Deaths and Hospital Injuries Due to the 1999 Taiwan Earthquake ()
1. Introduction
On 21 September 1999, at 1 h 47 m, an earthquake of magnitude 7.3 on the Richter scale struck the central area of Taiwan [1]. As a result of the earthquake, more than 100,000 houses were collapsed, 2347 people died, and more than 8000 were injured all over the island, of whom approximately 700 were seriously injured [2].
A number of past investigations of related morbidity and mortality have reported associations of deaths and injuries with seismic factors [3-7], structural factors [8-13], injury characteristics [14-17], personal characteristics [18- 23], and victim behavior and preparation [24-35].
The ground motion intensity correlated with poor antiseismic houses increased the risk of death as found in the 1999 Taiwan earthquake [5,13,36]. The mortality was higher among the female, disabled, and the elderly groups [5,15,22]. Chan suggested that precise disaster planning and management were necessary to improve the disaster responses [12]. Two studies described about the characteristics of non-fatal injuries for the victims of the disaster [32,34]. The victims were also more vulnerable to have posttraumatic outcomes following the 1999 Taiwan earthquake [37-44]. The suicide trends declined after two years by the proving strengthened psychiatric services [45]. No further studies have discussed the relationship between injury characteristics and victim behavior and response in the emergency period. To improve preparedness for earthquakes, we must rely on more knowledge about factors related to deaths and injuries. The goal of the first investigation was to understand the roles of structural, injury, and demographic characteristics played in earthquake-related deaths and injuries. The second investigation using base of a case-control study, was to understand of structural factors, medical assistance, personal characteristics, victim behavior and preparedness that contributed to physical injury.
2. Methods
2.1. Study Area and Subjects
Selected the Nantou County as the area of study subjects because the most severe destruction occurred in Nantou County that near the epicenter. Moreover 11 out of the total 13 townships in Nantou were within the strongest earthquake intensity area (earthquake intensity 7 = peak ground acceleration >400 gal). There were 824 people killed, and 2421 people injured. Age-specific population data from August 1999 were used as the standard population.
2.2. Collapsed Houses, Human Deaths and Injuries
Post-earthquake inspection data were obtained from the Architecture and Building Research Institute, Ministry of Interior. On the basis of architect-defined criteria, destroyed houses were categorized as either completely collapsed or partially collapsed. The degree of housing damage was used in many post-earthquake welfare and funding programs after the 1999 Taiwan earthquake.
Computerized data on earthquake-related deaths were retrieved from the Central Taiwan Office, Department of Health. These data included date of birth, gender, date of death, location, and cause of death coded by the International Classification of Diseases, Ninth Revision (ICD- 9).
The earthquake-related injuries were obtained from the Department of Public Health Bureau, Nantou County Government. These data were grouped according to ICD- 9 guideline, the relevant ICD codes were showed in the appendix.
There were two documents including serious injury and moderate injury. The serious injuries were defined as those patients whose injuries required hospitalization care with an extend follow-up of more than 30 days. The moderate injuries were defined as those patients whose injuries required hospitalization care less than or equal to 30 days. The local government provided 200 thousand Taiwan dollars for every serious injury and provided 50 thousand Taiwan dollars for every moderate injury respectively.
2.3. Case-Control Study
This study was begun in April 2002 and finished in December 2002. From detailed rosters of 271 severe injuries, 120 randomized cases were defined as study cases. For each of the cases, we selected a non-hospitalized control from a neighboring household. An effort was made to match the controls and cases according to sex and age within ±5 years. The ratio of cases versus controls was 1:2. After the variables of interest had been defined, a set of questions was formulated and a questionnaire was developed to a structural questionnaire. Personal interviews with structural questionnaire were conducted with the subjects by trained interviewers. The questionnaire was pre-tested on a sample of 15 cases and 15 controls, and validated by 8 experts. The questionnaire included structural information (completely collapsed, inside house, sleep in house, live alone, trapped), medical assistance (trapped time, received first medical care after extrication, rescuer of trapped victims), personal characteristics (illiteracy, unemployment, major disease before the earthquake, other family hurt), and behavior and preparedness (drill for disaster before the earthquake, evacuation road, put heavier objects in low places, put objectives in the doorway, prepare fire extinguishers, prepare flares, number of export escapes) following the earthquake. These questions were answered in a form of “yes” or “no”.
