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. 2018 Aug 28;146(16):2059–2065. doi: 10.1017/S0950268818002315

Excess mortality in Guadeloupe and Martinique, islands of the French West Indies, during the chikungunya epidemic of 2014

A R R Freitas 1,, P M Alarcón-Elbal 2, M R Donalisio 3
PMCID: PMC6453005  PMID: 30152293

Abstract

In some chikungunya epidemics, deaths are not completely captured by traditional surveillance systems, which record case and death reports. We evaluated excess deaths associated with the 2014 chikungunya virus (CHIKV) epidemic in Guadeloupe and Martinique, Antilles. Population (784 097 inhabitants) and mortality data, estimated by sex and age, were accessed from the Institut National de la Statistique et des Études Économiques in France. Epidemiological data, cases, hospitalisations and deaths on CHIKV were obtained from the official epidemiological reports of the Cellule de Institut de Veille Sanitaire in France. Excess deaths were calculated as the difference between the expected and observed deaths for all age groups for each month in 2014 and 2015, considering the upper limit of 99% confidence interval. The Pearson correlation coefficient showed a strong correlation between monthly excess deaths and reported cases of chikungunya (R = 0.81, p < 0.005) and with a 1-month lag (R = 0.87, p < 0.001); and a strong correlation was also observed between monthly rates of hospitalisation for CHIKV and excess deaths with a delay of 1 month (R = 0.87, p < 0.0005). The peak of the epidemic occurred in the month with the highest mortality, returning to normal soon after the end of the CHIKV epidemic. There were excess deaths in almost all age groups, and excess mortality rate was higher among the elderly but was similar between male and female individuals. The overall mortality estimated in the current study (639 deaths) was about four times greater than that obtained through death declarations (160 deaths). Although the aetiological diagnosis of all deaths associated with CHIKV infection is not always possible, already well-known statistical tools can contribute to the evaluation of the impact of CHIKV on mortality and morbidity in the different age groups.

Key words: Arboviruses, chikungunya virus, modelling, mortality, vectors

Introduction

The mosquito-borne chikungunya virus (CHIKV) affects human health worldwide and is transmitted mainly through the vectors Aedes aegypti and Ae. albopictus. From its discovery in 1953 in the Newala district of Tanganyika (present-day Tanzania), until the first years of the 21st century, CHIKV was recognised as an arbovirus that caused small outbreaks in Asia and Africa and had high attack rates but low case fatality rates. After 2005, there was a significant increase in the number of cases and an expansion in the transmission area in several regions of the world, which included continental Europe after 2007 [1, 2]. During 2005–2006, a major epidemic hit the Réunion Island, a French overseas region located in the Indian Ocean, where severe cases and deaths were reported [36]. In 2006, the island had an estimated 266 000 symptomatic patients and 255 deaths, with a fatality rate of one death per 1000 cases. Since then, several fatal cases have been described in the literature [712].

At the end of 2013, an autochthonous transmission of CHIKV was identified in Saint Martin, Guadeloupe and Martinique [13]. The transmission quickly spread through almost all the islands of the Caribbean and continental America. By the end of the 2014 epidemic, 1 118 578 CHIKV cases were reported in the Americas with 194 deaths, which were reported to Pan American Health Organization (PAHO), which resulted in a lethality rate of 0.02% which is much lower than what was reported in the literature [14]. Ae. aegypti was the suspected vector of the arbovirus because of the absence of Ae. albopictus on these islands. In fact, a recent study has shown that for the first time, CHIKV infections occurred in natural populations of Ae. aegypti on Martinique [15].

By the end of the epidemics in Guadeloupe and Martinique, 153 400 CHIKV cases were reported out of estimated 306 800 symptomatic patients [16]. Considering these data, the fatality rates in Guadeloupe and Martinique would be 0.04% and 0.06%, respectively, which are both half of the fatality rate observed in Réunion Island in 2006. Because in 2006, elderly individuals accounted for 9.6% of the population in Réunion Island and in 2014, they accounted for 15.7% and 17.6% of the population in Guadeloupe and Martinique [17], respectively, and because CHIKV deaths occur at more advanced ages, higher mortality would have been expected in Martinique and Guadeloupe (2014) than in Réunion (2006).

