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Clin Exp Emerg Med > Volume 8(2); 2021 > Article
Choi, Woo, Hyun, Jang, and Choi: Factors associated with injury severity among users of powered mobility devices

Abstract

Objective

To examine the features of powered mobility device-related injuries and identify the predictors of injury severity in such settings.

Methods

Emergency Department-based Injury In-depth Surveillance data from 2011 to 2018 were used in this retrospective study. Participants were assigned to the mild/moderate and severe groups based on their excess mortality ratio–adjusted injury severity score and their general injury-related factors and injury outcome-related factors were compared.

Results

Of 407 patients, 298 (79.2%) were assigned to the mild/moderate group and 109 (26.8%) to the severe group. The severe group included a higher percentage of patients aged 70 years or older (43.0% vs. 59.6%, P=0.003), injuries incurred in the daytime (72.6% vs. 82.4%, P=0.044), injuries from traffic accidents and falls (P=0.042), head injuries (38.6% vs. 80.7%, P<0.001), torso injuries (16.8% vs. 32.1%, P=0.001), overall hospital admission (28.5% vs. 82.6%, P<0.001), intensive care unit admission (1.7% vs. 37.6%, P<0.001), death after admission (1.4% vs. 10.3%, P=0.034), and total mortality (0.7% vs. 9.2%, P<0.001). The odds ratios (ORs) for injury severity were as follows: age 70 years or older (OR, 2.124; 95% confidence interval [CI], 1.239–3.642), head injury (OR, 10.441; 95% CI, 5.465–19.950), and torso injury (OR, 4.858; 95% CI, 2.495–9.458).

Conclusion

The proportions of patients aged 70 years or older, head and torso injuries, injuries from traffic accidents and falls, and injuries in the daytime were higher in the severe group. Our results highlight the need for measures to address these factors to lower the incidence of severe injuries.

INTRODUCTION

Wheelchairs are an important means by which older people and people with disabilities who have reduced mobility can continue participating in the activities of daily living and engaging in social activities through the enablement of independent transportation [1,2]. While manual wheelchairs serve this purpose, powered wheelchairs and four-wheel mobility scooters, both of which are referred to as “powered mobility devices”, are now beginning to replace them [3-5]. According to the “current needs and use of major assistive devices for people with disabilities”, as published by Statistics Korea, the number of powered mobility device users had increased from 22,000 in 2005 to 112,000 in 2014 [6]. As older adults are now more frequently utilizing powered mobility devices as a means of transport, the actual number of powered mobility device users is estimated to be higher than that reported [2,7].
Previous studies that examined the features of injuries among wheelchair users reported that a majority of injuries result from tips and falls from wheelchairs, with fracture, contusion, and laceration of the extremities the most commonly cited injuries, and that severe injuries occur rarely [4,5,8-11]. However, those studies are limited in that they only examined the overall features without distinguishing between manual wheelchairs, powered wheelchairs, and four-wheel mobility scooters, thereby failing to identify the unique features of injuries sustained from the use of powered mobility devices. Although a recent study reported on the injuries resulting from the use of powered mobility devices, there is a lack of sufficient data on the features of these injuries [12].
Accordingly, this study aimed to identify the features of powered mobility device-related injuries and identify the predictors of injury severity through comparisons of the features of patients with mild/moderate injuries and those with severe injuries, and ultimately explore measures aimed at the prevention of injuries and lowering the injury severity.

METHODS

Ethics statement

This study was performed in accordance with the Declaration of Helsinki and was approved by the institutional review board of Gachon University Gil Medical Center (GBIRB2020-162). The requirement for informed consent was waived due to the retrospective nature of the study.

Data source

This study used data from the Emergency Department-based Injury In-depth Surveillance (EDIIS), which were prospectively collected from across 23 hospitals nationwide from 2011 to 2018 by the Korea Centers for Disease Control and Prevention. The EDIIS was established for the collection of information on the mechanism and cause of injuries among patients admitted to an emergency department (ED) and utilizes this information for the development of injury prevention and management policies. As of 2020, the EDs of 23 nationwide hospitals are participating in this surveillance. When a patient with an injury presents to the ED, healthcare providers, such as physicians, nurses, and emergency medical technicians, first encode the injury-related information in a computer. A trained coordinator then collects the additional information based on the emergency care activity log, ED records, nursing records, and admission and discharge records and registers them in the comprehensive disease management system (http://is.cdc.go.kr) along with the information collected in the ED. The registered data are reviewed by the quality control team at the Korea Centers for Disease Control and Prevention, which provides feedback on errors, unknown data, and missing data to the hospital [13].

