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Journal of the Egyptian Public Health Association logoLink to Journal of the Egyptian Public Health Association
. 2023 Aug 2;98:14. doi: 10.1186/s42506-023-00139-3

The prevalence of seat belt use among drivers and passengers: a systematic review and meta-analysis

Shiva Kargar 1,, Alireza Ansari-Moghaddam 1, Hossein Ansari 1
PMCID: PMC10393920  PMID: 37528241

Abstract

Background

Seat belts might save people’s lives in car accidents by preventing severe collision damage and keeping passengers safe from critical injuries. This meta-analysis was performed to assess the prevalence of seat belt use among drivers and passengers.

Methods

The databases of PubMed, Web of Science (WOS), and Google Scholar were searched from the beginning of 2000 to late December 2020 to identify studies that investigated the prevalence of seat belt use among drivers and passengers. The pooled prevalence was calculated using a random-effects model. The STATA-v14 software was used to perform data analysis.

Results

Sixty-eight studies that met the inclusion criteria and were suitable for this meta-analysis were identified. The pooled prevalence of seat belt use was 43.94% (95% CI: 42.23–45.73) among drivers, 38.47% (95% CI: 34.89–42.42) among front-seat passengers, and 15.32% (95% CI: 12.33–19.03) among rear-seat passengers. The lowest seat belt use among drivers and passengers was observed in Asia, the Middle East, and Africa, while the highest use was reported in Europe and America. Moreover, the prevalence of seat belt use was higher among women drivers [51.47% (95% CI: 48.62–54.48)] than men drivers [38.27% (95% CI: 34.98–41.87)] (P < 0.001). Furthermore, the highest prevalence of seat belt use was seen among drivers (68.9%) and front-seat passengers (50.5%) of sports utility vehicles (SUVs); in contrast, the lowest prevalence was observed among drivers and passengers of public vehicles such as buses, minibuses, and taxis.

Conclusions

In general, the prevalence of seat belt use was not high among drivers and was even lower among passengers. Moreover, drivers and passengers in Asia, the Middle East, and Africa had the lowest prevalence of seat belt usage. Additionally, drivers and passengers of public transportation (buses, minibuses, and taxis) had a lower rate of seat belt use, especially among men. Therefore, effective interventional programs to improve seat belt use should be designed and implemented, particularly among these at-risk populations in Asia, the Middle East, and Africa.

Supplementary Information

The online version contains supplementary material available at 10.1186/s42506-023-00139-3.

Keywords: Prevalence, Seat belt usage, Drivers, Passengers, Meta-analysis

Introduction

Motor vehicle crashes are one of the significant causes of morbidity and mortality worldwide [1]. According to the World Health Organization, around 1.3 million people lose their lives every year, and between 20 and 50 million are injured as a result of road traffic accidents [2].

Road injuries create an enormous economic burden for countries. The global economy is estimated to incur a cost of US $1.8 trillion (constant 2010 US dollars) due to road injuries in 2015–2030, equivalent to 0.12% of the global gross domestic product (GDP) annually [3]. As a result, it is crucial to establish motor vehicle crashes prevention programs worldwide.

Most deaths from motor vehicle crashes occur among the car’s occupants [4]. Therefore, seat belts are a cost-effective preventive measure for reducing the severity of injury, disability, and death caused by road accidents [5]. By wearing a seat belt, the risk of death among drivers and passengers in the front seat decreases by 45–50%, and the risk of death and serious injury among passengers in the rear seat decreases by about 25% [2].

The prevalence of seat belt use varies across different countries of the world and depends to some extent on the regulations in place. Seat belt use in low- and middle-income countries is not high, despite strict driving laws and fines for those who do not use seat belts [6, 7]. Studies have shown that men, young people (18–34 years old), obese individuals, rear seat occupants, and villagers have lower rates of seat belt use [810].

Accordingly, estimating the prevalence of seat belt use is very important for public health policymakers to implement programs aiming at reducing mortality and morbidity from motor vehicle crashes. Moreover, there were no recent systematic reviews on seat belt use in the previous 5 years. Therefore, this study was conducted to determine the prevalence of seat belt use among drivers, front-seat passengers, and rear-seat passengers from the beginning of 2000 to late December 2020.

Methods

Search strategy and study selection

  1. This meta-analysis was performed according to the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines [11]. Relevant articles were identified through the databases of PubMed, Web of Science (WOS), and Google Scholar from the beginning of 2000 to late December 2020 using combined keywords and Medical Subject Headings (MESH) heading strategies such as "Seatbelt, "Safety belt, "Seat Belt Usage, "Prevalence," "Frequency, "Driver," "Vehicle," and "Passenger." Additionally, references from previous reviews were scanned to identify other relevant articles.

Studies that met the following criteria were selected for the current meta-analysis:

  1. Cross-sectional studies that reported data on seat belt use in commercial or personal vehicles for both drivers and front or rear seat passengers separately.

  2. Studies performed on passengers over the age of 12, as the seat belt use is suggested for those aged 12 and above, and passengers under the age of 12 should use child restraints [12].

  3. The target population was either the general population or a specific population, such as high school and university students, drivers, or passengers involved in motor vehicle crashes.

