I would like to add to the
Editor's argument [1] by emphasising the uniqueness, and the
potential value, of the East York ridership dataset.
Over the past 23 years, laws
prohibiting children (or everyone) from riding bicycles, unless they
wear helmets, have been enacted in hundreds of American
municipalities, the large majority of American states, seven out of
ten Canadian provinces, all of Australia and New Zealand, and
numerous other jurisdictions around the world. In how many of these
jurisdictions was child ridership objectively documented, to see
whether the helmet requirement had any adverse effect upon it?
Irresponsibly, in almost none.
So far, only in Melbourne (Victoria law, implemented in 1990) and
New South Wales (law implemented in 1991); in Calgary, Edmonton, and
surrounding communities (Alberta law, implemented in 2002); and in
East York (Ontario law, implemented in 1995). The Australian data
were published in a scientific journal in 1996 [2], while the
Alberta data, collected in 2000 and 2006, still languish in a PhD
thesis [3]-- perhaps because they are so unfavourable to helmet
legislation. (There are other examples of relevant ridership data
that have been collected, but not disseminated, such as for British
Columbia [4], and Duval County, Florida [5, 6, 7].) Only in East
York were the surveys carried out annually or biennially over a
relatively long time span, 1990 to 2001.
The East York dataset should be
a particularly useful complement to the others for additional
reasons. For one, unlike in Australia, and several other major and
minor jurisdictions, there has never been any police enforcement of
the law. From the beginning, police forces said they would not, or
could not, enforce it [8]. For another, bicycle helmet laws do not
spring up overnight: they are preceded by campaigns to increase the
perceived dangerousness of bicycle riding. In both Australia and
Ontario as elsewhere, these campaigns long preceded the actual
introduction of the legislation [9, 10, 11]. Yet in Australia, the
single early survey was done after the campaigns were already well
underway; and not done during the same season of the year as the
later ones-- November to January for 1987/88, but May and June of
1990, 1991, and 1992 [10]. Only in East York was there a survey done
(1990) before much, though by no means all [9, 11], of the early
campaigning; and only in East York was there also rough seasonal
consistency, the observation periods being August and September of
1990, June through October of 1991 and 1992, and what has been
described as either May to September [12] or April to October [13,
14, 15] of 1993-2001.
And therein
lies a rub, or at least a first hint of one. Unlike for Australia
and Alberta, the East York surveys have been described neither
consistently nor completely, and this not just for the dates but
crucially, for the sampling strategies, efforts, and site selections
as well [16]. Worse, the actual numbers of cyclists counted have
been reported with not just small discrepancies, but huge and
incomprehensible ones [Table 1]. Even the notice of correction [17]
appended to the original study is itself in need of a correction
notice, for-- as we can now determine, the actual corrections at
last having been published-- every statement in it is false. As
summarised by the Editor [1], "the inconsistency without
explanation diminishes the credibility of the results and diverts
attention from the central research question."
Table 1.
Counts of
Children Riding Bicycles, East York, Ontario, 1990-1997,
1999, 2001 One study, same events, as differently
reported by:
Year
Parkin et al.
1993, 1995 [18, 19]
Parkin et al.
2003 [13]
Macpherson et al.
2001 [20]; Macpherson 2003 [12] (Table 6)
Macpherson 2003
[12] (Table 7)
1990
1017
914
1991
1885
1879
1992
1861
1563
1993
984
1597
1994
1083
2355
1995
1227
763
1126
1996
1202
1371
1217
1997
916
1375
918
1999
747
1124
Table 1, continued:
Year
Report of pers.
comm. 2003 [21]
Macpherson 2005
[22]
Khambalia et al.
2005 [14]
Macpherson et
al., 2006/2012 [17]
1990
1991
1992
1993
894
1994
1040
1995
1126
1056
1996
1217
1199
1997
918
909
1999
1128
1124
1128
2001
614
All Years
At least one
year's count is 550 and at least one is 1795; total for all years
is 10,935
What then are we to make of
the East York data? With such inconsistencies, and no help from the
authors forthcoming, the natural conclusion is: little or nothing of
scientific value.
I have come to believe that,
with some clarification, this conclusion-- and the shameful waste it
would imply, of over a decade of research effort on an unrepeatable
historical circumstance-- is not inevitable, and this was one of the
motivations for my complaint to Injury Prevention. Regardless of any
data destruction, the authors should be able to tell the research
community whether there was a survey in 1989, or not; and if not, on
what basis they were able to say that the helmet use rate in that
year was 0% [11]. The authors should be able to tell us whether the
sites sampled, or their number, were the same for every year from
1990 to 2001 [15]; or not the same [14]. The authors should be able
to tell us whether, as seems the only logistical possibility, the
1990 survey was a minimal one, and therefore had all sites or areas
sampled to the same extent. They should be able to tell us if, as
seems implied by the statistical goals (to roughly double the 1990
sample size) and the time budget (again roughly double), the 1991
survey also had double the number of survey hours, and whether these
were again uniformly distributed amongst the sites or areas; or if
not, then according to what strategy. The authors should be able to
tell us what the situation was for 1992, and then again with regard
to the overall sampling strategy for 1993-2001. And the authors
should be able to tell us by what method they aggregated the
site-level cyclist counts and numbers of survey hours into overall
rates, something they have yet to clearly explain.
I think these are the minimal
explanations that the authors owe the research community, whose
members have endeavoured to understand, or wrongly used [23], their
work; the bicycling community, whose members had to defend their way
of life against the premise of it [24, 25]; and the Canadian
taxpayer, who paid for it.
References
1.
Johnston BD. Living in the grey area: a case for data sharing in
observational epidemiology. Injury Prevention 2012;0:1–2.
doi:10.1136/injuryprev-2012-040671.
2.
Robinson DL. Head injuries and bicycle helmet laws. Accid Anal Prev
1996;28:463-475.
3. Karkhaneh M. Bicycle helmet
use and bicyclists head injuries before and after helmet legislation
in Alberta Canada. PhD thesis, University of Alberta, 2011.
4. Foss RD, Beirness DJ. Bicycle
helmet use in British Columbia: effects of the helmet use law.
Pre-and post-law bicycle helmet use in British Columbia. April 2000.
University of North Carolina Highway Safety Research Center; Traffic
Injury Research Foundation.
http://www.hsrc.unc.edu/safety_info/bicycle/helmet_use_bc.pdf
(accessed Feb 24 2009).
