundation for Statistical Computing; version 4.3.1).

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Ethics Statement

The institutional review boards at CDC, Auxilio Mutuo, and Ponce Medical School Foundation approved the SEDSS study protocols 6,214 and 120308-VR, respectively. Written consent to participate was obtained from all adult participants and emancipated minors. For minors aged 14–20 years, written consent was obtained: for children aged 7–13 years, parental written consent and participant assent were obtained.

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Results

A total of 24,020 (27.2%) were recruited participants among 88,255 eligible patients from SLEH-Ponce (2012–2022), 2,893 (19.2%) among 15,071 from SLEH-Guayama (2013–2015), 9,240 (36.4%) recruited of 25,378 eligible from CEMI (2016–2022), 1,436 (23.6%) among 6,090 from UPR-Carolina (2013–2015), and 2,554 (10.6%) among 24,181 from Auxilio Mutuo Hospital (2021–2022) (Supplementary Table 2, https://stacks.cdc.gov/view/cdc/153721). The number of eligible patients was unavailable for Auxilio Mutuo Hospital (2018–2020); however, 2,733 participants were recruited during this period.

From May 2012 to December 2022, there were 43,608 unique visits from 35,855 total participants enrolled in SEDSS (Supplementary Figure 1, https://stacks.cdc.gov/view/cdc/153721), including 7,690 hospitalizations or transfers and 72 deaths (Table 2). Participants in SEDSS resided in 76 of the 78 municipalities in Puerto Rico; most visits were from participants residing in municipalities near the sentinel surveillance sites (e.g., Ponce [19,612 visits], Juana Díaz [3,535], Peñuelas [3,449], San Juan metro area [2,460], Villalba [1,719], Carolina [1,694], and Guayama [1,578]). Visits from participants were reported by residents of 18 U.S. states including Florida (nine), Texas (seven), and New York (six).

Etiologic Agents

Laboratory testing identified positive results for arboviruses, including DENV (959 confirmed and 473 probable cases), ZIKV (1,449 confirmed and 469 probable cases), and CHIKV (1,804 confirmed and 489 probable cases) (Figure 1). In addition, positive results were identified for the following respiratory viruses: IAV (3,756 cases), IBV (1,430 cases), SARS-CoV-2 (1,586 cases), HAdV (1,550 cases), RSV (1,489 cases), HPIV-1 (407 cases), HPIV-3 (993 cases), HMPV (862 cases), and HCoV (46 cases) (Figure 2).

Geographic Distribution and Temporal Trends

Arboviruses

The proportion of visits from participants testing positive for any arbovirus in municipalities with at least 100 participants tested was highest for those with residence in Guayama (539 of 1,543 [34.9%]), Salinas (144 of 594 [ 24.2%]), Patillas (64 of 308 [20.8%]), and Arroyo (62 of 303 [20.5%]) in southeast Puerto Rico and Loíza (33 of 146 [22.6%]) in northeast Puerto Rico (Figure 3). Conversely, municipalities that had the lowest proportion of visits from participants testing positive for arboviruses included Toa Baja (two of 118 [1.7%]) and Toa Alta (three of 105 [2.9%]) in northern Puerto Rico. The proportion of participants with AFI who tested positive for DENV were relatively consistent across PRDH regions (Supplementary Figure 2, https://stacks.cdc.gov/view/cdc/153721). The highest proportion of visits from participants testing positive for CHIKV was from San Juan metro area (296 of 2,481 [11.9%]) and Ponce (1,952 of 23,804 [8.2%]); the highest proportion who tested positive for ZIKV was from Ponce (1,886 of 19,324 [9.6%]).

Circulation of DENV, CHIKV, and ZIKV had minimal overlap, with transmission of each virus occurring during distinct periods (Supplementary Figure 3, https://stacks.cdc.gov/view/cdc/153721). SEDSS was initiated during an ongoing dengue outbreak in May 2012, and circulation continued until approximately February 2014. The majority of the 948 serotyped dengue cases were DENV-1 (891 [94.0%]), followed by DENV-4 (50 [5.3%]) (Figure 4) (Supplementary Figure 4, https://stacks.cdc.gov/view/cdc/153721). Six (0.6%) cases of DENV-2 and one (0.1%) case of DENV-3 were reported. CHIKV emerged on the island in January 2014 (25), and the first case was recorded in SEDSS in May 2014. Shortly after emergence, a large, time-limited outbreak of chikungunya occurred, which is reflected in the SEDSS data. During the peak of the chikungunya outbreak in September 2014, up to 195 cases per week were reported through SEDSS, representing 77.7% of all AFI cases in the system (Supplementary Figure 3, https://stacks.cdc.gov/view/cdc/153721). The outbreak eventually subsided in December 2014, with lingering low-level transmission occurring through November 2017. In December 2015, ZIKV emerged on the island, with the first case reported through SEDSS in January 2016. During the Zika outbreak peak, up to 101 cases per week were being reported through SEDSS before the outbreak ended in January 2017. In 2016, 1,612 of 6,301 (25.6%) of all ZIKV tests were positive (Supplementary Figure 5, https://stacks.cdc.gov/view/cdc/153721). ZIKV infections continued to be reported through SEDSS through 2018, albeit at low levels. During the Zika outbreak, 40 additional cases of probable flavivirus infections were reported, representing participants with cross-reactive IgM responses against ZIKV and DENV with no molecular evidence of infection. These cross-reactive IgM responses likely were associated with ZIKV because of the epidemiological context of a Zika outbreak and low DENV transmission during the same period. After the Zika outbreak subsided, low-to-no transmission of either ZIKV or DENV was observed until September 2019. Between September 2019 and December 2022, consistent low levels of weekly dengue cases (primarily DENV-1) were reported (Supplementary Figures 3 and 4, https://stacks.cdc.gov/view/cdc/153721), reaching a high of 23 cases observed in October 2020. Zero confirmed and nine probable ZIKV cases were reported from 2020 to 2022.

Respiratory Viruses

The proportion of visits from participants testing positive for any acute respiratory virus in municipalities with at least 100 participants tested was highest for those with residence in Toa Alta (44 of 113;[38.9%]), Bayamón (135 of 363; [34.4%]), Guaynabo (102 of 323; [31.6%]), and Toa Baja (41 of 130; [31.5%]) in northern Puerto Rico, whereas Canóvanas (71 of 358; [19.8%]), Loíza (31 of 153; [20.3%]), and Río Grande (41 of 201; [20.4%]) in northeast Puerto Rico had the lowest proportions of visits from participants testing positive for respiratory viruses (Figure 5). The proportions of visits from participants with AFIs who tested positive for HAdV, HMPV, IAV, IBV, RSV, and HPIV-3 were relatively consistent across PRDH regions (Supplementary Figure 2, https://stacks.cdc.gov/view/cdc/153721). Only participants from Ponce, San Juan metro area, and Bayamón tested positive for HPIV-1 (Supplementary Figure 2, https://stacks.cdc.gov/view/cdc/153721). Percentage positivity for SARS-CoV-2 ranged from 13.3% (825 of 6,211) in Ponce to 32.1% (35 of 109) in Fajardo.

Seasonality was observed for both IAV and IBV, with IAV circulation typically preceding IBV circulation each year (Supplementary Figure 6, https://stacks.cdc.gov/view/cdc/153721). Periods of sustained IAV transmission typically spanned late November to early March, whereas IBV transmission typically occurred from mid-April to mid-June. Two notable exceptions occurred during which sustained IAV transmission was observed from July through October 2013 and IBV transmission from October 2016 to January 2017. Strong seasonality also was observed for confirmed RSV infections. Each year, RSV outbreaks typically began between late October and early November, with seasonal peaks in late November and early December. Circulation of HAdV, HMPV, HPIV-1, and HPIV-3 occurred throughout the year. Each virus still exhibited seasonality, with more pronounced HAdV transmission in July, HPIV-1 in October, HPIV-3 in April and May, and HMPV in December and January. In March 2020, all acute respiratory viruses decreased after the emergence of SARS-CoV-2. From March 2020 to April 2021, approximately all identified respiratory viral infections were SARS-CoV-2 after which other respiratory viruses reemerged. The highest weekly number of SARS-CoV-2 infections occurred in January 2022, coinciding with the emergence of Omicron. In 2022, a total of 942 of 3,988 (23.6%) tests for SARS-CoV-2 were positive (Supplementary Figure 5, https://stacks.cdc.gov/view/cdc/153721).

Patient Characteristics, Signs, and Symptoms

Dengue Patient Characteristics, Symptoms, and Severity

A total of 1,432 dengue infections were identified among 1,427 study participants, which includes five participants who had two dengue infections during the study period (2012–2022). Of these infections, 1,026 (71.6%) occurred in 2012 and 2013 (Figure 1) (Supplementary Table 2, https://stacks.cdc.gov/view/cdc/153721). The majority of participants with dengue (765 [53.4%]) visited SEDSS sites within 3 days of symptom onset (Table 3). Most participants (764 [53.4%]) were male; among 668 female participants, 239 (35.8%) were women of childbearing age (15–44 years) and 11 were pregnant. A total of 587 (41.0%) participants with DENV infection were aged 10–19 years. Whereas 768 (53.6%) participants were ambulatory after the initial visit, 660 (46.1%) were admitted or transferred, and two participants died. The majority of common comorbidities were obesity (30.8%), hypertension (16.4%), chronic pulmonary disease (15.8%), and diabetes (9.6%). Before laboratory testing, 583 (40.7%) participants received a clinical diagnosis of dengue by a physician, 167 (11.7%) with a respiratory infection, and 560 (39.1%) with an unspecified infection. Among participants with DENV infection, 81 (5.7%) were coinfected with a respiratory virus, including 18 participants with HAdV and 28 with IAV or IBV.

Among the 1,432 participants with dengue reported through SEDSS, 263 (18.4%) received a diagnosis of dengue without warning signs, 788 (55.0%) received a diagnosis of dengue with warning signs and did not progress to severe dengue, and 381 (26.6%) received a diagnosis of severe dengue; two participants (0.1%) died. Among the 263 participants without warning signs, 788 with any warning sign, and 381 with severe dengue, 48 (18.3%), 293 (37.2%), and 319 (83.7%) were hospitalized or transferred, respectively. The distribution of dengue without warning signs, dengue with warning signs, and severe dengue was consistent across age groups with the exception that severe dengue was less prevalent among infants (Figure 6). Among the 557 participants with warning signs or severe dengue who were not hospitalized, 98 (17.6%) received a correct initial physician diagnosis of dengue. Age distribution of 1) specific clinical indicators of severity and 2) dengue without warning signs, dengue with warning signs, and severe dengue are presented (Table 4) (Figure 6). The most frequently reported general symptoms of dengue, in addition to fever, were headache (1,200 [83.8%]), myalgia (1,066 [74.4%]), and leukopenia (1,022 [71.4%]); however, all general symptoms, including fever, chills, nausea, rash, headache, retro-orbital pain, myalgia, arthralgia, and leukopenia, were reported in more than half of all participants with laboratory evidence of infection (Supplementary Figure 7, https://stacks.cdc.gov/view/cdc/153721). The most reported warning signs were abdominal pain (869 [60.7%]) and restlessness (699 [48.8%]). The most reported manifestation of severe dengue was severe plasma leakage (252 [17.6%]). Shock occurred in 32 (2.2%) participants. Severe organ impairment occurred in 57 (4.0%) participants, including 17 (1.2%) with liver impairment, seven (0.5%) with encephalopathy, seven (0.5%) with hepatitis, and one (0.1%) with aseptic meningitis. Seizures occurred in 26 (1.8%) participants (Table 4). Among the 11 pregnant women with laboratory evidence of DENV infection reported through SEDSS, seven (63.6%) had warning signs with no progression to severe dengue, and four (36.4%) had signs of severe dengue. Nine (81.2%) pregnant women were hospitalized.

Chikungunya Patient Characteristics and Symptoms

Among 2,293 confirmed or probable chikungunya cases reported to SEDSS, 1,884 (82.2%) were reported in 2014 (Figure 1) (Supplementary Table 2, https://stacks.cdc.gov/view/cdc/153721). Most participants (1,954 [85.2%]) visited SEDSS sites within 3 days of symptom onset (Table 3). A majority of participants were female (1,198 [52.2%]), and among the 450 women of childbearing age, 63 (14.0%) were pregnant. The plurality of cases with laboratory evidence of CHIKV infection were among participants aged ≥50 years (545 [23.8%]), followed by those aged 10–19 years (426 [18.6%]), those aged 1–4 years (309 [13.5%]), and those aged 20–29 years (281 [12.3%]). Most participants (1,923 [83.9%]) were discharged after the initial visit, whereas 337 (14.7%) were either admitted or transferred; three (0.1%) participants died. The most common comorbidities were hypertension (377 [16.4%]), asthma (354 [15.4%]), and diabetes (226 [9.9%]). Before laboratory testing, 345 (15.0%) participants received a clinical diagnosis of chikungunya by a physician after triage, 229 (10.0%) with a respiratory infection, and 1,297 (56.6%) with an unspecified infection. Among participants with CHIKV infection, 91 (4.0%) were coinfected with a respiratory virus, including 44 with IAV or IBV.