2.4. Statistic
These analyses focus on the types and body sites of injuries incurred by the residents as a result of the earthquake. Bivariate analyses were conducted to identify major trends among the three groups during the earthquake. Crosstabs with chi-square analysis were used to examine associations between variables. A conditional logistic regression analysis was adopted to assess the odds ratio of the statistically significant variable used in the case-control study. All variables were dichotomous without missing data. This analytic process was performed by using SPSS statistical software (SPSS Inc., Chicago, IL) for Window.
3. Results
Of all the 824 seismic deaths, 652 (79.1%) of the people died in their own houses, 83 (10.1%) died on their way to referral hospitals, 18 (2.2%) died in the referral hospitals, and 71 (8.6%) died in the evacuation area or the data were missing. There were 89.2% of the seismic deaths were not admitted to the emergency department of a hospital.
The injury documentation shows that a total of 2421 injuries were admitted to hospitals by transportation, 83 (3.4%) died on their way to referral hospitals, 591 (24.4%) required hospitalization and 1747 (72.2%) sustained only minor injury and were discharged after wound treatment. Among the 591 hospitalized injuries, 302 (51.1%) were defined moderate injuries, 271 (45.9%) were defined as serious injuries, and 18 (3.0%) were died in hospitals.
3.1. Demographic and Structural Characteristics
There were 545,181 people including 284,841 (52.2%) males and 260,340 (47.8%) females in the study area. Table 1 compares the basic demographic and collapsed houses information for the reported deaths, serious injuries, and moderate injuries following the Chi-Chi earthquake. Females were more likely to report death and injury than males but not significantly different (p < 0.05). From the distribution of age-specific death rates, it was found that the proportion of 65 years of age and older among the three injured subgroups were similar (death: 37.0%, serious injuries: 37.6%, moderate injuries: 36.1%). However, these proportions were all significantly higher than the proportion of people of 65 years of age and older in the general population (10.1%) (deaths: odds ratio
Table 1. Demographic and building characteristics of deaths and non-fatal injuries caused by the Chi-Chi earthquake, Nantou, Taiwan, 1999.
OR = 5.29, 95% confidence interval (CI): 2.45 - 11.41; serious injuries: OR = 5.52, 95% CI: 2.56 - 11.89; moderate injuries: OR = 5.06, 95% CI: 2.34 - 10.94).
The proportions of collapsed houses of the deaths (783/824 = 95.0%), serious injuries (241/271 = 88.9%), and moderate injuries (266/302 = 88.1%) were similar. For the collapsed houses, the completely collapsed occupied 94.5% (740/783) of the deaths, 63.9% (154/241) of the serious injuries, and 34.6% (92/266) of the moderate injuries, respectively. Compared to the moderate injuries, the crude odds ratios of completely collapsed houses were 32.55 (95% CI: 21.86 - 48.46) for deaths, and 3.35 (95% CI: 2.33 - 4.82) for serious injuries.
3.2. Injury Characteristics
Table 2 shows data related to the injury characteristics of deaths and non-fatal injuries. The distribution of types of injuries between the deaths and seriously injuries was different. Intracranial and internal injuries were the most frequently observed (43.4%), followed by asphyxiation, fracture, and early complication of trauma and unspecific injury (6.3%) of the deaths. Fracture (49.4%) was the most common type of injury, followed by open wounds, early complication of trauma and unspecific injury (12.9%), and burns (8.8%) of the serious injuries. Fracture (42.7%) was also the most frequently observed injury of the moderate injuries, followed by early complication of trauma and unspecific injury (27.8%), and open wounds (11.9%).