5. Bicycle helmet use laws:
lessons learned from selected sites. National Highway Transportation
Safety Authority.
http://www.nhtsa.gov/people/injury/pedbimot/bike/bikehelmetuselawsweb/pages/7ProfileBJacksonvill.htm
(accessed Nov 18 2012).
6. Conserve by Bicycle Phase 1
Study: Report. Florida Department of Transportation.
http://www.dot.state.fl.us/safety/ped_bike/brochures/pdf/CBBphase1%20Report062907.pdf(accessed
Nov 18 2012).
7. Florida Traffic and Bicycle
Safety Education Program.
www.saferoutesinfo.org/sites/default/files/page/Pieratte.pdf
(accessed Nov 18 2012).
8. Wright L, MacKinnon DJ.
Province eyes tougher law on helmets . The Toronto Star (metro
edition). 1996;Oct 17:A2.
9. Legislative Assembly of
Ontario, committee transcripts: Standing Committee on Resources
Development, November 20, 1991 - Bill 124, Highway Traffic Amendment
Act, 1991.
<http://www.ontla.on.ca/web/committee-proceedings/committee_transcripts_details.do?locale=en&Date=1991-11-20&ParlCommID=105&BillID=&Business=Bill+124%2C+Highway+Traffic+Amendment+Act%2C+1991&DocumentID=17013>
(accessed Nov 18 2012).
10. Finch CF, Heiman L, Neiger
D. Bicycle use and helmet wearing rates in Melbourne, 1987 to 1992:
the influence of the helmet wearing law. Monash University Accident
Research Centre 1993;Report No. 45.
http://monash.edu.au/muarc/reports/muarc093.html (accessed Jul 25
2009).
11. Wesson D, Spence L, Hu X, et
al. Trends in bicycling-related head injuries in children after
implementation of a community-based bike helmet campaign. J Ped Surg
2000;35:688-689.
12. Macpherson AK. An Evaluation
of the Effectiveness of Bicycle Helmet Legislation. PhD Thesis,
Institute of Medical Sciences, University of Toronto 2003.
13. Parkin PC, Khambalia A, Kmet
L, Macarthur C. Influence of socioeconomic status on the
effectiveness of bicycle helmet legislation for children: a
prospective observational study. Pediatrics 2003;112:e192-e196.
14. Khambalia A, MacArthur C,
Parkin PC. Peer and adult companion helmet use is associated with
bicycle helmet use by children. Pediatrics 2005;116:939-942.
15. Macpherson AK, Macarthur C,
To TM, Chipman ML, Wright JG, Parkin PC. Economic disparity in
bicycle helmet use by children six years after the introduction of
legislation. Inj Prev 2006;12:231-235.
16. Kary M. Compendium of errors
and omissions in Canadian research group's bicycle helmet
publications. http://www.cyclehelmets.org/papers/c2031.pdf (accessed
Dec 1 2011).
17. Update to Macpherson et al.
7 (3): 228. Correction. Inj Prev 2006;12:432.
http://injuryprevention.bmj.com/content/12/6/432.full (accessed Nov
18 2012).
18. Parkin PC, Spence LJ, Hu X,
Kranz KE, Shortt LG, Wesson DE. Evaluation of a promotional strategy
to increase bicycle helmet use by children. Pediatrics
1993;91:772-777.
19. Parkin PC, Hu X, Spence LJ,
Kranz KE, Shortt LG, Wesson DE. Evaluation of a subsidy program to
increase bicycle helmet use by children of low-income families.
Pediatrics 1995;96:283-287.
20. Macpherson AK, Parkin PC, To
TM. Mandatory helmet legislation and children’s exposure to
cycling. Inj Prev 2001;7:228–230.
22. Macpherson AK. An Evaluation
of the Effectiveness of Bicycle Helmet Legislation.
http://www.neurosurgery.pitt.edu/circl/webinars/archive/2005/documents/macpherson_101105.pdf
(accessed Dec 15 2008).
23. Legislation for the
compulsory wearing of cycle helmets. British Medical Association
Board of Science and Education, November 2004.
http://www.helmets.org/bmareport.htm (accessed Nov 18 2012).
24. Testimonies of Neil Farrow
and of the Windsor Bicycling Committee. Legislative Assembly of
Ontario, committee transcripts: Standing Committee on Resources
Development, December 02, 1991 - Bill 124, Highway Traffic Amendment
Act, 1991.
<http://www.ontla.on.ca/web/committee-proceedings/committee_transcripts_details.do?locale=en&Date=1991-12-02&ParlCommID=105&BillID=&Business=Bill+124%2C+Highway+Traffic+Amendment+Act%2C+1991&DocumentID=16994>
(accessed Nov 18 2012).
25. Testimony of Marcia Ryan.
Legislative Assembly of Ontario, committee transcripts: Standing
Committee on Resources Development, November 25, 1991 - Bill 124,
Highway Traffic Amendment Act, 1991.
<http://www.ontla.on.ca/web/committee-proceedings/committee_transcripts_details.do?locale=en&Date=1991-11-25&ParlCommID=105&BillID=&Business=Bill+124%2C+Highway+Traffic+Amendment+Act%2C+1991&DocumentID=16980#P181_55605>
(accessed Nov 18 2012).
Schwebel (1) raises the issue of how auditory processing might
contribute to safe negotiation of the roads by pedestrians. In particular,
does the masking of relevant auditory information entail unnecessary
danger? Almost coincidentally, a recent review (2) has considered possible
technological developments that might provide useful supplementary
information to aid drivers in avoiding collisions: potential sources might
be...
Schwebel (1) raises the issue of how auditory processing might
contribute to safe negotiation of the roads by pedestrians. In particular,
does the masking of relevant auditory information entail unnecessary
danger? Almost coincidentally, a recent review (2) has considered possible
technological developments that might provide useful supplementary
information to aid drivers in avoiding collisions: potential sources might
be auditory in nature.
The purpose of this note is to draw attention to psychophysical
evidence for the potential of auditory information in such contexts. For
those with normal or corrected-to-normal eyesight, visual information is
almost certainly of primary importance in conveying potential collision -
specifically, visual expansion of the viewed object, or "looming". The
object - say, an automobile - may be moving towards the static observer;
alternatively, the observer may be moving towards a static object. Also,
both observer and object could be moving towards each other. In contrast,
an unthreatening receding object undergoes visual contraction.