In Réunion Island, excess deaths during the CHIKV epidemic were estimated at 267 [18], which were very close to the 255 deaths that were recorded in the death certificates. However, these findings were different from those reported in Brazil, Ahmedabad, the Andaman and Nicobar Islands (belonging to India) and Mauritius, where a significant number of excess deaths did not coincide with those reported in the epidemiological surveillance system [1923]. Thus, there are some inconsistencies in the estimated mortality data being reported in CHIKV circulation regions.

The objective of this study was to assess excess deaths by sex and age in the Guadeloupe and Martinique Islands during the 2014 CHIKV epidemic using official data from the Institut National de La Statistique et des Études Économiques (INSEE). We hypothesise that there may have been excess deaths above the number of deaths identified by certificates.

Methods

A time series study of reported CHIKV incidence rates and mortality by sex and age group was conducted in Guadeloupe and Martinique in the period between 2011 and 2015.

Locality

Guadeloupe and Martinique are French overseas regions in the Caribbean and are islands of tropical climate (Classification Af according to the Köppen Climate System) located in the Lesser Antilles of the French West Indies. In 2014, Guadeloupe and Martinique had populations of 400 186 and 383 911 inhabitants, respectively [17]. We analysed the two French overseas regions together because they had similar climate, similar epidemiological and sociodemographic profiles and practically simultaneous CHIKV epidemics [16].

Data collection

Estimated by sex and age group, population and mortality data were accessed from the INSEE of the French government [24]. Epidemiological data on CHIKV, including number of cases, hospitalisations and deaths, were obtained in the official epidemiological reports of the Cellule de Institut de Veille Sanitaire (InVS) en Région (English Regional Office of the French Institute for Public Health Surveillance) [16]. As the influenza virus is known to be a cause of seasonal increases in overall mortality, we also extracted monthly influenza-like syndrome data reported to sentinel surveillance systems from the bulletins of InVS [25, 26]. Numerical data were extracted from the graphs of bulletins using the program Engauge Digitizer [27].

Statistical analysis

We calculated both monthly and annual age-specific mortality rate (ASMR) by sex from 2010 to 2013. The monthly number of expected deaths for 2014 and 2015 by age group and sex was calculated using the average mortality rates of each month of the reference period for the estimated population of the French regions of Guadeloupe and Martinique in 2014 and 2015. The reference period used was the 3 years prior to 2013, in which no transmission was reported in the study areas [28, 29]. For each month in 2014 and 2015, excess deaths were calculated as the difference between the monthly observed deaths and monthly expected deaths for all ages. The expected deaths by age group were calculated based on an average of ASMR of the reference years (2011–2013) applied using the estimated population of 2014. We also calculated a conservative 99% confidence interval (CI) for the monthly deaths (2014–2015) and total deaths for each sex and age group (2014).

The standardised mortality ratio (SMR) was calculated by dividing the monthly observed deaths by the monthly expected deaths. This value was compared with the null hypothesis (SMR = 1.00) according to formula (1) of the z score [30]:

graphic file with name S0950268818002315_eqn1.jpg 1

where n = observed deaths and A = expected deaths.

Statistical analysis was performed using IBM® SPSS® 24.0 software.

Results

CHIKV epidemic curve and monthly deaths

The monthly reported cases of CHIKV diagnosed by sentinel doctors, number of hospitalisations and excess deaths in 2014 in Guadeloupe and Martinique are presented in Table 1. The 2014 estimates of clinical cases of CHIKV in Guadeloupe and Martinique reported by InVS are also given. There was a strong correlation between the monthly incidence rates of CHIKV and excess deaths (R = 0.81, p < 0.005), and the correlation was even higher with a 1-month lag between CHIKV cases and excess deaths (R = 0.87, p < 0.001) (Table 1). We observed a strong correlation between monthly hospitalisation rates for CHIKV and excess deaths with a delay of 1 month (R = 0.87, p < 0.0005), while a moderate correlation was found between monthly hospitalisation rates and excess deaths (R = 0.66, p < 0.05) (Table 1).

Table 1.

