Area‐wide traffic calming for preventing traffic related injuries

Frances Bunn; Timothy Collier; Chris Frost; Katharine Ker; Rebecca Steinbach; Ian Roberts; Reinhard Wentz

doi:10.1002/14651858.CD003110

. 2003 Jan 20;2003(1):CD003110. doi: 10.1002/14651858.CD003110

Area‐wide traffic calming for preventing traffic related injuries

Frances Bunn ^1,^✉, Timothy Collier ², Chris Frost ², Katharine Ker ³, Rebecca Steinbach ⁴, Ian Roberts ³, Reinhard Wentz ⁵

Editor: Cochrane Injuries Group

PMCID: PMC8693445 PMID: 12535454

Abstract

Background

It is estimated that by 2020 road traffic crashes will have moved from ninth to third in the world disease burden ranking, as measured in disability adjusted life years, and to second in developing countries. Area‐wide traffic calming schemes that discourage through traffic on residential roads is one strategy for preventing traffic related injuries.

Objectives

To assess the effects of area‐wide traffic calming for preventing traffic related crashes, injuries, and deaths.

Search methods

We searched the the Cochrane Injuries Group Specialised Register, Cochrane Central Register of Controlled Trials, MEDLINE, EMBASE and TRANSPORT. We searched the web sites of road safety organisations, handsearched conference proceedings, checked reference lists of relevant papers and contacted experts in the area. The search was not restricted by language or publication status. The searches were last updated in 2008.

Selection criteria

Randomised controlled trials and controlled before‐after studies of area‐wide traffic calming schemes.

Data collection and analysis

Two authors independently extracted data on type of study, characteristics of intervention and control areas, and length of data collection periods. Before and after data were collected on the total number of road traffic crashes, all road user deaths and injuries, pedestrian‐motor vehicle collisions and road user deaths. The results of each study were expressed as rate ratios.

Main results

We found no randomised controlled trials, but 22 controlled before‐and‐after studies met our inclusion criteria. Seven studies were conducted in Germany, seven in the UK, two in Australia, two in the Netherlands, two in Denmark, one in Japan, and one in Spain. There were no studies in low or middle income countries. Nine trials reported the number of road traffic crashes resulting in deaths; pooled rate ratio 0.79 (95% CI 0.23 to 2.68). Eighteen studies reported the number of road traffic crashes resulting in injuries (fatal and non‐fatal); pooled rate ratio 0.85 (95% CI 0.75 to 0.96). Twelve studies reported the total number of road traffic crashes; pooled rate ratio 0.89 (95% CI 0.76 to 1.05). Fourteen trials reported the number of pedestrian‐motor vehicle collisions; pooled rate ratio 1.01 (95% CI 0.88 to 1.16). There was evidence of significant heterogeneity for the total number of crashes and road user injuries outcomes.

Authors' conclusions

The results from this review suggest that area‐wide traffic calming in towns and cities may be a promising intervention for reducing the number of road traffic injuries and deaths. However, further rigorous evaluations of such interventions are needed.

Plain language summary

Area‐wide traffic calming (such as introducing road/speed humps) may reduce death and injury from road traffic crashes but more research is needed

Road traffic crashes are a major problem worldwide. In high‐income countries, traffic calming schemes aim to make the roads safer (particularly for vulnerable road users such as pedestrians and cyclists) in areas that are particular 'hot spots'. Strategies include slowing down traffic (eg road/speed humps, mini‐roundabouts, reduced speed limit zones), visual changes (road surface treatment, changes to road lighting), redistributing traffic (blocking roads, creating one‐way streets), and/or changes to road environments (such as trees). This review found that area‐wide traffic calming may have the potential to reduce death and injuries, but more research is needed particularly in low and middle income countries.

Background

Description of the condition

The global epidemic of road traffic deaths and injuries is only just beginning. At present, an estimated 1.23 million people die each year and between 20 and 50 million suffer non‐fatal road injuries (WHO 2009). For people under 44 years, road traffic crashes are a leading cause of death and disablement second only to HIV and AIDS (Krug 2002). Moreover, many developing countries are still at comparatively low levels of motorisation and the situation in these countries can only be expected to get worse as motorisation increases. In 1995, road death rates in China were similar to those in the United States, but there were only five vehicles per 1000 population in China compared with 770 vehicles per 1000 in the United States (Roberts 1995). It is estimated that by 2020 road traffic crashes will have moved from ninth to third in the world disease burden ranking, as measured in disability adjusted life years (Murray 1997). Most of the road deaths in developing countries involve vulnerable road users such as pedestrians and cyclists. In Ethiopia, pedestrian injuries account for 84% of all road traffic fatalities compared with 32% in Britain and 15% in the USA (Barss 1998). In the heavily motorised countries drivers and passengers account for the majority of road deaths but pedestrians account for a large proportion of road deaths involving children. The identification of effective strategies for the prevention of road traffic injuries is of global health importance.

Description of the intervention

In urban areas many road traffic crashes are scattered widely, and in such situations traditional treatments for high‐risk sites are not appropriate. In high income countries, area‐wide traffic calming schemes, including the treatment of both main roads and residential roads, have been proposed as one strategy for reducing scattered crashes. Such schemes aim to discourage through traffic on residential roads and make the roads safer, particularly for vulnerable road users such as pedestrians and cyclists.