There is strong evidence of hard-wired sensory processing of visual
motion: motion aftereffects are well-known illusions in the visual
modality, whereby the observer perceives illusory motion of a static
stimulus after viewing steady motion of that stimulus for a minute of so.
The aftereffect of visual approach is substantially stronger than the
aftereffect of visual recession: the sensory-systems of humans (and many
other species) are much more sensitive to approach, almost certainly
reflecting the survival value in avoiding damaging collisions (3,4).
An analogous asymmetry applies to the auditory modality: in this
case, approach is conveyed predominantly by increasing sound-level, while
the less critical recession is conveyed by decreasing sound-level. Growing
-louder aftereffects are stronger than growing-softer aftereffects (5).
However, there is a limitation to the effectiveness of audition in
determining collision. In vision, most objects are rigid or near-rigid:
objects varying in size - for example, inflating or deflating balloons -
are unusual, so an assumption of rigidity with regard to vision is
extremely plausible. However, in audition, analogous assumptions are
weaker and more ambiguous. For example, many sounds are percussive: after
a short rise-time, their sound-levels steadily reduce. Indeed, evidence
suggests that compensation for this characteristic is necessary in
measuring auditory aftereffects (5).
The clear inference to be drawn is that vision provides better
evidence for collision than does audition. No doubt the latter is useful
for the visually-impaired - and might be quite well-developed for this
group. However, for the normal-sighted the ambiguity of auditory stimuli
may be such that vision inevitably predominates in responding to motion-in
-depth. Instead, the real issue of much auditory stimulation on the road -
such as music presented over earphones, or via an automobile's sound-
system - may be one of distracted attention.
REFERENCES
(1) Schebel DC. Do our ears help us cross streets safely? Inj Prev
2012 10.1136/injuryprev-2012-040682.
(2) Spence C. Drive safely with neuroergonomics. Psychologist 2012;
18: 664-667.
(3) Scott TR. Lavender AD, McWhirt RA, Powell DA. Directional
asymmetry of motion aftereffect. J Exp Psychol 1966; 72: 806-815.
(4) Reinhardt-Rutland AH. Perception of motion-in-depth from luminous
rotating spirals: direction asymmetries during and after rotation.
Perception 1994; 23: 763-769.
Re: Comparing apples with apples? Abusive Head Trauma, Drowning and LSVROs (response to Kaltner, Kenardy, Le Brocque & Page, 2012), by Watt, Franklin, Wallis, Griffin, Leggat and Kimble (2012)
Developing the epidemiological literature base on the occurrence of all forms of childhood injury is essential to the development and promotion of injury prevention efforts. As is rightfully highlighted by Watt, Franklin, Wall...
Re: Comparing apples with apples? Abusive Head Trauma, Drowning and LSVROs (response to Kaltner, Kenardy, Le Brocque & Page, 2012), by Watt, Franklin, Wallis, Griffin, Leggat and Kimble (2012)
Developing the epidemiological literature base on the occurrence of all forms of childhood injury is essential to the development and promotion of injury prevention efforts. As is rightfully highlighted by Watt, Franklin, Wallis, Griffin, Leggat and Kimble (2012), limitations in the availability of easily accessible child injury data exist in Queensland. Within Kaltner, Kenardy, Le Brocque & Page's (2012) paper, published figures on rates of alternate forms of childhood injury were utilised to contextualise the occurrence of Abusive Head Trauma (AHT). Their selection was based on the most recent figures available to the authors following extensive literature searches; as is discussed by Watt et al., more comparable and recent figures are not accessible in the public sphere.
With the cessation of funding to the Queensland Trauma Registry, the availability of up-to-date, reliable injury data within Queensland is limited. This presents a further challenge to all injury researchers in the state, alongside the hurdle of approvals necessary to access Queensland Health data as overviewed by Watt et al. (2012). In undertaking the important work of research and prevention for all forms of childhood injury, high level support-including financial commitment- for the development and maintenance of reliable and accessible injury databases is necessary.
Hemenway (1) describes three beliefs which may jeopardize injury-
avoidance: optimistic ("it will never happen to me"), fatalistic
("accidents happen") and materialistic ("you probably deserved it"). Such
a scheme parallels well-known trait theories regarding the individual's
general personality (2); given the value of those endeavours,Hemenway's
scheme deserves serious consideration.
Hemenway (1) describes three beliefs which may jeopardize injury-
avoidance: optimistic ("it will never happen to me"), fatalistic
("accidents happen") and materialistic ("you probably deserved it"). Such
a scheme parallels well-known trait theories regarding the individual's
general personality (2); given the value of those endeavours,Hemenway's
scheme deserves serious consideration.
Nonetheless, it may be incomplete. In this note, I argue for the
inclusion of values that I label as societal - that is, they are best
understood in terms of major societal groups. Evidence supporting this
proposal resides in a comparison of road-travel and rail-travel; this
suggests that society expects higher standards of safety for rail than for
road. Two examples follow:
A. SAFETY AND VEHICLE DESIGN: Traditionally, Britain's railway
carriages were equipped with slam-doors, which could be opened by
passengers even when the train was moving. During the mid-2000s, such
stock - even if relatively new - was mostly replaced by carriages using
less reliable sliding-doors under electronic control of guard and driver.
The saving in injuries and deaths has almost certainly been miniscule: I
see no evidence against this assertion in Britain's transport data (3).
Society deemed that the relevant legislation should be enacted, despite
the heavy costs involved.
Cost can have different implications on the road: SUVs - large and
powerful four-wheel-drive automobiles - are more dangerous than smaller,
cheaper-to-buy and cheaper-to-run automobiles (4). One might suppose that
governments would seek to reduce the prevalence of SUVs, since the choice
of SUV ownership appears to be little more than an issue of perceived
prestige.
B. ATTENTION TO THE TASK: Society has long expected that train
drivers pay undivided attention to their job. Indeed, the use of a "dead-
man's-handle" or its modern developments entails the train automatically
coming to a stand if the driver diverts attention (5).
In contrast, values concerning the road imply that drivers can safely
carry out other tasks during driving. A notably transparent example
concerns the common media device of televising an inverview while the
interviewee is driving. This presents an extraordinarily inept message to
the motoring community. Inattention on the road is supposedly discouraged,
although specific legislation is limited. The banning of mobile-phone use
is a rare case, but its effectiveness must be seriously doubted (6).