The exclusion criteria were as follows:

  1. Studies that were not written in English

  2. Studies conducted on specific populations, such as pregnant women and people with physical limitations on seat belt use and those who had undergone abdominal surgery

  3. Studies that lacked data for prevalence calculation with a 95% confidence interval

  4. Studies that reported mixed reporting of seat belt use among drivers and passengers

We also excluded studies for which we were unable to obtain a full text after contacting the corresponding author.

Quality assessment

An assessment of the quality of the included studies was performed using a quality checklist adapted from Loney et al. [13]. The checklist assesses the different aspects of methodology (study design and sampling method, sampling frame, sample size, appropriate measurement, unbiased measurement, and response rate) as well as the interpretation of results and application of findings. The study received 1 point for each criterion that was met. Scores for high-quality studies range from 7 to 8 points, for moderate-quality studies from 4 to 6 points, and for low-quality studies from 0 to 3.

Data extraction

Two researchers independently screened the identified articles from the databases based on the title and abstract. Then, the full text and abstract of the related articles were reviewed. Data were extracted from the eligible articles and recorded in an Excel checklist containing the names of authors, year of publication, study setting (country), age, gender, the number of participants, method, the prevalence of wearing a seat belt, and its 95% confidence interval. In this study, individuals who reported that they always, sometimes, often, full time, most of the time, or regularly wear seat belts were considered seat belt users. Table 1 presents a summary of the included studies in the meta-analysis.

Table 1.

Summary of the studies included in the meta-analysis

Authors Year of publication Country Setting Sampling Driver Front seat passengers Rear seat passengers How often
Age Method Sex N Prevalence (95% CI) Prevalence (95% CI) Prevalence (95% CI)
Kim [14] 2003 Hawaii  ≥ 18 _ FM 3457 FM 77.5 (76.1–78.9) 78.2 (75.5–80.9) _ _
La [15] 2013 Vietnam Hanoi 31.9 (6.8) _ FM 1214 FM 50.7 (47.8–53.5) _ _ Always
FM 11.7 (10.0–13.7) _ _ Usually
FM 10.7 (9.10–12.6) _ _ Sometimes
Routley [16] 2009 China Nanjing _ Interview survey FM 234 FM 56.4 (49.8–62.9) _ _ Always/mostly
FM 20.5 (15.5–26.3) _ _ Sometimes
Roadside observation FM 9294 FM 31.7 (30.7–32.6) _ _ _
In-taxi observation FM 285 FM 20.4 (15.8–25.5) _ _ _
Mohammadi [17] 2011 Iran Kerman 18–24 _ FM 250 FM 18.0 (13.4–23.3) _ _ Always
FM 1.06 (11.6–21.1) _ _ Most of the time
FM 20.0 (15.2–25.50) _ _ Sometimes
M 179 M 10.6 (6.05–16.0) _ _ Always
M 15.6 (10.6–21.8) _ _ Most of the time
M 19.9 (14.0–26.1) _ _ Sometimes
F 71 F 36.6 (25.5–48.9) _ _ Always
F 16.90 (9.0–27.6) _ _ Most of the time
F 21.1 (12.3–32.4) _ _ Sometimes
Allena [18] 2019 Virginia  ≥ 65 Stratified sampling FM 751 FM 96.4 (94.8–97.6) _ _ Always
M 392 FM 2.10 (1.20–3.40) _ _ Nearly always
F 350 FM 0.50 (0.10–1.30) _ _ Sometimes
Pérez-Núñez [19] 2013 Mexico  ≥ 10 Randomly, observational FM 12,064 FM 45.0 (44.3–45.7) _ _ _
García-España [20] 2012 USA _ Randomly selected FM 3126 FM 81.5 (77.0–85.2) 68.9 (64.5–72.9) _ Often/always
Chen [21] 2015 USA 47.8 FM 1265 FM 86.1 (81.6–90.7) _ _ Often
M 1183 FM 7.80 (6.50–9.10) _ _ Sometimes
F 86 _ _ -
Bener [22] 2013 Qatar  ≥ 20 Multistage stratified cluster FM 1824 FM 17.6 (15.9–19.4) _ _ Always
FM 29.6 (27.5–31.8) _