Why it is important to do this review

A previous meta‐analysis found that area‐wide traffic calming schemes on average reduce the number of injury crashes by about 15% (Elvik 2001). However, this study included uncontrolled before‐after studies in which the effect of traffic calming could be confounded by the effect of other concurrent changes in road traffic injury rates. For example, in many high income countries pedestrian injury rates have fallen because walking has become a less popular way of travelling. In this case, the inclusion of uncontrolled studies could exaggerate the apparent effect of traffic calming. We conducted a systematic review of area‐wide traffic calming including only controlled before‐after studies.

Objectives

To assess the effects of area‐wide traffic calming measures on the prevention of traffic related injuries.

Methods

Criteria for considering studies for this review

Types of studies

Studies were included if they involved either of the following research designs:

Randomised and quasi‐randomised controlled trial (RCT)
Controlled before and after study (CBA)

The definition of CBA is based on that used by the Cochrane Effective Practice and Organisation of Care Group and is given below:

RCT: A study involving at least one test and one control treatment, concurrent enrolment and follow‐up of the test‐ and control‐treated groups, and in which the treatments to be administered are selected by a random process, such as the use of a random numbers table (coin flips are also acceptable). If the author(s) state explicitly (usually by using some variant of the term 'random' to describe the allocation procedure used) that the groups compared in the trial were established by random allocation, then the trial is classified as 'RCT'. Treatment allocations using odd‐even numbers, days of the week, or other such pseudo‐ or quasi‐random processes, are designated as quasi‐randomised.
CBA: A design where there is contemporaneous data collection before and after the intervention and an appropriate control site or activity.

Types of participants

Areas covering a number of different streets, including residential and main roads, treated with traffic calming measures.

Types of interventions

Area‐wide traffic calming measures designed to discourage the use of residential streets for through travel; and to create an environment where residential streets are safe. Eligible schemes included those that involved a number of specific named changes to the road layout, road hierarchy, or road environment, such as:

Vertical and horizontal shifts in traffic (e.g. road humps, speed cushions, raised crosswalks, raised sections of road, chicanes, mini‐roundabouts, road narrowing, channelised slip lanes, etc.)
Optical measures (chevron road sings, road surface treatment (colour, texture), reduced horizontal visibility (shortened sightlines); audible measures (rumble areas, jiggle bars), alterations to road lighting
Redistribution of traffic or alteration to road hierarchy, (e.g. permanent or temporary blocking of road, diagonal blocks, gateways, creation of one‐way streets, re‐introduction of two‐way streets, four‐way stops)
Changes to road environment (increased vegetation (trees, shrubs) along road, introduction of street furniture).
Reduced speed limit zones (e.g. 20‐mph zones, 30 km/h zones) where speeds are physically limited by traffic calming measures.

We excluded studies evaluating single interventions or those looking solely at the following interventions:

Enforcement of legal interventions (enforcement of speed limits, increased fines for speeding, speed cameras (mock or real), educational programmes aimed at altering driver or pedestrian behaviour, or interventions involving vehicle design changes).
Fiscal/financial incentives/disincentives (local tolls to reduce extraneous traffic).
Studies solely describing intervention which separate different road users (cycle lanes, elevated pedestrian walkways, red (bus) lanes etc.).
Effects of improved public transport facilities.
Interventions investigating the effect of alterations to road signs or traffic lights alone.
"Road Diet" interventions (conversions of, for example, four lane undivided roads into three lanes‐ two through lanes and a centre turn lane).

Comparison of interventions in studies eligible for this review:

Area‐wide traffic engineering intervention versus no intervention
Area‐wide traffic engineering intervention versus legal and/or educational and/or fiscal measures

Types of outcome measures

Primary outcomes

Road user deaths.
Road user injuries.
Road traffic crashes.
Pedestrian‐motor vehicle collisions.

Our definition of 'road users' included all road users not just drivers and occupants of motor vehicles.

Secondary outcomes

Perceived quality of urban environment.
Perceived safety.

Search methods for identification of studies

Electronic searches

We searched the following electronic databases;

Cochrane Injuries Group Specialised Register (searched January 2008),
Cochrane Central Register of Controlled Trials (The Cochrane Library 2007, Issue 1),
MEDLINE (to December 2007, week 4)
EMBASE (to 2008, week 1),
Sociological Abstracts (to 2000),
Science (and Social Science) Citation Index,
TRANSPORT (pre‐1980 to 2006 issue 12)
Psychlit (to 2000),
National Research Register (2007, Issue 1),
International Bibliography of the Social Sciences (1951 to 2007/10).

The search strategies used for the updated searches performed in 2007/08 are presented in Appendix 1; Appendix 2; Appendix 3; Appendix 4; Appendix 5.

We searched the web sites of the following road safety organisations (searches performed in 2001):

