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Making Healthcare Safer IV: A Continuous Updating of Patient Safety Harms and Practices [Internet]. Rockville (MD): Agency for Healthcare Research and Quality (US); 2023 Jul-.

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Making Healthcare Safer IV: A Continuous Updating of Patient Safety Harms and Practices [Internet].

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Fatigue and Sleepiness of Clinicians Due to Hours of Service

Rapid Response

, M.A., Ph.D., , M.A., , B.S., , B.Sc., , B.A., and , M.D., M.P.H.

Created: .

Main Points

  • Interventions to reduce clinician fatigue and sleepiness due to long work hours have had mixed effects on the incidence of medical errors, patient mortality, and patient morbidity.
  • Recent research has focused primarily on resident physicians, and to a lesser extent, nurses and practicing physicians.
  • Interventions have focused primarily on work schedules, including limiting the number of hours worked in a shift or total over a week and ensuring adequate time for recovery between shifts.
  • Few studies have addressed fatigue risk management interventions beyond scheduling, but interventions have included lighting, breaks, and scheduled napping.
  • Barriers have included concerns about continuity of care and increased faculty clinical responsibilities arising from changes in resident duty hour limitations.
  • Facilitators have included handoff training and hiring mid-level providers.
  • No toolkits were identified to support implementation of interventions for reducing clinician fatigue and sleepiness due to long duty hours.

1. Background and Purpose

The Agency for Healthcare Research and Quality (AHRQ) Making Healthcare Safer (MHS) reports consolidate information for healthcare clinicians, health system administrators, researchers, and government agencies about patient safety practices (PSPs) that can improve patient safety across the healthcare system—from hospitals to primary care practices, long-term care facilities, and other healthcare settings. In Spring of 2023, AHRQ launched its fourth iteration of the MHS reports (MHS IV).

Fatigue and sleepiness of clinicians due to hours of service is a patient safety risk and associated PSPs were identified as high priority for inclusion in the MHS IV reports using a modified Delphi technique by a Technical Expert Panel (TEP) that met in December 2022. The TEP included 15 experts in patient safety with representatives of governmental agencies, healthcare stakeholders, clinical specialists, experts in patient safety issues, and a patient/consumer perspective. See the MHS IV Prioritization Report for additional details.1

Insufficient or disrupted sleep leads to a state of fatigue characterized by deficits in attention, memory, and cognitive speed.2 This neurobehaviorally degraded state translates into poorer performance by clinicians3 and ultimately can contribute to medical errors.4 Thirty-six percent of healthcare practitioners and technicians and 45 percent of personnel in healthcare support occupations report chronic short sleep durations.5 This is driven by long working hours, particularly for clinical trainees, and shift work schedules necessary to staff hospitals around the clock.

1.1. Overview of the Patient Safety Practice

Fatigue is a safety risk in the workplace across industries,6 and consequently general principles and practices for fatigue risk management systems have been developed7,8 and evaluated in different settings.9 This PSP topic was addressed in the MHS I report, which provided a broad review of workplace fatigue including studies across industries, as very little research had been conducted within healthcare settings at the time.10 The MHS I review covered interventions focused on hours of service (i.e., regulations limiting the maximum shift length or total hours worked, and comparisons of 8- versus 12-hour shift lengths), the direction and speed of rotation through shift work (i.e., shift rotation directions moving “forward” [day to evening to night] or “backward” [day to night to evening]; slow versus fast shift rotations), sleep hygiene education, work lighting, napping, and medical therapies (e.g., melatonin, sedatives, and stimulants). That report concluded that there was an insufficient evidence base within healthcare settings, but fatigue management interventions from other work domains had high face-validity, low likelihood of harm, and high ease of implementation. The hours of service and fatigue topic received a brief update in MHS II, focusing on evaluations of regulatory limitations on resident work hours.11 Based on several systematic reviews of that literature, the MHS II review concluded that work hour limitations did not reduce mortality or improve safety; but there were fewer objective and self-reported medical errors with 16-hour shift lengths than with traditional 30-hour shifts. Patient safety risks due to fatigue and sleepiness of healthcare workers were not addressed in MHS III.

In the decade since the MHS II report, the high levels of burnout among clinicians have come into focus.12,13 While burnout is complex, sleep deprivation has been implicated in the development and sustainment of high levels of burnout.14 The coronavirus disease of 2019 (COVID-19) pandemic may have amplified these issues in part due to atypical work schedules.15

In the prioritization process, the MHS IV TEP did not suggest alterations to past definitions of this patient safety risk or associated PSPs. However, due to the limited time and funding allocated for this rapid response, the report focuses on PSPs targeting clinicians rather than other healthcare workers because patient outcomes are more directly related to the performance of clinicians than to the performance of nonclinical healthcare workers. Clinicians are defined as any person providing healthcare to patients (e.g., physician, nurse, physician assistant, respiratory therapist, or pharmacist). The report also focuses on clinicians in acute care hospital settings because that is where interventions on shift schedules and fatigue risk management practices are most likely to have been conducted.

1.2. Purpose of the Rapid Response

The purpose of this rapid response is to summarize the most relevant and recent literature on PSPs focused on fatigue and sleepiness of clinicians related to hours of service and how these PSPs can be implemented. The report should be of interest to healthcare system and hospital leaders who are wrestling with concerns about clinician burnout.

1.3. Review Questions

  1. What are the frequency and severity of harms associated with fatigue and sleepiness of clinicians due to hours of service?
  2. What patient safety measures or indicators have been used to examine the harm associated with fatigue and sleepiness of clinicians?
  3. What PSPs have been used to prevent or mitigate the harms associated with fatigue and sleepiness of clinicians due to hours of service and in what settings have they been used?
  4. What is the rationale for the PSPs used to prevent or mitigate the harms associated with fatigue and sleepiness of clinicians due to hours of service?
  5. What studies have assessed the effectiveness and unintended effects of the PSPs and what new evidence has been published since the search was done for the MHS II report in 2013?
  6. What are common barriers and facilitators to implementing the PSPs?
  7. What resources (e.g., cost, staff, time) are required for implementation?
  8. What toolkits are available to support implementation of the PSPs?

2. Methods

We followed processes proposed by the AHRQ Evidence-based Practice Center Program.16 The rapid response is intended to present the end-user with an answer based on the best available evidence, but does not attempt to formally synthesize the evidence into conclusions. While the steps are similar to those of a typical systematic review, the methods are different (i.e., streamlined systematic review methods).17

For this rapid response, strategic adjustments were made to streamline traditional systematic review processes and deliver an evidence product in the allotted time. Adjustments included being as specific as possible about the questions, limiting the number of databases searched, modifying search strategies to focus on finding the most valuable studies (i.e., being flexible on sensitivity to increase the specificity of the search), and restricting the search to studies published recently (i.e., since 2013 when the search was performed for the MHS II report) in English and performed in the United States. Additionally, it was deemed out of scope for this rapid response to refer back to primary studies when included systematic reviews failed to provide sufficient clarification. For this report, we used the artificial intelligence (AI) feature of DistillerSR (AI Classifier Manager) as a second reviewer at the title and abstract screening stage.

We asked our content experts to answer Review Questions 1 and 2 by citing selected references that best answer the questions without conducting a systematic search for all evidence on the targeted harms and related patient safety measures or indicators. We focused on the harms and patient safety measures or indicators that are addressed in the studies we identified for Review Question 5. For Review Question 2, we focused on identifying relevant measures that are included in the Centers for Medicare & Medicaid Services (CMS) patient safety measures, AHRQ’s Patient Safety Indicators, or the National Committee for Quality Assurance (NCQA) patient safety related measures. We asked our content experts to answer Review Questions 3 and 4 by citing selected references, including patient safety practices (PSPs) used and explanations of the rationale presented in the studies we identified for Review Question 5. For Review Questions 6 and 7, we focused on the barriers, facilitators, and required resources reported in the studies we identified for Review Question 5. For Review Question 8, we identified publicly available patient safety toolkits developed by AHRQ or other organizations that could help to support implementation of the PSPs. To accomplish that task, we reviewed AHRQ’s Patient Safety Network (PSNet)18 and AHRQ’s listing of patient safety–related toolkits19 and we included any toolkits mentioned in the studies we find for Review Question 5. We identified toolkits without assessing or endorsing them.

2.1. Eligibility Criteria for Studies of Effectiveness

We searched for original studies and systematic reviews on Review Question 5 according to the inclusion and exclusion criteria presented in Table 1. As this review focuses on patient safety, we searched for studies and systematic reviews that report on clinical and patient safety outcomes. Work hours and fatigue risk management interventions also have intermediate outcomes for workers (e.g., well-being) and organizations (e.g., turnover and absenteeism), but these are out of scope for the current rapid response.