_

_

_

 More than half of the trip
M 1362 M 17.3 (15.3–19.4) _ _ Always
M 28.7 (26.3–31.2) _ _ More than half of the trip
F 462 F 18.6 (15.1–22.4) _ _ Always
F 32.2 (28.0–36.7) _ _ More than half of the trip
Kritsotakis [23] 2019 Greece 18–20 Random sample FM 536 FM 72.1 (67.9–76.1) 72.1 (68.1–75.9) 19.7 (16.4–23.3) Very often, regularly
FM 15.4 (12.3–18.9) 20.6 (17.3–24.3) 23.3 (19.7–27.1) Occasionally
M 375 M 71.4 (66.4–76.1) _ _ Very often, regularly
M 17.8 (13.9–22.3) _ _ Occasionally
F 161 F 73.9 (65.7–81.0) _ _ Very often, regularly
F 9.40 (5.10–15.5) _ _ Occasionally
Mohammadi [24] 2015 Iran Sistan and Baluchistan _ _ FM 1427 FM 58.2 (55.7–61.0) 73.3 (60.3–83.9) _ _
M 1393 M 58.3 (55.6–60.9) 32.3 (26.9–38.2) _ _
F 11 F 72.7 (39.0–93.9) 62.3 (51.1–72.6) _ _
Popoola [25] 2013 Nigeria Makurdi _ Observational FM 500 FM 57.0 (52.4–61.4) 40.3 (37.4–43.2) 3.00 (1.90–4.50) _
M 1137 M 31.2 (28.5–34.0) _ _ _
F 637 F 22.6 (19.4–26.0) _ _ _
Sangowawa [26] 2010 Nigeria Ibadan _ Cluster sampling technique, observational FM 5757 FM 31.7 (30.0–33.4) 10.3 (8.60–11.6) 0.40 (0.10–0.90) _
M 2627 M 30.2 (28.5–32.0) _ _ _
F 3130 F 47.3 (40.9–53.8) _ _ _
Mohammadzadeh [27] 2015 Iran Kashan _ FM 822 FM 68.1 (64.8–71.3) 65.5 (58.2–72.3) 30.2 (20.2–41.8) _
Praveen [28] 2020 India Observational FM 3345 FM 51.3 (49.6–53.1) _ 5.90 (5.00–6.80) _
M 3121 M 50.1 (48.4–51.9) _ 6.20 (5.00–7.50) _
F 224 F 63.8 (57.1–70.1) _ 5.60 (4.40–7.10) _
Bener [29] 2008 Qatar 18–65 A multistage stratified cluster FM 1110 _ _
FM 35.4 (32.5–38.3) _ _ More than half of the trips
FM 19.4 (17.1–21.9) _ _ Always
M 847 M 34.3 (31.1–37.6) _ _ More than half of the trips
M 18.3 (15.7–21.0) _ _ Always
F 263 F 38.7 (32.844.9) _ _ More than half of the trips
F 23.1 (18.2–28.7) _ _ Always
Briggs [30] 2008 USA  ≥ 16 Stratified three-stage cluster FM 12,731 FM 59.0 (55.3–62.6) _ _ Always
M M 52.1 (48.4–55.8) _ _ Always
F F 66.7 (62.7–70.5) _ _ Always
Fernandez [31] 2006 USA Massachusetts  ≥ 18 Systematic sampling FM 381 FM 50.1 (45.0–55.2) _ _ _
M M 42.0 (34.9–49.4) _ _ _
F F 58.0 (51.3–65.8) _ _ _
Alomari [32] 2020 Jordan Amman, Irbid, Zarqa  ≥ 18 Observational FM 2098 FM 13.0 (11.3–13.7) 8.00 (6.00–9.20) _ _
M M 9.90 (8.80–11.0) 6.80 (5.00–8.90) _ _
F F 28.6 (24.5–33.1) 8.90 (6.20–12.2) _ _
Gebresenbet [33] 2019 Ethiopia Addis Ababa May—55 Systematic sampling FM 167 FM 59.2 (38.8–77.6) _ _ _
M 122 _ _ _
F 42 _ _ _
Raman [34] 2014 Kuwait  ≥ 18 _ FM 741 FM 41.5 (37.9–45.2) 30.4 (27.1–33.9) _ Always
M 415 FM 31.7 (28.3–35.2) 32.9 (29.5–36.4) _ Mostly/sometimes
F 325 _ _ _ _
Jermakian [35] 2018 USA  ≥ 18 _ FM 1163 FM _ _ 72.1 (70.1–75.3) Always
M _ M _ _ 67.7 (62.8–72.6)
F _ F _ _ 75.4 (71.679.2)
FM 1163 FM _ _ 16.2 (14.1–18.5) Part time
M M _ _ 17.4 (9.40–25.4)
F F _ _ 15.3 (8.20–22.4)