In addition to fever, (2,271 [99.0%]) and chills (1,668 [72.7%]), the most reported symptoms among the 2,293 participants with laboratory evidence of CHIKV infection were myalgia (1,726 [76.5%]), arthralgia (1,726 [75.3%]), and headache (1,664 [72.6%]) (Table 5) (Supplementary Figure 7, https://stacks.cdc.gov/view/cdc/153721). The proportion of participants reporting headache, myalgia, and arthralgia consistently increased with age (p≤0.027); however, young children might be less likely to self-report certain of these symptoms.

Zika Patient Characteristics and Symptoms

Among 1,918 confirmed or probable Zika cases, 1,612 (84.0%) were reported to SEDSS in 2016 (Figure 1) (Supplementary Table 2, https://stacks.cdc.gov/view/cdc/153721). Most participants (1,467 [76.5%]) visited SEDSS sites within 3 days of symptom onset (Table 3). A larger proportion of participants with Zika were female (57.7%) versus participants with dengue (46.6%) (p<0.001), and approximately half of visits by women with ZIKV infection who enrolled in SEDSS (544 [49.1%]) were of childbearing age; 77 (14.2%) were pregnant. The plurality of participants with laboratory evidence of ZIKV infection were aged ≥50 years (456 [23.8%]), followed by those aged 20–29 years (370 [19.3%]), 10–19 years (337 [17.6%]), and 30–39 years (261 [13.6%]). Most participants (1,770 [92.3%]) were discharged after the initial visit, whereas 117 (6.1%) were either admitted or transferred; one participant died. The most common comorbidities were hypertension (374 [19.5%]), asthma (341 [17.8%]), and diabetes (224 [11.7%]). Before laboratory testing, 82 (4.3%) participants received a clinical diagnosis of Zika, 131 (6.8%) with a respiratory infection, and 1,231 (64.2%) with an unspecified infection. A total of 152 (7.9%) participants with ZIKV infection were coinfected with respiratory viruses, 82 of whom had IAV or IBV.

In addition to fever and chills, the most reported common symptoms among the 1,918 participants with laboratory evidence of ZIKV infection were headache (1,493 [77.8%]), arthralgia (1,451 [75.7%]), and myalgia (1,405 [73.3%]). A total of 1,411 (73.6%) participants reported respiratory illness (e.g., nasal discharge, sore throat, and cough), and 1,089 (56.8%) reported gastrointestinal symptoms. The proportion of participants reporting symptoms such as myalgia, arthralgia, and headache consistently increased with age (p≤0.002) (Table 6).

Respiratory Virus Patient Characteristics

Most confirmed respiratory virus cases were attributed to IAV (3,756), followed by SARS-CoV-2 (1,586), HAdV (1,550), RSV (1,489), IBV (1,430), HPIV-3 (993), HMPV (862), and HPIV-1 (407) (Table 7) (Figure 2) (Supplementary Table 3, https://stacks.cdc.gov/view/cdc/153721). A total of 1,842 participants with AFIs were tested for any of the HCoVs and 46 (2.5%) were infected, the majority of these cases were reported in 2012 and 2013 (41 [89.1%]) (Supplementary Figure 5, https://stacks.cdc.gov/view/cdc/153721). Among 11,922 participants testing positive for any of the respiratory viruses examined herein, 5,919 (49.7%) received a diagnosis of any respiratory virus before laboratory testing, whereas the remaining participants had AFI diagnosed that was attributed to other causes. The age distribution varied by virus identified. A plurality of cases with confirmed IAV or IBV infections were among participants aged 10–19 years (1,036 [20.0%]) followed by those aged 5–9 years (960 [18.5%]). Conversely, detection of RSV, HAdV, HPIV-1, HPIV-3, and HMPV was most frequent among those aged 1–4 years (758 [50.9%], 729 [47.0%], 222 [54.5%], 483 [48.6%], and 333 [38.6%]), respectively). RSV was the most frequent virus among infants aged <1 year (289 [19.4%]), whereas SARS-CoV-2 was most frequent among adults aged ≥50 years (36.4%). Most participants were discharged after triage; however, 367 (24.6%) of all participants with confirmed RSV infection were admitted or transferred. Nineteen participants with acute respiratory virus infections died; 12 were positive for SARS-CoV-2. The most common comorbidity across all participants with respiratory virus infections was asthma.

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Discussion

Initially designed for enhanced dengue surveillance, SEDSS has evolved into a valuable and nimble AFI surveillance system, providing insights into the early epidemiology of various emerging pathogens, including CHIKV, ZIKV, and SARS-CoV-2, while also monitoring trends in influenza and other respiratory viruses during the surveillance period. The system’s flexibility allowed for the rapid setup of studies to understand new viruses and support the development of public health guidelines, exemplified by the successful implementation of a study to evaluate the duration of ZIKV RNA in body fluids (26) as well as the evaluation of rapid, point-of-care testing for SARS-CoV-2 detection and an IgM assay to distinguish between DENV and ZIKV infections (27,28). Other studies leveraged SEDSS to examine epidemiologic, clinical, and spatiotemporal patterns of Zika, chikungunya, leptospirosis, and COVID-19 in Puerto Rico (2932).

In contrast to the limitations of passive surveillance (e.g., underreporting and delayed case identification), SEDSS facilitated real-time detection and collection of detailed information about participants affected by arboviruses and respiratory viruses. This adaptability highlights the value of SEDSS as a surveillance tool for novel infectious threats, addressing the limitations associated with relying solely on passive surveillance. The expansion of SEDSS’s scope allowed for the documentation of temporal variations in both endemic arboviruses and respiratory viruses, providing a more comprehensive understanding of disease dynamics. Furthermore, this analysis assessed disease severity, including the proportion of participants with warning signs and those requiring hospitalization, aiding in clinical care evaluation. These data are useful in evaluating the health care system’s response to these diseases, offering insights that can guide future interventions, research gaps, and clinical care guidelines.

Among the three arboviruses, the chikungunya epidemic in 2014 recorded the highest number of participants with confirmed disease reported through SEDSS (2,293 cases). This observation aligns with observations from other regions in the Western Hemisphere that similarly experienced intense periods of CHIKV transmission among immunologically naïve populations in 2014 (33). Chikungunya typically has a higher symptomatic attack rate than Zika, resulting in a larger number of reported cases compared with other arboviruses, which might contribute to observed differences in case numbers between chikungunya and Zika (34,35). ZIKV was the second most reported arbovirus in SEDSS, with 1,918 cases reported. The first Zika case reported through SEDSS in January 2016 followed the first cases reported islandwide in December 2015. ZIKV transmission slowed after the first quarter of 2017, with the last confirmed case reported in April 2018 and low numbers of probable cases reported through 2019. The presence of persistent ZIKV IgM antibodies in these cases might not necessarily indicate recent infection because ZIKV IgM antibodies can persist for an extended period after the acute phase of infection, complicating the interpretation of serologic results (36). Cross-reactivity with DENV antibodies further challenges precise diagnosis. Since 2019, patients among all locally acquired Zika cases in U.S. territories had Zika diagnosed by antibody testing (probable cases), which cannot distinguish recent from past infections. Although the total number of dengue cases reported through SEDSS was lower, the most recent dengue outbreak persisted for >2 years. The lower transmission intensity of dengue compared with chikungunya and Zika likely reflects a certain degree of population immunity from previous DENV infections during the outbreak periods. No confirmed dengue cases were reported through SEDSS in 2017 and 2018, the years immediately following the Zika epidemic. This observation comports with a stochastic compartmental model trained on surveillance data from Colombia and Brazil (accounting for combinations of enhancement or cross-protection) that supports cross-protection against dengue for 2.2–3.5 years after a Zika outbreak (37) and precedes dengue resurgence. Insights from studies in Thailand and Nicaragua suggest that contrary to a 2-year waning period, cross-reactive binding antibodies linked to protection or enhancement reach a stable setpoint approximately 8 months after primary infection and persist for many years afterward (38,39). Although cross-protection provides a partial explanation, other factors (e.g., public health interventions such as mosquito control programs, educational campaigns, and vector surveillance) could have been intensified in response to the Zika outbreak, potentially contributing to the decrease in DENV transmission.

Most participants affected by any of the three arboviruses were aged 5–50 years, but disproportionately more participants aged ≥50 years had Zika or chikungunya compared with the age distribution of the overall SEDSS population. Relatively few cases among infants aged <1 year were reported through SEDSS with any of the three arboviruses, but more cases among infants were reported with laboratory evidence of chikungunya infection (4.7% of the overall population) compared with dengue and Zika (2.0% and 1.7% of the overall population, respectively). This observation might reflect the possible higher morbidity including cutaneous alterations and arthralgia or arthritis associated with chikungunya infection in infancy (40,41) compared with the low relative morbidity associated with primary dengue or Zika infections (42). Twenty-seven percent of participants with dengue progressed to severe dengue. However, only 10.1% of children aged 1–4 years had severe dengue, which could reflect lower likelihood of experiencing antibody-dependent enhancement because of infection from other serotypes during previous outbreaks (43,44).

Fewer pregnant women were reported through SEDSS with evidence of dengue infection (4.6%) compared with Zika (14.2%) or chikungunya (14.0%). The higher proportion of pregnant women reported through SEDSS with evidence of confirmed or probable ZIKV infection could be because of increased health care-seeking behavior by pregnant women during the Zika epidemic (45).

The highest proportion of participants testing positive for any arbovirus was observed among residents in southeast Puerto Rico, particularly in Guayama. Urbanization and population density are associated with Aedes aegypti abundance, driven by favorable breeding conditions, higher larval development rates, and adult survival times, especially in rapidly urbanizing areas with unplanned settlements (46,47). Previous research has confirmed high mosquito populations in southern Puerto Rico (48,49). Abandoned and inhabited houses in lower socioeconomic neighborhoods in southern Puerto Rico contribute to Ae. aegypti pupal productivity, emphasizing the need for targeted vector control strategies in these neighborhoods (49).

These findings highlight challenges and gaps in arboviral disease management with a focus on dengue. First, many participants with confirmed dengue, Zika, and chikungunya were initially misdiagnosed with other diseases (e.g., respiratory illnesses) by ED physicians. Obtaining an accurate diagnosis based on clinical presentation alone is challenging, as demonstrated by systemic reviews of the accuracy of clinical definitions of dengue (50,51). Certain symptoms (e.g., headache) increased with age for dengue and Zika cases, and these findings were consistent with another SEDSS study that focused on children; however young children might be less likely to vocalize these symptoms (12). Another study using SEDSS data also reported overlapping symptoms between dengue and chikungunya, but patients receiving a diagnosis of chikungunya were more likely to report arthritis, skin rash, and irritability, and less likely to have signs of poor circulation, diarrhea, headache, and cough (52). Age-related symptom variations and frequent coinfections with respiratory viruses (e.g., IAV, IBV, and HAdV) highlight the complexity of arboviral infections and the necessity for precise diagnostic approaches that consider multiple pathogens for timely and accurate diagnoses (8,12).

Second, 37% of all participants with a dengue diagnosis who had warning signs and 84% of those with severe dengue diagnosed were hospitalized. The most recent guidelines recommend hospitalization for suspected patients with dengue and having warning signs or severe dengue (53). Among participants with warning signs or severe dengue who were not hospitalized, 17.6% received a correct initial dengue diagnosis. Taken together, these findings highlight the need for ongoing training for physicians on dengue clinical management guidelines and the need for more rapid detection of dengue. Moreover, these findings also underscore the potential strain on the health care system when a substantial proportion of patients necessitate hospitalization. SEDSS plays a pivotal role in enabling precise disease diagnosis and addressing the challenge of misclassification (29,54); however, results are still not prompt enough to guide clinical decision making at the bedside. Implementation of rapid diagnostic testing for dengue, currently unavailable in the United States or its territories, could expedite the identification of patients requiring hospitalization and address gaps in clinical care.

SEDSS continues to be used to monitor endemic arboviruses in Puerto Rico and acts as a sentinel for emerging pathogens which initially might be missed by clinical diagnosis. Approximately 545 recognized arboviruses exist worldwide, although estimates suggest this figure might represent less than 1% of all arboviruses because most are zoonotic infections among hosts other than humans (5557). Among the recognized arboviruses, approximately 150 have been documented to cause human disease (55). This observation highlights the importance of robust surveillance systems like SEDSS, which are essential for timely identification and monitoring of emerging infectious threats that might otherwise go undetected.

