Severe Injuries from Low-height Falls in the Elderly Population

Hyeji Lee; Sun Hyu Kim; Sang Cheal Lee; Sunpyo Kim; Gyu Chong Cho; Min Joung Kim; Ji Sook Lee; Chul Han

doi:10.3346/jkms.2018.33.e221

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Lee, Kim, Lee, Kim, Cho, Kim, Lee, and Han: Severe Injuries from Low-height Falls in the Elderly Population

Original Article

Emergency & Critical Care Medicine

Journal of Korean Medical Science 2018; 33(36): e221.

Published online: 5 July 2018

DOI: https://doi.org/10.3346/jkms.2018.33.e221

Severe Injuries from Low-height Falls in the Elderly Population

Hyeji Lee¹

, Sun Hyu Kim¹

, Sang Cheal Lee¹

, Sunpyo Kim²

, Gyu Chong Cho³

, Min Joung Kim⁴

, Ji Sook Lee⁵

, Chul Han⁶

¹Department of Emergency Medicine, University of Ulsan College of Medicine, Ulsan University Hospital, Ulsan, Korea.

²Department of Emergency Medicine, College of Medicine, Chosun University, Gwangju, Korea.

³Department of Emergency Medicine, Hallym University School of Medicine, Kangdong Sacred Heart Hospital, Seoul, Korea.

⁴Department of Emergency Medicine, College of Medicine, Yonsei University, Seoul, Korea.

⁵Department of Emergency Medicine, School of Medicine, Ajou University, Suwon, Korea.

⁶Department of Emergency Medicine, School of Medicine, Ewha Womans University, Seoul, Korea.

Address for Correspondence: Sun Hyu Kim, MD. Department of Emergency Medicine, University of Ulsan College of Medicine, Ulsan University Hospital, 877 Bangeojinsunhwando-ro, Dong-gu, Ulsan 44033, Republic of Korea. stachy1@paran.com

Received 6 February 2018 Accepted 14 June 2018

The Korean Academy of Medical Sciences

(open-access):

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (https://creativecommons.org/licenses/by-nc/4.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Background

Falls from low-height can cause severe injuries in the elderly population. This study was conducted to determine characteristics of injuries from low-height falls.

Methods

We retrospectively review surveillance data on injured patients who presented to six emergency departments from January 2011 to December 2015. Study subjects were divided into severe group and non-severe group based on severity of injury. The general and clinical characteristics were compared between the two groups and analyzed factors related with severe injuries.

Results

Of 1,190 elderly patients, severe group comprised 82 patients (7%). The severe group was 2 years younger than the non-severe group. In the severe group, 61% was men and 34% in the non-severe group. In the non-severe, the injuries more commonly occurred at residential facilities and indoors than those in the severe group. Paid work during injury occurrence was 15%, and the more patients presented with non-alert consciousness in the severe group. The most common regions of major injury were head and neck in the severe group.

Conclusion

Paid work, non-alert consciousness, and major injury to head and neck are relating factors to severe injuries in the elderly population.

Graphical Abstract

Keywords: Elderly, Falls, Injury, Relating Factors

INTRODUCTION

Falls are a major cause of injury in all ages,1 and account for 10% to 15% of emergency department (ED) visits. Generally, falls from higher heights cause more severe injuries.2 3 In the elderly population, however, even falls due to low-energy mechanisms are associated with higher hospitalization rates, longer lengths of hospital stays, and higher rates of mortality compared with younger adults.4 5 6 By 2000, the Republic of Korea had become an aging society, with the elderly population increasing at the fastest rate in the world. According to the Korean Statistical Information Service (KOSIS), elderly people aged 65 or older will account for 14% of the Korean population in 2017 and 20% of the population by 2025. As the elderly population increases, the burden of geriatric diseases is also increasing within the community. In particular, fall injuries in the elderly population will be a major social issue,5 and lead to increased health care costs.7

The most effective means of reducing the incidence of any injury is prevention. Identifying characteristics and relating factors to severe fall injuries in the elderly population is necessary to select management targets and establish a prevention strategy.8 There have been many studies on injuries associated with low-velocity falls (LVF) or ground-level falls (GLF) in the elderly population5 9; however, studies on the characteristics and relating factors to severe injuries caused by low-height falls (LHF) are lacking.