Koushki [36] 2006 Kuwait  ≥ 18 Random sample FM 1467 FM 36.6 (34.1–39.1) _ _ Always
FM 13.5 (11.8–15.3) _ _ Often
M 881 M 18.2 (15.7–20.9) _ _ Always
M 16.0 (13.6–18.6) _ _ Often
F 586 F 64.0 (60.1–68.0) _ _ Always
F 9.70 (7.40–12.4) _ _ Often
Wong [37] 2016 Asia Singapore, Malaysia, India, China  ≥ 18 _ FM 4576 FM 91.4 (90.3–92.4) 87.4 (85.0–89.6) 44.7 (41.2–48.2) _
Vaughn [38] 2012 USA _  ≥ 18 Multistage area probability FM 75,782 _ _ _
M M 97.2 (96.8–97.5) 96.85 (96.5–97.2) _ _
F F 98.4 (98.1–98.8) 98.3 (98.0–98.6) _ _
Taylor [39] 2019 USA _  ≥ 18 _ FM 5292 FM _ 68.0 (66.6–69.3) 63.0 (62.7–65.3) Full time
M 2465 M _ _ 64.0 (62.0–65.9) Full time
F 2796 F _ _ 62.9 (61.1–64.7) Full time
Tavafian [40] 2011 Iran Bandar Abbas Mean 31.6 ± 8.7 Convenience FM 251 FM 53.3 (47.0–59.6) _ _ Often
FM 32.6 (26.9–38.8) _ _ Sometimes
Siviroj [41] 2012 Thailand _ _ Quota sampling FM 13,722 FM 71.7 (70.9–72.4) _ _ _
M 10,603 M 70.2 (69.3–71.0) _ _ _
F 3095 F 76.7 (75.2–78.2) _ _ _
Densu [42] 2013 Ghana _ _ _ FM 9868 FM 33.4 (32.4–34.3) 10.1 (9.40–10.9) _ _
M 9421 M 32.3 (31.3–33.2) 10.5 (9.60–11.4) _ _
F 447 F 56.8 (52.0–61.4) 9.30 (7.90–10.8) _ _
Jawadi [43] 2017 Saudi Arabia _  ≥ 18 _ FM 695 FM 48.6 (44.8–52.4) _ _ _
M 345 _ _ _ _
F 350 _ _ _ _
Mahfoud [44] 2015 Qatar Doha Observational FM 2011 FM 72.7 (70.8–74.7) _ _ _
M 1885 M 72.5 (70.5–74.5) _ _ _
F 126 F 75.4 (66.9–82.6) _ _ _
Routley [45] 2008 China Nanjing and Zhoushan _ Observational FM 15,2128 FM 49.0 (47.2–50.0) 6.40 (6.00–6.70) 0.40 (0.30–0.50) _
M 76,591 M 48.6 (48.1–49.0) 5.60 (5.20–5.90) 0.30 (0.20–0.40) _
F 18,697 F 53.2 (51.8–54.5) 8.00 (7.40–8.60) 0.40 (0.20–0.50) _
Routley [46] 2007 China Nanjing _ Observational FM 31,700 FM 67.3 (66.6–68.0) 19.0 (18.00–19.8) 0.50 (0.30–0.70) _
M 24,672 M 67.0 (66.3–67.8) 17.7 (16.6–18.7) 0.60 (0.40–0.90) _
F 6678 F 68.9 (66.5–71.2) 21.2 (19.7–22.8) 0.50 (0.20–0.90) _
Xiao [47] 2017 China _  ≥ 18 Randomly sampled FM 98,254 FM 7.00 (6.00–8.00) _ _ Usually
FM 8.00 (6.00–10.0) _ _ Sometimes
M _ M 8.00 (6.00–10.0) _ _ Usually
M 9.00 (7.00–11.0) _ _ Sometimes
F _ F 1.00 (1.00–3.00) _ _ Usually
F 0.40 (0.01–1.80) _ _ Sometimes
Nabipour [48] 2014 Iran Tehran _ Observational FM 10,752 FM 70.9 (70.0–71.7) _ _ _
M 9941 M 70.8 (69.9–71.7) _ _ _
F 811 F 71.3 (68.0–74.3) _ _ _
Mohammadi [49] 2009 Iran Kerman _ Randomly, observational FM 800 FM 56.9 (52.6–59.6) _ _ _
Mohamed [50] 2011 Malaysia _ Mean 30 ± 9.7 _ FM 793 FM _ _ 22.7 (19.8–25.7) Always
FM _ _ 17.1 (14.5–19.9) Often
FM _ _ 28.5 (25.3–31.7) Sometimes
M 459 M _ _ 44.4 (39.4–49.4) _
F 324 F _ _ 46.3 (40.1–52.6) _
Reagan [51] 2013 USA _  ≥ 18 _ FM 134 FM 61.9 (53.1–70.1) _ _ Consistent
FM 20.9 (14.3–28.7) _ _ Occasional
M 73 M 60.2 (48.1–71.5) _ _ Consistent
M 19.1 (10.9–30.0) _

