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Original Investigation   Emergency Medicine

Injuries Associated With Standing Electric Scooter Use
Tarak K. Trivedi, MD, MS; Charles Liu, MD; Anna Liza M. Antonio, DrPH; Natasha Wheaton, MD; Vanessa Kreger, MD, MPH; Anna Yap, MD;
David Schriger, MD, MPH; Joann G. Elmore, MD, MPH

Abstract
IMPORTANCE Since September 2017, standing electric scooters have proliferated rapidly as an
inexpensive, easy mode of transportation. Although there are regulations for safe riding established
by both electric scooter companies and local governments, public common use practices and the
incidence and types of injuries associated with these standing electric scooters are unknown.

Key Points
Question What are the types of injuries
associated with standing electric scooter
use and the characteristics and
behaviors of injured patients?
Findings In this study of a case series,

OBJECTIVE To characterize injuries associated with standing electric scooter use, the clinical

249 patients presented to the

outcomes of injured patients, and common use practices in the first US metropolitan area to

emergency department with injuries

experience adoption of this technology.

associated with electric scooter use
during a 1-year period, with 10.8% of

DESIGN, SETTING, AND PARTICIPANTS This study of a case series used retrospective cohort

patients younger than 18 years and only

medical record review of all patients presenting with injuries associated with standing electric

4.4% of riders documented to be

scooter use between September 1, 2017, and August 31, 2018, at 2 urban emergency departments

wearing a helmet. The most common

associated with an academic medical center in Southern California. All electric scooter riders at

injuries were fractures (31.7%), head

selected public intersections in the community surrounding the 2 hospitals were also observed

injuries (40.2%), and soft-tissue

during a 7-hour observation period in September 2018.

injuries (27.7%).
Meaning In this study, injuries

MAIN OUTCOMES AND MEASURES Incidence and characteristics of injuries and observation of
riders’ common use practices.

associated with electric scooter use
were common, ranged in severity, and
suggest low rates of adherence to

RESULTS Two hundred forty-nine patients (145 [58.2%] male; mean [SD] age, 33.7 [15.3] years)
presented to the emergency department with injuries associated with standing electric scooter use

existing regulations around rider age
and low rates of helmet use.

during the study period. Two hundred twenty-eight (91.6%) were injured as riders and 21 (8.4%) as
nonriders. Twenty-seven patients were younger than 18 years (10.8%). Ten riders (4.4%) were
documented as having worn a helmet, and 12 patients (4.8%) had either a blood alcohol level greater
than 0.05% or were perceived to be intoxicated by a physician. Frequent injuries included fractures
(79 [31.7%]), head injury (100 [40.2%]), and contusions, sprains, and lacerations without fracture or
head injury (69 [27.7%]). The majority of patients (234 [94.0%]) were discharged home from the

+ Invited Commentary
+ Supplemental content
Author affiliations and article information are
listed at the end of this article.

