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Bicycle Helmet Assessment During Well Visits Reveals Severe Shortcomings in Condition and Fit

From Falmouth Pediatric Associates, Falmouth, Massachusetts

	ABSTRACT

TOP ABSTRACT METHODS RESULTS DISCUSSION CONCLUSIONS REFERENCES

 
Background. Improper bicycle helmet fit increases the risk of head injury.¹ Information on the rate of proper use of bicycle helmets is lacking. Promotion of helmet use is recommended at well-child and adolescent visits.² Actual helmet assessment during such visits has not been reported.

Objectives. The primary goal of this study is to measure the proportion of children whose helmets are in proper condition and can be made to fit properly by the child and/or parent. The secondary goal is to begin to assess the value and practicality of helmet inspection during well-child and adolescent visits.

Methods. The study took place at a private pediatric office in Falmouth, Massachusetts, from June 1 through August 31, 2001. Eligible children and adolescents were those aged 4 to 18 years presenting for well examination, along with siblings present at the visit. Eligible families completed a questionnaire, then had a timed attempt to fit a helmet, followed by an assessment of helmet fit and condition against a predetermined standard.

Results. Eighty-four percent (395/473) of eligible families participated. A total of 479 participants were assessed. Eighty-eight percent of participants (419/478) owned a helmet. Reported helmet use "always" or "almost always" was 73% for bicycling (317/434), 69% for in-line skating (193/279), 58% for scootering (179/310), and 50% for skateboarding (79/158). Compared with younger children, teenagers were less likely to wear helmets for all activities. Complete pass rate for every aspect of condition and fit was 4% (20/478, 95% confidence interval: 3–6). The pass rate when the parent alone fit the helmet was 0% (0/52). Three individual aspects of fit were most problematic: 1) helmet ‘resting position’ too high on the forehead (pass rate 249/479; 52%), 2) improper strap position (pass rate 157/476; 33%), and 3) excessive movement of the helmet from front to back of the head (pass rate 247/479; 52%). Mean time for questionnaire completion was 4 (standard deviation: ±1) minutes, and 7 (standard deviation: ±3) minutes for helmet assessment.

Conclusions. Ninety-six percent of children and adolescents wore helmets in inadequate condition and/or with inadequate fit. This occurred despite a high acceptance of helmet use by this population. Initial evidence suggests that helmet assessment during well visits may be practical and valuable.

Key Words: bicycle helmet • condition • fit • assessment

Head injury sustained during recreational activities continues to be a leading source of death. There are 900 bicycle-related deaths per year in the United States; three quarters of these are attributable to head injury.³ In 1997 there were >4000 head injuries related to in-line skating.⁴ Emergency department visits from scooter injuries increased by 18 times between May and October 2000 alone;⁵ of these, 27% involved the head and face. In addition, it is estimated that in 1999 >59 000 skateboard injuries occurred,⁶ 7% of which involved the head.⁷

Helmets substantially reduce the incidence of head injury.⁸ Although bicycle helmet use has increased, recent data suggests that only 12% to 15% of in-line skaters wear helmets.^4,9,10 Further, Rivara¹ et al have documented that among injured cyclists wearing helmets, poor helmet fit increases the rate of head injury. However, there are no detailed reports of the prevalence of proper helmet condition and fit. The American Academy of Pediatrics recommends promotion of helmet use as part of routine anticipatory guidance at well pediatric visits.² However, actual assessment of the helmet during such visits has not been reported.

The primary goal of this study was to document the prevalence of proper helmet condition and fit in a primary care setting, and the factors related to proper helmet use. The secondary goal is to investigate the value and practicality of actual helmet assessment during well visits.

	METHODS

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Experimental Design
The study was a prospective, cross-sectional assessment of the condition of children’s bicycle helmets and the ability of children and/or their parents to properly fit a helmet.

Setting and Participants
The setting was Falmouth (Cape Cod), Massachusetts, a town with a year-round population of 30 000, which increases to >75 000 in the summer. Falmouth Pediatric Associates, LLP, is a 3-pediatrician office-based primary care practice. It is 1 of 2 pediatric practices in the area. Patients are almost exclusively year-round residents.

Data were collected between June 1 and August 31, 2001. All children and adolescents aged 4 to 18 years presenting for well visits during office hours were eligible, as were appropriate-aged siblings present at the same visit. Participants were excluded if siblings had presented on a previous day or in the presence of severe developmental delay or disability that would preclude use of bicycles, etc.