Distinct seasonality in the circulation of respiratory viruses was observed, consistent with findings documented in the literature on virus-virus interactions and their effect on disease dynamics (5860). A related study using SEDSS found distinct seasonal patterns in Puerto Rico, with respiratory viruses peaking in fall and winter, while arboviruses (e.g., dengue) peaked in summer and early fall, emphasizing the importance of recognizing these seasonal trends for accurate diagnosis and public health interventions in pediatric patients with AFI (10). Viral interference, a phenomenon highlighted in previous research, plays a role in shaping the observed patterns (61,62). At the population level, viral interference might be induced when an outbreak caused by one virus hastens or delays an epidemic caused by another virus (58,60). These results indicate that the seasonality of IAV typically precedes that of IBV each year, consistent with documented interactions between influenza types and subtypes that might involve cross-immunity mechanisms (63,64). Another study using SEDSS data analyzed influenza trends in Puerto Rico during 2012–2018, illustrated that influenza seasonality in the region differed from that in the continental United States, with irregular and asynchronous epidemics initially but increased synchrony in recent years (54). The study suggests that factors beyond climate, such as travel and viral introductions, might contribute to the observed changes in influenza dynamics in Puerto Rico.

In addition, the strong seasonality observed for RSV reflects patterns observed in various regions, with increasing RSV epidemics over the years, particularly among children (65). The findings from this report revealed a high proportion of acute respiratory viral cases among children aged <5 years, including RSV, HPIV-3, HPIV-1, HAdV, and HMPV. Children, particularly those aged <5 years, have increased susceptibility to viral infections compared with adults, possibly because of higher contact frequencies with peers in school and child care settings, naïve immune systems, limited previous exposure, and a greater likelihood of medical care-seeking by parents (60,66).

From March 2020 to April 2021, nearly all respiratory viral infections identified were SARS-CoV-2, demonstrating its high transmissibility compared with other respiratory pathogens (67,68). The COVID-19 pandemic considerably altered RSV seasonality, with atypical transmission patterns observed in mid-2021 and during September–November 2022 (69). These trends in Puerto Rico align with those in the continental United States (69). Findings from this report align with recent research on the impact of the emergence of SARS-CoV-2, which led to a substantial reduction in the circulation of other acute respiratory viruses (70). Previous analyses conducted using data from SEDSS during the 2019–2020 respiratory virus season revealed a considerable reduction in the test positivity of IAV, IBV, RSV, HAdV, and other respiratory viruses following the implementation of COVID-19 stay-at-home orders (71). The reductions in test positivity persisted even after the initial impact of COVID-19 mitigation measures, indicating a sustained effect on the transmission of respiratory infections. This reduction is attributed to a combination of changes in human interactions, nonpharmaceutical interventions, reduced testing of seasonal respiratory viruses, and potential viral interferences (70).

The results presented in this study should be interpreted in the context of external factors that could influence disease dynamics. Puerto Rico has been increasingly vulnerable to climate change, characterized by more frequent and severe hurricanes. Extreme weather events, such as hurricanes, can disrupt health care infrastructure and disease surveillance efforts. The erosion of infrastructure during severe storms might have heightened the occurrence of certain diseases and led to population movements, potentially affecting population immunity. Severe storms might increase the number of mosquitoes by filling containers with rainwater, increasing the edge surface of groundwater habitats, and generating additional container aquatic habitats in destroyed or abandoned properties. This increase in aquatic habitats was observed after Hurricanes Irma and Maria in Caguas, where adult female Ae. aegypti doubled in numbers after the hurricanes, possibly because of an increase in the number of containers holding water, even in years with similar rainfall (72). The impact of these climatic disruptions, natural disasters, and population dynamics on disease patterns in Puerto Rico needs further investigation. In addition, climate change can alter the distribution and behavior of disease vectors, potentially affecting the geographic range of arboviral diseases (73).

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Limitations

The findings in this report are subject to at least six limitations. First, SEDSS was established at certain sentinel sites based on historically high dengue incidence. Therefore, these results might not be reflective of all of Puerto Rico. The results included in this report were derived principally from sentinel sites in southern Puerto Rico as well as the San Juan metro area; the geographic distribution of participant residences are skewed toward these regions. Second, the symptoms in the SEDSS clinic intake and follow-up forms were based on participant self-report and, in certain instances, were not sufficient to differentiate between dengue warning signs and signs of severe dengue. For example, SEDSS intake forms could capture self-reported mucosal bleeding (e.g., nose and gum bleeding, gastrointestinal bleeding, and excessive vaginal bleeding), but these self-reports could not clinically distinguish severe bleeding from the gastrointestinal tract (e.g., hematemesis and melena) or vagina (e.g., menorrhagia) as defined by the requirement for medical intervention, including intravenous fluid resuscitation or blood transfusion (74). Inpatient data, where available, were merged with the SEDSS data and enabled further dengue severity differentiation. Third, differentiating between dengue and Zika presented challenges after Zika emerged because probable dengue diagnosis relied on IgM tests for DENV with negative results for ZIKV and vice versa for probable Zika diagnosis because of cross-reactivity between dengue and Zika IgM antibodies in serologic tests. Fourth, SEDSS is a convenience sample, and recruited cases represent a fraction of total eligible patients (Supplementary Table 1, https://stacks.cdc.gov/view/cdc/153721). Fifth, the subjective nature of some self-reported symptoms (e.g., restlessness and abdominal pain) might have contributed to over-reporting of dengue warning signs, while health care provider-only warning signs (e.g., abdominal tenderness, liver enlargement, or substantial changes in hematocrit or platelet counts over two measurements) could have been missed. Subsequent iterations of intake and follow-up forms will address this issue in current and future years. Finally, SEDSS, while offering real-time and detailed information, presents challenges because of its labor-intensive nature and higher costs compared with passive surveillance methods, posing resource and infrastructure demands that might be challenging for implementation in various countries.

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Future Direction

In addition to contributing to research and public health efforts, SEDSS also provides a valuable system for piloting health care provider diagnostic support tools. The data in this report guide evidence-based strategies for preventing and controlling arboviral diseases and emerging pathogens with global relevance beyond Puerto Rico. Puerto Rico’s experience with febrile illness surveillance provides a model for similar applications in other areas where Ae. aegypti is prevalent. This is particularly relevant considering the potential of changes in climate and weather, which could lead to rising global temperatures and expand the geographic range of disease vectors (75). Leveraging the lessons from SEDSS, an opportunity to enhance health care system resilience by improving diagnostic capabilities, increasing surge capacity, and ensuring the stockpiling of essential medical supplies exists. SEDSS has the potential to integrate into global surveillance networks, strengthening international collaboration for early detection and response to emerging infectious diseases. Expansion of SEDSS to additional sentinel sites can supplement and enhance information provided through existing passive reporting mechanisms and improve the geographic representation of this active surveillance system.

SEDSS is uniquely positioned to provide a source population for future real-world effectiveness studies of novel vaccines for arboviral diseases. These vaccines might include vaccines like the live-attenuated, single-dose VLA1553 for chikungunya (76) and dengue antivirals (e.g., JNJ-1802) (77). Data analytics, modeling, and machine learning could be applied to SEDSS data to help identify disease trends, predict outbreaks, and optimize resource allocation for public health responses. SEDSS data might provide a quantitative measure of effectiveness for vector control strategies (e.g., novel insecticides and genetically modified mosquitoes) derived from observed case counts before and after intervention implementation. Prioritizing capacity building and training for local health care providers, researchers, and public health personnel is essential to enhance expertise in disease surveillance and management, ultimately improving responses to future outbreaks both in Puerto Rico and elsewhere.

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Conclusion

SEDSS enables in-depth patient tracking and follow-up to identify common and emerging arboviral and respiratory viruses causing AFI. SEDSS also facilitates understanding the temporal patterns of these viruses, potential interactions between them, and the populations most at risk for illness. In addition, SEDSS proved adaptable in detecting and collecting detailed information on participants affected by emerging arboviruses in Puerto Rico (e.g., CHIKV and ZIKV) and numerous respiratory viruses, including SARS-CoV-2. SEDSS serves as a versatile model for effective disease surveillance, offering valuable insights applicable beyond the context of Puerto Rico in the dynamic field of infectious disease monitoring.

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Acknowledgments

Nicole P. Lindsey, J. Erin Staples, National Center for Emerging and Zoonotic Infectious Diseases, CDC.

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Corresponding author: Zachary J. Madewell, PhD, Division of Vector-Borne Diseases, CDC, Telephone: 787-706-2399; Email: ock0@cdc.gov.

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1Division of Vector-Borne Diseases, CDC, San Juan, Puerto Rico; 2Ponce Health Sciences University, Ponce Research Institute, Ponce, Puerto Rico; 3Auxilio Mutuo Hospital, San Juan, Puerto Rico

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Conflicts of Interest

All authors have completed and submitted the International Committee of Medical Journal Editors form for disclosure of potential conflicts of interest. No potential conflicts of interest were disclosed.