Inclusion and exclusion criteria

We used data pertaining to powered wheelchair or four-wheel mobility scooter–related injuries that occurred between 2011 and 2018 in our analysis. To this end, we initially extracted data entered using the code “C1.98.05 (powered wheelchair)” or “C1.98.98 (other specified ground transportation [including scooters for people with disabilities])” for the cause of injury and data with injury descriptions including “powered wheelchair” and “four-wheel mobility scooter.” Data that were not pertinent to injuries sustained through the use of powered mobility device, data on vehicles other than powered mobility devices (such as cars for people with disabilities or carts for those with a handicap), data with missing information on whether the users of the scooters were elderly people or those with a disability, duplicate data, and missing data on the excess mortality ratio–adjusted injury severity score (EMR-ISS) were excluded.

Collected variables and definition of terms

Of the injury-related data, general parameters pertaining to the injury, including patients’ sex, age, time, activity and alcohol intake status at time of the injury, location at which the injury was sustained (indoor vs. outdoor), detailed accident location, cause of crash, and injury mechanism, and parameters related to the injury outcomes, including the vital signs at the ED visit, Glasgow Coma Scale, surgery, severity (EMR-ISS), ED outcomes, and admission outcomes, were used in the analysis.
The accident location was simply classified as “indoor” and “outdoor” and more specifically as “residence” (home, nursing home, etc.), “roadway”, “sidewalk”, “other facilities where vehicles can be driven” (parking lot, mart, park, etc.), and “others”. Cause of crash classified into “motor vehicles” such as cars and motorcycles and “fixed objects” such as floors, walls, and stairs.
The injury mechanisms were reclassified as follows, based on the coded data and specific descriptions pertaining to the injury: tips and falls, user injury caused by tipping and falling of the powered mobility device; traffic accidents, injury caused by collision with a moving car or motorcycle; collisions, injury caused by collision with a stationary object; and falls, injury caused by falling on a slope with a different height.
The EMR-ISS is a scale used for the assessment of the severity of an injury based on the International Classification of Diseases 10th edition (ICD-10) [14]. Excess mortality ratio is calculated as the percentage of deaths among patients diagnosed with each ICD-10 code against the expected mortality in the general population. The EMR-ISS is calculated by the summation of the squares of the three highest EMR grades from all the ICD-10 codes of a particular patient: EMR-ISS=(first highest EMR grade)2+(second highest EMR grade)2]+(third highest EMR grade)2. The severity of an injury can be classified into four groups depending on the EMR-ISS: mild (1< EMR-ISS ≤8), moderate (9< EMR-ISS ≤24), severe (25< EMR-ISS ≤74), and critical (EMR-ISS=75 or death). The EMR-ISS can relatively accurately predict mortality and is known to have a stronger discriminatory power than the more widely used ICD-9–based injury severity score. In this study, we divided patients into the following groups based on the severity of their injury, as assessed using the EMR-ISS: mild/moderate group (<25) and severe group (≥25) [12,14].

Primary outcomes

The primary outcomes of this study were the comparison of the injury-related features and treatment outcomes between the mild/moderate and severe groups and identification of the predictors of injury severity.

Statistical analysis

Data were analyzed using PASW Statistics ver. 18.0 (SPSS Inc., Chicago, IL, USA). Continuous variables are expressed as median and interquartile ranges, and comparisons were performed using the Mann-Whitney U-test. Categorical variables are expressed as frequencies and percentages, and comparisons were performed using the chi-square test or Fisher exact test. Multivariate binary logistic regression analysis was used to assess the independent predictors of injury severity. All variables with a significance level <0.10 in the univariate analysis were included in the multivariate logistic regression analysis. Variables with collinearity were excluded. The backward stepwise method was used to select the final model. The Hosmer-Lemeshow test was used for the assessment of the goodness of fit. All statistical tests were two-sided, and a P-value of <0.05 was considered significant.