Intervention
Families were contacted by telephone 1 or 2 business days before the well visit. The study was explained, and the family was asked to bring the child/adolescent’s helmet to the visit. If contact was unsuccessful, a message was left where possible. For those not reached in advance, the study was explained at the office.

Before or after the well visit, 1 investigator (K.E.H.) met the patient/family and reexplained the study. A cover letter, which included a disclaimer, was given. This was followed by a 15-item questionnaire, including questions related to demographics, participation and helmet use patterns, helmet condition, teaching of helmet fit, and personal knowledge of a head injury victim. Only those children who participated in an activity (eg, bicycling) answered questions about helmet use for that activity.

Subsequently, an attempt to fit the helmet as well as possible was made by the patient/parent; this was done using the child/adolescent’s helmet if present or, if not, using a helmet borrowed from our stock of several brands. For preteens, the parent was required to complete the questionnaire and to at least supervise the helmet fitting, while teens could do both, with or without their parents. This design was an attempt to simulate real life conditions.

Helmet fit and condition was then assessed by the same investigator (K.E.H.), according to a protocol, modified from Thompson et al.¹¹ Four broad categories were used for assessment: 1) condition, 2) stability, 3) room, and 4) strap (see Table 1 and Fig 1). Each category had from 2 to 5 subcomponents (14 total).

View larger version (107K): [in this window] [in a new window]   Fig 1. Photograph of directions to assess helmet movement: 1, "front to back"; 2, "rotation"; and 3, "side to side."

Pass Criteria
To be considered a "pass", all 14 subcomponents from the 4 categories assessed had to be passed. Participants who used one of our new helmets were not assessed for condition; these helmets were required to pass the 9 subcomponents from the stability, room, and strap categories.

Data Analysis
Data were entered into the EpiInfo 6.04 Y2K Update and EpiInfo 2000¹² with data cleaning at the time of entry and duplicate data review to reduce error. The relationship between variables was examined via 2 x 2 tables and ².

Ethical Approval and Consent
The study was ethically reviewed and approved by a committee from Falmouth Hospital, the local acute care health care facility. Parental consent was required for all minors; 18-year-olds could give their own consent.

	RESULTS

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This data indicates that only 4% (20/479) of children and parents passed the entire evaluation of condition and fit. There were 3 main difficulties encountered: 1) helmet resting position too high on the forehead, 2) improper strap position (failure of the straps to make a ‘V’ around the ears), and 3) excessive movement of the helmet from front to back of the head. The details of the results will now be explained.

A total of 479 children from 395 families took part. Four hundred seventy-three eligible families were scheduled for well visits during the study period, giving an assessment rate of 84% (395/473). Seventy families did not arrive for a scheduled visit or did not have appropriate consent, and 8 refused participation. The mean participant’s age was 10 years (standard deviation: ±4 years). Sixty-one percent of participants (292/479) were 12 years or younger and 39% (187/479) were 13 years or older. Ninety-four percent (452/479) were accompanied by a parent. Ninety-one percent of participants who responded (394/434) were white (see Table 2).

Eighty-eight percent of participants owned a bicycle helmet, 56% actually brought their helmet to the visit, and 44% used a helmet that we provided. Helmet use data are shown in Table 3. Self-(or parent)-reported helmet use "always" or "almost always" was 73% for cyclists, 69% for in-line skaters, 58% for scooter riders, and 50% for skateboarders. For all groups, helmet use was higher for preteenagers than for teenagers (P < .001). Ninety percent of participants felt that it was "easy" or "pretty easy" to fit a helmet.

Assessment time was 4 minutes (standard deviation: ±1 minute) for questionnaire completion, 7 (standard deviation: ±3) minutes for assessment and feedback and 11 (standard deviation: ±3) minutes overall.

	DISCUSSION

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This is the first study to examine the issue of helmet condition and fit in detail. In short, even in our controlled setting, the overwhelming majority of children, adolescents and their parents cannot properly fit a bicycle helmet. This is true regardless of age, gender, level of education or frequency of bicycle use. By measuring the different components of condition and fit, it was possible to specifically identify the problem areas. There were 3 particular problems: 1) resting position too high on the forehead, 2) improper strap position and, as a result, 3) excessive helmet movement from front to back off the forehead. All of these factors expose the frontal region, the most common site of impact in bicycle head injuries.^13,14

In 1989, Thompson et al⁸ reported that helmet use reduced the incidence of bicycle related head injury by 85%. According to Consumer Product Safety Commission data,¹⁵ helmet use increased from 18% in 1991 to 59% in 1999. Reported overall helmet use in this study was high (73% overall for bicycles). Although the validity of this data depends on reporting accuracy, this rate of helmet use would be one reason for cautious optimism.