The prevalence of burns of the serious injuries (8.8%) was significantly higher than the prevalence of burns of the moderate injuries (1.0%) (OR = 9.79, 95% CI: 1.22 - 78.8).
The distribution of injured body sites among the deaths and non-fatal injuries in collapsed houses was shown in Table 3. Head was the major body site of deaths (37.8%). However, the major body site of non-fatal injuries was the extremities (32.5% of serious injuries, and 38.3% of moderate injuries). The proportion of head injury of the deaths was significantly higher than the proportion of head injury of the serious injuries (5.0%, OR = 11.60, 95% CI: 6.38 - 21.10), and of the moderate injuries (6.4%, OR = 8.90, 95% CI: 5.33 - 14.96), respectively. There was no difference in the proportion of head injury between the serious injuries and the moderate injuries (OR = 0.77, 95% CI: 0.36 - 1.64). The proportion of neck and trunk injury of the deaths (13.3%) was significantly lower than the proportion of neck and trunk injury of the serious injuries (21.6%, OR = 0.56, 95% CI: 0.38 - 0.81). There was no difference in the proportion of neck and trunk injury between the moderate injuries (16.5%) and serious injuries (OR = 1.39, 95% CI: 0.89 - 2.17), and the
Table 2. Types of injuries among the deaths and non-fatal injuries caused by the Chi-Chi earthquake, Nantou, Taiwan, 1999.
Table 3. Injured body sites among deaths and non-fatal injuries in the collapsed houses caused by the Chi-Chi earthquake, Nantou, Taiwan.
fatal cases (OR = 0.77, 95% CI: 0.53 - 1.13), respectively.
The proportion of extremities injury of the deaths (0.4%) was significantly lower than the proportion of extremities injury of the serious injuries (32.5%, OR = 0.01, 95% CI: 0.00 - 0.03), and of the moderate injuries (38.3%, OR = 0.01, 95% CI: 0.00 - 0.02), respectively. The proportion of extremities injury of the serious injuries was significantly lower than the proportion of extremities injury among the moderate injuries (OR = 0.67, 95% CI: 0.46 - 0.97). The proportion of multiple fractures of the deaths (0.3%) was significantly lower than the proportion of multiple fractures of the serious injuries (14.9%, OR = 0.02, 95% CI: 0.00 - 0.06), and of the moderate injuries (4.9%, OR = 0.05, 95% CI: 0.01 - 0.22), respectively. The proportion of multiple fractures of the serious injuries was higher than the proportion of multiple fractures of the moderate injuries (OR = 3.42, 95% CI: 1.77 - 6.62).
The proportion of unspecific trauma of the deaths (5.9%) was significantly lower than the proportion of unspecific trauma of the serious injuries (14.1%, OR = 0.38, 95% CI: 0.24 - 0.61), and of the moderate injuries (18.4%, OR = 0.25, 95% CI: 0.18 - 0.42), respectively. There was no difference in the proportion of unspecific trauma between the serious injuries and moderate injuries (OR = 0.73, 95% CI: 0.45 - 1.17).
3.3. Risk Factor Analysis for Serious Injuries and Controls by a Case-Control Study
Only records with values for all structural, medical assistance, personal, and behavior variables (n = 370) were included in the estimation (Table 4). In the structural characteristics, completely collapsed of cases had 11.44 times (95% CI: 6.86 - 19.08) the risk compared to controls. Most of the study subjects (cases: 94.8%; controls: 88.8%) were sleeping in the middle of the night in their houses. Individual lived alone at the time of earthquake of the cases (10%) experienced a significantly higher proportion than those of the controls (4%, OR = 2.67, 95% CI: 1.12 - 6.36). Of the cases, 78.3% had been trapped that was significantly higher than the proportion of been trapped of the controls (12.4%, OR = 25.54, 95% CI: 14.38 - 45.37). In the medical assistance characteristics, the proportion of trapped time within 6 hours were similar between the cases (80.85%) and the controls (80.65%, OR = 1.01, 95% CI: 0.36 - 2.83). The first medical care received after extrication within 8 hours for the cases (78.7%) and the controls (80.6%) were similar. The initial extrication and rescue work was most carried out by local inhabitants of the cases (92.6%). This proportion was significantly higher than the controls (41.9%) (OR = 17.21, 95% CI: 6.02 - 49.16).