emergency department; of the 15 admitted patients, 2 had severe injuries and were admitted to the
intensive care unit. Among 193 observed electric scooter riders in the local community in September
2018, 182 (94.3%) were not wearing a helmet.
CONCLUSIONS AND RELEVANCE Injuries associated with standing electric scooter use are a new
phenomenon and vary in severity. In this study, helmet use was low and a significant subset of injuries
occurred in patients younger than 18 years, the minimum age permitted by private scooter company
regulations. These findings may inform public policy regarding standing electric scooter use.
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Introduction
Standing electric scooters first appeared in Santa Monica, California, in September 2017, when the
micromobility company Bird Rides, Inc, placed thousands of their scooters all around the city.1 These
scooters were immediately popular with riders, presumably due to their ease of use, convenience,
and low cost. The scooters are located and unlocked using a downloaded smartphone application,
rides are paid for by the minute, and the ride can be ended anywhere the rider decides. With a
maximum speed of 15 mph,2 these short-range electric vehicles consist of a narrow platform on
which the rider stands with 1 foot in front of the other and a waist-high rod with handlebars for
steering; after kicking off initially with 1 foot, riders accelerate and brake the scooter using triggers
activated with their thumbs.
Companies offering standing electric scooters are rapidly expanding in the United States. For
example, Lime-S scooters are available in more than 60 US cities and 6 cities internationally,3 and in
April 2018, Bird Rides, Inc, announced more than 1 million completed rides.4 Today, several major
companies, including Bird and Lime, offer dockless electric scooter services, and several other
companies, including the ride-sharing companies Uber and Lyft, have recently entered the market.5
Availability is projected to grow rapidly, with market analysis showing that Lime was valued at $1.1
billion and its rival Bird was valued at more than $2 billion.6
The early personal transporters by Segway, introduced in 2001, were few in number, expensive
to use, restricted to tourist locations, and associated with a specific set of injuries.7 In comparison,
many thousands of riders are now using standing electric scooters daily on US streets shared with
millions of pedestrians and drivers. Therefore, understanding the impact of rising scooter use on
public health is more important than ever. Local laws regarding electric scooters are variable, with
most locales prohibiting riding on the sidewalk and requiring the use of helmets,8 but no uniform set
of policies exists, and differences in enforcement further amplify this variation. The scooter rental
smartphone applications require riders to state that they will comply with state and local laws, show
proof of a driver’s license, be older than 18 years, and use a helmet as part of their initial user
agreements, but it is unclear to what extent these requirements are followed. Debates over the role
of greater regulation of electric scooters continue in cities like San Francisco9 and Santa Monica,
California.10 Of note, a bill supported by Bird to remove the helmet requirement for riders aged 18
years and older was recently signed into law in California,11,12 illustrating the timeliness of this issue as
well as the importance of garnering evidence to guide policy.
Given our institution’s proximity to where these electric scooters were first available in the
United States, we have the unique ability to describe injuries associated with electric scooters that
were severe enough to trigger an emergency department (ED) visit over the course of 1 year. We
report on the patient demographic and clinical characteristics of injuries associated with electric
scooter use evaluated in our institution’s 2 EDs. Additionally, we conducted public observations to
describe common scooter riding practices in the community near the 2 EDs.

Methods
Study Design
We retrospectively analyzed deidentified data from all patient encounters for standing electric
scooter injuries presenting to either of 2 EDs affiliated with the University of California, Los Angeles
(UCLA), Ronald Reagan UCLA Medical Center and UCLA Medical Center–Santa Monica. We report
summary statistics on the continuous and categorical variables of interest. Additionally, we observed
a convenience sample of scooter riders to describe common use practices of standing electric
scooters in the community surrounding our hospitals (eAppendix in the Supplement). The UCLA
institutional review board approved all aspects of this study with waiver of informed patient consent.
The study was conducted using the Strengthening the Reporting of Observational Studies in
Epidemiology (STROBE) reporting guideline.13

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Data Collection
We identified all ED encounters for injuries associated with standing electric scooter use in patients
of any age by querying our unified electronic medical record for ED encounters between September
1, 2017, and August 31, 2018, that contained a clinician note with any of the non–case-sensitive terms
“scooter,” “bird,” or “lime.” Two of us (T.K.T. and C.L.) reviewed the medical records to verify eligibility
and excluded ED encounters that were not due to trauma associated with standing electric scooter
use. The eAppendix in the Supplement describes our process of determining inclusion and data
abstraction, and eTable 1 in the Supplement details how categories of injuries were assigned using
International Classification of Diseases, Ninth Revision, Clinical Modification (ICD-9-CM)
diagnosis codes.

Statistical Analysis
In this descriptive study of a case series, we report proportions, calculate means and standard
deviations for normally distributed data, and calculate medians and interquartile ranges for data that
were not normally distributed.

Results
Two hundred forty-nine patients (145 [58.2%] male; mean [SD] age, 33.7 [15.3] years) presented to
the emergency department with injuries associated with standing electric scooter use during the
study period (Figure; eFigure in the Supplement). The demographic and incident characteristics of
these patients are shown in Table 1. A majority of patients (152 [61.0%]) were between the ages of 18
and 40, although ages ranged from 8 to 89, and 27 patients (10.8%) were younger than 18 years. Of
the 249 patients, 228 (91.6%) were riders and 21 (8.4%) were nonrider pedestrians (11 hit by a
scooter, 5 tripped over a parked scooter, and 5 were attempting to lift or carry a scooter not in use).