AAA Foundation for Traffic Safety (USA) ‐ www.aaafoundation.org
ARRB ‐ Australian Road Research Board ‐ www.arrb.org.au
Australian Transport Safety Bureau ‐ www.atsb.gov.au
CROW ‐ Information and Technology Centres for Transport and Infrastructure (Netherlands) ‐ www.crow.nl
Danish Council for Road Safety Research ‐ www.trm.dk/eng/veje/rft
Danish Transport Research Institute ‐ www.dtf.dk
DETR ‐www.detr.gov.uk/
DVR ‐ Deutscher Verkehrssicherheitsrat Road Safety Institute (Germany) ‐ www.dvr.de/
FINNRA ‐ Finnish National Road administration ‐ www.tieh.fi
INRETS ‐ Institut National de Recherche sur les Transports et leur Sécurité (France) ‐ www.inrets.fr
ITE ‐ Institute of Transportation Engineers (USA) ‐ www.ite.org
LET ‐ Laboratoire d'economie des transports (France) ‐ www.lsh‐lyon.cnrs.fr
NHTSA ‐ National Highway Traffic Safety Administration (USA) ‐ www.nhtsa.dot.gov
Swedish National Roads Administration ‐ www.vv.se/for_lang/english/
SWOV ‐ Institute for Road Safety Research (Netherlands) ‐ www.swov.nl
TOI ‐ Institute of Transport Economics (Norway) ‐ www.toi.no
TC ‐ Transport Canada ‐ www.tc.gov
TRB‐ Transportation Research Board‐ www.nas.edu/trb/
TRL‐ Transport Research Laboratory (UK) ‐ www.trl.co.uk
US Department of Transport ‐ Federal Highway Administration (USA) ‐ www.fhwa.dot.gov
VTI ‐ Swedish National Road and Transport Research Institute ‐ www.vti.se
VTT ‐ Finland www.vtt.fi/indexe.htm

Searching other resources

We handsearched the following conference proceedings:

Australian Road Research Board (ARRB). Proceedings of the 12th ARRB conference, Hobart Tasmania 27th to 31st August 1984.
Australian Road Research Board (ARRB). Proceedings of the 15th ARRB conference, Darwin, 26th to 31 August 1990.
Institution of Professional Engineers New Zealand (IPENZ). Annual conference Christchurch February 1992 Volumes 1 & 2.
Institution of Professional Engineers New Zealand (IPENZ). Proceedings of the technical session of the group at the annual conference of IPENZ, Auckland 8th to 12th February 1982.
Institute of Transportation Engineers (ITE). Proceedings of the 45th to 71st ITE annual meeting, 1975 to 2001.
Institute of Transportation Engineers (ITE). Transportation and traffic theory 9th international symposium, Netherlands 1984.
Institute of Transportation Engineers (ITE). Residential street design and traffic control 1989.
Israel Institute of technology. International conference on pedestrian safety. Haifa 20th to 23rd December 1976.
Landor Publishing Ltd. The third national traffic calming conference. London 18th October 1996.
Organisation for economic co‐operation and development (OECD). Proceedings of the symposium on techniques of improving urban conditions by restraint of road traffic; 25th to 27th October 1971.
PTRC Transport, Highways and Planning Summer 13th to 18th Annual Meetings, 1985‐1990.
Swedish Road and Traffic Research Institute. Proceedings of the conference on strategic highway research program and traffic safety on two continents; Gothenburg Sweden, September 18th to 20th, 1991.
Swedish Road and Traffic Research Institute. Proceedings of the conference on strategic highway research program and traffic safety on two continents; Gothenburg Sweden, September 27th to 29th, 1989.
Swedish Road and Traffic Research Institute. Proceedings of the conference on road safety and traffic environment in Europe, Gothenburg Sweden, September 26th to 28th, 1990.
The Technion Israel Institute of Technology. The second international conference on new ways for improved road safety and quality of life, 7th to 10th October 1991, Tel‐Aviv Hilton Hotel, Israel.
Transportation Research Institute. International conference on new ways and means for improved safety, Tel Aviv, Israel, Feb 20th to 23rd 1989.
Transport Research Laboratory. Safety 91 Papers on vehicle safety, traffic safety and road user safety research, TRL Laboratory Berks 1st to 2nd May 1991.

We identified further potential published or unpublished studies by checking references of relevant papers and reviews; contacting authors of relevant papers; and contacting international road safety organisations.

Data collection and analysis

Selection of studies

One author examined titles, abstracts, and keywords of citations, as given on electronic databases, for eligibility. Where possible, we obtained the full text of all possible relevant citations. One author decided whether studies met the inclusion criteria, and this was checked by a second author.

Data extraction and management

Two authors independently extracted data from each eligible study using a standard form. Data were extracted on the type of study (e.g. RCT, CBA), characteristics of intervention and control areas, the types of intervention, duration of follow up and the outcomes evaluated. Differences found in data extraction were resolved by discussion. Where necessary, we sought additional information from researchers involved in the studies.

Assessment of risk of bias in included studies

The assessment of the quality of non‐randomised trials is problematic. Controlled before‐after studies are recognised to be methodologically weaker than randomised controlled trials, and few quality assessment tools exist. In this review we assessed the quality of the CBAs by extracting data on how well the intervention and control areas were matched, and the length of the before and after data collection periods. Because of the potential for contamination, we also noted the distance between the intervention and control areas.

Measures of treatment effect

The results of each study are expressed as rate ratios. The rate ratio is the ratio of event rates post and pre intervention in the intervention area divided by the corresponding post to pre intervention event ratio in the control area. Provided that any changes in the population at risk are the same in both control and intervention areas, the rate ratio gives the reduction in the event rate in the intervention area compared to that in the control area. For example, a rate ratio of 0.8 corresponds to a 20% reduction in events in the intervention area compared to that predicted from the rates in the control area.

We calculated standard errors for logarithms of rate ratios and hence 95% confidence intervals for rate ratios, assuming that the number of events in each area in each period followed a Poisson distribution.