This study was conducted to compare the characteristics of injuries from LHF and to identify relating factors to severe injuries in the elderly population.

METHODS

With support from the Korea Center for Disease Control and Prevention (KCDC), we retrospectively reviewed surveillance data on injured patients who presented to the EDs of six general hospitals from January 2011 to December 2015. LHF were defined as falls from a height of less than one meter.2 10 Only data from patients who were able to report the height of the fall were included in this study. All patients were 65 years of age or older and were divided into 2 groups based on severity of injury: severe group and non-severe group. The severe group included patients who required emergency surgery, were admitted to the intensive care unit (ICU), were transferred to another medical facility for specialized care, or were either pronounced dead on arrival or death at the ED. The remaining patients were placed in the non-severe group.2

First, the general and clinical characteristics of the severe group were compared with those of the non-severe group. General characteristics of the patients included age, age range (65–74, 75–84, and ≥ 85 years), season of injury occurrence, time of injury occurrence, location of injury occurrence, whether the injury happened indoors or outdoors, specific description of the indoor area, activities during injury occurrence, alcohol consumption, education level, and occupation status. Patients were also sorted into groups based on the season in which the injury occurred: spring (March–May), summer (June–August), autumn (September–November), and winter (December–February). The time of injury occurrence was divided into 6-hour intervals: 0:00 to 6:00, 6:00 to 12:00, 12:00 to 18:00, and 18:00 to 24:00. The location where the injury occurred was classified as a residential facility, medical facility, sports facility, transportation area, work place, public or commercial facility, or other outdoor area. The location of an indoor injury was subdivided into the kitchen, living room, room or bedroom, store (including a mall) or office, hospital room, or other area. Activities during injury occurrence were divided into paid work, unpaid work such as cooking and cleaning, sports or leisure, daily activities such as showering, bathing and shaving, and other activities. Education level was divided into elementary school or less, junior high school, high school, and college or higher. Occupation status was classified as employed and unemployed.

The clinical characteristics of the patients while they were in the ED included blood pressure, consciousness, mode of transportation to the ED, major injury region, excess mortality ratio-adjusted injury severity score (EMR-ISS), result of ED treatment, surgical treatment, and injury severity. Consciousness was classified simply as alert or non-alert. Mode of transportation to the ED was classified as public ambulance, transfer from another medical facility, and individual transportation. Major injury regions were divided into head and neck, thorax, abdomen, hip and thigh, and other extremity. The EMR-ISS is an injury severity scoring systems based on the International Statistical Classification of Diseases and Related Health Problems 10th Revision (ICD-10). Every injury registered in the ICD-10 code was graded on a scale of 1–5 using the calculated excess mortality ratio for all ICD-10 codes from the Korean national injury database. EMS-ISS was calculated as the sum of squares of three maximum severity grades.11 12 13 If several diagnoses were registered, only the main diagnosis was selected. Results of ED treatment were categorized as discharge from ED, transfer to another medical facility, admission to the general ward, admission to the ICU, or dead on arrival or death at the ED.

In addition, the gender specific subgroup analysis was performed to determine the different characteristics between men and women in injuries from LHF.

Statistical analysis

The χ² test, t-test, and Fisher's exact test were used to compare the severe versus non-severe group. Univariate logistic regression analysis was used using the significant variables (P < 0.2) from the univariate comparison analysis to identify factors related with severe injury in the elderly group. Multivariate logistic regression was performed using statistically significant variables (P < 0.05) from the univariate logistic regression. We excluded clinical variables that directly related to severe injury classification, such as the mode of transportation to the ED, the result of ED treatment and surgical treatment. The gender specific subgroup analysis was compared using the χ² test. All data were analyzed using the Statistical Package for the Social Sciences version 21.0 (IBM Inc., Somers, NY, USA), and P values < 0.05 were considered significant.