CONCLUSION: Hemenway offers a useful scheme for investigating injury
prevention. I argue here that - at least regarding travel - the problems
are not simply to be understood by reference to the individual's beliefs.
The problems are also societal. The two examples above indicate greater
threat on road than on rail. There are other examples that can be
developed: the use of psychoactive drugs (7,8) and failure to observe
speed-limits (9). Paradoxically, the latter may have been exacerbated by
the legally-required use of seatbelts (10).
The imbalance in societal values is consistent with casualty
statistics (3). Until society is prepared to recognise and implement the
lessons from rail-travel, an important conduit for injury prevention in
road-travel will remain under-exploited.
REFERENCES
1. Hemenway D. Three common beliefs that are impdiments to injury
prevention. Inj Prev 2012;
00:1-4. doi:10.1136/injuryprev-2012-040507
2. Hewstone M, Fincham F, Foster J. Psychology. 2005. Leicester UK:
BPS.
3. Department for Transport 2011. Transport statistics GB: 2010
Annual report. London: TSO.
4. Simms S, O'Neill D. Sports utility vehicles and older pedestrians.
BMJ 2005;331:787-8.
5. Harris M. Dead man's handle. In Simmons J, Biddle G (eds). The
Oxford campanion to British railway history. 2002. Oxford:OUP (p 125).
6. McEvoy SP, Stevenson MR, McCartt AT, Woodward M, Haworth C,
Palmara P, Cercarelli R. Role of mobile phones in motor vehicle crashes
resulting in hospital attendance: a case-crossover study. BMJ 2005;331:428
-430.
7. Perkins A. Red Queen: the authorized biography of Barbara Castle.
2003. London: Macmillan.
8. Hall W. Driving while under the influence of cannabis. BMJ
2012;344:e595 doi: 10.1136/bmj.e595.
We acknowledge that we did not control for all of the differences in
road geometry and building typologies because there are no ideal matched
streets (Re: Cooper). However, alternative research designs also have
limitation and feasibility issues. For before and after study designs,
some of the Montreal cycle tracks are 20 years old, before injury
surveillance and traffic counting data systems were available. Limiting to...
We acknowledge that we did not control for all of the differences in
road geometry and building typologies because there are no ideal matched
streets (Re: Cooper). However, alternative research designs also have
limitation and feasibility issues. For before and after study designs,
some of the Montreal cycle tracks are 20 years old, before injury
surveillance and traffic counting data systems were available. Limiting to
cycle tracks that were developed after these data were available would
limit us to a much smaller number of cycle tracks, thus reducing the
statistical power. Utilizing a multivariate analysis to account for other
factors such as road geometry, buildings types, pedestrians, trees, etc.
would answer a different research question - about the possible
independent effect of each factor - and would require many more cycle
tracks or another unit of analysis (ex. intersections). Therefore,
bicycling on cycle tracks was compared to bicycling on streets without
cycle tracks. To select the alternative reference streets without cycle
tracks, a few parallel reference streets were considered for each street
with a cycle track, The parallel street was then selected because it had,
as much as possible, the same cross streets. Recognizing no perfect
reference street existed, we also compared relative danger from vehicular
traffic by obtaining the injuries to motor vehicle occupants (EMR data).
Given these limitations, none of the 6 pairs were found to have a
statistically significant higher risk of injury on the cycle tracks. Thus,
not one of the comparisons in this research conducted in Montreal
supported the old hypothesis that bicycling on cycle tracks posed greater
risk than bicycling in the road. In fact the opposite was true as
bicycling on the cycle tracks posed less risk.
Our population-based study (1) on the effectiveness of breed-specific
legislation (BSL) targeting pit-bull (terrier) type dogs in the Canadian
province of Manitoba generated some interest in the media and among policy
-makers and the public in Canada and the United States (2-10). With this
experience of listening to different stakeholders and communicating with
some, we hope to elaborate on our findings in language that is...
Our population-based study (1) on the effectiveness of breed-specific
legislation (BSL) targeting pit-bull (terrier) type dogs in the Canadian
province of Manitoba generated some interest in the media and among policy
-makers and the public in Canada and the United States (2-10). With this
experience of listening to different stakeholders and communicating with
some, we hope to elaborate on our findings in language that is accessible
to all. The objective of the study was to determine trends in the
frequency of dog-bite injury hospitalizations (DBIH) over time for
jurisdictions with and without a ban on pit bull (terrier)-type dogs in
Manitoba (1).
We reported that at the provincial level in Manitoba, there was a
decrease in incidence of DBIH from 3.47 to 2.84 per 100,000 person-years
associated with implementation of a ban on pit-bull terrier type dogs.
That is, there was a decrease by 0.63 per 100,000 persons per year (an
18.1% decrease in DBIH rate) in 16 self-selected urban and rural
jurisdictions. Correspondingly, in people aged 0 to < 20 years, there
were 1.76 fewer DBIH per 100,000 person-years (a 25.5% decrease in DBIH
rate) in Manitoba. This decrease in rates of DBIH may be a conservative
finding because enforcement of legislation, which was not measured and is
known to have varied across the jurisdictions and over the years, is
assumed to be minimal, if at all. While the type of legislation studied
was specifically a ban, no jurisdictions were known to have outlawed pit
bulls overnight. As existing individual dogs were allowed to live out
their lifetimes, no drastic reduction in numbers of pit bulls, and by
extension, in numbers of DBIH, was expected in jurisdictions that
implemented bans only gradually since 1990.
What does the change in incidence of DBIH at the provincial level
mean? The Canadian province of Ontario, with a population about 11 times
larger than Manitoba, has a province-wide ban on pit-bull terrier type
dogs since 2005 (11). Assuming that Ontario's DBIH rate, rate of
penetration of dog population (i.e., dogs per capita of human population)
and dog-breed distributions are similar to those in Manitoba, we applied
the decrease of 0.63 DBIH per 100,000 people per year to Ontario's
population of 12.8 million in 2011 (12,13). (While Manitoba's rural
population is considered to be 28%, Ontario's rural population is reported
to be 15%.) We estimate that there may have been 81 fewer DBIH in 2011
alone in Ontario on account of the province-wide ban. As Ontario's
population of those aged < 20 years was 3 million (13), 54 (66.7%) of
the estimated decrease by 81 DBIH among all ages in 2011 would have been
in people aged < 20 years.