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References

  1. Bhatt S, Gething PW, Brady OJ, et al. The global distribution and burden of dengue. Nature 2013;496:504–7. https://doi.org/10.1038/nature12060 PMID:23563266
  2. GBD 2017 Causes of Death Collaborators. Global, regional, and national age-sex-specific mortality for 282 causes of death in 195 countries and territories, 1980-2017: a systematic analysis for the Global Burden of Disease Study 2017. Lancet 2018;392:1736–88. PMID:30496103
  3. GBD 2017 DALYs and HALE Collaborators. Global, regional, and national disability-adjusted life-years (DALYs) for 359 diseases and injuries and healthy life expectancy (HALE) for 195 countries and territories, 1990–2017: a systematic analysis for the Global Burden of Disease Study 2017. Lancet 2018;392:1859–922. https://doi.org/10.1016/S0140-6736(18)32335-3 PMID:30415774
  4. Madewell ZJ. Arboviruses and their vectors. South Med J 2020;113:520–3. https://doi.org/10.14423/SMJ.0000000000001152 PMID:33005970
  5. Paz-Bailey G, Adams L, Wong JM, et al. Dengue vaccine: recommendations of the Advisory Committee on Immunization Practices, United States, 2021. MMWR Recomm Rep 2021;70:1–16. https://doi.org/10.15585/mmwr.rr7006a1 PMID:34978547
  6. Ryff KR, Rivera A, Rodriguez DM, et al. Epidemiologic trends of dengue in U.S. territories, 2010–2020. MMWR Surveill Summ 2023;72:1–12. https://doi.org/10.15585/mmwr.ss7204a1 PMID:37192141
  7. Departamento de Salud. Análisis de amenazas, vulnerabilidad y riesgo 2018–2022. San Juan, Puerto Rico: Departamento de Salud; 2023. https://www.salud.pr.gov/CMS/DOWNLOAD/7884
  8. Hsu CH, Cruz-Lopez F, Vargas Torres D, et al. Risk factors for hospitalization of patients with chikungunya virus infection at sentinel hospitals in Puerto Rico. PLoS Negl Trop Dis 2019;13:e0007084. https://doi.org/10.1371/journal.pntd.0007084 PMID:30640900
  9. Wong JM, Volkman HR, Adams LE, et al. Clinical features of COVID-19, dengue, and influenza among adults presenting to emergency departments and urgent care clinics—Puerto Rico, 2012–2021. Am J Trop Med Hyg 2023;108:107–14. https://doi.org/10.4269/ajtmh.22-0149 PMID:36410319
  10. Sánchez-González L, Quandelacy TM, Johansson M, et al. Viral etiology and seasonal trends of pediatric acute febrile illness in southern Puerto Rico; a seven-year review. PLoS One 2021;16:e0247481. https://doi.org/10.1371/journal.pone.0247481 PMID:33606839
  11. Salud.gov.pr [Internet]. Monacillos Río Piedras, Puerto Rico; 2023. https://www.salud.gov.pr
  12. Harris PA, Taylor R, Minor BL, et al.; REDCap Consortium. The REDCap consortium: building an international community of software platform partners. J Biomed Inform 2019;95:103208. https://doi.org/10.1016/j.jbi.2019.103208 PMID:31078660
  13. Harris PA, Taylor R, Thielke R, Payne J, Gonzalez N, Conde JG. Research electronic data capture (REDCap)—a metadata-driven methodology and workflow process for providing translational research informatics support. J Biomed Inform 2009;42:377–81. https://doi.org/10.1016/j.jbi.2008.08.010 PMID:18929686
  14. Paz-Bailey G, Sánchez-González L, Torres-Velasquez B, et al. Predominance of severe plasma leakage in pediatric patients with severe dengue in Puerto Rico. J Infect Dis 2022;226:1949–58. https://doi.org/10.1093/infdis/jiac165 PMID:35510941
  15. Santiago GA, Vergne E, Quiles Y, et al. Analytical and clinical performance of the CDC real time RT-PCR assay for detection and typing of dengue virus. PLoS Negl Trop Dis 2013;7:e2311. https://doi.org/10.1371/journal.pntd.0002311 PMID:23875046
  16. Santiago GA, Vázquez J, Courtney S, et al. Performance of the Trioplex real-time RT-PCR assay for detection of Zika, dengue, and chikungunya viruses. Nat Commun 2018;9:1391. https://doi.org/10.1038/s41467-018-03772-1 PMID:29643334
  17. Tomashek KM, Lorenzi OD, Andújar-Pérez DA, et al. Clinical and epidemiologic characteristics of dengue and other etiologic agents among patients with acute febrile illness, Puerto Rico, 2012–2015. PLoS Negl Trop Dis 2017;11:e0005859. https://doi.org/10.1371/journal.pntd.0005859 PMID:28902845
  18. Broor S, Dawood FS, Pandey BG, et al. Rates of respiratory virus-associated hospitalization in children aged <5 years in rural northern India. J Infect 2014;68:281–9. https://doi.org/10.1016/j.jinf.2013.11.005 PMID:24269675
  19. Lu X, Wang L, Sakthivel SK, et al. US CDC real-time reverse transcription PCR panel for detection of severe acute respiratory syndrome coronavirus 2. Emerg Infect Dis 2020;26:1654–65. https://doi.org/10.3201/eid2608.201246 PMID:32396505
  20. CDC. CDC’s Influenza SARS-CoV-2 Multiplex Assay [Internet]. Atlanta, GA: US Department of Health and Human Services, CDC; 2022. https://www.cdc.gov/coronavirus/2019-ncov/lab/multiplex.html
  21. Sharp TM, Fischer M, Muñoz-Jordán JL, et al. Dengue and Zika virus diagnostic testing for patients with a clinically compatible illness and risk for infection with both viruses. MMWR Recomm Rep 2019;68(No. RR-1):1–10. https://doi.org/10.15585/mmwr.rr6801a1 PMID:31194720
  22. CDC. Arboviral diseases, neuroinvasive and non-neuroinvasive 2015 case definition [Internet]. Atlanta, GA: US Department of Health and Human Services, CDC; 2021. https://ndc.services.cdc.gov/case-definitions/arboviral-diseases-neuroinvasive-and-non-neuroinvasive-2015
  23. World Health Organization. Handbook for clinical management of dengue. Geneva, Switzerland: World Health Organization; 2012. https://www.who.int/publications/i/item/9789241504713
  24. Read JS, Torres-Velasquez B, Lorenzi O, et al. Symptomatic Zika virus infection in infants, children, and adolescents living in Puerto Rico. JAMA Pediatr 2018;172:686–93. https://doi.org/10.1001/jamapediatrics.2018.0870 PMID:29813148
  25. Sharp TM, Roth NM, Torres J, et al.; CDC. Chikungunya cases identified through passive surveillance and household investigations—Puerto Rico, May 5–August 12, 2014. MMWR Morb Mortal Wkly Rep 2014;63:1121–8. PMID:25474032
  26. Paz-Bailey G, Rosenberg ES, Doyle K, et al. Persistence of Zika virus in body fluids—final report. N Engl J Med 2018;379:1234–43. https://doi.org/10.1056/NEJMoa1613108 PMID:28195756
  27. Madewell ZJ, Major CG, Graff N, et al. Diagnostic accuracy of the Abbot BinaxNOW COVID-19 antigen card test, Puerto Rico. medRxiv [Preprint posted online December 15, 2023]. https://www.medrxiv.org/content/10.1101/2023.12.14.23299967v1
  28. Medina FA, Vila F, Premkumar L, et al. Capacity of a multiplex IgM antibody capture ELISA to differentiate Zika and dengue virus infections in areas of concurrent endemic transmission. Am J Trop Med Hyg 2022;106:585–92. https://doi.org/10.4269/ajtmh.20-1651 PMID:34929668
  29. Sharp TM, Quandelacy TM, Adams LE, et al. Epidemiologic and spatiotemporal trends of Zika virus disease during the 2016 epidemic in Puerto Rico. PLoS Negl Trop Dis 2020;14:e0008532. https://doi.org/10.1371/journal.pntd.0008532 PMID:32956416
  30. Sharp TM, Ryff KR, Alvarado L, et al. Surveillance for chikungunya and dengue during the first year of chikungunya virus circulation in Puerto Rico. J Infect Dis 2016;214(suppl 5):S475–81. https://doi.org/10.1093/infdis/jiw245 PMID:27920177
  31. Volkman HR, Pérez-Padilla J, Wong JM, et al. Characteristics and clinical outcomes of patients hospitalized with laboratory-confirmed COVID-19—Puerto Rico, March-August 2020. PLoS One 2021;16:e0260599. https://doi.org/10.1371/journal.pone.0260599 PMID:34855817
  32. Gorbea H, Garcia-Rivera EJ, Torres H, et al. Leptospirosis cases infected with uncommon serogroups, Puerto Rico, 2013–2015. Am J Trop Med Hyg 2018;98:258–61. https://doi.org/10.4269/ajtmh.17-0538 PMID:29141761
  33. Rolph MS, Foo SS, Mahalingam S. Emergent chikungunya virus and arthritis in the Americas. Lancet Infect Dis 2015;15:1007–8. https://doi.org/10.1016/S1473-3099(15)00231-5 PMID:26333330
  34. Haby MM, Pinart M, Elias V, Reveiz L. Prevalence of asymptomatic Zika virus infection: a systematic review. Bull World Health Organ 2018;96:402–413D. https://doi.org/10.2471/BLT.17.201541 PMID:29904223
  35. Weaver SC, Lecuit M. Chikungunya virus and the global spread of a mosquito-borne disease. N Engl J Med 2015;372:1231–9. https://doi.org/10.1056/NEJMra1406035 PMID:25806915
  36. Stone M, Bakkour S, Lanteri MC, et al.; NHLBI Recipient Epidemiology Donor Evaluation Study REDS-III Program. Zika virus RNA and IgM persistence in blood compartments and body fluids: a prospective observational study. Lancet Infect Dis 2020;20:1446–56. https://doi.org/10.1016/S1473-3099(19)30708-X PMID:32673593
  37. Borchering RK, Huang AT, Mier-Y-Teran-Romero L, et al. Impacts of Zika emergence in Latin America on endemic dengue transmission. Nat Commun 2019;10:5730. https://doi.org/10.1038/s41467-019-13628-x PMID:31844054
  38. Salje H, Cummings DAT, Rodriguez-Barraquer I, et al. Reconstruction of antibody dynamics and infection histories to evaluate dengue risk. Nature 2018;557:719–23. https://doi.org/10.1038/s41586-018-0157-4 PMID:29795354
  39. Katzelnick LC, Zambrana JV, Elizondo D, et al. Dengue and Zika virus infections in children elicit cross-reactive protective and enhancing antibodies that persist long term. Sci Transl Med 2021;13:eabg9478. https://doi.org/10.1126/scitranslmed.abg9478 PMID:34613812
  40. Barr KL, Vaidhyanathan V. Chikungunya in infants and children: is pathogenesis increasing? Viruses 2019;294. https://doi.org/10.3390/v11030294 PMID:30909568
  41. Torales M, Beeson A, Grau L, et al. Chikungunya outbreak—Paraguay, 2022–2023. MMWR Morb Mortal Wkly Rep 2023;72:636–8. https://doi.org/10.15585/mmwr.mm7223a5 PMID:37289652
  42. Santos LLM, de Aquino EC, Fernandes SM, Ternes YMF, Feres VCR. Dengue, chikungunya, and Zika virus infections in Latin America and the Caribbean: a systematic review. Rev Panam Salud Publica 2023;47: 1–9. https://doi.org/10.26633/RPSP.2023.34 PMID:36788963
  43. Katzelnick LC, Gresh L, Halloran ME, et al. Antibody-dependent enhancement of severe dengue disease in humans. Science 2017;358:929–32. https://doi.org/10.1126/science.aan6836 PMID:29097492
  44. Whitehorn J, Simmons CP. The pathogenesis of dengue. Vaccine 2011;29:7221–8. https://doi.org/10.1016/j.vaccine.2011.07.022 PMID:21781999
  45. Lozier M, Adams L, Febo MF, et al. Incidence of Zika virus disease by age and sex—Puerto Rico, November 1, 2015–October 20, 2016. MMWR Morb Mortal Wkly Rep 2016;65:1219–23. https://doi.org/10.15585/mmwr.mm6544a4 PMID:27832051
  46. Kolimenakis A, Heinz S, Wilson ML, et al. The role of urbanisation in the spread of Aedes mosquitoes and the diseases they transmit—a systematic review. PLoS Negl Trop Dis 2021;15:e0009631. https://doi.org/10.1371/journal.pntd.0009631 PMID:34499653
  47. Madewell ZJ, Sosa S, Brouwer KC, et al. Associations between household environmental factors and immature mosquito abundance in Quetzaltenango, Guatemala. BMC Public Health 2019;19:1729. https://doi.org/10.1186/s12889-019-8102-5 PMID:31870343
  48. Pérez-Guerra CL, Rosado-Santiago C, Ramos SA, et al. Community perceptions on challenges and solutions to implement an Aedes aegypti control project in Ponce, Puerto Rico (USA). PLoS One 2023;18:e0284430. https://doi.org/10.1371/journal.pone.0284430 PMID:37068074
  49. Barrera R, Acevedo V, Amador M. Role of abandoned and vacant houses on Aedes aegypti productivity. Am J Trop Med Hyg 2021;104:145–50. https://doi.org/10.4269/ajtmh.20-0829 PMID:33021195
  50. Raafat N, Loganathan S, Mukaka M, Blacksell SD, Maude RJ. Diagnostic accuracy of the WHO clinical definitions for dengue and implications for surveillance: a systematic review and meta-analysis. PLoS Negl Trop Dis 2021;15:e0009359. https://doi.org/10.1371/journal.pntd.0009359 PMID:33901191
  51. Odio CD, Sánchez-González L, Delorey M, et al. The effect of age on dengue presentation and the diagnostic accuracy of the 2015 Pan American Health Organization case criteria in a Puerto Rican cohort. Open Forum Infect Dis 2023;10:ofad373. https://doi.org/10.1093/ofid/ofad373 PMID:37663092
  52. Alvarado LI, Lorenzi OD, Torres-Velásquez BC, et al. Distinguishing patients with laboratory-confirmed chikungunya from dengue and other acute febrile illnesses, Puerto Rico, 2012– 2015. PLoS Negl Trop Dis 2019;13:e0007562. https://doi.org/10.1371/journal.pntd.0007562 PMID:31329598
  53. Pan American Health Organization. Guidelines for the clinical diagnosis and treatment of dengue, chikungunya, and Zika. Washington, DC: Pan American Health Organization; 2021. https://www.paho.org/en/documents/guidelines-clinical-diagnosis-and-treatment-dengue-chikungunya-and-zika
  54. Paz-Bailey G, Quandelacy TM, Adams LE, et al. Recent influenza activity in tropical Puerto Rico has become synchronized with mainland US. Influenza Other Respir Viruses 2020;14:515–23. https://doi.org/10.1111/irv.12744 PMID:32614504
  55. Cleton N, Koopmans M, Reimerink J, Godeke GJ, Reusken C. Come fly with me: review of clinically important arboviruses for global travelers. J Clin Virol 2012;55:191–203. https://doi.org/10.1016/j.jcv.2012.07.004 PMID:22840968
  56. Pfeffer M, Dobler G. Emergence of zoonotic arboviruses by animal trade and migration. Parasit Vectors 2010;3:35. https://doi.org/10.1186/1756-3305-3-35 PMID:20377873
  57. Young PR. Arboviruses: a family on the move. Adv Exp Med Biol 2018;1062:1–10. https://doi.org/10.1007/978-981-10-8727-1_1 PMID:29845521
  58. Piret J, Boivin G. Viral interference between respiratory viruses. Emerg Infect Dis 2022;28:273–81. https://doi.org/10.3201/eid2802.211727 PMID:35075991
  59. Nickbakhsh S, Mair C, Matthews L, et al. Virus-virus interactions impact the population dynamics of influenza and the common cold. Proc Natl Acad Sci U S A 2019;116:27142–50. https://doi.org/10.1073/pnas.1911083116 PMID:31843887
  60. Madewell ZJ, Wang L-P, Dean NE, et al.; CDC Etiology of Respiratory Infection Surveillance Study Team. Interactions among acute respiratory viruses in Beijing, Chongqing, Guangzhou, and Shanghai, China, 2009–2019. Influenza Other Respir Viruses 2023;17:e13212. https://doi.org/10.1111/irv.13212 PMID:37964991
  61. Pinky L, Dobrovolny HM. Coinfections of the respiratory tract: viral competition for resources. PLoS One 2016;11:e0155589. https://doi.org/10.1371/journal.pone.0155589 PMID:27196110
  62. Kumar N, Sharma S, Barua S, Tripathi BN, Rouse BT. Virological and immunological outcomes of coinfections. Clin Microbiol Rev 2018;31:e00111–17. https://doi.org/10.1128/CMR.00111-17 PMID:29976554
  63. Opatowski L, Baguelin M, Eggo RM. Influenza interaction with cocirculating pathogens and its impact on surveillance, pathogenesis, and epidemic profile: a key role for mathematical modelling. PLoS Pathog 2018;14:e1006770. https://doi.org/10.1371/journal.ppat.1006770 PMID:29447284
  64. Krammer F. The human antibody response to influenza A virus infection and vaccination. Nat Rev Immunol 2019;19:383–97. https://doi.org/10.1038/s41577-019-0143-6 PMID:30837674
  65. Janet S, Broad J, Snape MD. Respiratory syncytial virus seasonality and its implications on prevention strategies. Hum Vaccin Immunother 2018;14:234–44. https://doi.org/10.1080/21645515.2017.1403707 PMID:29194014
  66. Mandelia Y, Procop GW, Richter SS, Worley S, Liu W, Esper F. Dynamics and predisposition of respiratory viral co-infections in children and adults. Clin Microbiol Infect 2021;27:631.e1–6. https://doi.org/10.1016/j.cmi.2020.05.042 PMID:32540470
  67. Liu Y, Rocklöv J. The effective reproductive number of the Omicron variant of SARS-CoV-2 is several times relative to Delta. J Travel Med 2022;29:taac037 . https://doi.org/10.1093/jtm/taac037 PMID:35262737
  68. Madewell ZJ, Yang Y, Longini IM Jr, Halloran ME, Dean NE. Household secondary attack rates of SARS-CoV-2 by variant and vaccination status: an updated systematic review and meta-analysis. JAMA Netw Open 2022;5:e229317 . https://doi.org/10.1001/jamanetworkopen.2022.9317 PMID:35482308
  69. Hamid S, Winn A, Parikh R, et al. Seasonality of respiratory syncytial virus—United States, 2017–2023. MMWR Morb Mortal Wkly Rep 2023;72:355–61. https://doi.org/10.15585/mmwr.mm7214a1 PMID:37022977
  70. Groves HE, Piché-Renaud PP, Peci A, et al. The impact of the COVID-19 pandemic on influenza, respiratory syncytial virus, and other seasonal respiratory virus circulation in Canada: a population-based study. Lancet Reg Health Am 2021;1:100015. https://doi.org/10.1016/j.lana.2021.100015 PMID:34386788
  71. Quandelacy TM, Adams LE, Munoz J, et al. Reduced spread of influenza and other respiratory viral infections during the COVID-19 pandemic in southern Puerto Rico. PLoS One 2022;17:e0266095. https://doi.org/10.1371/journal.pone.0266095 PMID:35476785
  72. Barrera R, Felix G, Acevedo V, et al. Impacts of hurricanes Irma and Maria on Aedes aegypti populations, aquatic habitats, and mosquito infections with dengue, chikungunya, and Zika viruses in Puerto Rico. Am J Trop Med Hyg 2019;100:1413–20. https://doi.org/10.4269/ajtmh.19-0015 PMID:30963992
  73. Robert MA, Stewart-Ibarra AM, Estallo EL. Climate change and viral emergence: evidence from Aedes-borne arboviruses. Curr Opin Virol 2020;40:41–7. https://doi.org/10.1016/j.coviro.2020.05.001 PMID:32569752
  74. Council of State and Territorial Epidemiologists. Revision of case definitions for national notification of dengue. Atlanta, GA; Council of State and Territorial Epidemiologists; 2014. https://cdn.ymaws.com/www.cste.org/resource/resmgr/2014PS/14_ID_10.pdf
  75. Iwamura T, Guzman-Holst A, Murray KA. Accelerating invasion potential of disease vector Aedes aegypti under climate change. Nat Commun 2020;11:2130 . https://doi.org/10.1038/s41467-020-16010-4 PMID:32358588
  76. Schneider M, Narciso-Abraham M, Hadl S, et al. Safety and immunogenicity of a single-shot live-attenuated chikungunya vaccine: a double-blind, multicentre, randomised, placebo-controlled, phase 3 trial. Lancet 2023;401:2138–47. https://doi.org/10.1016/S0140-6736(23)00641-4 PMID:37321235
  77. Goethals O, Kaptein SJF, Kesteleyn B, et al. Blocking NS3–NS4B interaction inhibits dengue virus in non-human primates. Nature 2023;615:678–86. https://doi.org/10.1038/s41586-023-05790-6 PMID:36922586