Assessment of heterogeneity

We examined statistical heterogeneity by using both the I‐squared and Chi² tests. The I² test describes the percentage of total variation across studies due to heterogeneity rather than chance. A value of 0% indicates no observed heterogeneity, and larger values show increasing heterogeneity; substantial heterogeneity is considered to exist when I² > 50% (Higgins 2008). For the Chi² statistic, we used a P value of < 0.10 to indicate the presence of statistically significant heterogeneity.

Data synthesis

Using the generic inverse variance method in Review Manager, we combined the rate ratios on a logarithmic scale using a random effects meta‐analysis model. The assumption of random effects both allows for the anticipated heterogeneity between effects across studies and provides robustness if the assumption that events follow Poisson distributions is violated through overdispersion.

In the analysis of road user deaths, where the majority of studies had no events in at least one period, no test of heterogeneity was carried out and a pooled estimate of the rate ratio was obtained from the column totals. The confidence interval for this estimate would, in expectation, be too narrow since the method ignores the likely heterogeneity between studies. However, under the circumstances of many zero observations, this method has some advantage over the alternative of adding 0.5 when observing zero.

Results

Description of studies

Results of the search

Our searches identified 13,520 published and unpublished reports. We obtained the full text of 635 reports and of these 22 controlled before‐after studies met our inclusion criteria (Charlottenburg 1990; Denmark 1992; GST‐Buxtehude 1993; GST‐Esslingen 1993; GST‐Borgentreich 1993; GST‐Ingolstadt 1993; GST‐Mainz 1993; GST‐Moabit 1993; London 2007; Madrid 2006; Mørkhøj 2001; Osaka 1998; Rijswijk/Eindhoven 1991; Swindon 1981; Sydney‐Canterbury 1990; Sydney‐Willoughby 1990; The Netherlands 1992; USP Bradford 1989; USP Bristol 1989; USP Nelson 1989; USP Reading 1989; USP Sheffield 1989). We found no randomised controlled trials.

Included studies

In all the studies in this review the areas involved were predominantly residential, often located close to the central commercial sector of a large town or city. Area‐wide traffic calming involved a reclassification of the streets in the area, aiming to move through traffic away from residential streets and concentrate it on roads that were classified as main roads. In all studies a combination of traffic calming measures was used, including interventions such as road closures, changes to junctions, changes to the road environment (for example with traffic humps or chicanes), improvement in pedestrian crossing facilities and the use of mini‐roundabouts. Seven studies were conducted in Germany (GST‐Borgentreich 1993; GST‐Buxtehude 1993; Charlottenburg 1990; GST‐Esslingen 1993; GST‐Mainz 1993; GST‐Moabit 1993; GST‐Ingolstadt 1993), seven in the UK (London 2007; Swindon 1981; USP Bradford 1989; USP Bristol 1989; USP Nelson 1989; USP Reading 1989; USP Sheffield 1989), two in Australia (Sydney‐Canterbury 1990; Sydney‐Willoughby 1990), two in the Netherlands (Rijswijk/Eindhoven 1991; The Netherlands 1992), two in Denmark (Denmark 1992; Mørkhøj 2001), one in Japan (Osaka 1998), and one in Spain (Madrid 2006). One of the German studies (Charlottenburg 1990) was a pilot scheme for the other six German towns; Borgentreich, Buxtehude, Esslingen, Mainz, Moabit, and Ingolstadt. One of the studies in the UK (Swindon 1981) was a pilot scheme for the other five Urban Safety Project towns; Bradford, Bristol, Nelson, Reading and Sheffield. The two Australian studies both took place in Sydney.

More details about individual studies can be found in the Characteristics of included studies table.

Risk of bias in included studies

As there is not an accepted instrument for appraising the quality of controlled before‐after‐studies we have not attempted a formal quality score or appraisal of the studies. Where possible we collected information on:

the length of data collection before and after the intervention;
how intervention and control areas were matched; and
proximity of control area to intervention area.

Berlin Charlottenburg (Charlottenburg 1990):   A controlled before‐after study with two years before and two years after data. Berlin Moabit was chosen as the control area. Little information was given about the control area. Data on the number of crashes and injuries were collected from police records. Incidence of crashes and injuries in the before period were much higher in the control area than the intervention area.

Denmark 1992:   A controlled before‐after study with three years before data and three years after data. The control areas were selected to match the intervention areas. There was no significant difference in the mean speeds of motor vehicles in the control and intervention areas.

German six towns study (GST‐Esslingen 1993; GST‐Ingolstadt 1993; GST‐Mainz 1993; GST‐Moabit 1993; GST‐Borgentreich 1993; GST‐Buxtehude 1993):   Controlled before‐after studies with two years before data and two years after data; except for Borgentreich where the after period was extended to three years to obtain a sufficient sample size. The controlled areas for each town are in brackets. Berlin‐Moabit (Berlin‐Wedding), Borgentreich (Borgholz), Buxtehude (Buxtehude‐Sud), Esslingen (Nurtingen), Ingolstadt (Regensburg), Mainz‐Bretzenheim (Mainz‐Finthen). Data on the number of crashes and injuries were collected from police records.

The criteria for choosing the control areas were:

similar sized cities;
same region of Germany;
similar structure to the area under study;
no traffic calming measures;
availability of data from police records; and
readiness of the city authorities to co‐operate.

N.B. additional information provided by one of the study authors.

London 2007:   A controlled before‐after study with five years of before data on both the intervention and control group, between one and five years of after data on the intervention group, and three years of after data on the control group. The control roads were all unclassified roads in London.