Table Icon

Table 1

Inclusion and exclusion criteria.

2.2. Literature Searches for Studies of Effectiveness

We searched PubMed and the Cochrane Library for systematic reviews and original studies published since the MHS II report in 2013 that address the review questions (Appendix Table A-1).

2.3. Selection of Studies

We used the AI Classifier Manager as a semi-automated screening tool to conduct this review efficiently at the title and abstract screening stage. The title and abstract of each citation were screened by a team member based on predefined eligibility criteria (Table 1), and then the AI Classifier Manager served as a second reviewer of each citation. The AI Classifier Manager generated a ranking score for each citation, based upon a training set of titles and abstracts screened first by team members. The threshold for the AI Classifier Manager to include citations was set at a ranking score of 0.5 or above (scale 0 to 1.0). The full text of each remaining potentially eligible article was reviewed by two team members to confirm eligibility. The data from eligible articles were extracted by a single team member who prepared a summary of the study, including author, year, study design, number of study participants, and main findings relevant to each of the review questions.

2.4. Risk of Bias (Quality) Assessment

For studies that addressed Review Question 5 about the effectiveness of PSPs, we used the Cochrane Collaboration’s tool for assessing the risk of bias of randomized controlled trials (RCTs) or the ROBINS-I tool for assessing the Risk Of Bias In Non-randomized Studies – of Interventions.2023

For RCTs, we used the items in the Cochrane Collaboration’s tool that cover the domains of selection bias, performance bias, detection bias, attrition bias, reporting bias, and other bias.20,22 For nonrandomized studies, we used specific items in the ROBINS-I tool that assess bias due to confounding, bias in selection of participants into the study, bias in classification of interventions, bias due to deviations from intended interventions, bias due to missing data, bias in measurement of outcomes, and bias in selection of the reported results.21,23 The risk of bias assessments focused on the main outcome of interest in each study.

For recent eligible systematic reviews, the primary reviewer used the criteria developed by the United States Preventive Services Task Force Methods Workgroup for assessing the quality of systematic reviews.24

  • Good – Recent relevant review with comprehensive sources and search strategies; explicit and relevant selection criteria; standard appraisal of included studies; and valid conclusions.
  • Fair – Recent relevant review that is not clearly biased but lacks comprehensive sources and search strategies.
  • Poor – Outdated, irrelevant, or biased review without systematic search for studies, explicit selection criteria, or standard appraisal of studies.

3. Evidence Base

3.1. Number of Studies

Our search retrieved 3,319 unique titles and abstracts from which we reviewed 400 full-text articles for eligibility. We found 12 systematic reviews and 20 primary studies (reported in 21 articles) that met the inclusion criteria (Figure 1).

Figure 1 shows the flow diagram of the literature search and screening process. 3,319 records were identified for screening, after which 2,919 were excluded. 400 were included for full-text review, with 33 considered eligible for inclusion.

Figure 1

Results of the search and screening. *Total exceeds the number of citations in the exclusion box because citations could be excluded for more than one reason (i.e., both reviewers did not need to agree on reason for exclusion).

Figure 2 shows a bar graph of the number of included primary studies published between the years of 2013 and 2023 by study design. Two cross-sectional studies with comparisons were included, one published in 2013 and one in 2016. Fourteen observational studies with comparison groups were included, with two studies published in 2016, three studies published in 2022, three studies in 2023, and one study published in each year: 2013, 2014, 2015, 2017, 2018, and 2020. Five randomized controlled trials were included with individual publication years of 2013, 2016, 2019, 2020, and 2021.

Figure 2

Number of included primary studies by year of publication and design. RCT = randomized controlled trial

3.2. Findings for Review Questions

3.2.1. Question 1. What Are the Frequency and Severity of Harms Associated With Fatigue and Sleepiness of Clinicians Due to Hours of Service?

The exact prevalence of fatigue and sleepiness of clinicians due to long hours of service and the effects on patient safety and patient outcomes is challenging to estimate. However, the Centers for Disease Control and Prevention (CDC) found that 36 percent of healthcare clinicians and technical workers reported short sleep durations in 2018, a 15 percent increase since 2010.5 Further, meta-analysis of studies evaluating sleep disturbances during the coronavirus disease of 2019 (COVID-19) pandemic estimated that 34.8 percent of nurses and 41.6 percent of physicians experienced sleep disturbances.25 Safety is a distal outcome for occupational fatigue, which is influenced by many factors including the hours worked, workload, and sleep amount and quality.26 Long work hours are common among healthcare industry workers, as is poor quality sleep.25 While work demands vary by clinical specialty and setting, between 2001 and 2021, average physician work hours per week decreased by 7.6 percent, from 52.6 to 48.6 hours per week, with rapid growth in total hours contributed to the workforce by advanced practice professionals.27 An estimated 17 percent of healthcare workers work 48 hours or more per week, and 6 percent work 60 or more hours per week,28 with over 100,000 resident physicians working 80 hours per week including shifts of 24 hours or longer in duration.29 Work-hour duration and shift structure can increase worker fatigue, which may decrease cognitive and psycho-motor performance, and increase the likelihood of adverse events and preventable patient harm including medication errors,30 and errors in clinical performance of physicians31 and nurses.32 The diversity of outcomes and studies prohibits a precise estimate of the magnitude of harm attributable to healthcare worker fatigue.

3.2.2. Question 2. What Patient Safety Measures or Indicators Have Been Used To Examine the Harm Associated With Fatigue and Sleepiness of Clinicians?

Patient safety outcomes reported in studies included in this review varied widely. The included systematic reviews focused on medication safety, surgical outcomes, patient injuries, errors made or detected by others, mortality, morbidity, readmission, infection, and length of stay. Primary studies included mortality, clinical complications, 30-day readmissions, self-reported and observed medical errors and adverse events, and medication errors.

3.2.3. Question 3. What Patient Safety Practices (PSPs) Have Been Used To Prevent or Mitigate the Harms Associated With Fatigue and Sleepiness of Clinicians due to Hours of Service and in What Settings Have They Been Used?

PSPs to mitigate the harms associated with fatigue and sleepiness of clinicians focus primarily on the total amount of hours worked or the structure of shifts. Primary studies included in this rapid response were conducted across emergency department, surgical ward, medical ward, and hospital-wide settings. Studies investigated aspects of the quantity and quality of sleep prior to a work shift on safety, the impact of completing an overnight call shift and amount of sleep during a call shift on safety the subsequent day, the total hours worked per shift or per week, and changes in duty hour regulations, including: (1) the 2011 policy limiting work to no more than 80 hours per week and no more than 30 hours worked per individual shift; (2) the 2011 policy restricting shifts to less than 16 hours during the first year of residents and 24 hours afterwards, requiring at least one day off per week, requiring at least 8 hours between duty periods, and requiring 14 hours free after 24-hour shifts; and (3) the 2017 policy, which eased restrictions on the maximum shift duration for first-year residents from 16 to 24 hours.

3.2.4. Question 4. What Is the Rationale for the PSPs Used To Prevent or Mitigate the Harms Associated With Fatigue and Sleepiness of Clinicians due to Hours of Service?

Interventions targeting maximum hours worked or maximum shift duration seek to minimize cognitive and physical performance decrements observed after long durations of focus at work.7,9 Interventions modifying shift schedules in terms of timing seek to maximize recovery between shifts or minimize circadian rhythm disruption.33 The three risk management interventions discussed in included reviews sought to reduce fatigue with lighting conditions designed to promote alertness, or with break or napping interventions designed to provide rest within a shift to decrease fatigue.

3.2.5. Question 5. What Studies Have Assessed the Effectiveness and Unintended Effects of the PSPs and What New Evidence Has Been Published Since the Search Was Done for the MHS II Report in 2013?

A total of 12 systematic reviews met the criteria for inclusion. Of those 12 reviews, 11 reported the effects of work shift modifications or interventions on specific patient safety outcomes (incidence of medical errors or adverse events)3444 and 6 reported the effects on other clinical outcomes.38,4042,44,45 Article types in reviews included, but were not limited to, randomized control trials (RCTs), non-randomized controlled trials, survey studies, observational studies, and meta-analyses. The clinician population in these SRs consisted of nurses, military and nonmilitary surgical teams, physicians, and residents. Of the 12 reviews, 5 reported findings for risk management practices and all 12 reviews investigated some type of work schedule modification. Reviews reported on outcomes including clinical and patient safety outcomes such as mortality, readmission, complications, or adverse events. Acute care settings included surgery, radiology, pediatrics, intensive care unit (ICU), and neonatal ICU, among others.