In the personal characteristics, the cases contained a greater percentage of unemployment (19.2%), illiteracy (27.5%), and possession of cars with major disease (12.5%) than the controls (5.2%, OR = 7.17, 95% CI: 3.01 - 16.59; 5.2%, OR = 11.47, 95% CI: 5.10 - 25.80; 3.2%, OR = 2.60, 95% CI: 1.20 - 5.67), respectively. The proportion of more than one victim in a family was higher in the cases than in the controls (82.5% versus 12.4%; OR = 33.30, 95% CI: 18.23 - 60.85). In the behavior and preparedness, there were lower prepared measures for disasters of the cases than of the controls, such as lower proportions of disaster drills (5.0% versus 14.0%; OR = 3.09, 95% CI: 1.26 - 7.57), putting heavier objects in low places (5.8% versus 22.8%; OR = 4.77, 95% CI: 2.10 - 10.81), not putting objects in doorways (6.7% versus 66.0%; OR = 27.18, 95% CI: 12.66 - 58.32), preparedness of extinguishers (8.3% versus 28%; OR = 10.39, 95% CI: 5.26 - 20.52), and preparedness of flares (14.1% versus 56.9%; OR = 3.47, 95% CI: 1.95 - 6.16).
We put above significant variables into conditional logistic regression analyses. The results identified only four significant risk factors for the serious injuries (Table 5). The highest risk was being trapped (OR = 12.31, 95% CI: 6.29 - 24.28), followed by illiteracy (OR = 7.65, 95% CI: 2.67 - 21.90), houses completely collapsed (OR = 4.55, 95% CI: 2.26 - 9.16), and lack of preparedness of flares (OR = 2.50, 95% CI: 1.10 - 6.25).
4. Discussion
The age-specific proportions of fatal and non-fatal injuries victims were higher among the elderly (65 + years of age). These patterns reflected that although the elderly occupied 10% of the total population, injured seniors occupied about 37% of the total population. The distributions of the age-specific mortality and morbidity caused by the Chi-Chi earthquake were similar to the conditions of the Armenia earthquake, Northridge earthquake, and Hanshin-Awagi earthquake [19,21,29].
There were 89.2% of the seismic deaths were not admitted to the emergency department of hospitals. The asphyxiation and intracranial injury occupied 77% of caused deaths. These results imply incomplete or inadequate resuscitation, and control of hemorrhage before or during transportation. Aggressive and directed management of the pulmonary system coupled with prompt recognition and control of hemorrhaging due to associated injuries is essential for optimal patient outcome.
Higher crude odds ratios were observed for victims in completely collapsed houses in the deaths and the serious injuries groups. This suggests that the higher the house damage occurred, the higher the victim were casualty. Other studies also confirmed the risk presented by dilapidated
buildings demonstrated in previous studies [12,19,35]. Forensic evidence indicates that intracranial and internal injuries for the crush of the head and trunk, and asphyxiation caused by acute obstructive pulmonary accounted for 77% of the deaths in the completely houses. These reflect that the primary cause of death was the complete collapse of houses. Intracranial, spine, intrathoracic, and visceral injuries as injuries to vital organs cause casualties resulting from earthquake injuries.