Madrid 2006:   A controlled before‐after study with two years of before data and two years of after data. The control areas and intervention areas were similar in that they both belonged to the highway network of the Autonomous Community of Madrid and both eventually received traffic calming. The control areas received traffic calming at a later date than the intervention areas.

Mørkhøj 2001:   A controlled before‐after study with three years of before data and three years of after data. The control area was the remainder of the municipality where the intervention was situated. No other information was given about the control area.

Osaka 1998:   A controlled before‐after study with six years of before data and six years of after data. No other information was given on the control areas.

Rijswijk/Eindhoven 1991:   A controlled before‐after study with six years before data and five years after data. The control and intervention areas were similar in that they were both residential districts, built before 1972, with adjacent main traffic arteries. To avoid contamination the control areas were not in the immediate vicinity of the demonstration areas. Data on the number of crashes and injuries were collected from police records.

Swindon 1981:   A controlled before‐after study with four years before data and two years after data. The controls chosen were similar routes where the local council agreed as far as possible to keep roadworks to a minimum. However, the authors note that the 'behaviour' of the control routes was not typical of other types of roads in Swindon during the two year after period. They concluded that the control technique had broken down. Data on the number of crashes and injuries were collected from County Council records.

Sydney‐Canterbury 1990:   A controlled before‐after study with three years before data and two and a half years after data. Although efforts were made to match the control and intervention areas they had different land use characteristics and, unlike the intervention area, the control had no industrial zone. Areas were of a similar size. The areas were close but not immediately adjacent. Data on the number of crashes and injuries were collated from the Traffic Authority of New South Wales records. There was a lower incidence of crashes and injuries in the before period in the intervention area, than in the before period in the control area.

Sydney‐Willoughby 1990:   Controlled before‐after study with two years before data and two years after data.The control area was selected because of its similar traffic problems to the intervention area, although it did not reflect the grid pattern of the study area. Areas were of a similar size.   Data on the number of crashes and injuries were collected from the records of the Traffic Authority of New South Wales.   In the before period the incidence of crashes was much higher in the intervention area than in the control area.

The Netherlands 1992:   A controlled before‐after study with three years before data and three years after data. The control areas were roads in built‐up areas, excluding arterial roads, in the same municipalities that the intervention areas were situated in.

Urban Safety Project (USP Bradford 1989; USP Bristol 1989; USP Nelson 1989; USP Reading 1989; USP Sheffield 1989):   These were controlled before after studies with matched comparison groups. For each town a five year 'before' period was used to detect trends and seasonal variation in the crash pattern and so to establish a range of crashes that might be expected in the 'after' period had the project not taken place. Two years of after data were collected. Any differences in crash‐rate between the 'before' and 'after' periods was taken to be due to a combination of system‐wide secular effects, random effects and the effects of the scheme itself. The criteria used for choosing the areas in the project were that they were of average risk, had a range of residential network types, and were large enough to show the interaction between main road and residential road traffic redistribution. A second area with similar crash and network characteristics was chosen for the control. The areas were not immediately adjacent. Data on the number of crashes and injuries were collected from police records. Incidence of crashes and injuries in the intervention and control areas were fairly well matched for the before period.

Effects of interventions

Road user deaths

Nine studies reported the number of road traffic crashes resulting in deaths (Denmark 1992; GST‐Borgentreich 1993; GST‐Buxtehude 1993; GST‐Esslingen 1993; GST‐Ingolstadt 1993; GST‐Mainz 1993; GST‐Moabit 1993; Sydney‐Canterbury 1990; Sydney‐Willoughby 1990). The pooled rate ratio was 0.79 (95% CI 0.23 to 2.68), which was calculated from the column totals, due to zero counts observed in a number of the studies. Individual results for each study are presented in Table 1. The results should be interpreted with caution; the method of using the column totals to calculate the rate ratio ignored the likely heterogeneity between the studies, and the estimate is likely to be too narrow.

1. Road user deaths.

Study ID	Intervention before	Intervention after	Control before	Control after	Rate ratio (95% CI)
Denmark	0	1	1	0	Undefined
GST‐Moabit	7	3	12	7	0.73 (0.14 to 3.80)
GST‐Borgentreich	0	0	0	0	Undefined
GST‐Buxtehude	0	0	0	1	Undefined
GST‐Esslingen	3	0	3	1	Undefined
GST‐ Ingolstadt	0	0	0	2	Undefined
GST‐Mainz	1	0	0	0	Undefined
Sydney‐Canterbury	1	0	2	1	Undefined
Sydney‐Willoughby	0	2	1	0	Undefined

Study	Intervention before	Intervention after	Control before	Control after	Rate Ratios (95% CI)
Charlottenburg	31	11	95	71	0.47 (0.22 to 1.01)
Denmark	40	13	19	17	0.36 (0.15 to 0.90)
GST‐Borgentreich	17	10	6	4	0.88 (0.20 to 3.90)
GST‐Buxtehude	40	41	96	61	1.61 (0.94 to 2,77)
GST‐Esslingen	103	90	91	82	0.97 (0.64 to 1.46)
GST‐Ingolstadt	185	139	272	182	1.12 (0.84 to 1.50)
GST‐Mainz	27	13	63	30	1.01 (0.46 to 2.23)
GST‐Moabit	275	228	379	392	0.80 (0.64 to 1.00)
London	387	208	7012	6811	0.55 (0.47 to 0.66)
Rijswijk/Eindhoven	923	458	4453	3069	0.72 (0.64 to 0.81)
Swindon	197	89	115	74	0.70 (0.48 to 1.03)
Sydney‐Canterbury	76	73	101	116	0.84 (0.55 to 1.27)
Sydney‐Willoughby	74	69	20	19	0.98 (0.48 to 1.99)
USP Bradford	551	190	629	232	0.93 (0.75 to 1.17)
USP Bristol	693	231	647	206	1.05 (0.84 to 1.30)
USP Nelson	539	180	634	228	0.93 (0.74 to 1.16)
USP Reading	714	303	653	257	1.08 (0.89 to 1.31)
USP Sheffield	636	181	520	214	0.69 (0.55 to 0.87)