_

_

 Occasional
F 61 F 63.9 (50.6–75.8) _ _ Consistent
F 22.9 (13.1–35.5) _ _ Occasional
Martínez-Sánchez [52] 2014 Spain Barcelona  ≥ 18 Observation FM 2442 FM 89.5 (87.9–90.9) 95.4 (93.5–96.8) 67.6 (63.6–71.4) _
M M 97.6 (96.6–98.4) _ _ _
F F 98.6 (97.2–99.4) _ _ _
Abu-Zidan [53] 2012 UAE Al-Ain _ _ FM 783 FM 25.6 (21.6–30.0) 6.50 (3.40–11.2) 1.30 (0.01–4.80) _
Afukaar [54] 2010 Ghana Kumasi Metropolis _ Observational FM 11,827 FM 17.6 (16.9–18.2) 4.90 (4.40–5.30) _ _
M 11,334 M 16.4 (15.7–17.0) 4.70 (4.20–5.20) _ _
F 493 F 44.8 (40.1–49.1) 5.4.0 (4.50–6.30) _ _
Beck [55] 2009 USA _  ≥ 18 _ FM 347,280 FM 82.4 (82.1–82.7) _ _ Always
Briggs [56] 2006 USA Non-Hispanic white  ≥ 16 _ FM 67,637 FM 40.3 (39.9–40.8) 44.8 (43.9–45.7) _ _
Mexican American FM 43.7 (42.1–45.3) 43.8 (41.3–46.4) _ _
Central American/South American FM 48.2 (44.4–52.2) 46.8 (40.7–53.0) _ _
Puerto Rican FM 43.1 (34.2–52.5) 39.3 (33.9–44.9) _ _
Cuban FM 39.6 (34.3–45.1) 41.0 (32.0–50.5) _ _
Sadeghnejad [57] 2014 Iran Tehran Stratified multistage, randomly FM 11,483 FM 77.9 (76.9–78.8) 43.7 (42.1–45.2) _ _
M 9334 M 77.5 (76.5–78.4) 44.7 (42.6–46.7) _ _
F 2150 F 81.0 (77.9–83.6) 42.1 (39.5–44.7) _ _
Han [58] 2015 Nebraska _  ≥ 15 FM 10,479 FM 83.0 (82.3–83.8) _ _ _
M 4439 M 77.1 (75.8–78.3) _ _ _
F 6040 F 87.5 (86.6–88.3) _ _ _
Kim [59] 2009 USA _ Teenage Observational FM 14,026 FM 60.7 (59.9–61.4) 64.1 (61.6–66.6) _ _
M 7620 _ _ _ _
F 7837 _ _ _ _
Kim [60] 2019 Korea _ Mean 34.7 _ FM 419 FM 82.8 (76.7–87.9) 64.4 (54.6–73.5) 24.8 (17.5–33.3) _
M 247 _ _ _
F 172 _ _ _
Kwak [61] 2015 Korea _  ≥ 19 _ FM 23,698 FM 76.6 (75.9–77.3) 45.6 (44.6–46.6) _ _
M 12,527 _ _ _
F 11,171 _ _ _
Lardelli-Claret [62] 2009 Spain _  ≥ 18 _ FM 84,338 FM 90.4 (90.2–90.6) 88.8 (88.6–89.1) _ _
Molnar [63] 2012 USA _ _ _ FM 19,090 FM 66.1 (65.5–66.8) _ _ _
M 13,439 M 62.3 (61.4–63.1) _ _ _
F 5651 F 75.3 (74.2–76.5) _ _ _
Sabzevari [64] 2016 Iran Kashmar, Bardaskan, Khalilabad Observational FM 10,255 FM 51.8 (50.8–52.7) _ _ _
M 9798 M 51.4 (50.4–52.3) _ _ _
F 457 F 60.5 (55.9–65.1) _ _ _
Zambon [65] 2008 Italy Veneto region _ Multistage sample stratification FM 16,040 _ _ _ _
Observational 2003 M M _ _ 10.6 (9.1–12.1) _
F F _ _ 11.7 (10.4–13.0) _
_ _ _
Self-reported 2003 M M _ _ 13.5 (12.0–15.1) _
F F _ _ 17.5 (15.8–19.1) _
_ _ _
Observational 2005 M M _ _ 25.0 (23.0–27.0) _
F F _ _ 27.6 (25.7–29.4) _
_ _ _
Self-reported 2005 M M _ _ 35.8 (33.2–38.4) _
F F _ _ 38.8 (36.9–40.7) _
Dulf [66] 2020 Romania Cluj-Napoca _ Observational FM 768 FM 66.8 (63.3–70.1) _ _ _
M 469 _ _ _
F 299 _ _ _
Beck [67] 2019 USA _  ≥ 18 Probability-based sampling FM 4170 FM _ 86.1 (85.0–87.1) 61.6 (60.0–63.1) Always
M 2009 M _ 82.2 (80.5–83.9) 60.0 (57.7–62.3)
F 2161 F _ 89.6 (88.4–90.9) 62.9 (60.9–650)
Bhat [9] 2015 USA _  ≥ 18 _ FM 3953 FM _ 62.0 (60.4–63.5) Always
M 1804 M _ 60.0 (56.9–63.1)
F 2149 F _ 62.9 (60.1–65.8)
Boakye [68] 2019 USA East Tennessee _ A multistage area probability, observational FM 33,310 FM 92.0 (91.6–92.3) 85.4 (85.0–85.8) _ _
M 22,172 M 86.0 (85.5–86.5) 79.0 (78.2–79.7) _ _
F 11,138 F 86.0 (85.3–86.6) 89.0 (88.5–89.4) _ _
Crandon [69] 2006 Jamaica Kingston _ Observational FM 2846 FM 81.2 (79.5–82.7) 74.0 (70.7–77.1) _ _
M 2028 M 77.3 (75.2–79.2) 66.3 (60.8–71.3) _ _
F 1014 F 92.5 (90.0–94.4) 80.0 (75.7–83.6) _ _
Fong [70] 2016 Australia _  ≥ 75 Observational FM 367 FM 97.0 (94.7–98.4) _ _
Iribhogbe [71] 2008 Nigeria Benin Observational FM 1785 FM 52.3 (47.0–57.5) 18.4 (14.1–23.3) 6.10 (4.80–7.70) _
Kamal [72] 2015 Malaysia Selangor 18–39 Convenience sampling FM 408 FM 45.1 (40.2–50.0) _ _ Always
FM 27.9 (23.6–32.5) _ _ Most of the time
FM 20.5 (16.7–24.8) _ _ Sometimes
_ _
M 184 M 40.2 (33.0–47.6) _ _ Always
M 28.2 (21.8–35.3) _ _ Most of the time
M 26.0 (19.9–33.0) _ _ Sometimes
_ _
F 224 F 49.1 (42.3–55.8) _ _ Always
F 27.6 (21.9–34.0) _ _ Most of the time
F 16.0 (11.5–21.5) _ _ Sometimes
Febres [73] 2020 Spain _ _ _ FM 257,851 FM 74.4 (74.2–74.5) _ _ _
M 178,839 _ _
F 76,837 _ _
Ünal [74] 2020 Turkey Semi-rural Mean 16.0 ± 1.2 _ FM 1465 FM 77.1 (74.9–79.2) _ _ _
M 759 M 74.3 (71.0–77.3) _ _ _
F 706 F 80.1 (77.0–83.0) _ _ _
Shaaban1 [75] 2018 Qatar _ 18–25 FM 3049 FM 61.4 (59.4–63.3) 48.8 (44.5–53.2) _ _
M 1856 M 58.0 (55.6–60.4) 40.6 (33.6–47.8) _ _
F 1193 F 67.9 (64.7–71.0) 53.6 (48.2–59.0) _ _
Shaaban [76] 2020 Qatar Doha  ≥ 18 _ FM 7908 FM 83.6 (82.7–84.4) _ _ _
M 7180 M 83.3 (82.4–84.2) _ _ _
F 728 F 86.1 (83.4–88.5) _ _ _
Siddiqui [77] 2014 Pakistan Karachi _ convenience FM 212 FM 15.0 (10.5–20.6) _ _ Regularly
M 126 FM 34.4 (28.0–41.2) _ _ Occasionally
F 86 _ _
Li [78] 2018 China Shanghai _ Stratified, observational FM 77,641 FM 88.4 (88.1–88.6) _ _ _
M 61,561 _ _ _ _
F 61,088 _ _ _ _
Kulanthayan [79] 2004 Malaysia _ _ _ FM 273 FM 76.6 (68.6–83.4) 56.0 (41.2–70.0) _ _
Lerner [80] 2001 USA _ 13–93 _ FM 1656 FM 71.9 (69.7–74.1) _ _ _
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Statistical analysis