We also identified 20 primary studies in 21 articles. Eight of these studies (reported in 9 articles) prospectively assessed the impact of shift structure modifications on outcomes of interest, and a further 12 were cross-sectional studies evaluating differences in total hours or shift structure on outcomes of interest.

An overview of the included systematic reviews and primary studies is presented in Tables 2a and 2b.

Table Icon

Table 2a

Overview of the systematic reviews.

Table Icon

Table 2b

Overview of the included primary studies.

3.2.5.1. Clinical Outcomes (Mortality, Complications, and Readmissions)

Evidence for the association between work schedule modifications and clinical outcomes is mixed. One review found that limiting all resident physicians to 80-hour work weeks and 28-hour shifts was associated with an 11 percent reduction in mortality (p< 0.001).44 Similarly, another review focusing on nurses found evidence that working more than 40 hours a week had an adverse effect on patient outcomes (medication error odds ratio [OR] 1.28 [95% CI: 1.10 to 1.49]; infection OR 1.14 [95% CI: 1.02 to 1.28]), as did increased overtime (urinary tract infection OR 2.53 [95% CI: 1.66 to 3.86]; decubitus ulcer OR 1.91 [95% CI: 1.17 to 3.11]), or having insufficient time away between shifts (pneumonia mortality OR 1.24 [95% CI: 1.03 to 1.50]; abdominal aortic aneurysm mortality OR 1.39 [95% CI: 1.11 to 1.73]).42 Supporting this, a meta-analysis revealed a significant weak association between extended duration shifts and increased patient mortality (OR 1.52 [95% CI: 0.75 to 3.07]).38 Mixed results have been found between overtime and adverse patient outcomes,42 as well as reduced resident duty-hours and patient outcomes (e.g., mortality, morbidity, adverse events).45 Finally, several systematic reviews failed to find any association between shift modifications and patient outcomes. One review found no difference between sleep deprived versus non-sleep deprived surgeons, due to overnight work or extended shifts, in patient mortality or postoperative complications, and findings on intraoperative complications and length of stay were mixed.40 In another, no significant association was identified between reduced shift length and length of stay.43 Additionally, another systematic review found no differences in length of stay, readmission rates, mortality, or codes associated with night floats.41

Eight primary studies (three trials, and five observational studies) reported mortality, complications or readmissions outcomes, including three RCTs. One RCT randomized medical residents to one of three teams, one compliant with the 2003 Accreditation Council for Graduate Medical Education (AGCME) duty hour regulations, and one of two different models compliant with the 2011 requirements, one with an overnight call shift every fifth day (Q5) and one with a night float schedule.59 There were no differences in 30-day readmission rates between shift conditions.59 The cluster-randomized non-inferiority iCOMPARE (Individualized Comparative Effectiveness of Models Optimizing Patient Safety and Resident Education) trial, including 63 internal medicine residency programs, found no differences in patient mortality between standard and flexible scheduling. Flexible scheduling did not impose maximum shift durations or minimum time off between shifts.67

Additionally, the Flexibility In Duty Hour Requirements for Surgical Trainees (FIRST) trial, a large cluster randomized trial including 117 general surgery residency programs found that ‘flexible’ work hour systems were noninferior to the standard work hour systems compliant with ACGME policies in patient mortality or postoperative complications.66 The flexible work hours intervention was required to maintain compliance with limitations of 80 total hours per week, 1 day off in 7, and on-call duty no more than every third night, but were not restricted on maximum shift length or minimum time off between shifts.

Five observational studies assessed the impact of work hours on patient outcomes. One study reported data from an intervention site in the FIRST trial described above, and, consistent with the overall study findings, found no differences in patient mortality for residents at their institution working under the flexible scheduling systems when compared to a representative national sample.65 Another study found that patients in a general medicine service who were cared for by residents working more than 80 hours per week had increased length of stay and risk of ICU transfer, but not increased rates of mortality or 30-day readmission.55

Using data from the American College of Surgeons National Quality Improvement Program, one study used a difference in difference approach to compare changes in a composite of death or serious morbidity, and secondary outcomes of postoperative complications and resident examination performance in the two years prior and following the 2011 ACGME duty hour restrictions.61 Across 23 teaching hospitals and 31 nonteaching hospitals, the duty hour reform was not associated with differences in general surgery patient outcomes.

One retrospective study of adult medical patients compared a handoff group (i.e., patients discharged within 7 days after a change in resident physician team) and a control group (i.e., patients discharged the third week of a four-week resident rotation) both before and after the ACGME 2011 duty hour regulation was implemented.60 Prior to the 2011 policy, mortality in the handoff group was significantly higher than in the control group; however, after the 2011 policy implementation, this difference lost significance.

Another study evaluated the impact of the 2017 ACGME policy relaxing extended shift restrictions on patient, intern, and resident perceptions as well as clinical outcomes (i.e., ICU transfers, length of stay, readmissions, mortality and complications).37 There were no differences in patient satisfaction or clinical outcomes, however, interns reported being less satisfied and more fatigued and residents reported more incorrect intern orders in the extended work hours system.

One study found no difference in mortality for patients undergoing percutaneous coronary interventions performed by sleep deprived operators (defined as operators performing a case between 7 am and 11:59 pm as well as a case the preceding night, between 12 am and 6:59 am).48

3.2.5.2. Specific Patient Safety Measures (Incidence of Medical Errors or Adverse Events)

Evidence connecting work shift modifications (e.g., limiting total hours, changes to on-call schedule, limiting consecutive nights worked) and patient safety (e.g., medical errors, near-misses) is mixed. Several systematic reviews found evidence that increased medical errors are associated with night shifts,34, 40 and extended work shifts.36,37 Specifically, medical errors were found to occur 12.1% more frequently during night or rotating shifts,34 and risk of self-reported errors related to fatigue increased with more nights of work-related sleep disturbance (relative risk (RR) 1.25 [95% CI: 1.06 to 1.49]).40 However, another systematic review found contradictory results, with one included primary study actually showing decreased diagnostic errors during night float.41 Additionally, a meta-analysis found that extended-duration shifts were weakly associated with serious medical errors (OR 1.65 [95% CI: 1.06 to 2.58]).38

Limited shift durations and shorter work weeks were also found to be associated with improved patient safety in RCTs and observational studies.44 However, other reviews found that duty hour restrictions had no association with serious medical errors43 or on patient care.41 Another review found mixed findings between overnight work and extended shifts with medical errors.40 Furthermore, a review on extended-duty shifts suggested that they may cause both cognitive (e.g., attention lapses, visual tracking errors, worsened recall) and physical (e.g., decreased motor skills, increased time to react to changes) errors by clinicians.39 Another review examining the impact of surgical team sleep deprivation on cognitive performance found that sleep deprivation after 24 hour on-call periods is associated with an increase in errors and omissions.35

We identified 12 primary studies that evaluated work schedules and patient safety outcomes, including two RCTs reported in three articles. In the RCT of residents described above,59 nurse and resident perceptions of care quality were lower in the Q5 and night float conditions, to such an extent that the study was terminated early due to safety concerns. In a pediatric ICU setting, Landrigan63 found that a shift structure intervention (eliminating extended shifts and cycling resident physicians through day and night shifts of 16 hours or less) was associated with significantly more serious medical errors made by physicians (RR 1.53) and unit-wide medical errors made (RR 1.56) than the control condition (night shifts followed by approximately 24 hours off duty, and then two or three consecutive day shifts). This finding was contrary to expectations. However, there was wide variability in the effect across the six study sites, and a secondary analysis controlling for patient loads per resident found no difference in safety outcomes across shift conditions. Resident sleepiness and attentional failures for this study were reported in a second article64, which showed the control extended-duration work roster was associated with a significantly higher number of attentional failures (6.8 failures per 10 minute neurobehavioral assessment compared to 2.9 in the rapid cycling roster), reaction time (18% higher in extended-duration roster), and subjective sleepiness (9% higher in extended-duration roster) than the rapidly cycling work roster.

Three studies of resident physicians evaluated shift structure on patient safety outcomes. One study62 evaluated the impact of the 2011 ACGME policy change with a large national survey of resident physicians’ perceptions of safety. They found this policy, which was rescinded in 2017, was associated with a 32% reduction in resident reported medical errors, 34% reduction in resident-reported preventable adverse events, and a 63% reduction in resident reported medical errors resulting in patient death. All differences were statistically significant.

Using the Agency for Healthcare Research Quality (AHRQ) National Inpatient Sample, one observational study58 evaluated the impact of the 2003 ACGME duty hour restriction policy limiting residents to no more than 80-hour work weeks on hospital-acquired conditions. They found that patients in the two years following the year of the policy change were 10% more likely to experience a hospital-acquired condition than in the two years prior to the policy implementation. This effect was predominantly in teaching hospitals.