However, Rivara et al¹ reported that improper helmet use is estimated to increase the risk of head injury by a factor of 3. In this light, our data suggests that most children and adolescents are receiving suboptimal head protection. Increased attention to teaching of helmet fit skills is required. We speculate that repeated reenforcement of proper helmet use techniques (ie, practice) will improve helmet fit rates. Possible locations for intervention include retail outlets, schools, bicycle rodeos, and (potentially) sites of pediatric care. A similar multidimensional approach has been shown effective for increasing the rate of helmet use.^16–19 Improvements in helmet design could also potentially simplify the process.

The practicality of helmet assessment in a medical setting has not been studied previously. However, the potential preventative health benefits make this idea worth considering. We speculate that assessment in a nonresearch setting will be substantially faster than it was in this study, and our anecdotal experience since the time of the initial data collection is consistent with this. Acceptance of routine helmet screening depends on convincing clinicians of its value as a preventative tool, which requires additional study. The value of many current routine components of the well examination has not been demonstrated,²⁰ and the authors caution against dismissal of an addition to the (already-demanding) well examination before an evidence-based evaluation of whether there is "fat to trim" from current recommendations.

This is also the first simultaneous assessment of helmet use patterns for bicycling, in-line skating, scooter-riding, and skateboarding. Although helmet use was a problem among adolescents in all groups, scooters and skateboards show trends to decreased helmet use at an earlier age.

This study has potential weaknesses. The pass rate depends on the appropriateness of the criteria used for proper helmet fit, but our criteria were not overly stringent and were based on published guidelines.¹¹ In addition, a large majority of those who failed did so in >1 category. In fact, when the data were reanalyzed using only the most essential components (proper resting position, helmet movement not excessive, lack of significant visible damage), the pass rate was only raised to 19% (95% confidence interval: 15–23). The low overall pass rate limited the ability to analyze variables associated with passing. It is clear, however, that no group does sufficiently well. In addition, our population is predominantly white, not urban, and conceivably more health-conscious than families who did not receive well visits. The high reported rate of helmet use would suggest an acceptance of the importance of helmets. For this reason, we doubt that most other populations would show higher rates of proper fit.

	CONCLUSIONS

TOP ABSTRACT METHODS RESULTS DISCUSSION CONCLUSIONS REFERENCES

 
Although reported helmet use among our population was high, the vast majority of children and parents failed the helmet condition and/or fit assessment. Increased attention to helmet resting position low on the forehead, proper strap position, and reduction of front to back movement may help reduce head injury rates. This assessment could potentially become part of well child visits.

	ACKNOWLEDGMENTS

 
This project was funded by a grant from the American Academy of Pediatrics.

We are very grateful to the American Academy of Pediatrics for research funding, to the staff of Falmouth Pediatric Associates for its support, to Vickoria Starczak, PhD, for statistical analysis, and Kevin Gordon, MD, MSc, for manuscript review. We would also like to thank Bell Sports, Inc (Rantoul, IL), J&B Importers, Inc (Miami, FL), and Louis Garneau Sports, Inc (Newport, VT) for donated helmets.

	FOOTNOTES

 
Received for publication Jun 10, 2002; Accepted Jan 29, 2003.

Reprint requests to (G.W.P.) Falmouth Pediatric Associates, 2 Bramblebush Park, Falmouth, MA 02540. E-mail: gparkinson{at}massmed.org

The authors have no conflicts of interest to disclose.