Monthly cases of chikungunya, influenza-like illness, excess deaths and SMR (Guadaloupe and Martinique, 2014)

Chikungunya cases (clinically diagnosed – sentinel physicians) Total of estimated chikungunya clinical cases Hospitalisation Influenza-like illness (sentinel surveillance) Excess deaths SMR SMR 95% CI p-Value
Jan 2161 4322 65 5608 5 1.01 (1.00–1.02) 0.418
Feb 4102 8204 101 5475 −12 0.97 (0.96–0.98) 0.712
Mar 7924 15 848 138 5136 13 1.03 (1.01–1.03) 0.286
Apr 18 254 36 508 258 3260 40 1.08 (1.07–1.09) <0.05
May 27 471 54 942 323 897 61 1.12 (1.11–1.13) <0.005
Jun 37 936 75 871 315 816 159 1.31 (1.30–1.31) <0.000001
Jul 26 197 52 395 260 610 105 1.19 (1.18–1.20) <0.00001
Aug 12 716 25 432 198 570 105 1.20 (1.19–1.21) <0.00001
Sep 7891 15 782 125 743 49 1.10 (1.09–1.10) <0.01
Oct 5871 11 742 59 1983 47 1.09 (1.08–1.09) <0.05
Nov 2326 4652 37 1857 36 1.08 (1.07–1.08) 0.054
Dec 851 1702 10 1547 31 1.06 (1.05–1.07) 0.089
Total 153 700 307 400 1888 639
Correlation (Pearson) with monthly excess deaths Without lag R 0.806 0.664 −0.76a
p <0.005 <0.05 <0.005
1 month lag R 0.868 0.872 −0.66a
p <0.001 <0.001 <0.05
2 month lag R 0.639 0.763 −0.197
p <0.05 <0.05 0.586
a

Without biological plausibility.

Figure 1 shows the number of observed deaths, the number of expected deaths per month and the upper limit of the 99% CI in Guadeloupe and Martinique for 2014–2015, and it also presents the number of monthly cases of CHIKV estimated by InVS. The peak of the epidemic was in June and coincided with the peak of deaths. Excess deaths remained above the 99% CI for April–November, which is the period with the highest incidences of CHIKV. In the months with a small number of CHIKV cases in 2014 (January–March and December) and in 2015, the number of monthly deaths was below the upper limit of the 99% CI.

Fig. 1.

Fig. 1.

Cases of chikungunya, expected and observed monthly deaths and 99% CI upper limit (Guadeloupe and Martinique 2014–2015).

Mortality by sex and age group

Except for the <19-year age group, all other age groups had a higher number of deaths than expected. ASMR was above the upper limit of the 99% CI in both sexes (Fig. 2) and in all age groups above 20 years of age, with the exception of the 40–59-year age group (Table 2). Excess deaths increased with age in both sexes. In 2015, ASMR was lower than that in 2014 and was below the upper limit of the CI in all age groups.

Fig. 2.

Fig. 2.

Excess deaths and excess mortality rate by sex and age group (Guadeloupe and Martinique, 2014).

Table 2.

Population, mortality data, observed and estimated by age group in Guadaloupe and Martinique (2014)

Population by age group (2014) Observed deaths (2014) [1] Expected deaths (2014) [2] Observed ASMR for 2014 [1] Observed ASMR for 2015 Upper limit 99% CI ASMR, mean (2011–2013) [2] Excess deaths Official data of deaths due to chikungunya a Excess ASMR ([1] − [2])
0–19 years 154 092 109 124 70.7 67.8 91.0 80.5 −15 −9.7
20–39 years 159 195 200 160 125.6 109.8 111.8 100.5 40 25.1
40–59 years 291 942 764 733 261.7 258.2 264.8 251.1 31 10.6
60–69 years 88 272 816 764 924.4 822.2 913.1 865.1 52 59.3
70–79 years 54 894 1233 1163 2246.1 1984.1 2212.9 2119.4 70 126.8
80–89 years 28 275 1949 1735 6893.0 5664.5 6359.4 6136.6 214 756.4
90 and more years 7427 1538 1291 20 708.2 16 841.6 18 124.8 17 378.1 247 3330.1
Total 784 097 6609 5970 639 160
Total of chikungunya cases 307 400
Excess mortality rate 81.5 20.4
Case fatality rate (deaths/1000 cases) 2.08 0.52

ASMR, age-specific mortality rate.

a

According to the death certificate listed chikungunya as a cause or contributing condition to death.