A large prospective cross-sectional survey of 4,826 post-graduate year 2 or greater resident physicians found that, when compared to working 40 hours a week or less, working greater than 48 hours per week was significantly associated with increased risk for self-reported medical errors, and preventable adverse events and fatal preventable adverse events (ORs 1.61, 1.54, and 0.66). In addition, working between 60 and 70 hours a week more than doubled the risk of preventable adverse events (OR 2.93), and fatal preventable adverse events (OR 2.75), compared to working 48 hours or less. Working one or more extended shifts a month while averaging no more than 80 hours per week was associated with increased risk of these outcomes as well when compared to working 48 hours or less in a week (OR for medical errors of 4.01, preventable adverse events 3.84, and fatal preventable adverse events 3.67).56

Three observational studies evaluated work hours for nurses and patient safety outcomes. One large cross-sectional survey of 3,710 pediatric nurses across 342 acute care hospitals53 found that nurses working shifts greater than 13 hours reported significantly worse job outcomes (i.e., burnout, job satisfaction), and lower safety and quality of care for patients (i.e., nurse reported central line blood stream infections, urinary tract infections, patient complaints) than nurses who reported working shifts of 8 hours or less.

A retrospective study of 5,372 nurses triggering 420,706 near-miss medication alerts over the course of two years found that nurses working greater than 60 hours per week were more likely to trigger a near miss alert (4% weekly near-miss alert rate) compared to nurses working less than 60 hours (3% weekly near miss alert).54

Another study evaluated the impact of mandatory nursing overtime protection regulations and hours worked on adverse patient events, surveying nurses from a state which had protections in place (West Virginia) and one that did not (North Carolina).52 Findings were mixed for the effect of mandatory overtime protection regulations, but when compared to nurses working 40 hours per week or less, nurses working more than 40 hours per week had increased risk of reporting involvement in adverse events (OR 14.36).52

Four studies evaluated clinician sleep and safety outcomes. One prospective observational study of 30 emergency department nurses found that lower quality of sleep measured through actigraphy immediately before a 12-hour shift was associated with more minor self-reported errors during the shift.47 The amount of sleep was not associated with errors.

One observational study evaluated differences between surgeons who were sleep deprived (defined as more than 2 hours of nighttime clinical duties the night prior to a procedure) and those who were not; no differences in errors between groups were found, though errors were uncommon in both groups.50

Another observational study surveyed practicing neurointerventionalists and found that less than four hours of sleep was significantly related to more self-reported medical errors (OR 2.60).49

A survey of 1,215 first year residents found that sleep durations less than six hours and work hours exceeding 70 hours per week were both associated with increased likelihood of self-reported medical errors.51 There was a significantly higher RR of self-reported medical errors for interns reporting short sleep duration (< 6 hours) at 3 months (1.3, p = 0.03) but a nonsignificant difference at 6 months. There was a significantly higher RR of self-reported medical errors for interns working 70 hours per week or more at both 3 and 6 months (RR 1.5, p < 0.01 and RR 1.4, p = 0.01, respectively).

3.2.5.3. Risk Management Practices

Less than half of the included systematic reviews investigated risk management practices. Results on the impact of risk management practices on patient safety and outcomes are mixed. One review focusing on the ergonomic design of workstations found that increasing ambient lighting was associated with decreased detection and identification errors for radiologists.37 Another found no direct effect between breaks and patient safety, but found that increased breaks are associated with less missed care (e.g., hand washing, turning a patient). This could be meaningful as they also found that missed care had a significant negative effect on patient safety (i.e., falls with injury and medication error).42 However, another review found that protected time for brief sleep breaks (i.e., approximately 2 to 4 hours in duration) had no impact on patient care in a Veterans Affairs center or hospital settings.41

We identified no primary studies evaluating the impact of a fatigue risk management practice on outcomes of interest.

3.2.6. Question 6. What Are Common Barriers and Facilitators to Implementing the PSPs?

Three primary studies, but no systematic reviews, included information about barriers or facilitators. The RCT of work schedules for residents reported faculty barriers to implementing work schedules such as less time for teaching, increased burden to perform clinical duties, and the pressure to “get the resident out on time.”59 A qualitative interview study of nurses found a wide range of barriers that aggravated fatigue including barriers at work (i.e., workload, shift structures [i.e., multiple shifts in a row, night shifts, 12-hour shifts, rotating shifts, and staying late], slowing down across a shift, and eating during a shift), and at home (i.e., not getting enough sleep, and competing demands).68

Two studies mentioned training programs for effective handoffs60,61 and hiring midlevel support staff61 as facilitators to safe continuity of care with implementation of shorter shift lengths.

3.2.7. Question 7. What Resources (e.g., cost, staff, time) Are Required for Implementation?

No primary studies or systematic reviews included information about resources required to support implementation. A recent scoping review of the economic benefits and costs associated with nonstandard work hours (i.e., shiftwork and long shift durations) across industries found that cost analysis of these issues is generally absent from the literature and an important research need.69

3.2.8. Question 8. What Toolkits Are Available To Support Implementation of the PSPs?

No systematic reviews included information about toolkits to support implementation of PSPs targeting risks of clinician fatigue and sleepiness due to work hours. Several online resources for learning more about work and fatigue and potential interventions were identified.

  • The National Institute of Occupational Safety and Health (NIOSH) maintains a web resource on work and fatigue outlining their research and learning resources.70
  • The Canadian Fatigue Risk Management Taskforce maintains a comprehensive toolkit of strategies for healthcare workers.71

4. Discussion

4.1. Interpretation of Findings

This rapid response identified 12 systematic reviews and 20 primary studies (reported in 21 articles) evaluating a patient safety practice (PSP) targeting patient harms associated with clinician fatigue and sleepiness due to long work hours. Consistent with the previous Making Healthcare Safer (MHS) II brief review on this topic, research on PSPs related to reducing the risks associated with clinician fatigue and sleepiness due to work hours continues to focus primarily on shift scheduling in physician trainee populations. All identified randomized controlled trials (RCTs) involved evaluating the impact of shift schedules compliant with different versions of the Accreditation Council for Graduate Medical Education (ACGME) duty hour regulations, and 7 of the observational studies also evaluated the impact of these policy changes. Studies involving practicing nurses or physicians were all observational.

Also consistent with MHS II, the evidence surrounding PSPs for mitigating the risks of fatigue and sleepiness due to duty hours remains mixed. The three RCTs on resident duty hour limitations included in this review generated conflicting findings. While the RCT for internal medicine residents found no difference in 30-day patient readmissions, self-reported patient safety was sufficiently lower in the two duty hour restricted conditions that they were terminated early (i.e., the study was halted due to safety concerns).59

Two large cluster-randomized trials, one in internal medicine and one in general surgery residency programs, found a flexible scheduling system (which did not impose maximum shift durations or time off between shifts) to be non-inferior to scheduling systems compliant with the ACGME 2011 regulations.72 However, a trial in general surgery programs has been criticized on both ethical and methodological grounds.73 Specifically, one interpretation of the meaning of the non-inferiority findings is that the ACGME should loosen regulations and give programs more discretion in flexibility, while others take the noninferiority to be evidence that the suspected risks of reduced continuity of care from reduced shift lengths is not meaningful.73

Findings from the RCT in pediatric residents63,64 first found that duty hour restricted scheduling systems had worse safety outcomes. However, follow-on analyses clearly demonstrated that the effects of fatigue on patient safety were not solely due to the amount of hours worked but to the intensity of workload experienced during those work hours.

Given the heterogeneity of findings, the ACGME duty hour policies remain contentious. Two prominent criticisms of the duty hour restrictions have been that they reduce educational opportunities for trainee physicians, and that they reduce continuity of care by increasing the number of patient handoffs as shorter shifts require more handoffs between clinicians.10 One included study showed decreased educational opportunities in duty hour restricted systems.59 However, research has directly examined differences for physicians who trained under duty hour restricted systems and those who did not. No differences in patient complications74 or mortality75 were found for surgeons, though patients with surgeons who trained under duty hour restrictions did have longer length of stay, anesthesia time and increased cost.75 No differences in mortality, readmissions, length of stay or cost was found for internists who trained under duty hour restrictions and those who did not.7577,45 One included primary study evaluated handoffs during resident team rotations prior to and after implementation of work hour restrictions and found that resident team transitions elevated risk of patient mortality, but this risk was significantly lower after the restrictions were in place.60

The literature remains sparse on fatigue risk management practices beyond modifying work schedules. No primary studies were identified, and only three interventions (i.e., lighting, breaks, and naps) were mentioned in systematic reviews, each with a focus in only one study. Lighting and breaks showed beneficial effects, but brief protected time for sleep was not related to patient care outcomes. Given the complexity of shift scheduling, the mixed findings to date, and the paucity of research linking risk mitigation PSPs to safety outcomes, more research is needed in this area.