Outcome or subgroup title	No. of studies	Statistical method	Effect size
1 Road user deaths	1	Rate Ratio (Random, 95% CI)	0.79 [0.23, 2.68]
2 Road user injuries	18	Rate Ratio (Random, 95% CI)	0.85 [0.75, 0.96]
3 Road traffic crashes	12	Rate Ratio (Random, 95% CI)	0.89 [0.76, 1.05]
4 Pedestrian‐motor vehicle collisions	1	Rate Ratio (Random, 95% CI)	1.01 [0.88, 1.16]

Methods	CBA   2 yrs before data.   2 yrs after data.
Participants	I) Densely populated residential area with small businesses.   C) Berlin‐Moabit
Interventions	I) Various traffic calming measures including different levels of road surface, staggered lanes and 30km speed limit.   C) No traffic calming.
Outcomes	Road traffic crash related deaths and injuries.   All road traffic crashes.
Notes	This was a pilot study for the German study on traffic calming in six towns.

Methods	This does not refer to a separate study. The 'column totals' identifier is used for the pooled analysis of road user deaths and pedestrian‐motor vehicle collisions, due to the presence of zero events in ≥1 of the study periods.
Participants
Interventions
Outcomes
Notes

Methods	CBA   3 yrs before data.   3 yrs after data.
Participants	I) 5 15 km/h streets and 39 30 km/h streets comprising 30km of road C) 52 control streets comprising 35km of road
Interventions	I) Area‐wide traffic calming including speed humps, limited road width, lateral dislocation C) No area‐wide traffic calming
Outcomes	Road traffic crash related injuries, deaths, and serious injuries
Notes	Collision data collected from police records

Methods	CBA I) 5 yrs before data   1‐5 yrs after data C) 5 yrs before data   3 yrs after data
Participants	I) 78 20 mph zones in London   C) All unclassified roads in London
Interventions	I) Area‐wide traffic calming including road humps, raised junctions, speed cushions, chicanes, and raised footways.   C) No area‐wide traffic calming.
Outcomes	Road traffic crash related injuries, deaths and serious injuries, and injuries to pedestrians, cyclists, powered 2‐wheeler riders, and car occupants. All road traffic crashes and crashes involving a death or serious injury. Road traffic crash related injuries to children.
Notes	Collision data collected from police records.

Methods	CBA   2 yrs before data   2 yrs after data
Participants	I) Undivided rural roads belonging to the highway network of the Autonomous Community of Madrid that received treatment between 1986 and 1989. C) Undivided rural roads belonging to the highway network of the Autonomous Community of Madrid that received treatment between 1990 and 1993. i.e. roads that during the time period of the study did not receive treatment but would later be treated.
Interventions	I) Highway upgrading, traffic signing, pavement markings, pavement resurfacing   C) No area‐wide traffic calming
Outcomes	Number of road traffic crashes
Notes	Data could not be extracted

Methods	CBA   3 yrs before data   3 yrs after data
Participants	I) Residential area with both single‐family houses and flats totaling 15.5km   C) The remainder of the Gladsaxe Municipality
Interventions	I) Speed humps, raised crossings, road signs and increased vegetation   C) No area‐wide traffic calming
Outcomes	Road traffic crashes
Notes	The intervention area had been suffering from a high accident rate before the intervention. Speed reducing measures in the intervention area were placed further apart than recommended in Danish road guidelines.

Methods	CBA   6 yrs before data   6 yrs after data
Participants	Ia) 10 districts in Osaka with "road‐pia" projects that started in 1987 or earlier   Ib) 9 districts in Osaka with "community street" projects   C) 9 districts in Osaka
Interventions	Ia) "Road‐pia" project introduced area‐wide traffic calming including speed humps, limited street width, coloured pavement, chicanes, and entry treatments.   Ib) "Community street" projects introduces chicanes, improved pavements, street furniture, and increased vegetation.   C) No area‐wide traffic calming
Outcomes	Road traffic crashes   Pedestrian crashes   Cyclist crashes
Notes	Collision data collected from police records.

Methods	CBA   6 yrs before data.   5 yrs after data.
Participants	I) Road districts in Rijswijk and Eindhoven in the Netherlands. The project began in 1976.   C) Number of residential zones bordering on main traffic arteries within the boundaries of Rijswijk and Eindhoven. They were not in the immediate vicinity of the intervention areas.   The experimental areas in Rijswijk consisted mainly of old residential districts whereas the control area is made up of new housing estates.   Each area was about 100 hectares.
Interventions	I) Public spaces were first reclassified, with a new distribution of traffic zones and zones for other functions. The traffic zones were then reconstructed in order to improve road safety and traffic flow. Interventions included: road humps, horizontal road shifts, road closures and restrictions, road narrowing and raised cross‐roads.   C) No traffic calming.
Outcomes	Road traffic crash related deaths and injuries.   Environmental effect.   Retail sales.   Public opinion.
Notes	Project began in 1976. The control areas were larger than the intervention areas and had many more residents. However, the residential density per hector was higher in the intervention area.