The underlined values are those referring to the age groups whose mortality was above 99% CI.

Overall excess deaths and fatality rate

During 2014, in Guadeloupe and Martinique, there were 639 excess deaths, which is four times greater than the number of deaths reported to InVS through death certificates. The excess mortality rate was 81.5 deaths per 100 000 inhabitants, and the case fatality rate in 2014 was estimated at 2.08 deaths per 1000 cases of CHIKV (Table 2).

Discussion

Time series analysis of deaths in the Guadeloupe and Martinique regions shows that mortality increased above the 99% CI during the CHIKV epidemic of 2014 and returned to normal soon after the end of the epidemic. In June, the peak of deaths occurred simultaneously with the peak of CHIKV cases. There was a strong temporal correlation between excess deaths, cases of CHIKV and hospitalisations. This correlation was stronger when we used 1 month of delay between clinically identified cases and deaths. This delay can be explained by prolonged hospitalisations before death [10]. The correlation between monthly hospitalisation rates and excess deaths reinforces this hypothesis. Excess mortality increased with age but did not occur only among older people; among people aged 20–39 years, there were excess deaths above the upper limit of the 99% CI. This same mortality pattern was observed in studies that reported CHIKV as a cause of death on death certificates [3] and in studies that used laboratory test results (RT-PCR, viral isolation or IgM) to confirm the disease [4, 7]. The 2014 excess mortality rate by age group in Guadeloupe and Martinique (Table 2) was very close to the CHIKV-specific mortality rate observed in Réunion in 2006 based on the declarations of deaths [3, 8]. These findings reinforce our hypothesis that increased mortality was associated with the CHIKV epidemic. The case fatality rate in the current study was 2.08 deaths per 1000 cases of CHIKV, which is practically twice the registered case fatality rate reported in Réunion (0.96 deaths per 1000 cases of CHIKV) in 2006 [3, 8]. These differences may be due to the fact that the proportion of older people in the French Antilles in 2014 was higher than that in Réunion Island in 2006.

There was no positive correlation between the increase in deaths and circulation of influenza virus, another frequent cause of increased overall mortality. There were no other phenomena in these islands that could be related to an increase in mortality during this period. There was an epidemic of dengue that began in mid-2013 and ended on March 2014 and April 2014 in Guadeloupe and Martinique, respectively, and there were no reports of other arboviruses [31, 32].

A total of 639 excess deaths were associated with CHIKV epidemic in 2014, which is four times higher than the number of CHIKV-caused deaths reported through death certificates. In the 2006 Réunion epidemic, the estimated excess was very similar to the number of deaths in which there was mention of CHIKV in death certificates as the basic or contributing cause [8, 18]. Because it was the first major epidemic in French territory, the aetiologic investigation and the detailed preparation of the death certificates may have been carried out more carefully by the health professionals. Considering that the InVS estimated the number of cases of symptomatic patients at 307 400, the estimated fatality rate was two deaths per 1000 cases, 10 times higher than the estimated fatality rate reported to PAHO by overall countries of Americas in 2014 [14]. In 2006, the fatality rate attributed to CHIKV in the Réunion Island was one death for 1000 CHIKV cases, and twice this rate was observed in the Antilles in 2014. This divergence probably was due to the difference in the age profile of the islands since the proportion of elderly people in the Antilles in 2014 was higher than the proportion of elderly people in Réunion in 2006 [8]. A published study evaluating excess mortality in India in 2006 posed the hypothesis that deaths could be linked to increased virulence related to mutations in the East/Central/South African lineage of CHIKV [20]. The current study found excess mortality to be associated with an epidemic of the Asian lineage of chikungunya suggesting that increased mortality during epidemics is a characteristic of the virus and not a consequence of mutations in a specific strain.