4.2. Limitations

We discuss limitations of the rapid response methods employed here as well as the literature on PSPs targeting clinician fatigue and sleepiness. First, rapid responses use streamlined processes to complete the effort in a short timeline. We only included primary studies and systematic reviews published between January 2013 and September 2023 that reported data on the impact of an intervention or strategy related to work hours on patient outcomes. Additionally, this rapid response report only focuses on acute care settings and studies based in the United States, which limits the generalizability to other settings and countries.

Findings from this rapid response revealed that there are several limitations to the literature on this topic, including a lack of evaluation of the impact of risk management practices on patient outcomes, inconsistent terminology, heterogeneity in both interventions and outcomes across studies, as well as the reliance on observational research making it difficult to draw strong conclusions from the literature. Information regarding the facilitators and barriers for the interventions and strategies identified is limited. Additionally, no primary study or review provided resources or toolkits for implementing these interventions.

This rapid response did not cover healthcare worker outcomes such as burnout or wellness or organizational outcomes like employee retention. This is important given overall concerns about the wellness of the healthcare workforce. Recent research from the World Health Organization and the International Labor Organization identified an increased risk of ischemic heart disease and stroke associated with working more than 55 hours a week.78,79

4.3. Implications and Conclusions

The inconsistent findings from this body of research make it difficult to determine the most appropriate evidence-based policies for mitigating the risk of patient harm from clinician fatigue and sleepiness due to long work hours. Research remains inconsistent on the ability of PSPs to mitigate the risks of patient harm from clinician fatigue and sleepiness due to long work hours. Most studies focused on the resident physician population and work hour interventions. Higher quality studies are needed, particularly for practicing clinicians. Increased healthcare consolidation and shifts in employment models (i.e., more hospital employed physicians) may enable larger prospective studies of scheduling and fatigue risk mitigation strategies. Additionally, research is needed to develop fatigue risk management interventions beyond work hour restrictions or changes in shift structure. A recent Delphi study prioritized research needs for reducing risks of fatigue due to long work hours in the healthcare setting and identified developing better designs for work schedules and improving culture and leadership approaches to shift work and long work hours as the highest priority.80

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Kelz RR, Niknam BA, Sellers MM, et al. Duty Hour Reform and the Outcomes of Patients Treated by New Surgeons. Ann Surg. 2020 Apr;271(4):599–605. doi: 10.1097/sla.0000000000003304. PMID: 31724974. [PMC free article: PMC6861619] [PubMed: 31724974] [CrossRef]
76.
Jena AB, Farid M, Blumenthal D, et al. Association of residency work hour reform with long term quality and costs of care of US physicians: observational study. Bmj. 2019 Jul 10;366:l4134. doi: 10.1136/bmj.l4134. PMID: 31292124. [PMC free article: PMC6619440] [PubMed: 31292124] [CrossRef]
77.
Jena AB, Schoemaker L, Bhattacharya J. Exposing physicians to reduced residency work hours did not adversely affect patient outcomes after residency. Health Aff (Millwood). 2014 Oct;33(10):1832–40. doi: 10.1377/hlthaff.2014.0318. PMID: 25288430. [PMC free article: PMC4269477] [PubMed: 25288430] [CrossRef]
78.
Pega F, Náfrádi B, Momen NC, et al. Global, regional, and national burdens of ischemic heart disease and stroke attributable to exposure to long working hours for 194 countries, 2000-2016: A systematic analysis from the WHO/ILO Joint Estimates of the Work-related Burden of Disease and Injury. Environ Int. 2021 Sep;154:106595. doi: 10.1016/j.envint.2021.106595. PMID: 34011457. [PMC free article: PMC8204267] [PubMed: 34011457] [CrossRef]
79.
Descatha A, Sembajwe G, Pega F, et al. The effect of exposure to long working hours on stroke: A systematic review and meta-analysis from the WHO/ILO Joint Estimates of the Work-related Burden of Disease and Injury. Environ Int. 2020 Sep;142:105746. doi: 10.1016/j.envint.2020.105746. PMID: 32505015. [PubMed: 32505015] [CrossRef]
80.
Caruso CC, Arbour MW, Berger AM, et al. Research priorities to reduce risks from work hours and fatigue in the healthcare and social assistance sector. Am J Ind Med. 2022 Nov;65(11):867–77. doi: 10.1002/ajim.23363. PMID: 35596665. [PMC free article: PMC10165664] [PubMed: 35596665] [CrossRef]

Afterword

Recognized for excellence in conducting comprehensive systematic reviews, the Agency for Healthcare Research and Quality (AHRQ) Evidence-based Practice Center (EPC) Program is developing a range of rapid evidence products to assist end-users in making specific decisions in a limited timeframe. AHRQ recognizes that people are struggling with urgent questions on how to make healthcare safer. AHRQ is using this rapid format for the fourth edition of its Making Healthcare Safer series of reports, produced by the EPC Program and the General Patient Safety Program. To shorten timelines, reviewers make strategic choices about which processes to abridge. However, the adaptations made for expediency may limit the certainty and generalizability of the findings from the review, particularly in areas with a large literature base. Transparent reporting of the methods used and the resulting limitations of the evidence synthesis are extremely important.

AHRQ expects that these rapid evidence products will be helpful to health plans, providers, purchasers, government programs, and the healthcare system as a whole. Transparency and stakeholder input are essential to AHRQ. If you have comments related to this report, they may be sent by mail to the Task Order Officer named below at: Agency for Healthcare Research and Quality, 5600 Fishers Lane, Rockville, MD 20857, or by email to vog.shh.qrha@SHM.

  • Robert Otto Valdez, Ph.D., M.H.S.A.
    Director
    Agency for Healthcare Research and Quality
  • Therese Miller, D.P.H.
    Director
    Center for Evidence and Practice Improvement
    Agency for Healthcare Research and Quality
  • Christine Chang, M.D., M.P.H.
    Director
    Evidence-based Practice Center Division
    Center for Evidence and Practice Improvement
    Agency for Healthcare Research and Quality
  • David W. Niebuhr, M.D., M.P.H., M.Sc.
    Evidence-based Practice Center Division Liaison
    Center for Evidence and Practice Improvement
    Agency for Healthcare Research and Quality
  • Craig A. Umscheid, M.D., M.S.
    Director
    Center for Quality Improvement and Patient Safety
    Agency for Healthcare Research and Quality
  • Margie Shofer, B.S.N., M.B.A.
    Director, General Patient Safety Program
    Center for Quality Improvement and Patient Safety
    Agency for Healthcare Research and Quality
  • Jennifer Eskandari
    Task Order Officer
    Center for Quality Improvement and Patient Safety
    Agency for Healthcare Research and Quality
  • Farzana Samad, Pharm.D., FISMP, CPPS
    Health Scientist Administrator
    Center for Quality Improvement and Patient Safety
    Agency for Healthcare Research and Quality