Ethics statement

This study was approved by the relevant Institutional Review Boards of Ulsan University Hospital (approval No. 2017-07-013). All data were analyzed anonymously. The requirement for informed consent was waived by the board.

RESULTS

During the study period, 1,190 patients were injured by LHF in the elderly population. The severe group consisted of 82 patients, accounting for approximately 7% of all patients. The mean age was 77 years in the non-severe group and 75 years in the severe group. Patients aged 65–74 years and 75–84 years had similar injury rates in the non-severe group; in the severe group, the most common age ranged was 65–74 years (56.5%). In both groups, the most common location of injury occurrence was a residential facility. However, the proportion of elsewhere except the residential facility was 35% higher in the severe group than 23% in the non-severe group. In the non-severe group, 85% of the patients were injured indoor and 72% in severe group; thus, LHF injuries that occurred outdoors were more likely to be classified as severe. The most common activity during which LHF injuries occurred was daily activities (77%), followed by unpaid work (8%) in the non-severe group, but daily activities (70%), and followed by paid work (15%) in the severe group. Alcohol consumption at the time of the injury was more frequent in the severe group (Table 1).

Table 1

General characteristics of LHF injuries in elderly patients based on the severity of injury

Variables		Non-severe (n = 1,108)	Severe (n = 82)	P value
Age, yr		77.1 ± 7.7	75.2 ± 7.2	0.033
Age range, yr (%)				0.012
	65–74	449 (40.5)	47 (57.3)
	75–84	450 (40.6)	24 (29.3)
	≥ 85	209 (18.9)	11 (13.4)
Gender, men (%)		376 (33.9)	50 (61.0)	0.000
Season of injury occurrence (%)				0.756
	Spring (March–May)	252 (22.7)	22 (26.8)
	Summer (June–August)	282 (25.5)	21 (25.6)
	Autumn (September–November)	324 (29.2)	20 (24.4)
	Winter (December–February)	250 (22.6)	19 (23.2)
Time of injury occurrence (%)				0.160
	00:00–06:00	135 (12.2)	7 (8.5)
	06:00–12:00	360 (32.5)	22 (26.8)
	12:00–18:00	363 (32.8)	26 (31.7)
	18:00–24:00	250 (22.6)	27 (32.9)
Location of injury occurrence (%)				0.010
	Residential facility	848 (76.7)	53 (64.6)
	Medical facility	102 (9.2)	10 (12.2)
	Sports facility	7 (0.7)	3 (3.7)
	Transportation area	47 (4.2)	7 (8.5)
	Work place	47 (4.2)	4 (4.9)
	Public or commercial facility	35 (3.2)	1 (1.2)
	Other outdoor area	20 (1.8)	4 (4.9)
Indoor or outdoor fall injury (%)				0.002
	Indoor	942 (85.0)	59 (72.0)	0.002
Specific indoor area (%)		n = 929	n = 59	0.544
	Kitchen	16 (1.7)	0 (0.0)
	Living room	157 (16.9)	11 (18.6)
	Room or bedroom	634 (68.2)	38 (64.4)
	Office or store	93 (10.0)	9 (15.3)
	Others	29 (3.1)	1 (1.7)
Activity during injury occurrence (%)				0.003
	Paid work	58 (5.2)	12 (14.6)
	Unpaid work	89 (8.0)	2 (2.4)
	Sports or leisure activity	65 (5.9)	5 (6.1)
	Daily activity	850 (76.9)	57 (69.5)
	Others	44 (4.0)	6 (7.3)
Alcohol consumption, No./total (%)		8/838 (1.0)	3/59 (5.1)	0.031
Education (%)		n = 60	n = 8	0.533
	Uneducated or elementary school	42 (70.0)	5 (62.5)
	Junior high school	9 (15.0)	1 (12.5)
	High school	7 (11.7)	1 (12.5)
	College or higher	2 (3.3)	1 (12.5)
Occupation (%)				0.506
	Employed	43 (9.2)	8 (11.8)
	Unemployed	423 (90.8)	60 (88.2)

Data are presented as means ± standard deviation (range).