The pooled prevalence of wearing a seat belt with a 95% confidence interval was calculated using random-effect meta-analyses. Inter-study heterogeneity was assessed using chi-squared tests and the I2 statistic. Additionally, subgroup analyses were performed to explore the sources of heterogeneity, and Egger’s test was used to detect publication bias. The STATA-v14 (Stata Corp, TX, USA) software was used to analyze the data [81].

Results

Out of 836 identified articles in the databases, 435 were excluded due to duplication or unrelated titles. Another 254 articles were removed after screening based on the abstract as they were review articles, published before 2000, or were not cross-sectional or observation studies. After that, 147 full-text articles were reviewed and assessed according to the eligibility criteria. Out of these, 79 articles were excluded as they did not report the prevalence or had sufficient data to calculate 95% CI or had mixed reporting of the prevalence of seat belt use among drivers and passengers. Finally, 68 articles with a total of 1,490,226 participants that met the inclusion criteria were included in this meta-analysis. The flowchart of the study selection process is shown in Fig. 1.

Fig. 1.

Fig. 1

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PRISMA flowchart of the study selection process

Out of 68 studies included in the meta-analysis, ten were considered high quality, 53 were considered moderate quality, and five were considered low quality (Supplementary Table S1). The pooled prevalence of seat belt use among drivers in the high-quality studies, the moderate quality studies, and the low-quality studies were 37.12% (95% CI: 33.00–41.76), 47.72% (95% CI: 45.77–49.75), and 37.75% (95% CI: 27.46–51.91), respectively, which showed some evidence of heterogeneity (P < 0.001) in terms of study quality. Therefore, we estimated pooled prevalence based on the type of vehicle in the three study groups, and no heterogeneity was observed. Therefore, the quality of the studies did not affect the present meta-analysis results (Supplementary Table S2).

Prevalence of seat belt use

In general, the pooled prevalence of seat belt use among drivers, front-seat passengers, and rear-seat passengers was 43.94% (95% CI: 42.23–45.73), 38.47% (95% CI: 34.89–42.42), and 15.32% (95% CI: 12.33–19.03), respectively. The lowest prevalence of seat belt use among drivers was in Asia [37.86% (95% CI: 34.44–41.61)] and Middle East [38.17% (95% CI: 34.25–42.55)] region, and the highest was in Western Europe [84.42% (95% CI: 72.32–98.55)] and the Americas [51.57% (95% CI: 47.54–55.93)]. Also, the lowest prevalence of seat belt use among front- and rear-seat passengers was found in Africa (17.43%, 2.29%), Asia (34.62%, 7.93%), and the Middle East (31.53%, 9.24%) (P < 0.001).

The prevalence of seat belt use was significantly higher in female drivers [51.47% (95% CI: 48.62–54.48)] compared to male drivers [38.27% (95% CI: 34.98–41.87)] (P < 0.001). In addition, the prevalence of seat belt use among female front-seat passengers [33.09% (95% CI: 29.45–37.18)] and rear-seat passengers [18.27% (95% CI: 13.73–24.32)] was higher than among male front-seat passengers [25.96% (95% CI: 20.18–33.38)] and rear-seat passengers [15.55% (95% CI: 10.97–22.04)], although this difference was not statistically significant (P = 0.08, P = 0.48).

The drivers and front-seat passengers of SUVs (68.9%, 50.5%) and vans (70.39%, 19.83%) showed a higher prevalence of seat belt use compared to drivers and front-seat passengers of other vehicle types. In contrast, drivers of buses (21.84%) and minibuses (28.16%) and front-seat passengers of minibuses (1.80%) and taxis (3.82%) displayed lower prevalence of seat belt use (P < 0.001).

Furthermore, the highest prevalence of seat belt use among drivers was in the morning [54.89% (95% CI: 46.85–64.32)], followed by in the afternoon/evenings [50.78% (95% CI: 43.52–59.25)] and the night [46.59% (95% CI: 31.49–68.91)], but the differences were not statistically significant (P = 0.66). On the other hand, the highest prevalence of seat belt use among front-seat passengers was at night [51.3% (95% CI: 41.80–60.70)] (P < 0.001).