	REFERENCES

TOP ABSTRACT METHODS RESULTS DISCUSSION CONCLUSIONS REFERENCES

 

1. Rivara FP, Astley SJ, Clarren SK, Thompson DC, Thompson RS. Fit of bicycle safety helmets and risk of head injuries in children. Inj Prev.1999; 5 :194 –197[Abstract/Free Full Text]
2. American Academy of Pediatrics, Committee on Injury and Poison Prevention. Bicycle helmets. Pediatrics.1995; 95 :609 –610[Abstract/Free Full Text]
3. Thompson DC, Rivara FP, Thompson R. Helmets for preventing head and facial injuries in bicyclists (Cochrane Review). In: The Cochrane Library, Issue 2. Oxford, United Kingdom: Update Software; 2001
4. Beirness DJ, Foss RD, Desmond KJ. Use of protective equipment by inline skaters: an observational study. Inj Prev.2001; 7 :51 –59[Abstract/Free Full Text]
5. Unpowered scooter-related injuries—United States, 1998–2000. MMWR Morb Mortal Wkly Rep.2000; 49 :1108 –1110[Medline]
6. US Consumer Product Safety Commission. Consumer Product Safety Review. Washington, DC: US Consumer Product Safety Commission. 2000;5:1–7
7. Schieber RA, Branche-Dorsey CM, Ryan GW. Comparison of in-line skating injuries with rollerskating and skateboarding injuries. JAMA.1994; 271 :1856 –1858[Abstract]
8. Thompson RS, Rivara FP, Thompson DC. A case-control study of the effectiveness of bicycle helmets. N Engl J Med.1989; 320 :1361 –1367[Abstract]
9. Young CC, Seth A, Mark DH. In-line skating: use of protective equipment, falling patterns and injuries. Clin J Sport Med.1998; 8 :111 –114[ISI][Medline]
10. Wanda L, Herlos S, Klassen TP, et al. An observational study of protective equipment use by inline skaters. Inj Prev.1998; 4 :198 –202[Abstract/Free Full Text]
11. Thompson DC, Thompson RS, Kaufman A, Rivara RP. Increasing bicycle helmet effectiveness: the importance of proper fit and wearing position. HMO Pract.1997; 11 :25 –26[Medline]
12. Centers for Disease Control and Prevention. EpiInfo 6.04 Y2K Update and EpiInfo 2000. Atlanta, GA: Centers for Disease Control and Prevention; 2000
13. McIntosh A, Dowdell B. A field and laboratory study of the performance of pedal cyclists in real accidents. In: Proceedings of the International IRCOBI Conference on Biomechanics of Impact. Bron, France: IRCOBI; 1992:51–60
14. Smith TA, Tees D, Thom DR, Hurt HH. Evaluation and Replication of Impact damage to bicycle accidents. In: Proceedings of the 37th Annual Conference, Association for the Advancement of Automotive Medicine. Barrington, IL: Association for the Advancement of Automotive Medicine; 1993
15. US Consumer Product Safety Commission. National Bike Helmet Use Survey. Washington, DC: US Consumer Product Safety Commission; 1999:1–7
16. DiGueseppi CG, Rivara FP, Koepsell TD, Polissar L. Bicycle helmet use by children. Evaluation of a community-wide campaign. JAMA.1989; 262 :2256 –2261[Abstract]
17. Morris BA, Trimble NE, Fendley SJ. Increasing bicycle helmet use in the community. Measuring response to a wide-scale 2-year effort. Can Fam Physician.1994; 40 :1126 –1131[ISI][Medline]
18. Rivara FP, Thompson DC, Thompson RS, et al. The Seattle children’s bicycle helmet campaign: changes in helmet use and head injury admissions. Pediatrics.1994; 93 :567 –569[Abstract/Free Full Text]
19. Farley C, Haddad S, Brown B. The effects of a 4-year program promoting bicycle-helmet use among children in Quebec. Am J Public Health.1996; 86 :46 –51[Abstract/Free Full Text]
20. Panagioutou L, Rourke LL, Rourke JTP, et al. Evidence-based well-baby care. Can Fam Physician.1998; 44 :558 –567[ISI][Medline]

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This Article Abstract Full Text (PDF) P3Rs: Submit a response Alert me when this article is cited Alert me when P3Rs are posted Alert me if a correction is posted Citation Map Services E-mail this article to a friend Similar articles in this journal Similar articles in ISI Web of Science Similar articles in PubMed Alert me to new issues of the journal Add to My File Cabinet Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via CrossRef Citing Articles via ISI Web of Science (4) Citing Articles via Google Scholar Google Scholar Articles by Parkinson, G. W. Articles by Hike, K. E. Search for Related Content PubMed PubMed Citation Articles by Parkinson, G. W. Articles by Hike, K. E. Related Collections Office Practice

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