LHF = low-height falls.

In the severe group, the fewer patients presented with alert consciousness at the ED than in the non-severe group. The most common mode of transportation to the ED was public ambulance (40%) in the non-severe group, and transfer from another medical facility (44%) in the severe group. As region of major injury, 35% of patients in the non-severe group and 71% in the severe group suffered injuries of the head and neck. After analyzing the results of ED treatment, most patients in the non-severe group (58%) were discharged from the ED and most patients in the severe group (70%) were admitted to the ICU. The patients who underwent surgery comprised 39% of the severe group compared with 7% of the non-severe group (Table 2).

Table 2

Clinical characteristics of LHF injuries in elderly patients based on the severity of injury

Variables		Non-severe (n = 1,108)	Severe (n = 82)	P value
Blood pressure, mmHg		n = 592	n = 51
	Systolic blood pressure	140.0 ± 25.4	137.9 ± 31.5	0.563
	Diastolic blood pressure	78.1 ± 14.2	79.1 ± 16.8	0.645
Consciousness at ED (%)		n = 493	n = 40	0.000
	Alert	480 (97.4)	29 (72.5)
	Non-alert	13 (2.6)	11 (27.5)
Mode of transportation to ED (%)		n = 1,104	n = 82	0.000
	Public ambulance	440 (39.9)	26 (31.7)
	Transfer from medical facility	199 (18.0)	36 (43.9)
	Individual transportation	465 (42.1)	20 (24.4)
Major injury region (%)				0.000
	Head and neck	391 (35.3)	58 (70.7)
	Thorax	66 (6.0)	3 (3.7)
	Abdomen	108 (9.7)	3 (3.7)
	Hip and thigh	300 (27.1)	14 (17.1)
	Extremity	243 (21.9)	4 (4.9)
EMR-ISS		9.7 ± 7.5 (n = 665)	10.4 ± 8.0 (n = 53)	0.520
Result of ED treatment (%)				0.000
	Discharge from ED	642 (57.9)	0 (0.0)
	Transfer to another medical facility	39 (3.5)	4 (4.9)
	Admission to general ward	427 (38.5)	15 (18.3)
	Admission to intensive care unit	0 (0.0)	57 (69.5)
	Death on arrival or death at ED	0 (0.0)	6 (7.3)
Surgery, No./total (%)		52/725 (7.2)	25/65 (38.5)	0.000

Data are presented as means ± standard deviation (range).

LHF = low-height falls, ED = emergency department, EMR-ISS = excess mortality ratio-adjusted injury severity score.

Results of the univariate logistic regression analysis demonstrated that severe injuries caused by LHF in the elderly population were more likely to occur in those aged 65–74 years compared with those aged more than 74 years. Other factors related with severe injuries were men vs. women, outdoor fall vs. indoor fall, paid work activity vs. daily activity, alcohol consumption, non-alert vs. alert consciousness at the ED, and head and neck vs. extremity as the major injury region. Based on the multivariate logistic regression analysis, elderly people injured by LHF were at greater relation of severe injuries if patients were injured during paid work, presented with non-alert consciousness at the ED, or if the major injury involved the head and neck (Table 3).

Table 3

Univariate and multivariate logistic regression analysis for relating factors to severe injury by a LHF in elderly patients

Variables		OR	95% CI
Univariate logistic regression
	Age range 65–74 yr vs. > 74 yr	1.971	1.252–3.103
	Gender, men vs. women	3.042	1.919–4.822
	Fall injury, outdoor vs. indoor	2.212	1.329–3.681
	Paid work vs. daily activity	3.085	1.568–6.071
	Alcohol consumption	5.558	1.435–21.530
	Consciousness at ED, non-alert vs. alert	14.005	5.774–33.972
	Head and neck vs. extremity as major injury region	9.012	3.231–25.136
Multivariate logistic regression
	Paid work vs. daily activity	8.777	1.124–68.528
	Non-alert vs. alert consciousness at ED	14.261	3.591–56.635
	Head and neck vs. extremity as major injury region	12.480	1.290–120.750

LHF = low-height falls, OR = odds ratio, CI = confidence interval, ED = emergency department.