In addition, the highest prevalence of seat belt use among drivers was observed on intercity roads [45.49% (95% CI: 33.48–61.80)], while the lowest prevalence was observed on side streets [29.68% (95% CI: 23.12–38.11)] (P = 0.04). Additionally, the highest prevalence of seat belt use among front-seat passengers was also on intercity roads [16.98% (95% CI: 4.06–70.91)] (P = 0.28) (Table 2, Fig. 2).

Table 2.

The prevalence of seat belt use among drivers and passengers

Variables No. of studies (population) Driver Front seat passengers Rear seat passenger
NR Prevalence (95% CI) Test for heterogeneity (p-value) NR Prevalence (95% CI) Test for heterogeneity (p-value) NR Prevalence (95% CI) Test for heterogeneity (p-value)
Total 68 (1,490,226) 86 43.94 (42.23–45.73) 36 38.47 (34.89–42.42) 21 15.30 (12.33–19.03)
Region
 Europe 5 (361,207) 6 65.33 (58.25–73.26) < 0.001 4 65.61 (57.93–74.32) < 0.001 11 22.86 (16.40–31.85) < 0.001
 Asia 16 (417,770) 24 37.86 (34.44–41.61) 6 34.62 (16.97–70.65) 8 7.930 (3.340–18.82)
 Africa 7 (32,750) 7 42.76 (25.44–71.88) 6 17.43 (6.580 – 46.12) 3 2.290 (0.820 – 6.370)
 Mediterranean & Middle East 19 (58,081) 26 38.17 (34.25–42.55) 8 31.53 (23.58–42.16) 2 9.24 (0.460–183.23)
Americas 21 (619,012) 27 51.57 (47.54–55.93) 13 64.92 (60.29–69.90) 4 64.44 (60.90–68.19)
Sex
 Male 39 (499,866) 43 38.27 (34.98–41.87) < 0.001 12 25.96 (20.18–33.38) 0.08 13 15.55 (10.97–22.04) 0.48
 Female 39 (232,169) 43 51.47 (48.62–54.48) 12 33.09 (29.45–37.18) 13 18.27 (13.73–24.32)
Type of vehicle
 Car 19 (405,955) 20 58.06 (53.32–63.23) < 0.001 8 24.25 (15.17–38.76) < 0.001 3 3.270 (00.15–71.33)
 SUV 6 (130,171) 7 68.90 (62.90–75.47) 1 50.50 (44.60–56.30) _ _
 Taxi 10 (314,269) 10 47.29 (38.71–57.76) 5 3.820 (0.830–17.52) 2 0.200 (00.13–0.300)
 Minibus 6 (129,070) 6 28.16 (19.07–41.56) 2 1.800 (00.38–08.49) _ _
 Bus 7 (112,558) 7 21.84 (15.22–31.35) 4 4.030 (2.690–6.040) _ _
 Van 6 (240,893) 6 70.39 (55.77–88.83) 3 19.83 (7.720–50.89) 1 0.200 (0.001–01.00)
 Pickup 11 (367,358) 11 52.91 (46.86–59.73) 3 9.01 (02.04–39.69) _ _
 Truck 10 (134,048) 11 28.27 (21.13–37.84) 4 8.660 (03.26–22.97) _ _
Time
 Morning 14 (247,090) 21 54.89 (46.85–64.32) 0.66 9 11.47 (6.820–19.30) < 0.001 6 0.400 (0.250–0.660) 1.00
 Afternoon/evening 12 (243,907) 20 50.78 (43.52–59.25) 8 10.78 (7.640–15.20) 6 0.400 (0.300–0.530)
 Night 5 (18,832) 5 46.59 (31.49–68.91) 1 51.30 (41.80–60.70) _ _
Type of road
 Main street 10 (247,122) 10 42.84 (34.14–53.75) 0.04 5 10.78 (6.100–19.04) 0.28 2 0.920 (0.540–1.560) 0.01
 Side street 9 (233,400) 9 29.68 (23.12–38.11) 5 6.260 (3.430–11.43) 2 0.270 (0.120–0.590)
 Intercity road 7 (68,729) 8 45.49 (33.48–61.80) 3 16.98 (4.060–70.91) _ _
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Fig. 2.

Fig. 2

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Sensitivity analysis of the prevalence of seat belt usage among drivers

Moreover, a subgroup analysis was performed between the data obtained from national surveys and the findings from observational studies. There was no evidence of heterogeneity between the pooled prevalence of seat belt use among drivers in observational studies [43.26% (95% CI: 40.93–45.72)] and national surveys [42.35% (95% CI: 38.7–46.24)] (P = 0.69).

Discussion

This study assessed the prevalence of seat belt use among drivers, front-seat passengers, and rear-seat passengers between 2000 and 2020. The results showed that the prevalence of seat belt use among drivers was not high (43.94%). Additionally, the study found that rear-seat passengers (15.32%) are less likely to always or more often wear seat belts compared to front-seat passengers (38.47%), which is consistent with the results of other studies [67, 82, 83]. A survey of adults also revealed that those who did not wear seat belts in the back seat believed that the rear seat was safer than the front seat and that seat belts were not necessary on short trips [35].