When considering rate differences in post-legislation period compared
with pre-legislation period in Winnipeg alone, our data do not indicate a
change in DBIH rate. Therefore, it is natural to assume that BSL does not
work. However, our study does not account for changes in overall number
of dogs over the long period under study. Based on growth in number of
pet dog populations in the United States over the last two decades
(14,15), we propose that any hypothesized decrease in the number of DBIHs
due to pit-bull attacks is likely masked, and the effect of legislation
diluted, by a simultaneous increase in DBIHs due to attacks by dogs from
other breeds or breed groups. Again, this explanation is quickly assumed
to be evidence that breed bans do not work. After all, an argument
against BSL is that breed composition in dog populations can change such
that other dangerous dogs replace dogs from banned breeds. A limitation
of the study was our inability to separate the proportion of DBIHs caused
by dogs of banned breeds from the proportion caused by dogs of other
breeds or breed groups. However, with the assumption that replacement is
necessarily different from addition of more dangerous dogs to the existing
numbers, we compared DBIH rates in jurisdictions with pit bull-specific
ban (e.g., Winnipeg) to DBIH rates in jurisdictions without such bans
(e.g., Brandon). The idea behind this analysis is that, unlike pit-bull
specific bans, voluntary changes in breed popularity have no boundaries,
and jurisdictions with bans are assumed to be similar to jurisdictions
without bans in every respect other than the existence of the ban. Such an
analytic approach is also an improvement over a pre/post analysis of data
from a single jurisdiction adopting the ban.
We adopted a generalized estimating equations (GEE) model for this
comparative analysis. This multivariate model allowed us to isolate the
effect of legislation while modeling annual DBIH counts adjusted for human
population counts, calendar year of DBIHs and baseline differences in
underlying DBIH rates across jurisdictions with and without legislation.
The model yielded an incidence rate ratio--i.e., the rate of DBIHs in
jurisdictions with a ban relative to the rate in jurisdictions without a
ban.
The results from the GEE model were not remarkable when data from all
Manitoba jurisdictions were analyzed, but as control jurisdictions were
more likely to be rural jurisdictions, there was a high inter-correlation
among variables. One way of controlling for the confounding effects of
rurality of jurisdictions is to stratify the dataset into rural and urban.
Therefore, we restricted analyses to urban jurisdictions alone. The
results indicated that for every one DBIH in Brandon, there were 1.29
DBIHs in Winnipeg before the pit-bull ban and 1.10 DBIHs after the ban.
This is a 14.7% reduction in rate of DBIH in people of all ages. In
people younger than 20 years old, for every one DBIH in Brandon, there
were 1.28 DBIHs in Winnipeg before the ban and 0.92 DBIHs after the ban.
This amounts to a 28.1% reduction in rate of DBIH. These findings were
statistically significant. Other reasons for this decrease cannot be ruled
out in this real-world, observational study which can be thought of as a
non-randomized, self-selected community trial. However as far as we can
ascertain, no other dog-control legislation is different between the two
jurisdictions.
Going forward, researchers should compare DBIH rates temporally as
well as geographically. Future (controlled) studies in other places where
pit-bull specific bans have been in effect long-term are still necessary
to conclusively understand if rates of DBIHs generally and gradually
decline when pit-bulls are removed from the population. This is because
effectiveness (or magnitude of rate decrease) may be variable depending on
local conditions, even if everyone agreed that pit-bulls caused a
disproportionate number of DBIHs. For example, if rate of pit-bull
penetration is high, then magnitude of effectiveness of a pit-bull ban
would likely be higher than observed in our study, if a cause-effect
relationship truly exists. However, if rate of pit-bull penetration is
zero (i.e., no pit bulls), then a ban that was proven to be 100% effective
elsewhere (hypothetically speaking) would bring about little change to
DBIH rate as, technically, there are no dogs to be banned. Furthermore,
pit bulls in one region of the world may be less aggressive than pit bulls
in another region owing to potentially different lineages and differences
in dog-owning cultures. While the value inherent in local data should not
be underestimated for the purposes of local policies, data from larger
jurisdictions with bigger populations of dogs, including those from the
banned breeds, and higher rates of DBIHs will further shed light on this
public health topic that appears to attract a lot of public and
stakeholder interest.
References
1. Raghavan M, Martens P, Chateau D, Burchill C. Effectiveness of
breed-specific legislation in decreasing the incidence of dog-bite injury
hospitalizations in people in the Canadian province of Manitoba. Injury
Prevention doi:10.1136/injuryprev-2012-040389. E-pub ahead of print.
2. Blackwell T. Controversial pit bull bans result in fewer dog
bites: study. National Post, July 5, 2012.
http://news.nationalpost.com/2012/07/05/controversial-pit-bull-bans-result
-in-fewer-dog-bites-study/ (accessed 9 September, 2012).
3. Kaufman B. Calgary bylaw boss dismisses pit bull breed ban study.
Calgary Sun. July 6, 2012. http://www.calgarysun.com/2012/07/06/calgary-
bylaw-boss-dismisses-pit-bull-breed-ban-study (accessed 9 September,
2012).
4. Kay B. Study proves pit bull ban is justified. National Post, July
6, 2012. http://fullcomment.nationalpost.com/2012/07/06/barbara-kay-
study-proves-pitbull-ban-is-justified/ (accessed 9 September, 2012).
5. DogsBite Blog. New Canadian study shows pit bull bans result in
fewer hospitalizations. Dogsbite.org, Austin, Texas. July 9, 2012.
http://blog.dogsbite.org/2012/07/new-canadian-study-shows-pit-bull-
bans.html (accessed 9 September, 2012).
6. Anonymous. Winnipeg, Manitoba far behind Calgary in community
safety. National Canine Research Council, LLC , Amenia, New York. July 9,
2012. http://www.nationalcanineresearchcouncil.com/blog/winnipeg-manitoba
-far-behind-calgary-in-community-safety/ (accessed 9 September, 2012).
7. Parsons L. Severe bites down after pit bull ban. Winnipeg Metro,
July 10, 2012. http://metronews.ca/news/winnipeg/291327/severe-dog-bites-
down-in-winnipeg-since-pit-bull-ban-study/ (accessed 9 September, 2012).