Appendixes

Appendix A. Methods

Search Strategies for Published Literature

Table A-1PubMed search strategy

#ConceptSearch Terms
1Population“Medical Staff, Hospital”[mh] OR “Physicians”[mh] OR “hospital medical staff” [tiab] OR physician[tiab] OR physicians[tiab] OR clinician[tiab] OR clinicians[tiab] OR “health care providers”[tiab] OR “healthcare providers”[tiab]OR “health professional”[tiab] OR “health professionals”[tiab] OR “health provider”[tiab] OR “health providers”[tiab] OR “healthcare professional”[tiab] OR “health care professional”[tiab] OR hospitalist[tiab] OR hospitalists[tiab] OR “house staff”[tiab] OR “house staffs”[tiab] OR doctor [tiab] OR doctors [tiab] OR “healthcare workers”[tiab] OR “healthcare staff” [tiab] OR nurse [tiab] OR nurses [tiab] OR surgeons[tiab]
2Fatigue and sleep“duty hour”[tiab] OR “duty hours”[tiab] OR “Work Schedule Tolerance”[mh] OR “Shift Work Schedule” [mh] OR “work hours”[tiab] OR “working hours”[tiab] OR “shift work”[tiab] OR “work shift” [tiab] OR “work shifts” [tiab] OR “shift patterns”[tiab] OR “shift duration”[tiab] OR “service hour”[tiab] OR “service hours”[tiab] OR “shift rotation” [tiab] OR “shift rotations”[tiab] OR “Fatigue management” [tiab] OR “Fatigue risk” [tiab] OR “fatigue monitoring”[tiab] OR “fatigue reporting”[tiab] OR “Sleep hygiene” [tiab] OR napping [tiab] OR “workplace lighting”[tiab] OR “fatigue interventions” [tiab] OR “fatigue intervention” [tiab] OR “Sleep depriv*”[tiab] OR “Sleep Deprivation” [mh] OR “sleep patterns” [tiab] OR sleep [mh] OR “sleep management”[tiab] OR “fatigue self-management” [tiab] OR “Managing Fatigue” [tiab] OR stimulant [tiab] OR stimulants [tiab] OR caffeine [tiab] OR caffeine [mh] OR “pharmacologic interventions” [tiab]
3Patient safety and harm“patient safety”[mh] OR “patient safety” [tiab] OR “Patient Harm”[mh] OR “Patient Harm*”[tiab] OR “patient risk*”[tiab] OR “quality of care” [tiab] OR “adverse event*”[tiab] OR “undesired event*”[tiab] OR “medical errors”[mh] OR “medical error*”[tiab] OR “Diagnostic Errors” [mh] OR “diagnostic error*”[tiab] OR “diagnostic mistake*”[tiab] OR “health care error*”[tiab] OR “healthcare error*”[tiab] OR “medical fault*”[tiab] OR “medical mistake*”[tiab] OR “erroneous diagnos*”[tiab] OR “failure to diagnose”[tiab] OR “false diagnos*”[tiab] OR “faulty diagnos*”[tiab] OR misdiagnos*[tiab] OR “mistaken diagnos*”[tiab] OR “wrong diagnos*”[tiab] OR “well being”[tiab] OR wellbeing[tiab] OR wellness[tiab] OR satisfaction [tiab] OR complication [tiab] OR complications [tiab] OR mortality [tiab] OR coping [tiab] OR distress[tiab] OR distressed[tiab] OR distresses[tiab] OR distressing[tiab] OR injury [tiab] OR injuries [tiab] OR “work life balance”[tiab] OR “Work Health and Safety” [tiab] OR accident [tiab] OR accident [mh] OR exhaustion[tiab] OR “safety management” [tiab] OR “safety management” [mh] OR “burned out”[tiab] OR “burn out”[tiab] OR “burn outs”[tiab] OR burnout[tiab] OR burnouts[tiab] OR “burnt out”[tiab] OR “adverse effects” [tiab] OR exhausted[tiab] OR exhaustion[tiab] OR exhausting[tiab] OR exhausts[tiab]
41 AND 2 AND 3
5Pubmed filterPublication date 2013 – September 18th, 2023]
6Exclude(“Animals”[Mesh] NOT “Humans”[Mesh]) OR address[pt] OR “autobiography”[pt] OR “bibliography”[pt] OR “biography”[pt] OR congress[pt] OR “dictionary”[pt] OR “directory”[pt] OR “festschrift”[pt] OR “historical article”[pt] OR lecture[pt] OR “legal case”[pt] OR “legislation”[pt] OR “periodical index”[pt] OR Comment[pt] OR Letter[pt] OR Editorial[pt] OR “news”[pt] OR “newspaper article”[pt] OR “patient education handout”[pt] OR “periodical index”[pt] OR “study guide”[pt] OR “Study protocol” [ti] OR “trial protocol” [ti] OR “review protocol” [ti] OR editorial[pt] OR letter[pt] OR “case reports”[pt]OR rats[tw] OR cow[tw] OR cows[tw] OR chicken[tw] OR chickens[tw] OR horse[tw] OR horses[tw] OR mice[tw] OR mouse[tw] OR bovine[tw] OR sheep[tw] OR ovine [tw] OR murine[tw] OR “environmental scan”[ti]

Table A-2Cochrane search strategy

#ConceptSearch Terms
1Population“Medical Staff, Hospital”[mh] OR “Physicians”[mh] OR (“hospital medical staff” OR physician OR physicians OR clinician OR clinicians OR “health care providers” OR “healthcare providers” OR “health professional” OR “health professionals” OR “health provider” OR “health providers” OR “healthcare professional” OR “health care professional” OR hospitalist OR hospitalists OR “house staff” OR “house staffs” OR doctor OR doctors OR “healthcare workers” OR “healthcare staff” OR nurse OR nurses OR surgeons):ti OR (“hospital medical staff” OR physician OR physicians OR clinician OR clinicians OR “health care providers” OR “healthcare providers” OR “health professional” OR “health professionals” OR “health provider” OR “health providers” OR “healthcare professional” OR “health care professional” OR hospitalist OR hospitalists OR “house staff” OR “house staffs” OR doctor OR doctors OR “healthcare workers” OR “healthcare staff” OR nurse OR nurses OR surgeons):ab
2Fatigue and sleep“Work Schedule Tolerance”[mh] OR “Shift Work Schedule”[mh] OR “Sleep Deprivation”[mh] OR sleep[mh] OR caffeine[mh] OR (“duty hour” OR “duty hours” OR “work hours” OR “working hours” OR “shift work” OR “work shift” OR “work shifts” OR “shift patterns” OR “shift duration” OR “service hour” OR “service hours” OR “shift rotation” OR “shift rotations” OR “Fatigue management” OR “Fatigue risk” OR “fatigue monitoring” OR “fatigue reporting” OR “Sleep hygiene” OR napping OR “workplace lighting” OR “fatigue interventions” OR “fatigue intervention” OR “sleep patterns” OR “sleep management” OR “fatigue self-management” OR “Managing Fatigue” OR stimulant OR stimulants OR caffeine OR “pharmacologic interventions” OR “sleep deprive” OR “sleep deprived”):ti OR (“duty hour” OR “duty hours” OR “work hours” OR “working hours” OR “shift work” OR “work shift” OR “work shifts” OR “shift patterns” OR “shift duration” OR “service hour” OR “service hours” OR “shift rotation” OR “shift rotations” OR “Fatigue management” OR “Fatigue risk” OR “fatigue monitoring” OR “fatigue reporting” OR “Sleep hygiene” OR napping OR “workplace lighting” OR “fatigue interventions” OR “fatigue intervention” OR “sleep patterns” OR “sleep management” OR “fatigue self-management” OR “Managing Fatigue” OR stimulant OR stimulants OR caffeine OR “pharmacologic interventions” OR “sleep deprive” OR “sleep deprived”):ab OR
3Patient safety and harm“patient safety”[mh] OR “Patient Harm”[mh] OR “medical errors”[mh] OR “Diagnostic Errors”[mh] OR accident[mh] OR “safety management”[mh] OR (“patient safety” OR “patient harm” OR “patient harms” OR “patient risk” OR “patient risks” OR “quality of care” OR “adverse event” OR “adverse events” OR “undesired event” OR “undesired events” OR “medical error” OR “medical errors” OR “diagnostic error” OR “diagnostic errors” OR “diagnostic mistake” OR “diagnostic mistakes” OR “health care error” OR “health care errors” OR “healthcare error” OR “healthcare errors” OR “medical fault” OR “medical faults” OR “medical mistake” OR “medical mistakes” OR “erroneous diagnose” OR “erroneous diagnoses” OR “failure to diagnose” OR “false diagnose” OR “false diagnoses” OR “faulty diagnose” OR “faulty diagnoses” OR misdiagnose OR misdiagnoses OR “mistaken diagnose” OR “mistaken diagnoses” OR “wrong diagnose” OR “wrong diagnoses” OR “well being” OR wellbeing OR wellness OR satisfaction OR complication OR complications OR mortality OR coping OR distress OR distressed OR distresses OR distressing OR injury OR injuries OR “work life balance” OR “work health and safety” OR accident OR exhaustion OR “safety management” OR “burned out” OR “burn out” OR “burn outs” OR burnout OR burnouts OR “burnt out” OR “adverse effects” OR exhausted OR exhaustion OR exhausting OR exhausts):ti OR (“patient safety” OR “patient harm” OR “patient harms” OR “patient risk” OR “patient risks” OR “quality of care” OR “adverse event” OR “adverse events” OR “undesired event” OR “undesired events” OR “medical error” OR “medical errors” OR “diagnostic error” OR “diagnostic errors” OR “diagnostic mistake” OR “diagnostic mistakes” OR “health care error” OR “health care errors” OR “healthcare error” OR “healthcare errors” OR “medical fault” OR “medical faults” OR “medical mistake” OR “medical mistakes” OR “erroneous diagnose” OR “erroneous diagnoses” OR “failure to diagnose” OR “false diagnose” OR “false diagnoses” OR “faulty diagnose” OR “faulty diagnoses” OR misdiagnose OR misdiagnoses OR “mistaken diagnose” OR “mistaken diagnoses” OR “wrong diagnose” OR “wrong diagnoses” OR “well being” OR wellbeing OR wellness OR satisfaction OR complication OR complications OR mortality OR coping OR distress OR distressed OR distresses OR distressing OR injury OR injuries OR “work life balance” OR “work health and safety” OR accident OR exhaustion OR “safety management” OR “burned out” OR “burn out” OR “burn outs” OR burnout OR burnouts OR “burnt out” OR “adverse effects” OR exhausted OR exhaustion OR exhausting OR exhausts):ab
4.1 AND 2 AND 3
5Cochrane filterPublication date 2013 – September 18, 2023
6Exclude(“Animals”[Mesh] NOT “Humans”[Mesh]) OR (address OR autobiography OR bibliography OR biography OR congress OR dictionary OR directory OR festschrift OR “historical article” OR lecture OR “legal case” OR legislation OR periodical index OR comment OR letter OR editorial OR news OR “newspaper article” OR “patient education handout” OR “periodical index” OR “study guide” OR editorial OR letter OR “case report”):pt OR (“study protocol” OR “environmental scan” OR “trial protocol” OR “review protocol”):ti OR (rats OR cow OR cows OR chicken OR chickens OR horse OR horses OR mice OR mouse OR bovine OR sheep OR ovine OR murine):kw OR