In the gender specific subgroup analysis, men comprised 36% and women 64% in the elderly population. The most common time of injury occurrence was between 12:00 to 18:00 in men and between 06:00 to 12:00 in women. In both groups, the most common locations of injury were residential facilities, respectively 67.0% and 80.8%. The most patients were injured indoors; this was more in women (90%). Especially, LHF injuries occurred most commonly in a room or bedroom. In both groups, the most common activity was daily activity, but the second most common activity was paid work (12%) in men. In men, more patients were educated and employed than in women (Table 4). The most common major injury regions were head and neck followed by extremity in men and head and neck followed by hip and thigh in women. Severe injuries were more common in men compared with those in women (Table 5).

Table 4

General characteristics of LHF injuries in elderly men and women

Variables		Men (n = 426)	Women (n = 764)	P value
Age, yr		75.2 ± 7.3	77.9 ± 7.7	0.000
Age range, yr (%)				0.000
	65–74	226 (53.1)	270 (35.3)
	75–84	147 (34.5)	327 (42.8)
	≥ 85	53 (12.4)	167 (21.9)
Season of injury occurrence (%)				0.686
	Spring (March–May)	98 (23.0)	176 (23.0)
	Summer (June–August)	115 (27.0)	188 (24.6)
	Autumn (September–November)	124 (29.1)	220 (28.8)
	Winter (December–February)	89 (22.9)	180 (23.6)
Time of injury occurrence (%)				0.031
	00:00–06:00	56 (13.1)	86 (11.3)
	06:00–12:00	114 (26.8)	268 (35.1)
	12:00–18:00	152 (35.7)	237 (31.0)
	18:00–24:00	104 (24.4)	173 (22.6)
Location of injury occurrence (%)		n = 424	n = 764	0.000
	Residential facility	284 (67.0)	617 (80.8)
	Medical facility	34 (8.0)	78 (10.2)
	Sports facility	7 (1.7)	3 (0.4)
	Transportation area	34 (8.0)	20 (2.6)
	Work place	36 (8.5)	15 (2.0)
	Public or commercial facility	15 (3.5)	21 (2.7)
	Other outdoor area	14 (3.3)	10 (1.3)
Indoor or outdoor fall injury (%)		n = 426	n = 764	0.000
	Indoor	310 (72.8)	691 (90.4)	0.000
Specific indoor area (%)		n = 303	n = 685	0.410
	Kitchen	4 (1.3)	12 (1.8)
	Living room	54 (17.8)	114 (16.6)
	Room or bedroom	196 (64.7)	476 (69.5)
	Office or store	39 (12.9)	63 (9.2)
	Others	10 (3.3)	20 (2.9)
Activity during injury occurrence (%)		n = 424	n = 764	0.000
	Paid work	51 (12.0)	19 (2.5)
	Unpaid work	40 (9.4)	51 (6.7)
	Sports or leisure activity	34 (8.0)	36 (4.7)
	Daily activity	282 (66.5)	625 (81.8)
	Others	17 (4.0)	33 (4.3)
Alcohol consumption, No. (%)		10 (3.0)	1 (0.2)	0.000
Education (%)		n = 28	n = 40	0.030
	Uneducated or elementary school	14 (50.0)	33 (82.5)
	Junior high school	7 (25.0)	3 (7.5)
	High school	5 (17.9)	3 (7.5)
	College or higher	2 (7.1)	1 (2.5)
Occupation (%)		n = 180	n = 354	0.000
	Employed	36 (20.0)	15 (4.2)
	Unemployed	144 (80.0)	339 (95.8)

Data are presented as means ± standard deviation (range).

LHF = low-height falls.