This study showed that the prevalence of seat belt use in the Asian, Mediterranean and Middle East, and African regions was lower than in Europe and the Americas, which may partially be attributed to the differences in driving laws and regulations within countries in these regions.

According to Word Health Organization’s previous reporting, the African region has the highest traffic injury death rates, while the European region has the lowest [2]. Other studies have also highlighted that the prevalence of seat belt use is not high in low- and middle-income countries, and more than 90% of the world’s road fatalities occur in these countries [7, 84].

The National Highway Traffic Safety Administration (NHTSA) of the USA recommended that wearing a seat belt is one of the safest choices that drivers and passengers can make on the road. It also asserted that the national use rate was 90.4% in 2021, and that seat belts saved an estimated 14,955 American lives in 2017 alone, and they could have saved an additional 2549 people if they had been wearing seat belts [85].

It has been demonstrated that in 2013, almost 85,000 people died from road traffic injuries in the WHO European Region. In this region, 95% of the population is governed by comprehensive traffic laws which are in line with best practices for seat belts. Additionally, in 36 European countries, the median reported usage of seat belts among front-seat occupants was 86%, and the median proportion of rear seat-belt use was 65% [86].

This study also found that the prevalence of seat belt use in women drivers and passengers was significantly higher than in men. This pattern has been observed in other studies [8789], which may be due to women being more conservative drivers and more likely to follow driving laws. Previous studies have also reported more traffic violations among men than women [90], which explains why men are more likely to be injured in traffic accidents [23].

This study observed a significant relationship between the type of vehicle and seat belt use among drivers and passengers. SUV drivers and passengers were more likely to wear seat belts than drivers and passengers of other vehicles, which is consistent with a study conducted in the USA [91]. This difference could be due to various factors, including SUV drivers and passengers exhibiting healthier behaviors due to their higher socioeconomic status [92, 93].

On the other hand, drivers and passengers of public vehicles (buses, minibuses, and taxis) tend to wear seat belts less frequently. In many countries, public transport makes frequent stops, and drivers are sometimes forced to disembark at many stations to meet passengers’ needs, making it uncomfortable for them to wear seat belts. Other studies have also shown that seat belt use is less common in public transport due to the frequent stops [71, 94].

Previous studies have shown a statistically significant relationship between seat belt use and the time of day [37, 95, 96]. In many countries, officers are usually present to monitor the roads at any time of day, and drivers familiar with the regulations tend to use seat belts as a precaution. In agreement, this study found that drivers wore seat belts more frequently during the day than at night, although this difference was not statistically significant. This study also showed that drivers were more likely to use seat belts while driving on intercity roads than on the main and side streets in the city. This finding may be attributed to the greater presence of traffic police and the higher number of traffic cameras on intercity roads. Moreover, a study in Nigeria has shown that seat belt use is more common on interurban roads than on rural roads [97].

limitations

Finally, there were limitations to this study that should be taken into consideration when interpreting the results. The first limitation was the different methods used to measure seat belt usage across different studies. The second limitation was the unequal number of studies conducted in the five geographical regions, as well as the use of different sampling methods, which could be a contributing source to the variation in the prevalence of seat belt use across these regions. The third limitation was the lack of information on seat belt use by time and road type in some studies.

Conclusion

This meta-analysis showed that, in general, the prevalence of seat belt use among drivers and car passengers is not high. Seat belt use was found to be lower in Asia, the Mediterranean and Middle East, and Africa compared to Europe and the Americas. We also found that women wore seat belts significantly more than men. Furthermore, seat belt use among drivers and passengers of public transportation (buses, minibuses, taxis) was lower than in other vehicles. Therefore, it is necessary to design and implement well-structured targeted interventional programs, such as developing training campaigns about the benefits of seat belt use among these vulnerable populations, especially in Asia, the Mediterranean and Middle East, and Africa. Additionally, we recommend further research be conducted to explore the factors that affect drivers’ and passengers’ attitudes and knowledge about seat belt use.

Supplementary Information

42506_2023_139_MOESM1_ESM.docx (31.1KB, docx)

Additional file 1: Table S1. Quality assessment for included studies. Table S2. The prevalence of seat belt use based on the type of vehicle in three studies groups.

Acknowledgements

Not applicable.

Abbreviations

SUVs

Sports utility vehicles

GDP

Global gross domestic product

Authors’ contributions

SK was involved in the conception and design of the study. SK and HA were involved in the investigation and screening of articles and data extraction. SK and AAM were involved in the analysis and interpretation of data. SK was involved in the drafting and critical revision of the manuscript. All authors read and approved the manuscript.

Funding

Not applicable.

Availability of data and materials

Data are available upon request.

Declarations

Ethical approval and consent to participate

Not applicable.

Consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

Footnotes

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Change history

12/7/2023

Incorrect spelling in affiliation. It was published: Health Promotion Research Centre, Zahedan University of Medical Sciences, Zahedan, Iran. It should be: Health Promotion Research Center, Zahedan University of Medical Sciences, Zahedan, Iran.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

42506_2023_139_MOESM1_ESM.docx (31.1KB, docx)

Additional file 1: Table S1. Quality assessment for included studies. Table S2. The prevalence of seat belt use based on the type of vehicle in three studies groups.

Data Availability Statement

Data are available upon request.

Articles from Journal of the Egyptian Public Health Association are provided here courtesy of Springer

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