Appendix B. List of Excluded Studies Upon Full-Text Review

1.
Abera H, Hunt M, Levin JH. Sleep Deprivation, Burnout, and Acute Care Surgery. Curr Trauma Rep. 2023;9(2):40–6. doi: 10.1007/s40719-023-00253-9. PMID: 36721843. - Narrative or scoping review [PMC free article: PMC9880369] [PubMed: 36721843] [CrossRef]
2.
Actrn. Sleep health management for healthcare workers. http://www​.who.int/trialsearch/Trial2​.aspx?TrialID​=ACTRN12616000369426. 2016 PMID: CN-02440080. - No original data
3.
Alexander R, Waite S, Bruno MA, et al. Mandating Limits on Workload, Duty, and Speed in Radiology. Radiology. 2022 Aug;304(2):274–82. doi: 10.1148/radiol.212631. PMID: 35699581. - Narrative or scoping review [PMC free article: PMC9340237] [PubMed: 35699581] [CrossRef]
4.
Alfonsi V, Scarpelli S, Gorgoni M, et al. Healthcare Workers after Two Years of COVID-19: The Consequences of the Pandemic on Psychological Health and Sleep among Nurses and Physicians. Int J Environ Res Public Health. 2023 Jan 12;20(2)doi: 10.3390/ijerph20021410. PMID: 36674167. - Does not address fatigue and sleepiness of clinicians related to hours of service [PMC free article: PMC9859438] [PubMed: 36674167] [CrossRef]
5.
Alfonsi V, Scarpelli S, Gorgoni M, et al. Sleep-Related Problems in Night Shift Nurses: Towards an Individualized Interventional Practice. Front Hum Neurosci. 2021;15:644570. doi: 10.3389/fnhum.2021.644570. PMID: 33796014. - Narrative or scoping review [PMC free article: PMC8007770] [PubMed: 33796014] [CrossRef]
6.
Al-Hammouri MM, Rababah JA. Work family conflict, family work conflicts and work-related quality of life: The effect of rotating versus fixed shifts. J Clin Nurs. 2023 Aug;32(15–16):4887–93. doi: 10.1111/jocn.16581. PMID: 36369607. - Non-US study [PubMed: 36369607] [CrossRef]
7.
Al-Kofahi M, Mohyuddin GR, Taylor ME, et al. Reducing Resident Physician Workload to Improve Well Being. Cureus. 2019 Jun 29;11(6):e5039. doi: 10.7759/cureus.5039. PMID: 31501731. - No outcome of interest [PMC free article: PMC6721886] [PubMed: 31501731] [CrossRef]
8.
Amirian I, Andersen LT, Rosenberg J, et al. Working night shifts affects surgeons’ biological rhythm. Am J Surg. 2015 Aug;210(2):389–95. doi: 10.1016/j.amjsurg.2014.09.035. PMID: 25678472. - Non-US study [PubMed: 25678472] [CrossRef]
9.
An R, Li C, Ai S, et al. Effect of shift work on fatigue, reaction time and accuracy of nurses in the Department of Neurology: A cross-sectional observational study. J Nurs Manag. 2022 Sep;30(6):2074–83. doi: 10.1111/jonm.13665. PMID: 35510385. - Non-US study [PubMed: 35510385] [CrossRef]
10.
Anagnostopoulos F, Demerouti E, Sykioti P, et al. Factors associated with mental health status of medical residents: a model-guided study. J Clin Psychol Med Settings. 2015 Mar;22(1):90–109. doi: 10.1007/s10880-014-9415-2. PMID: 25554496. - No concurrent or historical comparison groups [PubMed: 25554496] [CrossRef]
11.
Anderson C, Ftouni S, Ronda JM, et al. Self-reported Drowsiness and Safety Outcomes While Driving After an Extended Duration Work Shift in Trainee Physicians. Sleep. 2018 Feb 1;41(2)doi: 10.1093/sleep/zsx195. PMID: 29281091. - No outcome of interest [PubMed: 29281091] [CrossRef]
12.
Angerer P, Schmook R, Elfantel I, et al. Night Work and the Risk of Depression. Dtsch Arztebl Int. 2017 Jul 16;114(24):404–11. doi: 10.3238/arztebl.2017.0404. PMID: 28669378. - No outcome of interest [PMC free article: PMC5499504] [PubMed: 28669378] [CrossRef]
13.
Arbour MW, Gordon IK, Saftner M, et al. The experience of sleep deprivation for midwives practicing in the united states. Midwifery. 2020 Oct;89:102782. doi: 10.1016/j.midw.2020.102782. PMID: 32554134. - Qualitative study with no quantitative data [PubMed: 32554134] [CrossRef]
14.
Arzalier-Daret S, Buléon C, Bocca ML, et al. Effect of sleep deprivation after a night shift duty on simulated crisis management by residents in anaesthesia. A randomised crossover study. Anaesth Crit Care Pain Med. 2018 Apr;37(2):161–6. doi: 10.1016/j.accpm.2017.05.010. PMID: 28882740. - Non-US study [PubMed: 28882740] [CrossRef]
15.
Asaoka S, Aritake S, Komada Y, et al. Factors associated with shift work disorder in nurses working with rapid-rotation schedules in Japan: the nurses’ sleep health project. Chronobiol Int. 2013 May;30(4):628–36. doi: 10.3109/07420528.2012.762010. PMID: 23445510. - Non-US study [PubMed: 23445510] [CrossRef]
16.
Asfour L, Asfour V, McCormack D, et al. In surgeons performing cardiothoracic surgery is sleep deprivation significant in its impact on morbidity or mortality? Interact Cardiovasc Thorac Surg. 2014 Sep;19(3):479–87. doi: 10.1093/icvts/ivu118. PMID: 24879643. - Narrative or scoping review [PubMed: 24879643] [CrossRef]
17.
Assaye AM, Wiechula R, Schultz TJ, et al. Impact of nurse staffing on patient and nurse workforce outcomes in acute care settings in low- and middle-income countries: a systematic review. JBI Evid Synth. 2021 Apr;19(4):751–93. doi: 10.11124/jbisrir-d-19-00426. PMID: 32881732. - Non-US studies [PubMed: 32881732] [CrossRef]
18.
Asta ML, Lo Presti S, Pasetti P, et al. [Relation between sleep deprivation and nursing errors during the night shift]. Prof Inferm. 2022 Jul 1;75(2):101–5. doi: 10.7429/pi.2022.752101. PMID: 36964920. - Not written in English [PubMed: 36964920] [CrossRef]
19.
Ayas NT, Jeklin AT, Tholin H, et al. Consecutive nursing shifts and the risk of hypoglycemia in critically ill patients who are receiving intravenous insulin: a multicenter study. J Clin Sleep Med. 2020 Jun 15;16(6):949–53. doi: 10.5664/jcsm.8382. PMID: 32065114. - Non-US study [PMC free article: PMC7849663] [PubMed: 32065114] [CrossRef]
20.
Aydin Guclu O, Karadag M, Akkoyunlu ME, et al. Association between burnout, anxiety and insomnia in healthcare workers: a cross-sectional study. Psychol Health Med. 2022 Jun;27(5):1117–30. doi: 10.1080/13548506.2021.1874434. PMID: 33486992. - Non-US study [PubMed: 33486992] [CrossRef]
21.
Babu R, Thomas S, Hazzard MA, et al. Worse outcomes for patients undergoing brain tumor and cerebrovascular procedures following the ACGME resident duty-hour restrictions. J Neurosurg. 2014 Aug;121(2):262–76. doi: 10.3171/2014.5.jns1314. PMID: 24926647. - Narrative or scoping review [PMC free article: PMC4527330] [PubMed: 24926647] [CrossRef]
22.
Bakhru RN, Basner M, Ecker A, et al. The effects of nocturnal in-hospital intensivist coverage on sleep, work and behavioral alertness in faculty and fellows. American journal of respiratory and critical care medicine. 2013;187 PMID: CN-01091785. - Conference/meeting abstract/poster
23.
Bakhru RN, Basner M, Kerlin MP, et al. Sleep and Work in ICU Physicians During a Randomized Trial of Nighttime Intensivist Staffing. Crit Care Med. 2019 Jul;47(7):894–902. doi: 10.1097/ccm.0000000000003773. PMID: 30985450. - No outcome of interest [PMC free article: PMC6579612] [PubMed: 30985450] [CrossRef]
24.
Ball J, Day T, Murrells T, et al. Cross-sectional examination of the association between shift length and hospital nurses job satisfaction and nurse reported quality measures. BMC Nurs. 2017;16:26. doi: 10.1186/s12912-017-0221-7. PMID: 28559745. - Non-US study [PMC free article: PMC5445490] [PubMed: 28559745] [CrossRef]