Figure. Identifying Visits for Injuries Associated With Standing Electric Scooter Use
523 Emergency department encounters with medical record
entry containing “scooter” OR “lime” OR “bird”
79 Excluded
“Bird” or “lime” referred to in a different context, such as
a name of a person or street or the animal or fruit
91 Excluded (wrong type of scooter)
48 Nonmotorized (eg, Razor)
18 Motorcycle or moped (eg, Vespa)
17 Mobility wheelchair
6 Knee scooter for injuries
2 Segway
17 Excluded
References to standing electric scooters without traumatic
event related to their intended use (eg, assault using scooter
as weapon, lawsuit against scooter company, attempt to
steal scooter)
13 Excluded
Repeat visits for the same patient event (eg, suture removal,
continued pain)
74 Excluded
Nonspecific type of scooter (insufficient information
available in chart)
249 Emergency department encounters for standing electric
scooter injuries

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A majority of ED visits (141 [56.6%]) occurred during the late afternoon and evening hours, between
3 PM and 11 PM.
Among scooter riders, the most common mechanisms of injury were fall (183 riders [80.2%]),
collision with an object (25 riders [11.0%]), and being hit by a moving vehicle or object (20 riders
[8.8%]). Only 10 riders were documented as wearing a helmet, constituting 4.4% of all riders or
11.9% of riders whose helmet use status was documented. Twelve patients (4.8%) had physiciandocumented intoxication or a blood alcohol level greater than 0.05%.
Table 2 describes the ED evaluation and injury characteristics of patients presenting with
injuries associated with standing electric scooter use. The majority of patients (200 [80.3%])
received imaging in the ED, with the most common imaging studies being radiographs or computed
tomography of the distal upper extremity (36.5%), computed tomography of the head (29.7%), and
radiographs or computed tomography of the distal lower extremity (20.1%). A total of 8.4% of
patients underwent a trauma-protocol computed tomography scan (head, cervical spine, chest,
abdomen, and pelvis), indicating high concern for serious injury. Two hundred thirty-four patients
(94.0%) were discharged home from the ED.

Table 1. Patient and Accident Characteristics for ED Visits Associated With Standing Electric Scooters
During a 1-Year Period
No. (%)
Characteristic

Riders (n = 228)

Nonriders (n = 21)

Total (N = 249)

<18

26 (11.4)

1 (4.8)

27 (10.8)

18-25

61 (26.8)

1 (4.8)

62 (24.9)

26-40

85 (37.3)

5 (23.8)

90 (36.1)

41-64

51 (22.4)

10 (47.6)

61 (24.5)

≥65

5 (2.2)

4 (19.1)

9 (3.6)

134 (58.9)

11 (52.4)

145 (58.2)

Demographic Characteristics
Age, y

Male
Accident Characteristics
Mechanism of injury
Rider
Fall, no specific details

183 (80.2)

NA

NA

Collision with an object

25 (11.0)

NA

NA

Hit by a vehicle or moving object

20 (8.8)

NA

NA

Hit by scooter

NA

11 (52.4)

NA

Tripped over scooter in road

NA

5 (23.8)

NA

Othera

NA

5 (23.8)

NA

Nonrider

Mechanism of ED transport
Self-presented

151 (66.2)

17 (81.0)

168 (67.5)

Emergency medical services

77 (33.8)

4 (19.1)

81 (32.5)

20 (8.8)

0

20 (8.0)

7 AM-3 PM

57 (25.0)

8 (38.1)

65 (26.1)

3 PM-11 PM

130 (57.0)

11 (52.4)

141 (56.6)

11 PM-7 AM

41 (18.0)

2 (9.5)

43 (17.3)

Unknown

144 (63.2)

NA

NA

No helmet

74 (32.5)

NA

NA

Wearing a helmet

10 (4.4)

NA

NA

12 (5.2)

0

12 (4.8)

Emergency medical services trauma activation
Time of day

Abbreviations: ED, emergency department; NA, not
applicable.
a

Other mechanisms involved 4 people injuring foot
while attempting to lift or manipulate scooter and 1
person who injured their hand while trying to
lift scooter.

b

Numbers for nonriders are not calculated, as they
would not be wearing helmets. One nonrider was a
bicyclist wearing a helmet who was hit by a scooter.

c

Patients were considered not intoxicated unless
there was physician documentation of intoxication
or blood alcohol testing with a result of greater
than 0.05%.

