key: cord-0693031-fwywa3tu
authors: Sugimura, Mana; Chimed-Ochir, Odgerel; Yumiya, Yui; Taji, Akihiro; Kishita, Eisaku; Tsurugi, Yoko; Kiwaki, Koji; Wakai, Akinori; Kondo, Hisayoshi; Akahoshi, Kouki; Chishima, Kayoko; Toyokuni, Yoshiki; Koido, Yuichi; Kubo, Tatsuhiko
title: Incidence of Acute Respiratory Infections during Disasters in the Absence and Presence of COVID-19 Pandemic
date: 2022-01-11
journal: Prehosp Disaster Med
DOI: 10.1017/s1049023x22000085
sha: 424002e0492bbfd4299359da47ef02da2bfdca57
doc_id: 693031
cord_uid: fwywa3tu

INTRODUCTION: Japan recently experienced two major heavy rain disasters: the West Japan heavy rain disaster in July 2018 and the Kumamoto heavy rain disaster in July 2020. Between the occurrences of these two disasters, Japan began experiencing the wave of the coronavirus disease 2019 (COVID-19) pandemic, providing a unique opportunity to compare the incidence of acute respiratory infection (ARI) between the two disaster responses under distinct conditions. SOURCES FOR INFORMATION: The data were collected by using the standard disaster medical reporting system used in Japan, so-called the Japan-Surveillance in Post-Extreme Emergencies and Disasters (J-SPEED), which reports number and types of patients treated by Emergency Medical Teams (EMTs). Data for ARI were extracted from daily aggregated data on the J-SPEED form and the frequency of ARI in two disasters was compared. OBSERVATION: Acute respiratory infection in the West Japan heavy rain that occurred in the absence of COVID-19 and in the Kumamoto heavy rain that occurred in the presence of COVID-19 were responsible for 5.4% and 1.2% of the total consultation, respectively (P <.001). ANALYSIS OF OBSERVATION AND CONCLUSION: Between the occurrence of these two disasters, Japan implemented COVID-19 preventive measures on a personal and organizational level, such as wearing masks, disinfecting hands, maintaining social distance, improving room ventilation, and screening people who entered evacuation centers by using hygiene management checklists. By following the basic prevention measures stated above, ARI can be significantly reduced during a disaster.

The rate of disaster has increased over the past several decades. Floods account for 40%-50% of all disasters and disaster-related deaths world-wide 1,2 and have widespread social and health impacts. Floods accounted for 14% of total disaster events in Japan from 1985 through 2018. 3 However, according to Japan's Meteorological Agency (Minato City, Tokyo, Japan), annual rainfall of 50mm per hour has increased 1.4-times in the last 30 years, 4 making emergency response a critical issue in the country.

Japan recently experienced two major heavy rain disasters: the West Japan heavy rain disaster in July 2018, which claimed 263 lives, left eight people missing, and injured 484 people; 5 and the Kumamoto heavy rain disaster in July 2020, which claimed 84 lives, left two people missing, and injured 80 people. 6 In terms of population density, 7-11 average temperature, 12 and humidity 13 in the rainiest month (July), these two locations are similar, though Kumamoto Prefecture had higher rainfall than West Japan in 2018 14 (Table 1 ). In the time between these two disasters, Japan began experiencing the first wave of the coronavirus disease 2019 (COVID-19) pandemic, providing a unique opportunity to compare the incidence of acute respiratory infection (ARI) between the two disaster responses in the presence of different pandemic and response conditions. Thus, the current study aims to describe the differences in the frequency of ARI in the 2018 West Japan heavy rain disaster in the absence of COVID-19 and the 2020 Kumamoto heavy rain event in the presence of COVID-19.

The data were collected by using the standard medical reporting form and system used in Japan, so-called the Japan-Surveillance in Post-Extreme Emergencies and Disasters (J-SPEED). 15 Deployed Emergency Medical Teams (EMTs) used the J-SPEED form to report the number and types of patients treated on that day to the EMT Coordination Cell (EMTCC). The data for the West Japan heavy rain disaster were collected from July 8 -September 11, 2018 and the data for the Kumamoto heavy rain disaster were collected from July 5 -July 31, 2020.