RESULTS

Baseline characteristics of the study population

Of the 487 patients with injuries related to the use of powered mobility devices, data on 80 (of which 49 did not involve an injury sustained by the driver of the powered mobility device, four in which vehicles other than powered mobility devices were used [such as cars for people with disabilities or carts for those with a handicap], 13 cases in which it was undetermined whether the users of the scooters were elderly or had a disability, six cases in which duplicate data were present, and eight cases in which EMR-ISS data were missing) were excluded. Data on only 407 people were included in this study (Fig. 1). In total, 298 (73.2%) patients were assigned to the mild/moderate group and 109 (26.8%) to the severe group.
Table 1 summarizes the baseline injury-related characteristics of the mild/moderate and severe groups. Both groups had a higher percentage of male patients, and no significant differences were observed between the two groups in terms of sex (61.4% vs. 63.3%, P=0.728). The median age in the severe group was significantly higher than that in the mild/moderate group (67.0 [53.0–76.0] vs. 73.0 [62.0–79.5], P<0.001). In addition, the severe group had a significantly higher percentage of patients aged 70 years or older. When patients were divided into quartiles, the injury severity significantly increased with increasing age (Fig. 2) (P=0.001). The severe group had a higher percentage of daytime injuries (72.6% vs. 82.4%, P=0.044) and injuries caused by traffic accidents and falls (P=0.042).

Outcomes of the study population

Table 2 presents a summary of the injury-related outcomes in each group. The severe group had a significantly higher percentage of head and torso injuries (38.6% vs. 80.7%, P<0.001; 16.8% vs. 32.1%, P=0.001), while the mild/moderate group had a higher percentage of lower limb injuries (33.2% vs. 11.0%, P<0.001). The severe group had a higher rate of overall admission and intensive care unit admission (28.5% vs. 82.6%, P<0.001; 1.7% vs. 37.6%, P<0.001), as well as death after admission and total mortality (1.4% vs. 10.3%, P=0.034; 0.7% vs. 9.2%, P<0.001).

Multivariate logistic regression analysis

The results of the multivariate logistic regression analysis focusing on the severity of the injuries sustained from the use of powered mobility devices showed that severe injury was significantly associated with older age (70 years or older) (odds ratio [OR], 2.124; 95% confidence interval [CI], 1.239–3.642), head injury (OR, 10.441; 95% CI, 5.465–19.950), and torso injury (OR, 4.858; 95% CI, 2.495– 9.458) (Table 3).

DISCUSSION

In the present study, the proportions of patients aged 70 years or older, head and torso injuries, injuries from traffic accidents and falls, and injuries sustained in the daytime were higher in the severe group. It is necessary to examine the background and cause of severe injuries by each of these factors and to explore measures to prevent severe injuries based on such examination.

Age

Age influences the quality of sensory reception and processing in response to external stimuli and motor capabilities. The deterioration of the perceptual and cognitive abilities required for driving based on visual information increases the driver’s exposure to risky situations that may lead to an accident [15]. Further, aging weakens balance and strength performance, which in turn diminishes one’s torso control ability; this is speculated to increase the risk of secondary injury by easily pushing the user out of the device upon impact [16]. As aging is an uncorrectable factor, measures to lower the incidence of accidents are needed in order to decrease the incidence of severe injuries among older adult users. To this end, environmental factors that may trigger an accident as well as users’ level of awareness on safe driving need to be improved; in particular, older adult users should be informed about the basic manipulation, safe use, and regular maintenance and repair of powered mobility devices [15,17,18]. The degeneration of sensory and motor functions accompanying neurological and musculoskeletal disorders that develop with advancing age may have an impact on disease severity. However, we could not determine the correlation between the presence of disease and injury severity due to the lack of information on comorbidities in our data. Therefore, additional studies should be conducted to examine whether age and the presence of underlying disease are independent variables that are correlated with injury severity.

Head and torso injuries

The higher percentage of head and torso injuries observed in the severe group may be attributed to the fact that the injured areas tend to include body parts that are essential for the maintenance of stable vital signs, such as the brain and internal organs. Therefore, the use of protective devices for the head and torso may be effective in lowering the incidence of severe injuries. Helmets are known to reduce the incidence and severity of brain damage from accidents involving mobility devices used in a similar environment, such as bicycles and motorcycles [19,20]. Furthermore, the use of seat belts lowers the incidence and severity of injury by reducing the possibility of secondary injury and preventing users from being pushed off the mobility device upon impact [21-23]. According to the “Ministry of Food and Drug Safety Notification 2019-61, Standard specifications for medical devices, Schedule 2. ‘48. Powered wheelchairs and medical scooters”, seat belts are not mandatory when driving a powered mobility device [24]. In fact, a survey conducted among Korean users reported that more than 70% of users do not wear a seat belt [4]. To reduce the severity of injuries, the use of protective devices such as helmets and seat belts should be strongly recommended.

