The impact of sleep deprivation and alcohol on driving: a comparative study

Lowrie, Joanna; Brownlow, Helen

doi:10.1186/s12889-020-09095-5

Cited by 19 publications

(10 citation statements)

References 55 publications

(69 reference statements)

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“…As for the tiresome driving tasks, the results showed a clear and tangible increase in the average response time than it was in the nonfatigue driving task, where the increase in response time increased gradually, with the highest average response time being recorded in the last quarter of an hour, where the average response time was 1.23 seconds. The results in this study are in agreement with the findings of the studies [11], [15], [24], where the reason for this increase is attributed to mental fatigue resulting from driving conditions represented by lack of sleep and examination time, which represents the second peak of sleep fatigue, as shown in Figure (6). The results of this study showed that when comparing the average cognitive time for fatigued and non-Fatigue driving tasks, there was a clear change in the response time for the participants.…”

Section: For All Participantssupporting

confidence: 93%

“…And [15], after testing 30 participants, showed a clear increase in cognitive time for drivers in tiring driving tasks compared to non-fatigue, as the increase was estimated at 0.31 milliseconds. In addition, [11] tested 30 participants in a driving simulator in fatigued driving tasks and alert driving tasks, the results showed a clear and tangible increase in the response time, as the increase was estimated (0.5) milliseconds. [16] also tested 22 participants with a driving simulator with multiple driving tasks, including fatigued and non-fatigue driving tasks.…”

Section: Literature Reviewmentioning

confidence: 99%

“…As a result, finding signs of burnout is important for enhancing driver safety on the roads. Moreover, having a good view of the limits of exhaustion will help determine when drivers should be told to take a break [11].…”

Section: Introductionmentioning

confidence: 99%

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Assessing the Effect of Lack of Sleep on Driver's Performance: A Simulator Study

Muneer¹,

Abduljabbar²,

Al-Dahwi³

2021

ETJ

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Current research assesses the effect of fatigue on drivers' performance.• The results show that the level of alertness has decreased in fatigued driving. • Male participants have showed better response time when compared to female participants. • Young participants are more affected by fatigue driving than older people. Science evidence suggests that fatigue due to lack of sleep is a major cause of most traffic accidents. Fatigue can arise when people do not get enough sleep, which is at least 7 hours, and this deprivation can impair body performance physically and mentally while driving. This study investigated the effect of sleep deprivation fatigue on driving performance. Experiments were performed for two types of tasks, Fatigue driving tasks (sleep deprivation) and non-Fatigue driving tasks (without sleep deprivation) on a driving simulator at the University of Technology, in which 42 participants; aged (19-55) took part with an average age (mean = 33.14, SD = 10.26). Driver performance was assessed using descriptive methods to verify response time and subjective behavior methods using the Stanford Drowsiness Scale. The results showed a gradual increase in the average response time of the fatigued drivers compared to the non-fatigue drivers. The results of the response time indicated that all groups were affected by the test conditions, through the variation in the average response time between the two tasks. In a related context, the results of the Stanford Drowsiness Scale show a significant increase in the average degree of drowsiness for fatigue drivers, as it was greater than for non-Fatigue drivers.

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Section: For All Participantssupporting

confidence: 93%

Section: Literature Reviewmentioning

confidence: 99%

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Assessing the Effect of Lack of Sleep on Driver's Performance: A Simulator Study

Muneer¹,

Abduljabbar²,

Al-Dahwi³

2021

ETJ

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“…Studies of sleep restriction suggest that cognitive deficits accumulate when adults attain less than 7 hr per night (Goel et al, 2009). Chronic sleep restriction, which is not uncommon in a military environment, can result in cognitive deficits equivalent to those observed after 24 hr of wakefulness (Van Dongen et al, 2003), and this level of sleep deprivation results in deleterious effects similar to drink‐drive limits (Fairclough & Graham, 1999; Lowrie & Brownlow, 2020). Further, emotional, behavioural and functional dysfunction have all been identified in a military context following poor sleep quality (Mantua et al, 2020; Mantua, Bessey, et al, 2021a).…”

Section: Discussionmentioning

confidence: 99%

Operation early‐bird: Investigating altered light exposure in military barracks on sleep and performance—a placebo‐controlled study