In the current study, ARI data from daily aggregated data on the J-SPEED form were extracted. Fischer test was used to see if there was a difference in the frequency of ARI in two hydrological disasters among people of all ages, children, adults, and the elderly. Microsoft Excel (Microsoft Corp.; Redmond, Washington USA) and STATA v15.1 (STATA Corp.; College Station, Texas USA) were used for analysis.

Approval for ethical review was obtained from Hiroshima University (Hiroshima, Japan), 2020 (approval number: E-2059).

The two disasters currently being studied are both heavy rains followed by flooding, which are hydrological disasters. During the heavy rains of 2018 West Japan and 2020 Kumamoto, respectively, 85 and 80 EMTs provided medical consultation for 41 and 27 days, respectively, from July 8 through September 11, 2018 and July 5-31, 2020 (Table 1) . Table 2 depicts the frequency of ARI during the two disasters. A total of 3,620 consultations were conducted in the West Japan heavy rain, while 816 consultations were conducted within the period of the Kumamoto event. Acute respiratory infection in the West Japan and the Kumamoto disasters was responsible for 5.4% and 1.2% of the total consultations, respectively (P <.0001).

When compared to the Kumamoto heavy rain event (0.7%), the frequency of ARI in adults (15-64 years old) was significantly higher in the West Japan heavy rain (4.4%; P = .001). There was also a significant difference in the frequency of ARI in elders in the West Japan heavy rain event (6.0%) compared to the Kumamoto heavy rain event (0.6%; P <.0001). No significant difference was found in ARI frequency among children (P = .94).

The current study found a significant decrease in the frequency in ARI in the Kumamoto heavy rain disaster compared to that of West Japan. The Kumamoto disaster occurred in July 2020, during which time Japan was experiencing the first wave of the COVID-19 pandemic. As a result, during this time period, Japan implemented COVID-19 preventive measures on a personal and organizational levels, such as wearing masks, disinfecting hands and surfaces, maintaining social distance, and improving room ventilation. Hygiene management checklists were used to control the hygiene environment at the evacuation centers at Hitoyoshi Public Health Center in Kumamoto Prefecture, and a medical thermometer, acrylic panels, and hand sanitizers were placed at the reception desk to screen people who entered evacuation centers.

Furthermore, the evacuation shelters were designed in such a way that social distance was maintained. 16 There were no confirmed cases of COVID-19 among evacuees. The significant difference in ARI incidence may have been reflected by COVID-19 prevention measures. It can also be stated that any type of ARI can be avoided by taking precautionary measures such as wearing masks and organizing evacuation centers in such a way that social distance is maintained during disasters. Children aged zero to 14 years old, on the other hand, showed no significant difference. It could be that children are less likely to follow preventive measures including wearing masks than adults and elders, 17 and that the mask was not as effective in children as in adults, which could be due to the fit of the masks on their smaller faces. 18 Furthermore, it is highly likely that children do not maintain a social distance when they are playing. The World Health Organization (WHO; Geneva, Switzerland) stated that children aged five years and under should not be required to wear masks. The WHO also advised that the decision to use masks for children aged six to 11 years should be based on the ability of a child to safely and appropriately use a mask and the infection situation in the area. 19 Effective preventive measures of ARI among children require further research.

A significant reduction in ARI was observed during heavy rain events that occurred in the presence of COVID-19 compared to those that occurred in the absence of COVID-19. Thus, preventive measures against COVID-19 can substantially reduce incidence of ARI during a disaster. 

The public health impact of hurricanes and major flooding

The OFDA/CRED International Disaster Database. Disaster Profiles. Centre for Research on the Epidemiology of Disasters web site

The Small and Medium Enterprise Agency. Impact of natural disasters on SMEs

Japan's Meteorological Agency web site

Japan's Fire and Disaster Management Agency web site

Japan's Fire and Disaster Management Agency web site

Population Survey of Hiroshima Prefecture

Population of Okayama Prefecture. Summary of Population Census in Okayama Prefecture

Estimated population of prefecture

Population of Kumamoto Prefecture

Geographic area of prefectures, cities, towns, and villages of Japan

Monthly value for humidity

Monthly value for rainfall

Standard Disaster Medical Record -Report. Joint Committee for Disaster Medical Record of Japan web site

Japan's Fire and Disaster Management Agency web site

Presented at: first press seminar by researchers of novel coronaviruses

Professional and home-made face masks reduce exposure to respiratory infections among the general population

COVID-19): children and masks. World Health Organization web site