Although some researchers still consider that the deaths caused by CHIKV are rare [33], data from Martinique and Guadeloupe regions and others studies [3, 4, 19, 20, 23, 29, 34, 35] suggest the opposite. The lack of consensus on the possibility of CHIKV leading to serious manifestations may induce physicians not to attribute deaths to CHIKV in death certificates, leading to underreporting as noted in the current study. Recent studies carried out in the Antilles have shown that the elderly present an acute clinical picture that is different from the clinical picture of young people [4, 6, 36]. Another explanation for the difficulty in recognising CHIKV as the cause of death is the fact that many patients who die from chikungunya are carriers of chronic diseases such as cardiovascular diseases and diabetes [4, 12, 34] which may induce medical assistants to erroneously indicate the previous diseases as the basic cause of death on the death certificate. Many studies conducted in the Americas and other continents have shown that CHIKV can lead to severe illness and death in patients with and without previous chronic diseases and in the various age groups [4, 711]. Therefore, we suggest that public health authorities should be clearer in risk communication, recognising that CHIKV can manifest as severe forms and lead to death. Unclear messages from public health officials about the risk of death by CHIKV may lead the population to a false sense of security lead health professionals to neglect the potential severity of the disease by delaying hospitalisations, and discourage research in this field.

The main limitation of this study is associated with the ecological study design that is based on a temporal series of deaths with no aetiological definition of each death individually. Moreover, it is not appropriate to infer directly for the individual as the results were obtained at the population level. Other phenomena may have been responsible for this increase in overall mortality in Guadeloupe and Martinique. However, the temporal pattern and age at death are very similar to those found in epidemics that occurred in other localities, in which laboratory criteria were used to confirm cases. Our results are compatible with the association of CHIKV transmission with excess mortality and higher impact in the elderly. The lack of aetiological diagnosis of the infection may not mean that the disease does not increase risk of death. A situation similar to this is observed for influenza in which only a small number of deaths are diagnosed as such. Most influenza-related deaths result from secondary bacterial pneumonia or from decompensation of chronic diseases caused by viral infection and death is not classified as influenza on the death certificate. Thus, the impact of influenza on mortality is estimated by assessing the excess of influenza mortality [37, 38]. Using similar methodology to the current study, excess deaths due to influenza among those over 65 years of age are estimated at 73 deaths per 100 000 per year [37]. The excess deaths associated with a CHIKV epidemic are 324 per 100 000 inhabitants over 60 years or 4.4 times higher than the annual average of mortality associated with influenza [37].

Mortality rate and case lethality rate are very expressive indicators for assessing disease burden and are important for use in prioritising public health investments, including vaccine production. Official documents have stated that mortality associated with CHIKV is a rare, less important event that occurs only in the elderly population and that CHIKV participates only partially (not solely) in the cause of death [3941]. Studies in Réunion Island, India and the Americas have shown that a significant proportion of deaths occurred in chikungunya patients who had relatively common and non-severe conditions such as high blood pressure and diabetes, and even occurred in patients who did not have underlying diseases [4, 7, 9, 10, 33].

Between 2004 and 2015 in Guadeloupe and Martinique, 49 deaths were attributed to dengue and 171 550 cases were estimated resulting in a fatality rate of 0.29 deaths per 1000 cases [42]. According to official data from the InVS that considers death certificates, the number of deaths per CHIKV in Guadeloupe and Martinique in a single year is 3.3 times higher (160 deaths) than the accumulated dengue in 10 years and fatality rate almost twice as high (0.52 deaths per 1000 cases). The current study suggests that excess deaths associated with the CHIKV epidemic in a single year were 13 times greater than that accumulated in 10 years of dengue epidemics in the same locality, and the case fatality rate of CHIKV was 7.7 times greater than that of dengue.

Although it is not possible to make an aetiological diagnosis of all deaths associated with CHIKV infection, well-known statistical tools can contribute to an evaluation of the impact of this virus on mortality in different age groups, and these tools are currently used to assess deaths attributed to extreme weather phenomena and seasonal and pandemic influenza [38, 43, 44].

Understanding CHIKV epidemic's potential for morbidity and mortality in the most vulnerable populations may help health professionals during epidemics.

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