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TABLE 1. Laboratory criteria for diagnosis of confirmed and probable dengue, chikungunya, and Zika virus infections, Puerto Rico, 2012–2022*Return to your place in the text
Classification Confirmed or probable Period Nucleic acid amplification tests (reverse transcription polymerase chain reaction) Immunoglobulin M enzyme-linked immunosorbent assay
DENV infection Confirmed 2012–2022 DENV assay positive DENV assay positive, negative, or not performed
Probable 2012–2015 DENV assay negative or not performed DENV assay positive
Probable 2016–2022 DENV assay negative or not performed DENV assay positive and ZIKV assay negative or not performed
CHIKV infection Confirmed 2014–2022 CHIKV assay positive CHIKV assay positive, negative, or not performed
Probable 2014–2022 CHIKV assay negative or not performed CHIKV assay positive
ZIKV infection Confirmed 2016–2022 ZIKV assay positive ZIKV assay positive, negative, or not performed
Probable 2016–2022 ZIKV assay negative or not performed ZIKV assay positive and DENV assay negative
Recent flavivirus infection Probable 2016–2022 DENV assay negative or not performed and ZIKV assay negative or not performed DENV assay positive and ZIKV assay positive, or DENV assay positive and ZIKV assay not performed, or DENV assay not performed and ZIKV assay positive
Arboviral co-infection Confirmed 2012–2022 Viral assays positive for any two of the arboviruses tested
Viral assays positive for all three of the arboviruses tested		 Any combination of viral assays positive, negative, or not performed for the arboviruses tested

Abbreviations: DENV = dengue virus; CHIKV = chikungunya virus; ZIKV = Zika virus.
* Sources: Sharp TM, Fischer M, Muñoz-Jordán JL, et al. Dengue and Zika virus diagnostic testing for patients with a clinically compatible illness and risk for infection with both viruses. MMWR Recomm Rep. 2019 Jun 14;68:1-10. CDC. Arboviral diseases, neuroinvasive and non-neuroinvasive 2015 case definition [Internet]. Atlanta, GA: US Department of Health and Human Services, CDC; 2021. https://ndc.services.cdc.gov/case-definitions/arboviral-diseases-neuroinvasive-and-non-neuroinvasive-2015

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TABLE 2. Number and percentage of visits associated with acute febrile illness or suspected arboviral or acute respiratory viral illness, by selected characteristics — Sentinel Enhanced Dengue Surveillance System, Puerto Rico, 2012–2022Return to your place in the text
Characteristic Male Female Total
No. (%) No. (%) No. (%)
Days post onset
0–3 16,276 (78.5) 17,421 (76.2) 33,699 (77.3)
4–7 2,706 (13.0) 3,382 (14.8) 6,092 (14.0)
>7 267 (1.3) 362 (1.6) 629 (1.4)
Unknown 1,491 (7.2) 1,696 (7.4) 3,188 (7.3)
Age, yrs
<1 1,851 (8.9) 1,473 (6.4) 3,324 (7.6)
1–4 5,387 (26.0) 4,462 (19.5) 9,849 (22.6)
5–9 2,981 (14.4) 2,697 (11.8) 5,679 (13.0)
10–19 3,175 (15.3) 3,235 (14.2) 6,411 (14.7)
20–29 1,880 (9.1) 3,057 (13.4) 4,938 (11.3)
30–39 1,308 (6.3) 2,074 (9.1) 3,383 (7.8)
40–49 1,131 (5.5) 1,655 (7.2) 2,786 (6.4)
≥50 3,027 (14.6) 4,208 (18.4) 7,238 (16.6)
Clinical disposition
Ambulatory 16,518 (79.6) 18,944 (82.9) 35,467 (81.3)
Admitted or transferred 4,014 (19.4) 3,675 (16.1) 7,690 (17.6)
Left against medical advice 74 (0.4) 96 (0.4) 170 (0.4)
Deceased 48 (0.2) 24 (0.1) 72 (0.2)
Unknown 86 (0.4) 122 (0.5) 209 (0.5)
Co-existing medical condition
Diabetes 1547 (7.5) 1,991 (8.7) 3,538 (8.1)
Chronic pulmonary disease 3,919 (18.9) 4,561 (20.0) 8,482 (19.5)
Hypertension 2,478 (11.9) 3,294 (14.4) 5,773 (13.2)
Chronic kidney disease 286 (1.4) 262 (1.1) 548 (1.3)
Immunodeficiency 115 (0.6) 155 (0.7) 270 (0.6)
Sickle cell disease 53 (0.3) 139 (0.6) 192 (0.4)
Obesity 3,072 (20.2) 4,547 (26.0) 7,619 (23.3)
Total 20,740 (100.0) 22,861 (100.0) 43,608* (100.0)

* Sex was not recorded for seven visits.
Among persons with available body mass index, n = 15,191 males, n = 17,501 females, and N = 32,698 total persons.

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Return to your place in the textFIGURE 1. Confirmed or probable dengue, chikungunya, and Zika virus cases, by year — Sentinel Enhanced Dengue Surveillance System, Puerto Rico, May 2012–December 2022*
The figure is a histogram that illustrates the confirmed or probable dengue, chikungunya, and Zika virus cases, by year, during May 2012–December 2022 in Puerto Rico. The data are from the Sentinel Enhanced Dengue Surveillance System.

* Cases were deemed to be laboratory-confirmed if a serum or urine specimen was polymerase chain reaction– or immunoglobulin M–positive for a particular arbovirus.

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Return to your place in the textFIGURE 2. Acute respiratory virus cases, by year — Sentinel Enhanced Dengue Surveillance System, Puerto Rico, May 2012–December 2022*
The figure is a histogram that illustrates the number of various acute respiratory viral cases, by year, during May 2012–December 2022 in Puerto Rico. The data are from the Sentinel Enhanced Dengue Surveillance System.

* Respiratory viruses were identified and confirmed by reverse transcription–polymerase chain reaction testing of nasopharyngeal swabs.

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Return to your place in the textFIGURE 3. Number and proportion of acute febrile illness cases with participants testing positive for any arbovirus, by municipality — Sentinel Enhanced Dengue Surveillance System, Puerto Rico, 2012–2022*,†
The figure is a map of Puerto Rico that illustrates the number and proportion of acute febrile illness cases with participants testing positive for any arbovirus during 2012–2022, by municipality. The data are from the Sentinel Enhanced Dengue Surveillance System.

Abbreviation: SEDSS = Sentinel Enhanced Dengue Surveillance System.

* Arboviruses included dengue, chikungunya, and Zika viruses; the number of tests for any arbovirus in each municipality is shown.

The proportion of acute febrile illness cases testing positive for arboviruses is divided into intervals of equal size (5%).

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Return to your place in the textFIGURE 4. Confirmed dengue cases, by serotype and year — Sentinel Enhanced Dengue Surveillance System, Puerto Rico, May 2012 – December 2022*
The figure is a histogram that illustrates the number of confirmed dengue cases, by serotype and year, in Puerto Rico during May 2012–December 2022. The data are from the Sentinel Enhanced Dengue Surveillance System.

* Dengue cases were assigned a serotype if a participant’s serum specimen was polymerase chain reaction–positive for a specific dengue virus serotype.

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Return to your place in the textFIGURE 5. Number and proportion of acute febrile illness cases with participants testing positive for any acute respiratory virus, by municipality — Sentinel Enhanced Dengue Surveillance System, Puerto Rico, 2012–2022*,†
The figure is a map of Puerto Rico that illustrates the number and proportion of acute febrile illness cases with participants testing positive for any acute respiratory virus during 2012–2022, by municipality. The data are from the Sentinel Enhanced Dengue Surveillance System.

Abbreviation: SEDSS = Sentinel Enhanced Dengue Surveillance System.

* Respiratory viruses included influenza A and B, respiratory syncytial virus, human adenovirus, human metapneumovirus, human parainfluenza viruses 1 and 3, human coronavirus, and SARS-CoV-2; the number of tests for any arbovirus in each municipality is shown.

The proportion of acute febrile illness cases testing positive for respiratory viruses is divided into intervals of equal size (5%).