Helmet useb

Drug or alcohol intoxicationc
Blood alcohol level >0.05% or subjectively indicated
by physician

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Table 2. Emergency Department Resource Use and Injury Characteristics
No. (%)
Riders (n = 228)a

Nonriders (n = 21)a

Total (N = 249)a

1: Most concerning

2 (0.9)

0

2 (0.8)

2

26 (11.4)

0

26 (10.4)

3

52 (22.8)

7 (33.3)

59 (23.7)
153 (61.4)

Characteristic
Triage acuity

4

139 (61.0)

14 (66.7)

5: Least concerning

6 (2.6)

0

6 (2.4)

Missingb

3 (1.3)

0

3 (1.2)

183 (80.3)

17 (81.0)

200 (80.3)

Distal

87 (38.2)

4 (19.0)

91 (36.5)

Proximal

39 (17.1)

3 (14.3)

42 (16.9)

Distal

47 (20.6)

3 (14.3)

50 (20.1)

Proximal

21 (9.2)

2 (9.5)

23 (9.2)

40 (17.5)

3 (14.3)

43 (17.3)

Head

66 (28.9)

8 (38.1)

74 (29.7)

Head and cervical spine

44 (19.3)

1 (4.8)

45 (18.1)

Head, cervical spine, chest, abdomen,
and pelvis

21 (9.2)

0

21 (8.4)

Face

23 (10.1)

2 (9.5)

25 (10.0)

Cervical spine

45 (19.7)

1 (4.8)

46 (18.5)

Abdomen

22 (9.6)

0

22 (8.8)

Chest

21 (9.2)

0

21 (8.4)

Patients discharged, No.

214

20

234

<4 h

156 (72.9)

19 (95.0)

175 (70.3)

>4 h

58 (27.1)

1 (5.0)

59 (23.7)

Home

214 (93.9)

20 (95.2)

234 (94.0)

Admit to floor or observation

12 (5.3)

1 (4.8)

13 (5.2)

Intensive care unit

2 (0.9)

0

2 (0.8)

71 (31.1)

8 (38.1)

79 (31.7)

Distal

30 (13.2)

1 (4.8)

31 (12.5)

Proximal

15 (6.6)

2 (9.5)

17 (6.8)

Distal

9 (4.0)

2 (9.5)

11 (4.4)

Proximal

3 (1.3)

0

3 (1.2)

Facial

12 (5.3)

2 (9.5)

14 (5.6)

Vertebral column

2 (0.9)

0

2 (0.8)

Thoracic

3 (1.3)

1 (4.8)

4 (1.6)

Head injury

92 (40.4)

8 (38.0)

100 (40.2)

Minor head injurye

87 (38.2)

8 (38.0)

95 (38.2)

Intracranial hemorrhage

5 (2.2)

0

5 (2.0)

63 (27.5)

6 (28.6)

69 (27.7)

Imaging
Received any radiograph or CT
Received extremity radiograph or CT
Upper extremity

Lower extremity

Received other radiography or CTc
Chest radiograph
CT

ED length of stay for discharged patientsc

ED disposition

Injury characteristicsd
Any fracture
Upper extremity

Lower extremity

Contusions, sprains, and lacerations with no
fracture or head injury

(continued)

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Table 2. Emergency Department Resource Use and Injury Characteristics (continued)
No. (%)
Riders (n = 228)a

Nonriders (n = 21)a

Total (N = 249)a

Majorf

9 (3.9)

0

9 (3.6)

Minorg

2 (0.9)

0

2 (0.8)

8 (3.5)

0

8 (3.2)

Characteristic
Dislocations

Procedural sedation for fracture reduction
or joint dislocation
Lacerations

65 (28.5)

6 (28.6)

71 (28.1)

Major intra-abdominal or intrathoracic injuriesh

3 (1.3)

0

3 (1.2)

Abbreviations: CT, computed tomography; ED, emergency department.
a

Unless otherwise noted.

b

3 Cases were missing an acuity; on review, all 3 were trauma activations.

c

Proportions calculated based only on discharged patients.

d

Categories are not mutually exclusive.

e

Minor head injuries include all closed head injuries without skull fracture or intracranial hemorrhage.

f

Major dislocations include dislocations of the jaw, hips, shoulders, elbows, knees, and ankles.

g

Minor dislocations included dislocations of the fingers or foot.

h

Major intra-abdominal or intrathoracic injuries were defined as any internal injury of the thorax, abdomen, and pelvis
represented by International Classification of Diseases, Ninth Revision, codes 860 to 869. The 3 cases included a splenic
laceration and 2 lung contusions.