25.
Barger LK, Sullivan JP, Blackwell T, et al. Effects on resident work hours, sleep duration, and work experience in a randomized order safety trial evaluating resident-physician schedules (ROSTERS). Sleep. 2019 Aug 1;42(8)doi: 10.1093/sleep/zsz110. PMID: 31106381. - No outcome of interest [PMC free article: PMC6685326] [PubMed: 31106381] [CrossRef]
26.
Bari A, Khan RA, Rathore AW. Medical errors; causes, consequences, emotional response and resulting behavioral change. Pak J Med Sci. 2016 May–Jun;32(3):523–8. doi: 10.12669/pjms.323.9701. PMID: 27375682. - No concurrent or historical comparison groups [PMC free article: PMC4928391] [PubMed: 27375682] [CrossRef]
27.
Bashir K, Elsotohy HH, Elmoheen A. Do Night Shifts Increase the Risk of Benign Paroxysmal Positional Vertigo Among Doctors and Nurses? J Multidiscip Healthc. 2020;13:963–6. doi: 10.2147/jmdh.s256055. PMID: 32982272. - Non-US study [PMC free article: PMC7509318] [PubMed: 32982272] [CrossRef]
28.
Basner M, Dinges DF, Shea JA, et al. Sleep and Alertness in Medical Interns and Residents: An Observational Study on the Role of Extended Shifts. Sleep. 2017 Apr 1;40(4)doi: 10.1093/sleep/zsx027. PMID: 28329124. - No outcome of interest [PMC free article: PMC5806581] [PubMed: 28329124] [CrossRef]
29.
Beebe D, Chang JJ, Kress K, et al. Diet quality and sleep quality among day and night shift nurses. J Nurs Manag. 2017 Oct;25(7):549–57. doi: 10.1111/jonm.12492. PMID: 28695685. - Does not address fatigue and sleepiness of clinicians related to hours of service [PubMed: 28695685] [CrossRef]
30.
Bell T, Sprajcer M, Flenady T, et al. Fatigue in nurses and medication administration errors: A scoping review. J Clin Nurs. 2023 Sep;32(17–18):5445–60. doi: 10.1111/jocn.16620. PMID: 36707921. - Narrative or scoping review [PubMed: 36707921] [CrossRef]
31.
Berastegui P, Jaspar M, Ghuysen A, et al. Fatigue-related risk perception among emergency physicians working extended shifts. Appl Ergon. 2020 Jan;82:102914. doi: 10.1016/j.apergo.2019.102914. PMID: 31422293. - Non-US study [PubMed: 31422293] [CrossRef]
32.
Bihari S, Venkatapathy A, Prakash S, et al. ICU shift related effects on sleep, fatigue and alertness levels. Occup Med (Lond). 2020 Apr 20;70(2):107–12. doi: 10.1093/occmed/kqaa013. PMID: 31974569. - Non-US study [PubMed: 31974569] [CrossRef]
33.
Blackwell T, Kriesel DR, Vittinghoff E, et al. Design and recruitment of the randomized order safety trial evaluating resident-physician schedules (ROSTERS) study. Contemp Clin Trials. 2019 May;80:22–33. doi: 10.1016/j.cct.2019.03.005. PMID: 30885799. - No outcome of interest [PMC free article: PMC6482052] [PubMed: 30885799] [CrossRef]
34.
Blasche G, Pasalic S, Bauböck VM, et al. Effects of Rest-Break Intention on Rest-Break Frequency and Work-Related Fatigue. Hum Factors. 2017 Mar;59(2):289–98. doi: 10.1177/0018720816671605. PMID: 27760865. - Other: Mixed population [PubMed: 27760865] [CrossRef]
35.
Blouin AS, Smith-Miller CA, Harden J, et al. Caregiver Fatigue: Implications for Patient and Staff Safety, Part 1. J Nurs Adm. 2016 Jun;46(6):329–35. doi: 10.1097/nna.0000000000000353. PMID: 27214335. - Does not include clinicians in an acute care setting [PubMed: 27214335] [CrossRef]
36.
Bogossian F, Winters-Chang P, Tuckett A. “The pure hard slog that nursing is..”: a qualitative analysis of nursing work. J Nurs Scholarsh. 2014 Sep;46(5):377–88. doi: 10.1111/jnu.12090. PMID: 25163354. - Qualitative study with no quantitative data [PubMed: 25163354] [CrossRef]
37.
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Disclaimers: This report is based on research conducted by the Johns Hopkins University under contract to the Agency for Healthcare Research and Quality (AHRQ), Rockville, MD (Contract No. 75Q80120D00003). The findings and conclusions in this document are those of the authors, who are responsible for its contents; the findings and conclusions do not necessarily represent the views of AHRQ. Therefore, no statement in this report should be construed as an official position of AHRQ or of the U.S. Department of Health and Human Services.
None of the investigators have any affiliations or financial involvement that conflicts with the material presented in this report.
The information in this report is intended to help healthcare decision makers—patients and clinicians, health system leaders, and policymakers, among others—make well-informed decisions and thereby improve the quality of healthcare services. This report is not intended to be a substitute for the application of clinical judgment. Anyone who makes decisions concerning the provision of clinical care should consider this report in the same way as any medical reference and in conjunction with all other pertinent information, i.e., in the context of available resources and circumstances presented by individual patients.
This report is made available to the public under the terms of a licensing agreement between the author and the Agency for Healthcare Research and Quality. Most AHRQ documents are publicly available to use for noncommercial purposes (research, clinical or patient education, quality improvement projects) in the United States and do not need specific permission to be reprinted and used unless they contain material that is copyrighted by others. Specific written permission is needed for commercial use (reprinting for sale, incorporation into software, incorporation into for-profit training courses) or for use outside of the United States. If organizational policies require permission to adapt or use these materials, AHRQ will provide such permission in writing.
AHRQ or U.S. Department of Health and Human Services endorsement of any derivative products that may be developed from this report, such as clinical practice guidelines, other quality enhancement tools, or reimbursement or coverage policies, may not be stated or implied.
A representative from AHRQ served as a Contracting Officer’s Representative and reviewed the contract deliverables for adherence to contract requirements and quality. AHRQ did not directly participate in the literature search, determination of study eligibility criteria, data analysis, interpretation of data, or preparation or drafting of this report.
AHRQ appreciates appropriate acknowledgment and citation of its work. Suggested language for acknowledgment: This work was based on an evidence report, Fatigue and Sleepiness of Clinicians Due to Hours of Service, by the Evidence-based Practice Center Program at the Agency for Healthcare Research and Quality (AHRQ).

Rosen M, Kilcullen MP, Zhang A, Sharma R, Xiao C, Bass EB. Fatigue and Sleepiness of Clinicians Due to Hours of Service. Rapid Response. (Prepared by the Johns Hopkins University Evidence-based Practice Center under Contract No. 75Q80120D00003). AHRQ Publication No. 23(24)-EHC019-14. Rockville, MD: Agency for Healthcare Research and Quality. May 2024. https://doi.org/10.23970/AHRQEPC_MHS4FATIGUE. Posted final reports are located on the Effective Health Care Program search page.

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