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TABLE 3. Number and percentage of cases of laboratory evidence of dengue, Zika, or chikungunya infection,* by selected characteristics —Sentinel Enhanced Dengue Surveillance System, Puerto Rico, 2012–2022Return to your place in the text
Characteristic Dengue confirmed Dengue probable Dengue total Chikungunya confirmed Chikungunya probable Chikungunya total Zika confirmed Zika probable Zika total
No. (%) No. (%) No. (%) No. (%) No. (%) No. (%) No. (%) No. (%) No. (%)
Emergency department physician diagnosis
Dengue 441 (46.0) 142 (30.0) 583 (40.7) 142 (7.9) 32 (6.5) 174 (7.6) 16 (1.1) 5 (1.1) 21 (1.1)
Chikungunya 3 (0.3) 12 (2.5) 15 (1.0) 318 (17.6) 27 (5.5) 345 (15.0) 1 (0.1) 1 (0.2) 2 (0.1)
Zika 1 (0.1) 0 (—) 1 (0.1) 0 (—) 3 (0.6) 3 (0.1) 80 (5.5) 2 (0.4) 82 (4.3)
Influenza 32 (3.3) 24 (5.1) 56 (3.9) 165 (9.1) 53 (10.8) 218 (9.5) 6 (0.4) 60 (12.8) 66 (3.4)
Leptospirosis 9 (0.9) 2 (0.4) 11 (0.8) 6 (0.3) 4 (0.8) 10 (0.4) 3 (0.2) 10 (2.1) 13 (0.7)
Respiratory infections 105 (10.9) 62 (13.1) 167 (11.7) 146 (8.1) 83 (17.0) 229 (10.0) 45 (3.1) 86 (18.3) 131 (6.8)
Infection not otherwise specified§ 353 (36.8) 207 (43.8) 560 (39.1) 1,056 (58.5) 241 (49.3) 1,297 (56.6) 1,003 (69.2) 228 (48.6) 1,231 (64.2)
Days post-onset
0–3 563 (58.7) 202 (42.7) 765 (53.4) 1,693 (93.8) 261 (53.4) 1,954 (85.2) 1,195 (82.5) 272 (58.0) 1,467 (76.5)
4–7 392 (40.9) 250 (52.9) 642 (44.8) 109 (6.0) 218 (44.6) 327 (14.3) 253 (17.5) 192 (40.9) 445 (23.2)
>7 4 (0.4) 21 (4.4) 25 (1.7) 2 (0.1) 10 (2.0) 12 (0.5) 1 (0.1) 5 (1.1) 6 (0.3)
Sex
Male 522 (54.4) 242 (51.2) 764 (53.4) 857 (47.5) 238 (48.7) 1,095 (47.8) 608 (42.0) 203 (43.3) 811 (42.3)
Female 437 (45.6) 231 (48.8) 668 (46.6) 947 (52.5) 251 (51.3) 1,198 (52.2) 841 (58.0) 266 (56.7) 1,107 (57.7)
Age, yrs
<1 16 (1.7) 12 (2.5) 28 (2.0) 80 (4.4) 27 (5.5) 107 (4.7) 26 (1.8) 6 (1.3) 32 (1.7)
1–4 63 (6.6) 36 (7.6) 99 (6.9) 214 (11.9) 95 (19.4) 309 (13.5) 77 (5.3) 23 (4.9) 100 (5.2)
5–9 148 (15.4) 67 (14.2) 215 (15.0) 202 (11.2) 44 (9.0) 246 (10.7) 100 (6.9) 54 (11.5) 154 (8.0)
10–19 427 (44.5) 160 (33.8) 587 (41.0) 347 (19.2) 79 (16.2) 426 (18.6) 242 (16.7) 95 (20.3) 337 (17.6)
20–29 120 (12.5) 49 (10.4) 169 (11.8) 231 (12.8) 50 (10.2) 281 (12.3) 307 (21.2) 63 (13.4) 370 (19.3)
30–39 60 (6.3) 26 (5.5) 86 (6.0) 155 (8.6) 38 (7.8) 193 (8.4) 217 (15.0) 44 (9.4) 261 (13.6)
40–49 46 (4.8) 25 (5.3) 71 (5.0) 148 (8.2) 38 (7.8) 186 (8.1) 162 (11.2) 46 (9.8) 208 (10.8)
≥50 79 (8.2) 98 (20.7) 177 (12.4) 427 (23.7) 118 (24.1) 545 (23.8) 318 (21.9) 138 (29.4) 456 (23.8)
Clinical disposition
Ambulatory 499 (52.0) 269 (56.9) 768 (53.6) 1,554 (86.1) 369 (75.5) 1,923 (83.9) 1,377 (95.0) 393 (83.8) 1,770 (92.3)
Admitted or transferred 459 (47.9) 201 (42.5) 660 (46.1) 237 (13.1) 100 (20.4) 337 (14.7) 51 (3.5) 66 (14.1) 117 (6.1)
Left against medical advice 0 (—) 0 (—) 0 (—) 0 (—) 1 ( 0.2) 1 ( 0.0) 20 (1.4) 5 (1.1) 25 (1.3)
Deceased 1 (0.1) 1 (0.2) 2 (0.1) 2 (0.1) 1 (0.2) 3 (0.1) 0 (—) 1 (0.2) 1 (0.1)
Unknown 0 (—) 2 (0.4) 2 (0.1) 11 (0.6) 18 (3.7) 29 (1.3) 1 (0.1) 4 (0.9) 5 (0.3)
Chronic conditions
Diabetes 44 (4.6) 53 (11.2) 97 (6.8) 174 (9.6) 52 (10.6) 226 (9.9) 156 (10.8) 68 (14.5) 224 (11.7)
Chronic pulmonary disease 179 (18.7) 108 (22.8) 287 (20.0) 285 (15.8) 74 (15.1) 359 (15.7) 237 (16.4) 108 (23.0) 345 (18.0)
Hypertension 63 (6.6) 73 (15.4) 136 (9.5) 296 (16.4) 81 (16.6) 377 (16.4) 248 (17.1) 126 (26.9) 374 (19.5)
Chronic kidney disease 5 (0.5) 6 (1.3) 11 (0.8) 21 (1.2) 9 (1.8) 30 (1.3) 10 (0.7) 3 (0.6) 13 (0.7)
Immunodeficiency 7 (0.7) 5 (1.1) 12 (0.8) 12 (0.7) 4 (0.8) 16 (0.7) 12 (0.8) 4 (0.9) 16 (0.8)
Sickle cell disease 4 (0.4) 3 (0.6) 7 (0.5) 11 (0.6) 2 (0.4) 13 (0.6) 3 (0.2) 3 (0.6) 6 (0.3)
Obesity 97 (26.4) 68 (31.9) 165 (28.4) 199 (30.8) 86 (17.6) 285 (29.6) 466 (32.5) 128 (27.9) 594 (31.4)
Pregnant**
Yes 5 (2.9) 6 (9.4) 11 (4.6) 55 (15.8) 8 (7.9) 63 (14.0) 67 (15.8) 10 (8.3) 77 (14.2)
No 143 (81.7) 52 (81.2) 195 (81.6) 260 (74.5) 85 (84.2) 345 (76.7) 351 (82.8) 107 (89.2) 458 (84.2)
Unknown 27 (15.4) 6 (9.4) 33 (13.8) 34 (9.7) 8 (7.9) 42 (9.3) 6 (1.4) 3 (2.5) 9 (1.6)
Visits from women aged 15–44 years, no. 175 64 239 349 101 450 424 120 544
Coinfections
Arboviral co-infection 0 (—) 55 (11.6) 55 (3.8) 1 (0.1) 43 (8.8) 44 (1.9) 1 (0.1) 3 (0.6) 4 (0.2)
Respiratory virus co-infection†† 34 (3.5) 47 (9.9) 81 (5.7) 34 (1.9) 57 (11.7) 91 (4.0) 41 (2.8) 111 (23.7) 152 (7.9)
Total 959 (100.0) 473 (100.0) 1,432 (100.0) 1,804 (100.0) 489 (100.0) 2,293 (100.0) 1,449 (100.0) 469 (100.0) 1,918 (100.0)

Abbreviations: DENV = dengue virus; IgM = immunoglobulin M; ZIKV = Zika virus.
* Confirmed infection for the three arboviruses was by positive reverse transcription-polymerase chain reaction results. Before Zika, probable dengue included positive IgM tests. After Zika emerged, probable dengue included IgM positivity for DENV along with negative IgM results for ZIKV because of notable cross-reactivity between dengue IgM and Zika IgM antibodies in serologic tests. Probable Zika included IgM positivity for ZIKV along with negative IgM results for DENV. Excludes unspecified flavivirus infections.
Respiratory infections include pneumonia, upper respiratory tract infections, bronchitis, bronchiolitis, respiratory syncytial virus, and COVID-19.
§ Infections not otherwise specified include urinary tract infections, gastroenteritis, pharyngitis, fever unspecified, viral syndrome, tonsillitis, otitis media, sinusitis, impetigo, cellulitis, infected wound, lymphadenopathy cervical, herpangina, febrile seizure, meningitis, sepsis, bacteremia, encephalitis, pancreatitis, myositis, conjunctivitis, myocarditis, Guillain-Barré syndrome, mononucleosis, and pyelonephritis.
Among persons with available body mass index: dengue (n = 581), Zika (n = 1,893), and chikungunya (n = 962).
** Denominators for these analyses include visits from women of childbearing age defined as any female aged 15–44 years.
†† Respiratory virus coinfections included adenovirus, human parainfluenza virus (types 1 and 3), influenza virus (types A and B), respiratory syncytial virus (types A and B), human metapneumovirus, human coronavirus (HcoV-229E, HcoV-HKU1, HcoV-NL63, and HcoV-OC43), and SARS-CoV-2.

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Return to your place in the textFIGURE 6. Number and proportion of dengue cases, by participant age group without warning signs, with warning signs without progressing to severe dengue, and severe dengue — Sentinel Enhanced Dengue Surveillance System, Puerto Rico, 2012–2022
The figure comprises two bar graphs that illustrate the number and proportion of dengue cases, by participant age group without warning signs, by age group with warning signs without progressing to severe dengue, and severe dengue in Puerto Rico during May 2012–December 2022. The data are from the Sentinel Enhanced Dengue Surveillance System.