Among the 15 patients (6.0%) who were admitted or transferred, 13 patients were admitted to
a floor or observation bed and 2 patients to the intensive care unit (one with traumatic subarachnoid
hemorrhage, the other with a subdural hematoma). The reasons for hospitalization for the 15 patients
admitted were orthopedic injuries (n = 5), intracranial hemorrhage (n = 5), major intra-abdominal or
intrathoracic injuries (n = 3), cervical spine fracture (n = 1), and concussion (n = 1).
The most common injuries were fracture (79 patients [31.7%]), head injury (100 [40.2%]), and
contusions, sprains, and lacerations without fracture or head injury (69 [27.7%]). Common fracture
locations included the distal upper extremity (31 [12.5%]), proximal upper extremity (17 [6.8%]),
distal lower extremity (11 [4.4%]), and face (14 [5.6%]). There was 1 open fracture. Eight patients
(3.2%) received procedural sedation in the ED for reduction of a fracture or dislocation. Ninety-five
patients (38.2%) sustained a minor head injury (head injury without intracranial hemorrhage or skull
fracture), and 5 patients (2.0%) had an intracranial hemorrhage. Five of 95 patients (5.3%) with a
minor head injury were documented as wearing a helmet during the incident, while none of the 5
patients with an intracranial hemorrhage had such documentation. Three patients had injuries to the
intrathoracic or intra-abdominal organs, specifically pulmonary contusion, pneumothorax or
hemothorax, and splenic injury.
A total of 193 scooter riders were observed during 3 public observation sessions, and the
following unsafe riding practices were observed: no helmet use (182 riders [94.3%]), tandem riding
(15 riders [7.8%]), and failure to comply with traffic laws (18 riders [9.3%]), as shown in eTable 2 in the
Supplement. Additionally, many riders were observed to be riding on the sidewalk (51 riders
[26.4%]), where scooter use is prohibited.

Discussion
To our knowledge, this is the first study examining the injury patterns and clinical outcomes of
patients presenting to the ED after incidents involving standing electric scooters. This rapidly
expanding technology is a disruptive force in short-distance transportation, and policy makers
seeking to understand associated risks and appropriate regulatory responses should seriously
consider its effects on public health. Riders share roads with fast-moving vehicular traffic but appear
to underestimate hazards; we found that 94.3% of observed riders in our community were not

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wearing a helmet. Unsurprisingly, injuries associated with standing electric scooter use are prevalent,
with 249 patients presenting to the ED over the course of 1 year in our study of 2 EDs. Comparatively,
in a post hoc analysis prompted by the review process, we identified 195 visits for bicyclist injuries
(ICD-10 V10-V19) and 181 visits for pedestrian injuries (ICD-10 V00-V09) during the same time period
at the 2 EDs. Scooter injuries documented in this study were mostly minor, but could also be severe
and costly, with 6.0% of patients admitted to the hospital, and 0.8% admitted to the intensive
care unit.
Like standing electric scooters, personal transporters launched by Segway offered a novel and
convenient means of short-distance transportation, but came with a serious risk for orthopedic and
neurologic trauma.14-16 Segway-related injuries commonly included upper and lower extremity
fractures, but some were severe, including reported cases of intracranial hemorrhage requiring
admission to the intensive care unit.16 We noted similar patterns of injury with standing electric
scooters. However, unlike Segway transporters, standing electric scooters could have substantial
impact on public health given their low cost, popularity, and accessibility.
While riders of electric scooters in California are required to be at least 16 years old by state law
and 18 years old by company rental agreements,17,18 we found that 10.8% of electric scooter injuries
were in patients younger than 18 years. This suggests that current self-enforced regulations imposed
by private electric scooter companies may be inadequate. Although California law required helmet
use while operating electric scooters during the entire study period, only 4.4% of injured scooter
riders were documented to be wearing a helmet. A newly passed California law will make helmet use
optional for electric scooter riders older than 18 years on January 1, 201911,12; it is unclear how this
change in policy will affect rider practices and injury patterns.