Table 5

Clinical characteristics of LHF injuries in elderly men and women

Variables		Men (n = 426)	Women (n = 764)	P value
Blood pressure, mmHg		n = 231	n = 412
	Systolic blood pressure	140.4 ± 25.5	139.7 ± 26.0	0.751
	Diastolic blood pressure	79.1 ± 14.5	77.7 ± 14.3	0.232
Consciousness at ED (%)		n = 186	n = 347	0.043
	Alert	173 (93.0)	336 (96.8)
	Non-alert	13 (7.0)	11 (3.2)
Mode of transportation to ED (%)		n = 425	n = 761	0.060
	Public ambulance	152 (35.8)	314 (41.3)
	Transfer from medical facility	98 (23.1)	137 (18.0)
	Individual transportation	175 (41.2)	310 (40.7)
Major injury region (%)				0.000
	Head and neck	199 (46.7)	250 (32.7)
	Thorax	29 (6.8)	40 (5.2)
	Abdomen	35 (8.2)	76 (9.9)
	Hip and thigh	78 (18.3)	236 (30.9)
	Extremity	85 (20.0)	162 (21.2)
EMR-ISS		9.2 ± 7.5 (n = 257)	10.0 ± 7.7 (n = 461)	0.165
Result of ED treatment (%)				0.000
	Discharge from ED	227 (53.3)	415 (54.3)
	Transfer to another medical facility	16 (3.8)	27 (3.5)
	Admission to general ward	144 (33.8)	298 (39.0)
	Admission to intensive care unit	35 (8.2)	22 (2.9)
	Death on arrival or death at ED	4 (0.9)	2 (0.3)
Surgery, No./total (%)		35/278 (12.6)	42/512 (8.2)	0.047
Severe patients (%)		50 (11.7)	32 (4.2)	0.000

Data are presented as means ± standard deviation (range).

LHF = low-height falls, ED = emergency department, EMR-ISS = excess mortality ratio-adjusted injury severity score.

DISCUSSION

The mean age of elderly patients injured by LHF in this study was 77 years; this is 7 years older than the age 70 that predicted GLF mortality in previous studies. Age alone is considered to be a risk factor for severe injury and poor prognosis after a fall regardless of the mechanism.3 14 Careful attentions should therefore be paid to elderly patients presenting to the ED with fall injuries.

In the elderly population, LHF injuries occurred most commonly in residential and medical facilities. The most frequent indoor area where elderly patients fell was a room or bedroom followed by the living room; LHF injuries also occurred mainly during daily activities. A previous study showed a similar result, in that most fall injuries in the elderly population occurred at home during daily activities such as bathing, sleeping, and eating.15 Therefore, in this population, safety precautions should be taken, including the installation of low-height beds and bed railings, not standing on furniture above the ground, and caution in slippery areas such as bathtubs or toilets. Warning labels should also emphasize that elderly people are more at risk of falling from equipment such as scaffolding or ladders. Also, the medical staff and family members of elderly patients in long-term care facilities should strive to prevent fall injuries. Several studies have reported that training in the form of pamphlets, e-books, and electronic applications for elderly patients and their caregivers can reduce the incidence of fall injuries; therefore, more education through these methods is needed.16 17

In addition, Helling et al.18 showed that many elderly patients suffered severe injuries after falls from heights less than 6 meter, even when their vital signs were initially stable. Therefore, the elderly patients should be considered at risk for severe injury, even though who presented to the ED with injury by mechanism of a LHF. It is also preferable to transport elderly patients directly from the scene of an accident to the regional trauma center to avoid aggravating the patient's condition. A trauma team should then promptly and carefully evaluate an elderly patient upon arrival to the ED.

Rau et al.10 reported that the most common injury regions caused by falls were extremities at all adult ages, including the hip and pelvis, regardless of the height of the fall. In particular, extremity injuries were significantly more common in elderly patients, and head and neck injuries were the second most common in both groups. In this study, the most common injury regions were head and neck followed by hip and thigh, in the elderly population. These results demonstrate that the injury characteristics of LHF are different from those of falls in general. In the elderly population, head and neck injuries were the most common in both the severe and non-severe groups; however, head and neck injuries were more than twice as common in the severe group compared with the non-severe group. This suggests that the higher rate of non-alert consciousness in the severe group is mostly likely due to serious injuries of the head and neck. Results from the multivariate logistic regression show that head and neck injuries and non-alert consciousness were both relating factors to severe injury in the elderly population; thus, ED medical staff should be especially vigilant in evaluating these patients.