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TABLE 4. Number and percentage of cases of confirmed or probable dengue and clinical characteristics, by patient age — Sentinel Enhanced Dengue Surveillance System, Puerto Rico, 2012–2022Return to your place in the text
Symptom <1 yr 1–4 yrs 5–9 yrs 10–19 yrs 20–29 yrs 30–39 yrs 40–49 yrs ≥50 yrs Total
No. (%) No. (%) No. (%) No. (%) No. (%) No. (%) No. (%) No. (%) No. (%)
General symptom
Fever* 28 (100.0) 99 (100.0) 215 (100.0) 586 (99.8) 169 (100.0) 86 (100.0) 71 (100.0) 171 (96.6) 1,425 (99.5)
Chills 12 (42.9) 39 (39.4) 154 (71.6) 497 (84.7) 151 (89.3) 77 (89.5) 64 (90.1) 148 (83.6) 1,142 (79.7)
Nausea 10 (35.7) 44 (44.4 139 (64.7) 438 (74.6) 133 (78.7) 65 (75.6) 52 (73.2) 103 (58.2) 984 (68.7)
Rash 14 (50.0) 51 (51.5) 138 (64.2) 372 (63.4) 97 (57.4) 45 (52.3) 34 (47.9) 50 (28.2) 801 (55.9)
Headache 5 (17.9) 37 (37.4) 176 (81.9) 541 (92.2) 155 (91.7) 83 (96.5) 67 (94.4) 136 (76.8) 1,200 (83.8)
Retro-orbital pain 5 (17.9) 16 (16.2) 98 (45.6) 398 (67.8) 129 (76.3) 74 (86.0) 52 (73.2) 97 (54.8) 869 (60.7)
Myalgia 10 (35.7) 31 (31.3) 133 (61.9) 448 (76.3) 147 (87.0) 79 (91.9) 68 (95.8) 150 (84.7) 1,066 (74.4)
Arthralgia 4 (14.3) 20 (20.2) 112 (52.1) 351 (59.8) 136 (80.5) 73 (84.9) 60 (84.5) 141 (79.7) 897 (62.6)
Tachypnea 2 (7.1) 7 (7.1) 57 (26.5) 336 (57.2) 72 (42.6) 48 (55.8) 27 (38.0) 76 (42.9) 625 (43.6)
Leukopenia (white blood cells <4,000/mm3) (N = 1,389) 3 (11.5) 36 (38.7) 135 (64.9) 431 (75.3) 109 (66.5) 53 (61.6) 39 (56.5) 63 (36.8) 869 (62.6)
Warning sign
Persistent vomiting (three or more times in 24 hours) 4 (14.3) 22 (22.2) 59 (27.4) 167 (28.4) 59 (34.9) 19 (22.1) 15 (21.1) 32 (18.1) 377 (26.3)
Abdominal pain 5 (17.9) 41 (41.4) 143 (66.5) 389 (66.3) 110 (65.1) 49 (57.0) 41 (57.7) 91 (51.4) 869 (60.7)
Clinical fluid accumulation§ 2 (7.1) 4 (4.0) 5 (2.3) 24 (4.1) 8 (4.7) 7 (8.1) 4 (5.6) 15 (8.5) 69 (4.8)
Mucosal bleeding 0 (—) 5 (5.1) 21 (9.8) 95 (16.2) 37 (21.9) 12 (14.0) 14 (19.7) 19 (10.7) 203 (14.2)
Restlessness** 14 (50.0) 42 (42.4) 92 (42.8) 263 (44.8) 88 (52.1) 47 (54.7) 42 (59.2) 111 (62.7) 699 (48.8)
Indicator of severe dengue
Severe plasma leakage or shock 1 (3.6) 4 (4.0) 23 (10.7) 165 (28.1 16 (9.5) 16 (18.6) 5 (7.0) 34 (19.2) 264 (18.4)
Severe plasma leakage or intravascular permeability†† 1 (3.6) 4 (4.0) 23 (10.7) 157 (26.7) 16 (9.5) 14 (16.3) 5 (7.0) 32 (18.1) 252 (17.6)
  Ascites 1 (3.6) 0 (—) 1 (0.5) 2 (0.3) 1 (0.6) 1 (1.2) 0 (—) 2 (1.1) 8 (0.6)
  Pleural or pericardial effusion 2 (7.1) 4 (4.0) 2 (0.9) 16 (2.7) 1 (0.6) 1 (1.2) 1 (1.4) 4 (2.3) 32 (2.2)
  Hemoconcentration§§ 5 (17.9) 5 (5.1) 6 (2.8) 44 (7.5) 17 (10.1) 9 (10.5) 11 (15.5) 27 (15.3) 124 (8.7)
    Low albumin (N = 699)¶¶ 2 (14.3) 22 (61.1) 63 (62.4) 218 (66.7) 32 (41.6) 19 (48.7) 14 (42.4) 44 (61.1) 414 (59.2)
Shock*** 0 (—) 0 (—) 1 (0.5) 19 (3.2) 0 (—) 4 (4.7) 1 (1.4) 6 (3.4) 31 (2.2)
  Hypotension (N = 1400)††† 0 (—) 1 (1.1) 20 (9.4) 77 (13.4) 10 (6.1) 4 (4.7) 4 (5.7) 8 (4.6) 124 (8.9)
  Drop in systolic blood pressure >40 mmHg (N = 845) 2 (13.3) 0 (—) 4 (3.2) 13 (3.7) 2 (1.9) 5 (9.4) 2 (4.5) 16 (15.0) 44 (5.2)
  Narrow pulse pressure 1 (3.6) 3 (3.0) 6 (2.8) 15 (2.6) 0 (—) 0 (—) 1 (1.4) 3 (1.7) 29 (2.0)
  Capillary refill (>2 seconds) 0 (—) 4 (4.0) 10 (4.7) 42 (7.2) 14 (8.3) 5 (5.8) 5 (7.0) 14 (7.9) 94 (6.6)
  Pale or cold skin 8 (28.6) 37 (37.4) 97 (45.1) 308 (52.5) 90 (53.3) 46 (53.5) 38 (53.5) 91 (51.4) 715 (49.9)
  Blue skin or lips 0 (—) 2 (2.0) 7 (3.3) 40 (6.8) 7 (4.1) 5 (5.8) 1 (1.4) 2 (1.1) 64 (4.5)
  Tachycardia§§§ 2 (7.1) 24 (24.2) 29 (13.5) 139 (23.7) 67 (39.6) 29 (33.7) 29 (40.8) 40 (22.6) 359 (25.1)
  Use of vasopressors, inotropic, vasodilators, or albumin 2 (7.1) 1 (1.0) 1 (0.5) 9 (1.5) 0 (—) 3 (3.5) 0 (—) 0 (—) 16 (1.1)
Hemorrhage 4 (14.3) 2 (2.0) 18 (8.4) 40 (6.8) 20 (11.8) 11 (12.8) 10 (14.1) 26 (14.7) 131 (9.1)
  Gastrointestinal bleeding 3 (10.7) 1 (1.0) 13 (6.0) 25 (4.3) 10 (5.9) 5 (5.8) 7 (9.9) 19 (10.7) 83 (5.8)
  Vomit with blood 0 (—) 1 (1.0) 6 (2.8) 14 (2.4) 10 (5.9) 4 (4.7) 1 (1.4) 3 (1.7) 39 (2.7)
  Pulmonary hemorrhage 0 (—) 0 (—) 0 (—) 2 (0.3 0 (—) 0 (—) 0 (—) 0 (—) 2 (0.1)
  Any blood product received 1 (3.6) 0 (—) 0 (—) 9 (1.5) 2 (1.2) 2 (2.3) 2 (2.8) 6 (3.4) 22 (1.5)
Severe organ involvement 1 (3.6) 4 (4.0) 5 (2.3) 30 (5.1) 4 (2.4) 2 (2.3) 3 (4.2) 8 (4.5) 57 (4.0)
  Liver impairment (aspartate aminotransferase or alanine aminotransferase >1,000 IU/L) (N = 793) 0 (—) 0 (—) 3 (2.5) 11 (2.9) 2 (2.3) 0 (—) 1 (2.9) 0 (—) 17 (2.1)
  Seizures 0 (—) 4 (4.0) 3 (1.4) 11 (1.9) 2 (1.2) 2 (2.3) 0 (—) 4 (2.3) 26 (1.8)
  Intubation or mechanical ventilation 0 (—) 0 (—) 0 (—) 1 (0.2) 0 (—) 0 (—) 0 (—) 1 (0.6) 2 (0.1)
  Prothrombin time and international normalized ratio ≥1.5 (N = 90) 0 (—) 0 (—) 1 (9.1) 0 (—) 0 (—) 0 (—) 2 (50.0) 2 (18.2) 5 (5.6)
  Aseptic meningitis 0 (—) 0 (—) 0 (—) 1 (0.2) 0 (—) 0 (—) 0 (—) 0 (—) 1 (0.1)
  Encephalopathy 0 (—) 1 (1.0) 0 (—) 4 (0.7) 0 (—) 0 (—) 0 (—) 2 (1.1) 7 (0.5)
Total 28 (100.0) 99 (100.0) 215 (100.0) 587 (100.0) 169 (100.0) 86 (100.0) 71 (100.0) 177 (100.0) 1,432 (100.0)

Abbreviation: bpm = beats per minute.
* Fever defined as either fever during the visit or in past 7 days
Tachypnea is an age-specific variable defined by respiratory rate (breaths per minute). Persons aged 0–3 months: >60 breaths per minute; persons aged 4–6 months: >45 breaths per minute; persons aged 7–12 months: >40 breaths per minute; persons aged 13 months–3 years: >30 breaths per minute; persons aged 4–6 years: >25 breaths per minute; persons aged 7–12 years: >22 breaths per minute; and persons aged >13 years: >18 breaths per minute.
§ Clinical fluid accumulation included pleural effusion, ascites, peritoneal fluid, pericardial effusion, free fluid, and swollen hands.
Mucosal bleeding defined as bleeding from gums or nose, vaginal bleeding, or hematuria.
** Restlessness defined as nervousness, agitation, irritability, or disorientation.
†† Severe plasma leakage defined as respiratory distress and plasma leakage. Respiratory compromise defined as tachypnea, respiratory distress, accessory muscles use, supplemental oxygen, or intubation. Plasma leakage defined as pleural effusion, pericardial effusion, ascites, free fluid in abdomen, hematocrit change >20% during illness, hematocrit value >20% above baseline for age and sex at any time, or albumin low for age.
§§ Hemoconcentration defined as hematocrit change ≥20% during illness or hematocrit value ≥20% above baseline for age and sex at any time. Baseline values (females and males): 0–7 days: <61.2; 8–29 days: <52.8; 30–59 days: <42; 60 days – <3 years: <43.2; 3 – <6 years: <44; 6 – <9 years: <45.6; 9 – <12 years: <46.8; Males: 12 – <15 years: <50.4; 15 – <50 years: <54; 50 – <60 years: <52.8; ≥60 years: <51.6; Females: 12 – <15 years: <48; 15 – <50 years: 46.8; >50 years: <48.
¶¶ Low albumin defined based on age-specific criteria. If albumin level falls below the specified cut-off values (g/dL) by age: 0–15 days: <3.0; 15 days–1 year: <2.2; >1–15 years: <3.6; 16–18 years: <3.9; ≥19 years: <3.2.
*** Shock is defined as 1) shock listed in medical assessment at any time; 2) use of vasopressors, inotropes, or vasodilators, or albumin; 3) pulse pressure <20 mmHg or hypotension or drop in systolic blood pressure >40 mmHg and any two of the following: elevated heart rate, capillary refill >2 seconds, mottled skin, thready, weak pulse, pale or cold skin, blue skin or lips, cyanotic limbs, or cold limbs. Source: Paz-Bailey G, Sánchez-González L, Torres-Velasquez B, et al. Predominance of severe plasma leakage in pediatric patients with severe dengue in Puerto Rico. J Infect Dis 2022;226:1949–58.
††† For persons aged ≥10 years, hypotension is defined as systolic blood pressure of <90 mmHg or mean arterial pressure <70 mmHg. Hypotension in children aged <10 years defined as systolic blood pressure of <70 + (age in years x 2) mmHg.
§§§ Tachycardia is an age-specific variable that might be an indicator of hypovolemia and dengue severity when combined with indicators of plasma leakage. A participant was defined as tachycardic at the following age-specific variables, according to Nelson’s Essentials of Pediatrics (2002): <1 day: >154 bpm; 1–2 days: >159 bpm; 3–6 days: >166 bpm; 1–3 weeks: >182 bpm; 1–2 months: >179 bpm; 3–5 months: >186 bpm; 6–11 months: >169 bpm; 1–2 years: >151 bpm; 3–4 years: >137 bpm; 5–7 years: >133 bpm; 8–11 years: >130 bpm; 12–15 years: >119 years; >16 years: >100 bpm.

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TABLE 5. Number and percentage of cases of confirmed or probable chikungunya virus infection and clinical characteristics, by age — Sentinel Enhanced Dengue Surveillance System, Puerto Rico, 2012–2022Return to your place in the text
Symptom <1 yr 1–4 yrs 5–9 yrs 10–19 yrs 20–29 yrs 30–39 yrs 40–49 yrs ≥50 yrs Total
No. (%) No. (%) No. (%) No. (%) No. (%) No. (%) No. (%) No. (%) No. (%)
Fever* 103 (96.3) 308 (99.7) 246 (100.0) 423 (99.3) 280 (99.6) 190 (98.4) 183 (98.4) 538 (98.7) 2,271 (99.0)
Chills 52 (48.6) 190 (61.5) 171 (69.5) 309 (72.5) 207 (73.7) 163 (84.5) 152 (81.7) 424 (77.8) 1,668 (72.7)
Nausea 26 (24.3) 129 (41.7) 111 (45.1) 234 (54.9) 139 (49.5) 114 (59.1) 107 (57.5) 269 (49.4) 1,129 (49.2)
Rash 75 (70.1) 185 (59.9) 163 (66.3) 305 (71.6) 195 (69.4) 134 (69.4) 104 (55.9) 257 (47.2) 1,418 (61.8)
Headache 9 (8.4) 112 (36.2) 168 (68.3) 365 (85.7) 249 (88.6) 173 (89.6) 167 (89.8) 421 (77.2) 1,664 (72.6)
Eye pain 9 (8.4) 80 (25.9) 82 (33.3) 231 (54.2) 155 (55.2) 125 (64.8) 111 (59.7) 281 (51.6) 1,074 (46.8)
Myalgia 28 (26.2) 126 (40.8) 165 (67.1) 339 (79.6) 252 (89.7) 180 (93.3) 168 (90.3) 497 (91.2) 1,755 (76.5)
Arthralgia 17 (15.9) 115 (37.2) 159 (64.6) 338 (79.3) 249 (88.6) 175 (90.7) 172 (92.5) 501 (91.9) 1,726 (75.3)
Red or swollen joints or arthritis 20 (18.7) 51 (16.5) 62 (25.2) 143 (33.6) 121 (43.1) 105 (54.4) 97 (52.2) 325 (59.6) 924 (40.3)
Total 107 (100.0) 309 (100.0) 246 (100.0) 426 (100.0) 281 (100.0) 193 (100.0) 186 (100.0) 545 (100.0) 2,293 (100.0)

* Fever defined as either fever during the visit or in the past 7 days.