Limitations
While this is the first study, to our knowledge, of trauma associated with electric scooter use to
provide data on a full year of ED visits, our study is retrospective and therefore necessarily limited to
available clinical variables. Future work would benefit from efforts to improve ED clinician
documentation of relevant incident characteristics, such as helmet use. We likely underestimated the
number of electric scooter–associated injuries for several reasons. We excluded 74 ED encounters
where it was suspected, but not clear, that an electric scooter was involved, and we did not include
outpatient visits to urgent care or primary care clinics for minor injuries. Additionally, scooter use and
availability rapidly increased toward the end of our study period, evidenced by the fact that most
associated injuries occurred during the later months of the study (eFigure in the Supplement). We
were also unable to evaluate the geographic and urban planning factors influencing the incidence
and severity of these injuries. Future work should include prospective data collection and examine
the effects of bikeway availability and speed limits, which may modify the occurrence of injuries
associated with electric scooter use. It would also be meaningful to characterize the costs incurred by
patients and the health care system from trauma associated with electric scooter use. This
descriptive study was unable to identify any risk factors for injury; future work could use data from
private scooter companies to calculate the rates of injury based on number of trips, distance traveled,
and demographic characteristics of scooter users.

Conclusions
Standing electric scooters are a novel, innovative, and rapidly expanding form of transportation with
the potential to alleviate traffic congestion, provide affordable transportation to residents of all
incomes, and reshape how commuters travel the “last mile” to home or work. Our findings provide
insight into the public health and safety risks associated with this rapidly growing form of
transportation and provide a foundation for modernizing public policy to keep pace with this trend.

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ARTICLE INFORMATION
Accepted for Publication: November 29, 2018.
Published: January 25, 2019. doi:10.1001/jamanetworkopen.2018.7381
Open Access: This is an open access article distributed under the terms of the CC-BY License. © 2019 Trivedi TK
et al. JAMA Network Open.
Corresponding Author: Tarak K. Trivedi, MD, MS, National Clinician Scholar Program, University of California, Los
Angeles, 1100 Glendon Ave, Ste 900, Los Angeles, CA 90024 (tktrivedi@mednet.ucla.edu).
Author Affiliations: Veterans Administration, Greater Los Angeles Healthcare System, Los Angeles, California
(Trivedi, Liu); National Clinician Scholars Program, University of California, Los Angeles, Los Angeles, California
(Trivedi, Liu, Elmore); Department of Emergency Medicine, University of California, Los Angeles (Trivedi, Wheaton,
Kreger, Yap, Schriger); Department of Surgery, Stanford University, Stanford, California (Liu); Department of
Surgery, University of California, Los Angeles (Liu); Office of Health Informatics and Analytics, UCLA Health,
University of California, Los Angeles (Antonio); Division of General Internal Medicine and Health Services Research,
University of California, Los Angeles (Elmore).
Author Contributions: Drs Trivedi and Liu had full access to all of the data in the study and take responsibility for
the integrity of the data and the accuracy of the data analysis.
Concept and design: Trivedi, Antonio, Wheaton, Kreger, Yap, Schriger, Elmore.
Acquisition, analysis, or interpretation of data: Trivedi, Liu, Antonio, Wheaton, Kreger, Yap, Schriger.
Drafting of the manuscript: Trivedi, Liu, Antonio, Wheaton, Kreger, Yap, Schriger.
Critical revision of the manuscript for important intellectual content: Trivedi, Liu, Wheaton, Kreger, Yap,
Schriger, Elmore.
Statistical analysis: Trivedi, Antonio, Wheaton, Schriger.
Obtained funding: Elmore.
Administrative, technical, or material support: Trivedi, Schriger.
Supervision: Schriger, Elmore.
Conflict of Interest Disclosures: None reported.
Funding/Support: Drs Trivedi and Liu were supported by the UCLA National Clinician Scholars Program at the
David Geffen School of Medicine at UCLA. Drs Trivedi and Liu are supported by the VA Office of Academic
Affiliations through the VA/National Clinician Scholars Program. Dr Schriger’s time was supported in part by a grant
from the Korein Foundation.
Role of the Funder/Sponsor: The funders had no role in the design and conduct of the study; collection,
management, analysis, and interpretation of the data; preparation, review, or approval of the manuscript; and
decision to submit the manuscript for publication.
Disclaimer: The contents do not represent the views of the US Department of Veterans Affairs or the US
government.
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JAMA Network Open   Emergency Medicine

Injuries Associated With Standing Electric Scooter Use

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SUPPLEMENT.
eAppendix. Supplemental Methods
eTable 1. ICD-9 Codes and Other Criteria Used to Generate Injury Categories
eTable 2. Observation of Rider Behaviors and Pediatric Riders
eFigure. Case Frequency by Date, Definite Cases (Included) vs Unclear Cases (Excluded)

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