In this study, there are more woman patients (64%) in the elderly population. This is consistent with results from previous studies showing that elderly women are more frequently injured by falls and more likely to present with a fall injury to the ED.10 19 20

Recently, Gelbard et al.9 reported that men account for about half of all elderly patients with fall injuries, and Con et al.8 reported that elderly men are much more likely to fall in special situations (e.g., from a ladder) related to income activities or outdoor activities than their woman counterparts. It has also been reported that severe fall injuries in the elderly population are more common in men than women.14 21 Consistent with these findings, we found that the elderly men were more likely to suffer an injury from LHF than the women elderly, especially in the severe group. Furthermore, injuries that occurred outdoors were more likely to fall into the severe group than the non-severe group. In addition, the average age of patients in the severe group was 2 years younger than the average age in the non-severe group, and more than half of the patients in the severe group were in the 65–74 years age range. This suggests that relatively young, healthy, and active elderly men who participated in income activities or outdoor activities,19 22 23 were more likely to present to the ED with severe injuries after a fall.24

This study is limited due to its retrospective design. This is not a population-based study, and the data were limited to EDs from 6 general hospitals. There are also limitations due to coding inconsistency, which is common in large multi-institutional registries. Because 5 out of 6 of the hospitals included in this study were tertiary hospitals, there may have been a higher proportion of severely injured patients. It is also possible that the severe injury group may have been underestimated in this study if the patients or guardians refused further treatment due to the patient's age. The severity of fall injuries in the elderly population may vary depending upon comorbidities,14 25 use of anti-coagulants,26 and the level of performance ability; however, these factors were not taken into account in this study. In both the non-severe group and the severe group, the value of variable consciousness at the ED was missing by more than 50% of the data. The missing values were presumed mostly to be alert, however the data were not manipulated for more objective results. In the future, these problems can be complemented by improvement activities of data quality. Finally, it is a meaningful result that paid work was the relating factor to severe injury, because income activities of the elderly population will be increased with an extend life expectancy. Further studies should be conducted focusing on occupation injury or physical activity in the elderly population.

Severe injuries can be occurred in about 7% of the total injuries caused by falls from even low-height in the elderly population. The relating factors to severe injuries were paid work, non-alert consciousness at the ED and major injury to head and neck.

ACKNOWLEDGMENTS

The authors appreciate the Korea Center for Disease Control and Prevention for supporting the registry and all colleagues associated with in-depth surveillance of emergency department injury in Korea.

Notes

^Disclosure The authors have no potential conflicts of interest to disclose.

^{Author Contributions}

Conceptualization: Lee H, Kim SH, Lee SC, Kim S, Cho GC, Kim MJ, Lee JS, Han C.
Data curation: Lee H, Kim SH, Lee SC, Kim S, Cho GC, Kim MJ, Lee JS, Han C.
Formal analysis: Lee H, Kim SH, Lee SC, Kim S, Cho GC, Kim MJ, Lee JS, Han C.
Methodology: Lee H, Kim SH, Lee SC, Kim S, Cho GC, Kim MJ, Lee JS, Han C.
Writing - original draft: Kim H, Kim SH.
Writing - review & editing: Lee H, Kim SH, Kim S, Cho GC, Kim MJ, Lee JS, Han C.

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TOOLS

ORCID iDs

Hyeji Lee
https://orcid.org/0000-0002-6584-1471

Sun Hyu Kim
https://orcid.org/0000-0002-4836-0940

Sang Cheal Lee
https://orcid.org/0000-0001-8704-6922

Sunpyo Kim
https://orcid.org/0000-0001-6802-0807

Gyu Chong Cho
https://orcid.org/0000-0001-9228-3674

Min Joung Kim
https://orcid.org/0000-0003-1634-5209

Ji Sook Lee
https://orcid.org/0000-0002-0522-1350

Chul Han
https://orcid.org/0000-0002-2157-9707

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