8. Jonas G. The state has no business in the dog houses of the
nation. National Post, July 11, 2012.
http://fullcomment.nationalpost.com/2012/07/11/george-jonas-the-state-has-
no-business-in-the-doghouses-of-the-nation/ (accessed 9 September, 2012).
9. Editorial: Pit bull bans may actually be working. The Hamilton
Spectator, July 11, 2012. Excerpt reprinted from The St. John's Telegram.
10. Raghavan M. Invited presentation: Study on the effectiveness of
breed-specific legislation in decreasing dog-bite injury hospitalizations
in Manitoba--what it means to researchers, policy-makers and the public.
Manitoba Agriculture, Food and Rural Initiatives (MAFRI) Lunch & Learn
Session. August 13, 2012, Winnipeg, Manitoba.
11. Ontario Ministry of the Attorney General. Information on the dog
owners' liability act and public safety related to dogs statute law
amendment act, 2005.
http://www.attorneygeneral.jus.gov.on.ca/english/about/pubs/dola-
pubsfty/dola-pubsfty.asp#TOC_03 (accessed 9 September, 2012).
12. Statistics Canada. Population, urban and rural, by province and
territory. http://www.statcan.gc.ca/tables-tableaux/sum-
som/l01/cst01/demo62a-eng.htm (accessed 9 September, 2012).
13. Statistics Canada. Focus on geography series, 2011 census--
province of Ontario. http://www12.statcan.gc.ca/census-recensement/2011/as
-sa/fogs-spg/Facts-pr-eng.cfm?Lang=Eng&GK=PR&GC=35 (accessed 9 September,
2012).
14. PRWeb. New survey reveals pet ownership at its highest level in
two decades and pet owners are willing to pay when it comes to pet's
health. American Pet Products Association Press Release, Greenwich, CT
(Vocus/PRWEb) April 04, 2011.
http://www.prweb.com/releases/2011/4/prweb8252684.htm (accessed 2Feb
2012).
15. Shepherd AJ. Results of the 2006 AVMA survey of companion animal
ownership in US pet-owning households. J Am Vet Med Assoc 2008;232:695-6.
Kerrianne Watt1, Richard C Franklin1, Belinda Wallis2, 3, Bronwyn
Griffin2, 3, Peter Leggat1; Roy Kimble2,3
1School of Public Health, Tropical Medicine and Rehabilitation
Sciences, James Cook University
2Queensland Children's Medical Research Institute
3Royal Children's Hospital, Centre for Burns and Trauma Research,
School of Medicine, University of Queensland
Re Infant Abusive Head Trauma incidence in Queensland, Australia
Kaltner et al doi:10.1136/injuryprev-2012-040331
Head trauma in children, particularly as a consequence of abuse, is an important issue and we support the need for interventions in this area. We would however like to clarify some potentially misleading information published in the article by Kaltner et al, regarding the incidence of abusive head trauma (AHT) in Queensland in relation to other serious childhood trauma such as drowning and low speed vehicle run-overs (LSVROs).
Kaltner et al estimated that the incidence rate for AHT (as defined by death or admission to hospital for greater than 24 hours) among children aged 0-2 yrs in Queensland during 2005-2008 was 6.7 per 100 000 per annum. Kaltner argued that the incidence rate for AHT was higher than that for drowning and LSVROs. However, the references used for incidence rates related to drowning and LSVROs are not comparable in several respects. Firstly, there is a 10 year gap between the incidence rates for LSVROs and drowning referenced by Kaltner et al, and the calculated AHT incidence rates. The Mackie1 data on drowning are derived from 1992-1997, and the data on LSVROs from the Queensland Council on Paediatric Morbidity and Mortality2 relate to 1994-1996. Secondly, the incidence rates for drowning and LSVROs referred to by Kaltner relate to fatalities, whereas the incidence rates calculated for AHT relate to hospital admissions and fatalities. Thirdly, Kaltner et al used data relating to 0-4 yr old children in their incidence rate calculations, whereas the referenced incidence rates for drowning and LSVRO relate to 0-5 yr olds (drowning) and 0-4yr olds (LSVRO), respectively. We suggest that for these three reasons, it is not appropriate to compare incidence rates calculated for AHT and drowning / LSVROs.
We present for alternative consideration incidence rates calculated from two recently completed studies on drowning and LSVROs funded by the Queensland Injury Prevention Council. In these studies, data from multiple sources (death, hospital admission, Emergency Department presentation, ambulance) were linked to calculate incidence rates for fatal and nonfatal drowning (2002-2008) and LSVRO incidents (1999-2009)3-4. From data collected for these two studies, we have calculated incidence rates for drowning and LSVROs using the same definitions employed by Kaltner et al for AHT (i.e., fatalities and admission to hospital for 24hrs or more), for 0-2 yr old children in Queensland, for the same time period (2005-2008). The comparable incidence rates (IR) are as follows: drowning IR = 65.27 per 100 000 per annum; LSVRO IR = 42.06 per 100 000 per annum. These incidence rates are much higher than those referenced by Kaltner et al (drowning – 4.6; LSVRO 2.4).
This information is yet to be publicly released, and highlights the value of linked data when exploring injury issues. The difficulties associated with obtaining these data may explain why Kaltner et al reported incidence rates that were not directly comparable. This also reinforces the importance of defining serious injury to allow comparison of like with like5.
There is currently no linked health dataset in Queensland. Linked data to obtain accurate, contemporary and crucial information regarding injury are only available on a project by project basis, when specific funding, ethical approval, and access approval (via the Director General of Queensland Health), are obtained. In addition, funding for the Queensland Trauma Registry was terminated, thus losing another vital source of information about injury in Queensland. As highlighted earlier this year in this journal, reliable information about injuries fundamentally underpins good injury prevention6
There is no doubt that AHT among young children is an important issue and one that deserves increased attention and focus on prevention. However this does not diminish the importance of other causes of serious and fatal injury among young children, such as drowning and LSVROs. We advocate for urgent attention on better data collection regarding serious injury in Queensland to facilitate prevention strategies for all injury among children.
References:
1. Mackie IJ. Patterns of Drowning in Australia, 1992-1997. Medical Journal of Australia; 1999; 171:587-90.
2. Queensland Council on Obstetric and Paediatric Morbidity and Mortality. Maternal, Perinatal and Paediatric Morbidity and Mortality 1994-1996. Brisbane: Queensland Council on Obstetric and Paediatric Morbidity and Mortality. Brisbane, 1998.