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TABLE 6. Number and percentage of cases of confirmed or probable Zika virus infection and clinical characteristics, by age — Sentinel Enhanced Dengue Surveillance System, Puerto Rico, 2012–2022Return to your place in the text
Symptom <1 yr 1–4 yrs 5–9 yrs 10–19 yrs 20–29 yrs 30–39 yrs 40–49 yrs ≥50 yrs Total
No. (%) No. (%) No. (%) No. (%) No. (%) No. (%) No. (%) No. (%) No. (%)
Fever* 31 (96.9) 99 (99.0) 153 (99.4) 319 (94.7) 298 (80.5) 195 (74.7) 184 (88.5) 395 (86.6) 1,674 (87.3)
Chills 12 (37.5) 52 (52.0) 91 (59.1) 247 (73.3) 243 (65.7) 194 (74.3) 166 (79.8) 350 (76.8) 1,355 (70.6)
Rash 23 (71.9) 66 (66.0) 105 (68.2) 239 (70.9) 301 (81.4) 215 (82.4) 165 (79.3) 312 (68.4) 1,426 (74.3)
Headache 3 (9.4) 34 (34.0) 107 (69.5) 296 (87.8) 305 (82.4) 219 (83.9) 176 (84.6) 353 (77.4) 1,493 (77.8)
Eye pain 3 (9.4) 20 (20.0) 45 (29.2) 220 (65.3) 225 (60.8) 176 (67.4) 140 (67.3) 275 (60.3) 1,104 (57.6)
Myalgia 1 (3.1) 22 (22.0) 51 (33.1) 229 (68.0) 303 (81.9) 221 (84.7) 195 (93.8) 383 (84.0) 1,405 (73.3)
Arthralgia 1 (3.1) 17 (17.0) 61 (39.6) 231 (68.5) 311 (84.1) 227 (87.0) 196 (94.2) 407 (89.3) 1,451 (75.7)
Calf pain 1 (3.1) 11 (11.0) 34 (22.1) 129 (38.3) 172 (46.5) 144 (55.2) 151 (72.6) 282 (61.8) 924 (48.2)
Red or swollen joints or arthritis 0 (—) 6 (6.0) 17 (11.0) 59 (17.5) 137 (37.0) 123 (47.1) 108 (51.9) 230 (50.4) 680 (35.5)
Mucosal bleeding 2 (6.2) 17 (17.0) 22 (14.3) 40 (11.9) 68 (18.4) 50 (19.2) 35 (16.8) 60 (13.2) 294 (15.3)
  Respiratory 25 (78.1) 77 (77.0) 118 (76.6) 264 (78.3) 268 (72.4) 169 (64.8) 157 (75.5) 333 (73.0) 1,411 (73.6)
  Nasal discharge 17 (53.1) 64 (64.0) 74 (48.1) 158 (46.9) 123 (33.2) 89 (34.1) 80 (38.5) 186 (40.8) 791 (41.2)
  Sore throat 5 (15.6) 32 (32.0) 71 (46.1) 203 (60.2) 210 (56.8) 120 (46.0) 116 (55.8) 240 (52.6) 997 (52.0)
  Cough 20 (62.5) 57 (57.0) 84 (54.5) 148 (43.9) 153 (41.4) 93 (35.6) 98 (47.1) 225 (49.3) 878 (45.8)
Gastrointestinal illness 18 (56.2) 42 (42.0) 64 (41.6) 177 (52.5) 216 (58.4) 147 (56.3) 140 (67.3) 285 (62.5) 1,089 (56.8)
  Nausea or vomiting 9 (28.1) 31 (31.0) 47 (30.5) 143 (42.4) 176 (47.6) 115 (44.1) 114 (54.8) 232 (50.9) 867 (45.2)
  Diarrhea 13 (40.6) 22 (22.0) 34 (22.1) 94 (27.9) 124 (33.5) 88 (33.7) 89 (42.8) 167 (36.6) 631 (32.9)
Total 32 (100.0) 100 (100.0) 154 (100.0) 337 (100.0) 370 (100.0) 261 (100.0) 208 (100.0) 456 (100.0) 1,918 (100.0)

* Fever defined as either fever during the visit or in the past 7 days.

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TABLE 7. Number and percentage of cases of respiratory viral illness (caused by influenza virus, respiratory syncytial virus, adenovirus, human parainfluenza virus, human metapneumovirus, human coronaviruses, and SARS-CoV-2) among all participants assessed and tested, by selected characteristics — Puerto Rico, Sentinel Enhanced Dengue Surveillance System, 2012–2022Return to your place in the text
Characteristic Influenza A Influenza B Respiratory syncytial virus* Adenovirus Human parainfluenza virus 1 Human parainfluenza virus 3 Human metapneumovirus Human coronavirus SARS-CoV-2
No. (%) No. (%) No. (%) No. (%) No. (%) No. (%) No. (%) No. (%) No. (%)
Emergency department physician diagnosis
Dengue 57 (1.5) 59 (4.1) 5 (0.3) 19 (1.2) 5 (1.2) 9 (0.9) 7 (0.8) 3 (6.5) 0 (—)
Chikungunya 7 (0.2) 2 (0.1) 0 (—) 2 (0.1) 0 (—) 3 (0.3) 1 (0.1) 0 (—) 0 (—)
Zika 2 (0.1) 2 (0.1) 2 (0.1) 1 (0.1) 1 (0.2) 1 (0.1) 2 (0.2) 0 (—) 0 (—)
Influenza 1,913 (50.9) 817 (57.1) 90 (6.0) 100 (6.5) 21 (7.4) 40 (5.1) 68 (7.9) 0 (—) 26 (1.6)
Leptospirosis 8 (0.2) 2 (0.1) 2 (0.1) 3 (0.2) 1 (0.2) 0 (—) 2 (0.2) 0 (—) 1 (0.1)
Respiratory infections§ 657 (17.5) 248 (17.3) 679 (45.6) 373 (24.1) 65 (23.0) 266 (34.1) 372 (43.2) 14 (30.4) 460 (29.0)
Infection not otherwise specified 818 (21.8) 336 (23.5) 477 (32.0) 951 (61.4) 139 (49.3) 351 (45.0) 287 (33.3) 21 (45.7) 190 (12.0)
Days post onset
0–3 3,396 (90.4) 1,226 (85.7) 1,188 (79.8) 1,284 (82.8) 357 (87.7) 825 (83.1) 696 (80.7) 35 (76.1) 1,161 (73.2)
4–7 342 (9.1) 198 (13.8) 282 (18.9) 249 (16.1) 48 (11.8) 159 (16.0) 155 (18.0) 11 (23.9) 308 (19.4)
>7 18 (0.5) 6 (0.4) 15 (1.0) 14 (0.9) 2 (0.5) 9 (0.9) 11 (1.3) 0 (—) 117 (7.4)
Missing 0 (—) 0 (—) 4 (0.3) 3 (0.2) 0 (—) 0 (—) 0 (—) 0 (—) 0 (—)
Sex
Male 1,819 (48.4) 735 (51.4) 752 (50.5) 832 (53.7) 222 (54.5) 483 (48.6) 438 (50.8) 25 (54.3) 722 (45.5)
Female 1,937 (51.6) 695 (48.6) 737 (49.5) 718 (46.3) 185 (45.5) 510 (51.4) 424 (49.2) 21 (45.7) 864 (54.5)
Age, yrs
<1 152 (4.0) 42 (2.9) 289 (19.4) 154 (9.9) 39 (9.6) 181 (18.2) 97 (11.3) 6 (13.0) 47 (3.0)
1–4 618 (16.5) 197 (13.8) 758 (50.9) 729 (47.0) 222 (54.5) 464 (46.7) 333 (38.6) 12 (26.1) 102 (6.4)
5–9 591 (15.7) 369 (25.8) 131 (8.8) 326 (21.0) 71 (17.4) 83 (8.4) 138 (16.0) 6 (13.0) 71 (4.5)
10–19 689 (18.3) 347 (24.3) 86 (5.8) 150 (9.7) 26 (6.4) 51 (5.1) 57 (6.6) 6 (13.0) 144 (9.1)
20–29 513 (13.7) 131 (9.2) 49 (3.3) 73 (4.7) 16 (3.9) 37 (3.7) 56 (6.5) 6 (13.0) 213 (13.4)
30–39 375 (10.0) 100 (7.0) 33 (2.2) 48 (3.1) 9 (2.2) 38 (3.8) 34 (3.9) 3 (6.5) 223 (14.1)
40–49 280 (7.5) 72 (5.0) 36 (2.4) 26 (1.7) 9 (2.2) 31 (3.1) 33 (3.8) 1 (2.2) 209 (13.2)
≥50 538 (14.3) 172 (12.0) 107 (7.2) 44 (2.8) 15 (3.7) 108 (10.9) 114 (13.2) 6 (13.0) 577 (36.4)
Clinical disposition
Ambulatory 3,386 (90.1) 1,279 (89.4) 1,111 (74.6) 1,270 (81.9) 355 (87.2) 863 (86.9) 712 (82.6) 35 (76.1) 1,354 (85.4)
Admitted or transferred 342 (9.1) 142 (9.9) 367 (24.6) 277 (17.9) 51 (12.5) 125 (12.6) 142 (16.5) 10 (21.7) 205 (12.9)
Left against medical advice 11 (0.3) 4 (0.3) 3 (0.2) 1 (0.1) 0 (—) 3 (0.3) 5 (0.6) 1 (2.2) 2 (0.1)
Deceased 4 (0.1) 0 (—) 1 (0.1) 0 (—) 0 (—) 1 (0.1) 1 (0.1) 0 (—) 12 (0.8)
Unknown 13 (0.3) 5 (0.3) 7 (0.5) 2 (0.1) 1 (0.2) 1 (0.1) 2 (0.2) 0 (—) 13 (0.8)
Co-existing medical condition
Diabetes 269 (7.2) 98 (6.9) 49 (3.3) 28 (1.8) 15 (3.7) 61 (6.2) 68 (7.9) 5 (10.9) 220 (13.9)
Chronic pulmonary disease 720 (19.2) 302 (21.1) 264 (17.7) 263 (17.0) 85 (20.9) 152 (15.3) 192 (22.3) 7 (15.2) 345 (21.8)
Hypertension 434 (11.6) 133 (9.3) 85 (5.7) 46 (3.0) 12 (2.9) 97 (9.8) 90 (10.4) 5 (10.9) 389 (24.5)
Chronic kidney disease 19 (0.5) 9 (0.6) 7 (0.5) 7 (0.5) 1 (0.2) 8 (0.8) 10 (1.2) 2 (4.3) 36 (2.3)
Immunodeficiency 17 (0.5) 8 (0.6) 4 (0.3) 2 (0.1) 2 (0.5) 2 (0.2) 9 (1.0) 1 (2.2) 12 (0.8)
Sickle cell disease 15 (0.4) 5 (0.3) 5 (0.3) 5 (0.3) 0 (—) 0 (—) 3 (0.3) 0 (—) 4 (0.3)
Obesity** 712 (24.4) 185 (17.3) 130 (11.1) 103 (9.9) 27 (9.6) 110 (14.1) 117 (18.0) 5 (29.4) 550 (38.3)
Pregnant††
Yes 66 (8.9) 19 (9.5) 3 (3.3) 4 (4.1) 4 (17.4) 7 (8.8) 5 (6.5) 1 (25.0) 9 (2.5)
No 642 (86.3) 180 (89.5) 80 (88.9) 93 (94.9) 18 (78.3) 70 (87.5) 72 (93.5) 2 (50.0) 347 (95.6)
Unknown 36 (4.8) 2 (1.0) 7 (7.8) 1 (1.0) 1 (4.3) 3 (3.7) 0 (—) 1 (25.0) 7 (1.9)
Visits from women aged 15–44, no. 744 201 90 98 23 80 77 4 363
Coinfections
Arboviral co-infection 77 (2.1) 74 (5.2) 28 (1.9) 55 (3.5) 9 (2.2) 33 (3.3) 40 (4.6) 6 (13.0) 2 (0.1)
Respiratory virus co-infection 78 (2.1) 25 (1.7) 71 (4.8) 106 (6.8) 19 (4.7) 40 (4.0) 43 (5.0) 5 (10.9) 9 (0.6)
Total 3,756 (100.0) 1,430 (100.0) 1,489 (100.0) 1,550 (100.0) 407 (100.0) 993 (100.0) 862 (100.0) 46 (100.0) 1,586 (100.0)

* Respiratory syncytial virus includes subtypes A and B.
Human coronavirus includes types 229E, OC43, NL63, and HKU1.
§ Respiratory infections include pneumonia, upper respiratory tract infections, bronchitis, bronchiolitis, respiratory syncytial virus, and COVID-19.
Infections not otherwise specified include urinary tract infections, gastroenteritis, pharyngitis, fever unspecified, viral syndrome, tonsillitis, otitis media, sinusitis, impetigo, cellulitis, infected wound, lymphadenopathy cervical, herpangina, febrile seizure, meningitis, sepsis, bacteremia, encephalitis, pancreatitis, myositis, conjunctivitis, myocarditis, Guillain-Barré syndrome, mononucleosis, and pyelonephritis.
** Among persons with available body mass index. Influenza A (n = 2,917), influenza B (n = 1,430), respiratory syncytial virus (n = 1,167), adenovirus (n = 1,037), human parainfluenza virus 1 (n = 282), human parainfluenza virus 3 (n = 780), human metapneumovirus (n = 651), human coronavirus (n = 17), and SARS-CoV-2 (n = 1,437).
†† Denominators for these analyses include visits from women of childbearing age defined as any female aged 15–44 years.

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Suggested citation for this article: Madewell ZJ, Hernandez-Romieu AC, Wong JM, et al. Sentinel Enhanced Dengue Surveillance System — Puerto Rico, 2012–2022. MMWR Surveill Summ 2024;73(No. SS-3):1–29. DOI: http://dx.doi.org/10.15585/mmwr.ss7303a1.

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