Traffic accidents

According to the Road Traffic Act, powered mobility device users are considered pedestrians and these devices are only allowed to be operated on sidewalks [25]. However, the uneven, cracked, and sunken surfaces of some block-paved sidewalks, presence of trees lining the street and standing signboards, and certain road facilities may hinder the use of powered mobility devices, causing accidents [5,26]. Due to these factors, users operate powered mobility devices on the road instead of the sidewalk, and consequent collisions with cars and motorcycles lead to severe injuries. To prevent such injuries, sidewalks should be altered to enable easy powered mobility device use, and users should be educated about traffic laws and safe driving. Furthermore, it may be helpful to install reflectors or lights on powered mobility devices to allow for automobile drivers to easily detect them. While we were unable to obtain official statistics pertaining to traffic accidents involving powered mobility devices in South Korea, our data analysis revealed that traffic accidents account for 30.5% of all injuries, and that the percentage of injuries caused by traffic accidents increases every year, having risen from 10.5% in 2011 to 24.2% in 2014 and 35.0% in 2018. Recently, the illegal driving of powered mobility devices on the road and consequent traffic accidents have emerged as social problems. In addition to performing an accurate statistics survey on relevant accidents, future studies should compare the injury-related features and outcomes with those related to the use of other similar modes of transport, such as bicycles and motorcycles, as well as those among pedestrians.

Falls

Compared to other types of injuries, falls involve a greater impact; this may be the reason for the higher percentage of falls in the severe group. A detailed analysis of our data revealed that falls generally occur on stairs (29.1%) and farm roads (25.5%). A previous study found that stairs are associated with fatal wheelchairrelated injuries [27]. These results highlight the need to expand the proportion of accessible facilities such as entryways, lifts, or elevators for powered mobility devices. As most farm roads are not paved, roads with uneven surfaces and unclear boundaries between a level ground and steep slope potentially cause accidents. Particularly, farm roads are frequently utilized by older adult users in agricultural areas; hence, it is necessary to maintain these roads to make them powered mobility device-friendly and reduce the severity of any injuries.

Daytime injuries

A previous study observed that the rate of severe injuries is high among male patients between the ages of 6 and 17 years, which is a period marked by a high level of involvement in outdoor sports and social activities [8]. The high percentage of daytime injuries in the severe group in our study is also believed to be due to the fact that occupational activities, routine daily activities, and leisure activities are frequently performed during the day. Furthermore, a substantial percentage of the severe injuries observed in association with traffic accidents may be due to the presence of higher levels of traffic during the day.
This study has some limitations. First, we used data collected nationwide during a specific period; the retrospective analysis of this data may be susceptible to patient selection bias. Second, the data used in this study were collected from 23 large hospitals nationwide, and hence, the overall severity of the injuries and incidence of injury mechanisms correlated with severe injuries may have been overestimated. Third, multiple terms were used to refer to powered mobility devices, such as powered wheelchairs, scooters for people with disabilities, electric mobility scooters, and four-wheel mobility scooters, in the EDIIS; therefore, some data may have been omitted in the search.
In summary, the percentages of patients aged 70 years or older, head and torso injuries, injuries from traffic accident and falls, and injuries sustained during the day were higher in the group of patients with severe injuries in association with powered mobility device use. To lower the rate of severe injuries, it is important to provide education on basic device manipulation, safe driving, regular maintenance and repair, and traffic laws; to strongly recommend the use of protective devices such as helmets and seat belts; and to improve the conditions of frequently used sidewalks and farm roads to be powered mobility device-friendly.

NOTES

No potential conflict of interest relevant to this article was reported.

ACKNOWLEDGMENTS

The data used in this study were provided by the Korea Centers for Disease Control and Prevention.