Edgar

Beaven

Gill

et al. 2023

Journal of Sleep Research

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The manipulation of light exposure in the evening has been shown to modulate sleep, and may be beneficial in a military setting where sleep is reported to be problematic.This study investigated the efficacy of low-temperature lighting on objective sleep measures and physical performance in military trainees. Sixty-four officer-trainees (52 male/12 female, mean ± SD age: 25 ± 5 years) wore wrist-actigraphs for 6 weeks during military training to quantify sleep metrics. Trainee 2.4-km run time and upperbody muscular-endurance were assessed before and after the training course. Participants were randomly assigned to either: low-temperature lighting (LOW, n = 19), standard-temperature lighting with a placebo "sleep-enhancing" device (PLA, n = 17), or standard-temperature lighting (CON, n = 28) groups in their military barracks for the duration of the course. Repeated-measures ANOVAs were run to identify significant differences with post hoc analyses and effect size calculations performed where indicated. No significant interaction effect was observed for the sleep metrics; however, there was a significant effect of time for average sleep duration, and small benefits of LOW when compared with CON (d = 0.41-0.44). A significant interaction was observed for the 2.4-km run, with the improvement in LOW (Δ92.3 s) associated with a large improvement when compared with CON (Δ35.9 s; p = 0.003; d = 0.95 ± 0.60), but not PLA (Δ68.6 s). Similarly, curl-up improvement resulted in a moderate effect in favour of LOW (Δ14 repetitions) compared with CON (Δ6; p = 0.063; d = 0.68 ± 0.72). Chronic exposure to low-temperature lighting was associated with benefits to aerobic fitness across a 6-week training period, with minimal effects on sleep measures.

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“…It is unlikely there is one single explanation, but we have argued that the sedating effects of alcohol and drugs (as opposed to the intoxicating effects) are an understudied contributor of impaired driving crashes [ 18 – 20 ]. While drowsiness produces quantitative decrements in driving-related skills similar to alcohol and some drugs [ 21 ], we argue that falling asleep behind the wheel (for which drowsiness is a precursor) represents a qualitative change in crash risk. Crashes due to quantitative skill impairment require there being objects to track and avoid, things to drive around and react to, situations requiring decision making, etc.…”

Section: Discussionmentioning

confidence: 99%

The prevalence of alcohol-involved crashes across high and low complexity road environments: Does knowing where drinking drivers crash help explain why they crash?

Johnson

2022

PLoS ONE

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Objective Alcohol use has been linked to impairment of cognitive and psychomotor driving skills, yet the extent to which skill impairment contributes to actual crashes is unknown. A reasonable assumption is that some driving situations have higher skill demands than others. We contend that intersections, the presence of other vehicles or moving objects, and work zones are examples of common situations with higher skill demands. Accordingly, if skill deficits are largely responsible for alcohol-involved crashes, crashes involving a drinking driver (versus only sober drivers) should be overrepresented in these driving situations. Method Publicly available FARS data from 2010 to 2017 were collected. Fatal crashes were coded as alcohol-involved (1+ driver with a blood alcohol concentration [BAC] ≥ .05 g/dl) or having no impaired driver (BACs = .000). Drug-positive crashes were excluded. Crashes were also coded as involving moving versus stationary objects, occurring at versus away from intersections, being multivehicle versus single vehicle, occurring at or away from work zones. Results Across multiple models, controlling for time of day and type of road, alcohol-involved crashes were significantly underrepresented in crashes at intersections, with moving objects, and other vehicles. Most strikingly, alcohol-involved crashes were 24 percentage points more likely to be with a stationary object than a moving object. Conclusions No evidence supported the idea that skill reductions are a primary contributor to alcohol-involved crashes. Alternative explanations and limitations are discussed.

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The impact of sleep deprivation and alcohol on driving: a comparative study

Cited by 19 publications

References 55 publications

Assessing the Effect of Lack of Sleep on Driver's Performance: A Simulator Study

Assessing the Effect of Lack of Sleep on Driver's Performance: A Simulator Study

Operation early‐bird: Investigating altered light exposure in military barracks on sleep and performance—a placebo‐controlled study

The prevalence of alcohol-involved crashes across high and low complexity road environments: Does knowing where drinking drivers crash help explain why they crash?

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