3. Kimble R, Wallis B, Nixon J, Watt K, Cass D, Gillen T & Griffin B. 10 Year Review of Low Speed Vehicle Run-Overs in 0-15 years across Queensland. Injury Prevention; 2010; 16 (Suppl 1): A1-289.
4. Wallis B, Watt K, Franklin R, Nixon JA, Kimble R. Nonfatal drowning in children and young people in Queensland (Australia) 2002-2008. Injury Prevention; 2010; 16 (Suppl 1): A138
5. Langley J, Cryer C. A consideration of severity is sufficient to focus our prevention efforts. Injury Prevention; 2012; 18(2) 73-74.
6. Langley JD, Davie GS, Simpson JC. Quality of hospital discharge data for injury prevention. Injury Prevention; 2007; 13: 42-44.
When Lusk et al. submit to the editor a formal list of errata to be attached to their article, I expect they will duly correct all the errors, omissions, and false statements that have been brought to their attention, and not just the three they chose to mention here. This would include amongst other items providing a correct explanation for their choices of particular termination points (rather than the non...
When Lusk et al. submit to the editor a formal list of errata to be attached to their article, I expect they will duly correct all the errors, omissions, and false statements that have been brought to their attention, and not just the three they chose to mention here. This would include amongst other items providing a correct explanation for their choices of particular termination points (rather than the nonsensical one found in footnote 2 to their Table 1), and retracting their false statement that the path and comparison streets have similar cross traffic and numbers of intersections. And as I also already objected, the authors need to explain how they got the usage data for the year 2000 they claim to have for the de Maisonneuve path segment. Considering that no municipality maintains automatic counters there, and that the authors' study was not underway in 2000, contrary to their claim it would seem they do not have data as they describe for that year.
Since I expect the authors will do their duty and correct these faults, I use the space remaining to correct two new errors they have introduced, and to object further.
(1) The path segment they claimed to have studied from 1999 to 2008 but that did not exist for almost the entirety of that period was created in 2007, not 1997.
(2) The corresponding length correction would have been approximately 180 metres, if they had gotten the extra length right to begin with. They did not, and so the correction should be instead approximately 350 metres. The authors are yet to explain how they got their lengths.
(3) The authors tell us not to worry about their selections of comparison streets: these were done "a priori, without knowledge of their safety record, in consultation with local cycling advocates". In fact the biases are so extreme that they are obvious without any measurement. Who were these sight, smell, and hearing impaired local advocates? Their contribution is not identified in either the contributorship statement or the acknowledgements, and the genesis of the study's path and comparison samples remains as mysterious as ever.
(4) The authors say their failures to describe the radical divergences between their path and comparison streets "do not affect the study results." They need to be reminded that without appropriate comparisons, their study lacks validity. Indeed, showing that a comparison is preposterous does not change the results so calculated: instead, it discredits them.
(5) I object to the authors' claim that "not even one comparison pair showed significantly greater risk" for the path. Let us be clear: even with the biased nature of the comparisons, over the near decade of the study period, according to their methods the actual injury rates on the paths were in three cases respectively 21%, 18%, and 1% worse than on the comparison streets. That none of these were found statistically significant is an indictment of the imprecision of the authors' methods, not an endorsement of the paths. I particularly object to this exploitation of the confusion between statistical and public health significance because I already called the authors on it in my previous criticism.
The authors bemoan the fact that on-street path construction has been "hampered" by the AASHTO guidelines, and present their own results as enough against them that it should no longer be discouraged. This summer a cyclist riding on the Christophe Colomb path segment studied by the authors-- a cyclist who did everything right by the rules of the path, and therefore much wrong by the ordinary rules of the road-- was killed by a truck [1] in circumstances exactly as warned about on page 34 of the AASHTO guidelines [2].
References
1. http://www.cbc.ca/news/canada/montreal/story/2012/07/24/montreal-cyclist-hit-24-07-2012.html?cmp=rss, accessed Aug 26 2012.
2. AASHTO Task Force on Geometric Design (1999). Guide for the development of bicycle facilities. Washington, DC: American Association of State Highway and Transportation Officials.
We regret the two errors that Kary identified. "What this study adds"
should read published crash [not injury] rates (the article body states it
correctly), and the Rachel length is 1.7 km [not 3.5]. In Table 1,
correcting for 1.7 doubles Rachel's absolute incident rates; however, it
raises overall crash and injury rates by only 10% to 9.6 and 11.5,
respectively. In Table 2, the relative risk comparison is unaffected sinc...
We regret the two errors that Kary identified. "What this study adds"
should read published crash [not injury] rates (the article body states it
correctly), and the Rachel length is 1.7 km [not 3.5]. In Table 1,
correcting for 1.7 doubles Rachel's absolute incident rates; however, it
raises overall crash and injury rates by only 10% to 9.6 and 11.5,
respectively. In Table 2, the relative risk comparison is unaffected since
the comparison street has the same length as Rachel. Thus, the study
conclusions remain intact.
Exclusion of the 180-m Maisonneuve extension completed in 1997 should
slightly lower its incident rates, and could not raise them by more than
10%, and would therefore not affect the overall results.
Kary's extensive criticisms focus on differences between the cycle
track and comparison streets that do not affect the study results. Readers
may be assured that all comparison segments were selected a priori,
without knowledge of their safety record, in consultation with local
cycling advocates (some of whom prefer mixed traffic over cycle tracks) as
the most similar yet realistic alternative routes. St. Denis, 10 blocks
but only 700 m from Brebeuf, was Brebeuf's comparison because, although
different in geometry, it was the main parallel alternative route for
cyclists crossing the area. Comparisons of MVO injuries demonstrate that
in the aggregate, cycle track and comparison streets revealed similar
environmental danger. Because differences are unavoidable when comparing
streets, we provide results for each comparison pair.
We welcome other studies that better control for the road
environment, including before-after studies. For now, Montreal is North
America's only long-standing, multi-route experiment with cycle tracks.
And while the comparisons in our study are not ideal case-controls, the
findings are strong, as not even one comparison pair showed significantly
greater risk for the cycle track.
1. Rue de Brebeuf Cycle Track vs. Rue St. Denis between Rachel and
Laurier.
These streets are not comparable.