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Fig. 1.
Flowchart of the patient selection process. EDIIS, Emergency Department-based Injury In-depth Surveillance; PMD, powered mobility device; EMR-ISS, excess mortality ratio-adjusted injury severity score.
ceem-20-078f1.jpg
Fig. 2.
Relationship between injury severity and age group (P=0.001). Q, quartile.
ceem-20-078f2.jpg
Table 1.
General characteristics of the study population and the injury mechanisms
Variable Mild/moderate group (n = 298) Severe group (n = 109) P-value
Sex, male 183 (61.4) 69 (63.3) 0.728
Age (yr) 67.0 (53.0–76.0) 73.0 (62.0–79.5) < 0.001
Age, ≥ 70 yr 128 (43.0) 65 (59.6) 0.003
Time (9 a.m. to 6 p.m.) 215 (72.6) 89 (82.4) 0.044
Season 0.536
 Spring 81 (27.2) 26 (23.9)
 Summer 80 (26.8) 35 (32.1)
 Autumn 86 (28.9) 34 (31.2)
 Winter 51 (17.1) 14 (12.8)
Drunk driving 20 (6.7) 7 (6.4) 0.887
Purpose of driving, working 69 (23.2) 21 (19.3) 0.403
Accident location, outdoor 279 (93.6) 103 (94.5) 0.916
Detailed accident location 0.353
 Residence 21 (7.0) 5 (4.6)
 Roadway 194 (65.1) 71 (65.1)
 Sidewalk 59 (19.8) 18 (16.5)
 Other facilities where vehicles can be driven 7 (2.3) 3 (2.8)
 Others 17 (5.7) 12 (11.0)
Crash opponents 0.381
 Motor vehicles 88 (31.3) 36 (36.0)
 Fixed objects 184 (65.5) 63 (63.0)
 Others 9 (3.2) 1 (1.0)
Mechanism of injury 0.042
 Tips and falls 141 (51.8) 40 (40.8)
 Traffic accidents 88 (32.4) 36 (36.7)
 Collisions 10 (3.7) 1 (1.0)
 Falls 33 (12.1) 21 (21.4)

Values are presented as number (%) or median (interquartile range).

Table 2.
Comparison of patient between the mild/moderate and severe groups
Variable Mild/moderate group (n = 298) Severe group (n = 109) P-value
Systolic blood pressure (mmHg) 136.0 (120.0–155.3) 134.5 (120.0–153.8) 0.915
Diastolic blood pressure (mmHg) 80.0 (70.0–90.0) 80.0 (70.0–90.0) 0.598
Heart rate (min) 81.0 (72.0–92.0) 83.0 (73.0–96.8) 0.336
Respiration rate (min) 20.0 (18.0–20.0) 20.0 (18.0–20.0) 0.043
Body temperature (°C) 36.6 (36.3–36.8) 36.5 (36.2–36.8) 0.132
Glasgow Coma Scale score 15.0 (15.0–15.0) 15.0 (15.0–15.0) < 0.001
Head injury 115 (38.6) 88 (80.7) < 0.001
Spine injury 32 (10.7) 15 (13.8) 0.398
Torso injury 50 (16.8) 35 (32.1) 0.001
Upper extremities injury 63 (21.1) 24 (22.0) 0.848
Lower extremities injury 99 (33.2) 12 (11.0) < 0.001
Surgery 40 (13.4) 15 (13.8) 0.929
Admission 85 (28.5) 90 (82.6) < 0.001
ICU admission 5 (1.7) 41 (37.6) < 0.001
Death in ED 1 (0.3) 2 (1.8) 0.176
Death after admission 1 (1.4) 8 (10.3) 0.034
Death (overall) 2 (0.7) 10 (9.2) < 0.001

Values are presented as median (interquartile range) or number (percentage).

ICU, intensive care unit; ED, emergency department.

Table 3.
Multivariate logistic regression analysis of the independent factors associated with powered mobility device-related injury severity
Variable Odds ratioa) 95% confidence interval
Lower Upper
Sex, male 1.370 0.788 2.384
Age, ≥ 70 yr 2.124 1.239 3.642
Head injury 10.441 5.465 19.950
Torso injury 4.858 2.495 9.458

Variables included in this analysis were sex, age (≥70 yr), head injuries, torso injuries, and injury mechanism (falls).

a) Calculated using backward stepwise logistic regression analysis.

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