Study	Intervention before	Intervention after	Control before	Control after	Rate Ratios (95% CI)
Charlottenburg	172	115	400	357	0.75 (0.57 to 0.99)
GST‐Borgentreich	62	82	23	17	1.79 (0.88 to 3.63)
GST‐Buxtehude	537	629	349	438	0.93 (0.78 to 1.12)
GST‐Essligen	887	982	434	413	1.16 (0.99 to 1.37)
GST‐Ingolstadt	1015	876	957	627	1.32 (1.15 to 1.51)
GST‐Mainz	569	473	358	342	0.87 (0.72 to 1.05)
GST‐Moabit	1902	2026	2089	2745	0.81 (0.74 to 0.88)
London	322	188	6022	5800	0.61 (0.50 to 0.73)
Mørkhøj	16	1	310	158	0.12 (0.01 to 0.93)
Osaka	45	39	20	20	0.87 (0.41 to 1.84)
Sydney‐Canterbury	217	201	312	347	0.83 (0.65 to 1.06)
Sydney‐Willoughby	229	271	61	98	0.74 (0.51 to 1.06)

Study	Intervention before	Intervention after	Control before	Control after	Rate ratios (95% CI)
GST‐Borgentreich	3	1	0	0	Undefined
GST‐Buxtehude	26	13	24	16	0.75 (0.30 to 1.88)
GST‐Esslingen	50	36	12	12	0.72 (0.29 to 1.78)
GST‐Ingolstadt	56	32	105	75	0.80 (0.47 to 1.35)
GST‐Mainz	13	9	18	7	1.78 (0.53 to 6.02)
GST‐Moabit	179	143	179	142	1.10 (0.74 to 1.37)
Osaka	12	6	5	3	0.83 (0.15 to 4.72)
USP‐Bradford	174	65	231	78	1.11 (0.75 to 1.62)
USP‐Bristol	136	67	170	45	1.86 (1.20 to 2.89)
USP‐Nelson	219	80	267	103	0.95 (0.67 to 1.33)
USP‐Reading	173	73	116	48	1.02 (0.66 to 1.57)
USP‐Sheffield	248	68	206	83	0.68 (0.47 to 0.99)
Sydney‐Canterbury	9	9	17	20	0.85 (0.28 to 2.63)
Sydney‐Willoughby	8	12	1	0	Undefined

Study	Reason for exclusion
Amundsen 1984	Uncontrolled before/after
Brownfield 1980	Uncontrolled before/after
Chick 1994	Uncontrolled before/after
Chua 1991	Uncontrolled before/after
Cloke 1999	Uncontrolled before/after
Cole 1990	Uncontrolled before/after
Drammen Byplankontor 1980	Uncontrolled before/after
Ebbecke 1977	Uncontrolled before/after
Elmberg 1972	Uncontrolled before/after
Engel 1982	Not area‐wide traffic calming
Engel 1983	Uncontrolled before/after
Engel 1989a	Not area‐wide traffic calming
Engel 1989b	Not area‐wide traffic calming
Engel 1990	Not area‐wide traffic calming
Fager 1984	Uncontrolled before/after
Faure 1992	Uncontrolled before/after
Fisher 1989	Uncontrolled before/after
Gennaoui 1987	Uncontrolled before/after
Gunnarsson 1992	Uncontrolled before/after
Haakenaasen 1982	Uncontrolled before/after
Hagan 1988	Uncontrolled before/after
Hart 1982	Uncontrolled before/after
Heaton 1980	Uncontrolled before/after
HRC 1987	Uncontrolled before/after
HRC 1988	Uncontrolled before/after
Kraay 1984	Unable to locate full text to enable assessment for inclusion.
Kuemmel 1983	Uncontrolled before/after
McDonald 1984	Uncontrolled before/after
Meyer 2000	Uncontrolled before/after
Mok 2003	Uncontrolled before/after
Mountain 1989	Uncontrolled before/after
Muskaug 1976	Uncontrolled before/after
Oslo Byplankontor 1978	Uncontrolled before/after
Pau 2001	Uncontrolled before/after
Portland 2000	Uncontrolled before/after
Rimiller 2003	Only evaluated "road diet" interventions
Scottish Exec. 1999	Uncontrolled before/after
Stolen 1988	Uncontrolled before/after
Tester 2004	Case‐control
TRL 1997	Uncontrolled before/after

Trial name or title	Stockholm
Methods	CBA
Participants	I) 20 areas in Stockholm and Örebro   C) 18 areas in Stockholm and Örebro
Interventions	I) Road cushions, road narrowing, handrails and lampposts at pedestrian and cyclist crossings
Outcomes	traffic speeds   motorists‐pedestrian/cyclist conflicts   motorist behaviour   road user opinions
Starting date	1997
Contact information	Lund University, Department of Technology and Society
Notes

Methods	CBA   4 yrs before data.   2 yrs after data.
Participants	I) 2.8 KM section of an all purpose arterial road in Swindon, UK   C) Three routes of similar layout, frontage development and radial function. The local council agreed to keep road works to a minimum in this area.
Interventions	I) A number of traffic calming measures including roundabouts, pedestrian crossings and changes to intersections.   C) No changes.
Outcomes	Road traffic crash related injuries.
Notes	Behaviour of the control routes was atypical of other types of road in Swindon during the study period.   No information given on perceived safety or quality of environment.