Brebeuf (which has a cycle track) is a narrow 40kph slow-moving one-
way residential street with one traffic lane and one parking lane.
Rue St. Denis (which has no cycle track) is a six-lane (two lanes
often taken up by parking) 50kph limit two-way highway in a commercial
area with lot...
1. Rue de Brebeuf Cycle Track vs. Rue St. Denis between Rachel and
Laurier.
These streets are not comparable.
Brebeuf (which has a cycle track) is a narrow 40kph slow-moving one-
way residential street with one traffic lane and one parking lane.
Rue St. Denis (which has no cycle track) is a six-lane (two lanes
often taken up by parking) 50kph limit two-way highway in a commercial
area with lots of stores and distractions.
It seems to me that more accidents will naturally occur on the six-
lane highway with a faster speed limit. It's unsurprising then that the
study did indeed find a statistically significant advantage in terms of
safety for Rue de Brebeuf. However, I would argue that this has nothing to
do with the safety of the cycle track and everything to do with the very
different nature of the roads compared.
2. Rue Berri Cycle Track vs. Rue St. Denis between Cherrier and
Viger.
These streets are not comparable.
Rue Berri (which has a cycle track) is a 50kph limit divided highway
along 1/3rd of its length with the cycle track removed from busy
intersections by an underpass, so cyclists are naturally removed from the
possibility of intersection accidents.
Along this stretch of Rue St. Denis, the road (which has no cycle
track) is a one-way street with a 50kph speed limit. However it is a much
busier road than Rue Berri in terms of people doing their business
somewhere along that stretch, with a relatively narrow street and lots of
intersections and distractions in the form of little shops and cafes along
the whole route.
Rue Berri showed a statistically significant reduction in injuries
compared with its reference street. However, more accidents are bound to
occur where there are lots of intersections and where drivers are likely
to be distracted. It seems reasonable that the advantage in terms of
reduced injury results on Rue Berri derive from the very different nature
of the roads compared and not from the presence of a cycle track.
3. Boulevard de Maisonneuve Cycle Track vs. Rue Sherbrooke and Rue
Ste. Catherine between Claremont and Wood.
Boulevard de Maisonneuve (which has a cycle track) is a quiet 30kph
one-way two lane residential street along much of its length. The bike
track goes through a park for 1/5th of its length, thus removing any
possibility of intersection conflicts in that area. The presence of the
park effectively reduces the chance of traffic collisions by 20%.
Sherbrooke (which has no cycle track) is a downtown 40kph commercial
street with four lanes of moving traffic and parking on both sides. It has
numerous business distractions along its length. It should be noted that a
recent study found that Sherbrooke is the single most dangerous route in
Montreal for cyclists. Ste. Catherine (which also has no cycle track) is a
similar downtown street, but with a 30kph limit and just two lanes of
moving traffic and a lane for parking on both sides.
The idea that these streets are comparable on anything but the most
superficial level (i.e. they are streets) is a joke. It is ridiculous, in
my view, to attribute a reduction of injuries on Boulevard de Maisonneuve
to the presence of a cycle track, when the streets being compared are not
at all similar - and when the street with the cycle track has obvious and
significant advantages in terms of safety that are unrelated to the
bicycle track itself.
-----------------------
Here we have what seems to me to be a clear case of selection bias.
Note: Even though the three other street comparisons show similar
bias, the remaining street comparisons showed statistically insignificant
results.
Schwebel (1) raises the issue of how auditory processing might contribute to safe negotiation of the roads by pedestrians. In particular, does the masking of relevant auditory information entail unnecessary danger? Almost coincidentally, a recent review (2) has considered possible technological developments that might provide useful supplementary information to aid drivers in avoiding collisions: potential sources might be...
Developing the epidemiological literature base on the occurrence of all forms of childhood injury is essential to the development and promotion of injury prevention efforts. As is rightfully highlighted by Watt, Franklin, Wall...
Hemenway (1) describes three beliefs which may jeopardize injury- avoidance: optimistic ("it will never happen to me"), fatalistic ("accidents happen") and materialistic ("you probably deserved it"). Such a scheme parallels well-known trait theories regarding the individual's general personality (2); given the value of those endeavours,Hemenway's scheme deserves serious consideration.
Nonetheless, it may be inco...
We acknowledge that we did not control for all of the differences in road geometry and building typologies because there are no ideal matched streets (Re: Cooper). However, alternative research designs also have limitation and feasibility issues. For before and after study designs, some of the Montreal cycle tracks are 20 years old, before injury surveillance and traffic counting data systems were available. Limiting to...
Our population-based study (1) on the effectiveness of breed-specific legislation (BSL) targeting pit-bull (terrier) type dogs in the Canadian province of Manitoba generated some interest in the media and among policy -makers and the public in Canada and the United States (2-10). With this experience of listening to different stakeholders and communicating with some, we hope to elaborate on our findings in language that is...
Kerrianne Watt1, Richard C Franklin1, Belinda Wallis2, 3, Bronwyn Griffin2, 3, Peter Leggat1; Roy Kimble2,3
1School of Public Health, Tropical Medicine and Rehabilitation Sciences, James Cook University
2Queensland Children's Medical Research Institute
3Royal Children's Hospital, Centre for Burns and Trauma Research, School of Medicine, University of Queensland
Re Infant Abusive H...
When Lusk et al. submit to the editor a formal list of errata to be attached to their article, I expect they will duly correct all the errors, omissions, and false statements that have been brought to their attention, and not just the three they chose to mention here. This would include amongst other items providing a correct explanation for their choices of particular termination points (rather than the non...
We regret the two errors that Kary identified. "What this study adds" should read published crash [not injury] rates (the article body states it correctly), and the Rachel length is 1.7 km [not 3.5]. In Table 1, correcting for 1.7 doubles Rachel's absolute incident rates; however, it raises overall crash and injury rates by only 10% to 9.6 and 11.5, respectively. In Table 2, the relative risk comparison is unaffected sinc...
1. Rue de Brebeuf Cycle Track vs. Rue St. Denis between Rachel and Laurier.
These streets are not comparable.
Brebeuf (which has a cycle track) is a narrow 40kph slow-moving one- way residential street with one traffic lane and one parking lane.
Rue St. Denis (which has no cycle track) is a six-lane (two lanes often taken up by parking) 50kph limit two-way highway in a commercial area with lot...
Pages