Comparing of the body sites of injuries, the proportion of multiple fractures and burns were higher of the serious injuries than of the moderate injuries, respectively. These results imply that the more the sites of injuries which occurred, the greater the severity of injuries occurred. The victims with spine and back injuries were fewer than the victims with trunk injuries in all the 3 study groups. Maruo et al. has demonstrated that if the patients are standing or sitting at the time of injury, the most frequently observed fractures are those of the vertebral column and if the patients are lying in supine or lateral positions at
Table 5. Results of conditional logistic regression analyses, Chi-Chi earthquake, Nantou, Taiwan, 1999.
the time of the earthquake, most fractures are those of the pelvis and thoracic cage skeleton [46]. Most of he study subjects were sleeping in the middle of the night in their houses from the interview results. Therefore, our study strongly agreed with the findings of Maruo et al. The victims with upper extremities injuries were fewer than the victims with lower extremities injuries in all the 3 study groups. Naghi et al. suggested that the injuries of upper or lower extremities may have to do with the time of day that the earthquake occurred. In the dark, respondents cannot see the objects that they trip or fall over and it is easy to injury the lower extremities, whereas in the light, victims were more likely to be upright and be struck by falling objects and it is easy to injury the upper limbs [16]. Such a relation was also observed in our study cases.
The cases seemed to be lower socioeconomic status such as, illiteracy, more unemployment, and possession of major disease cars than the controls. The illiteracy showed to be the predominant odd ratio of socioeconomic status compared to the controls. Owing to the lower socioeconomic status, the cases had poor safety knowledge and preparedness, such as disaster drills, putting heavier objects in low places, not putting objects in doorways, preparedness of extinguishers, and preparation for flares for the disasters expectantly. More than one victim in a family was higher of the study cases than of the controls. The sign implied that there was a significant family cluster in the serious injuries group.
In the conditional logistic regression analyses, the results clearly demonstrate that been trapped, completely collapsed houses, illiteracy, and no flares preparation for disasters were the most important risk factors. These findings implied the trapped and completely collapsed as the structure characteristics, illiteracy as the personal characteristic, and unprepared the flares as the preparation characteristic that all could increase the risk of serious injury in the 1999 Chinese Taipei earthquake. Liao et al. and Ellidokuz et al. indicated that poor seismic capacity was the major factor that caused great loss of lives [13,35]. Osaki et al., and Peek-Asa et al. implied older adults, physical disabilities, and completely destroyed dwellings could increase the mortality among people [21, 47]. Chou et al., Doocy et al., and Mahue-Giangreco et al. demonstrated that health and socioeconomic statuses were the most relevant factors to earthquake injury and mortality [22,23,48]. The low socioeconomic status of victim was also a risk factor of PTSD after the earthquakes. Seplaki et al. indicated the low socioeconomic status reported higher levels of depressive symptoms [40]. Chen et al. indicated the low educational level was a risk factor of psychological outcome of 1999 Chinese Taipei earthquake survivors [42]. Our study suggests that poor earthquake resistant building and lower socioeconomic status are both related to the serious injuries among people. Literacy education is a basic method to enlarge the knowledge and improve the occupational skill. When an illiteracy is educated to be a literacy, he will get more safety knowledge and be a proper behavior to prevent and prepare for the disasters.
After the 1999 Chinese Taipei earthquake, the Central Government established the institution “The Chi-Chi Earthquake Post-Disaster Reconstruction Commission” that utilized several reconstructing policies such as urban planning, new community construction, and implementation of disaster prevention, rescue, and emergency medical services. After the practice of reconstruction, there were many improvements in the disaster areas such as, the percentage of reinforced concrete area increased from 93.78% in 1997 to 99.17% in 2010, the percentage of illiterate population decreased from 5.71% in 1997 to 1.98% in 2010, and the number of ambulances increased from 12 in 1997 to 29 in 2010 [49].
This study was limited by the sample selection. The number of fatalities and hospitalizations comprised a small proportion of the overall number of injuries. These diverse reports demonstrate the difficulty in determining the incidence of injury following a major disaster.
5. Conclusion
Physical injuries are correlated with house collapse and victim behavior at the time of earthquake impact. This study suggested that improvements in anti-seismic construction, head protection, and literacy education could decrease the effect of disaster. Further, using a flashlight to see in the dark, and moving slowly rather than running should be rigorously recommended as common-sense responses.
6. Acknowledgements
This work was supported by grant MOIS 902031 from the Architecture and Building Research Institute Ministry of Interior.
Appendix