Methods	CBA   3 yrs before data.   2.5 yrs after data.   The control area was chosen due to its closeness to the trial area and its similar characteristics.
Participants	I) Predominantly residential area in Sydney, Australia. The area also contained an industrial zone.   C) An area to the south of the test area. This area was different in that it did not contain an industrial zone.
Interventions	I) Local area traffic management scheme (LATM) implemented in 1982, including speed humps, slow points, roundabouts and a 40km speed limit.   C) No LATM scheme.
Outcomes	Road traffic crash related deaths and injuries.   All road traffic crashes.   Pedestrian crashes.   Residents opinions on the value of LATM.
Notes	The schemes in Canterbury and Willoughby are both reported in the same paper.   Collision data collected from police records.

Methods	CBA
Participants	I) 15 areas throughout the Netherlands   C) Built‐up areas (excluding arterial roads) of the municipalities where the interventions were situated
Interventions	I) 30 km/h zones including signs, road humps, limited road width, elongated humps, raised sections, traffic islands and refuges, mini roundabouts, turning bans, diagonal closures, and speed humps with special cycle lanes.   C) No area‐wide traffic calming
Outcomes	Traffic speeds   Traffic volumes   Road traffic crashes
Notes	Could not extract data

Methods	CBA   5 yrs before data. 2 yrs after data.
Participants	I) Area in Bradford to the South west of the city centre, with a population of 33,000 in around 12,000 households. The area was mainly residential in generally unplanned street system.   C) Area of much the same size and character on the opposite side of the city.
Interventions	I) General area wide scheme including: junction redesign, closures of through routes; and installation of central refuges.   C) No area‐wide traffic calming.
Outcomes	Road traffic crash related deaths and injuries.   Pedestrian crashes.
Notes	One of the five cities and towns involved in the Urban Safety Project led by the Transport and Road Research Laboratory, UK.   Injury data collected from police records.   No information given on perceived safety or quality of environment.

Methods	CBA   5 yrs before data.   2 yrs after data.
Participants	I) An area that consists mainly of the town of Nelson (excluding the town centre), covering an area of 7 square km. In 1981 it had approximately 11,400 households with 30,000 people. Many pre‐1914 houses in long terraces, some post‐1945 local authority housing. Steep hills.   C) An area of approximately the same size and character in the adjacent district of Burnley. The centre of Burnley lies about 3 miles to the south of Nelson.
Interventions	I) General area wide scheme including: Junction redesign, Road closures, Mini‐roundabouts.
Outcomes	Road traffic crash related deaths and injuries.   Pedestrian crashes.
Notes	One of the five cities and towns involved in the Urban safety project led by the Transport and Road Research Laboratory, UK.   No information given on perceived safety or quality of environment.

Methods	CBA   5 yrs before data. Nearly 2 yrs after data.   A comparable control area in the same city was chosen.
Participants	I) An area to the west of the central commercial area which covers approximately 8 square km.   In 1981 area had a population of about 36,000 people occupying 15,000 households.   C) An area similar in size to the southeast of the central area.
Interventions	I) General area wide scheme including:   Road closures, Right turn bans, Mini roundabouts.
Outcomes	Road traffic crash related deaths and injuries.   Pedestrian crashes.
Notes	One of the five cities and towns involved in the Urban safety project led by the Transport and Road Research Laboratory, UK.   Injury data collected from police records.   Modifications to the design of the measures was made in the first 9 months in response to localised increases in the number of accidents.   No information given on perceived safety or quality of environment.

PERMALINK

Area‐wide traffic calming for preventing traffic related injuries

Frances Bunn

Timothy Collier

Chris Frost

Katharine Ker

Rebecca Steinbach

Ian Roberts

Reinhard Wentz

Abstract

Background

Objectives

Search methods

Selection criteria

Data collection and analysis

Main results

Authors' conclusions

Plain language summary

Background

Description of the condition

Description of the intervention

Why it is important to do this review

Objectives

Methods

Criteria for considering studies for this review

Types of studies

Types of participants

Types of interventions

Types of outcome measures

Primary outcomes

Secondary outcomes

Search methods for identification of studies

Electronic searches

Searching other resources

Data collection and analysis

Selection of studies

Data extraction and management

Assessment of risk of bias in included studies

Measures of treatment effect

Assessment of heterogeneity

Data synthesis

Results

Description of studies

Results of the search

Included studies

Risk of bias in included studies

Effects of interventions

Road user deaths

1. Road user deaths.

Road traffic injuries (fatal and non fatal)

2. Road user injuries.

Road traffic crashes

3. Road traffic crashes.

Pedestrian‐motor vehicle collisions

4. Pedestrian‐motor vehicle collisions.

Perceived safety

Discussion

Summary of main results

Overall completeness and applicability of evidence

Quality of the evidence

Potential biases in the review process

Authors' conclusions

Implications for practice.

Implications for research.

What's new

History

Acknowledgements

Appendices

Appendix 1. MEDLINE & EMBASE search strategy

Appendix 2. TRANSPORT search strategy

Appendix 3. CENTRAL search strategy

Appendix 4. National Research Register search strategy

Appendix 5. International Bibliography of the Social Sciences

Data and analyses

Comparison 1. Area‐wide traffic calming versus control.

1.1. Analysis.

1.2. Analysis.

1.3. Analysis.

1.4. Analysis.

Characteristics of studies