Pediatric trainees systematically under-report duty hour violations compared to electronic health record defined shifts
Authors:
Adam C. Dziorny aff001; Evan W. Orenstein aff003; Robert B. Lindell aff002; Nicole A. Hames aff003; Nicole Washington aff004; Bimal Desai aff004
Authors place of work:
Department of Biomedical and Health Informatics, Children’s Hospital of Philadelphia, Philadelphia, Pennsylvania, United States of America
aff001; Division of Critical Care Medicine, Department of Anesthesiology and Critical Care, Children’s Hospital of Philadelphia, University of Pennsylvania Perelman School of Medicine, Philadelphia, Pennsylvania, United States of America
aff002; Department of Pediatrics, Emory University School of Medicine and Division of Hospital Medicine, Children’s Healthcare of Atlanta, Atlanta, Georgia, United States of America
aff003; Division of General Pediatrics, Department of Pediatrics, Children’s Hospital of Philadelphia, University of Pennsylvania Perelman School of Medicine, Philadelphia, Pennsylvania, United States of America
aff004
Published in the journal:
PLoS ONE 14(12)
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pone.0226493
Summary
Duty hour monitoring is required in accredited training programs, however trainee self-reporting is onerous and vulnerable to bias. The objectives of this study were to use an automated, validated algorithm to measure duty hour violations of pediatric trainees over a full academic year and compare to self-reported violations. Duty hour violations calculated from electronic health record (EHR) logs varied significantly by trainee role and rotation. Block-by-block differences show 36.8% (222/603) of resident-blocks with more EHR-defined violations (EDV) compared to self-reported violations (SRV), demonstrating systematic under-reporting of duty hour violations. Automated duty hour tracking could provide real-time, objective assessment of the trainee work environment, allowing program directors and accrediting organizations to design and test interventions focused on improving educational quality.
Keywords:
Pediatrics – Graduates – Medical education – Inpatients – Intensive care units – Fatigue – Electronic medical records – trainees
Introduction
To reduce errors associated with fatigue, the Accreditation Council for Graduate Medical Education mandates duty hour restrictions on trainees [1] but does not stipulate how monitoring should be accomplished [2]. Self-report systems are common [3] but are onerous for trainees to complete and vulnerable to recall bias and both under- and over-reporting [4,5]. Numerous single- and multi-institution surveys have demonstrated that trainees across many specialties substantially under-report duty hours [6–9]. Known reasons for under-reporting include the risk of loss of program accreditation [9], time for completion of electronic health record (EHR) documentation, guilt for leaving sick patients, and a “feeling that it was expected of them” [10,11]. However, the frequency of duty hour violations has not been measured objectively across a large sample of trainee shifts and rotations.
Trainees spend a substantial amount of time interacting with the electronic health record (EHR) [12,13]. Access logs store timestamps when users perform specific actions in the EHR. These logs provide objective measures of note-writing time [14], order entry workflow [15], time spent charting after hours [16] as well as trainee EHR usage [17]. Gilleland et al [16] suggested that adding objective EHR data to trainee self-reported duty hours would add an average of 1.44 new duty hour violations per trainee per month. Shine et al [18] found that average reported hours were 7.3% higher from self-reporting compared to EHR logs among internal medicine trainees on a single rotation, the medical intensive care unit.
We compared EHR-defined violations (EDV) to self-reported violations (SRV) across all inpatient rotations in a large pediatric residency program using an automated, validated algorithm to accurately identify provider shifts from electronic health record (EHR) logs [19].
Methods
We included all pediatric trainees practicing on inpatient rotations at the Children’s Hospital of Philadelphia, a large academic training program in a quaternary care center, from 7/1/2015 through 6/30/2016. Trainees were classified as junior (e.g. interns at PGY-1) or senior trainees (e.g. PGY 2–4) in a front-line ordering clinician role (Jr FLC or Sr FLC), or senior trainees in a supervisory role (Sr Suprv). A resident-block was defined as a trainee working on a given rotation during a 4-week block. All blocks were 28 days in duration except for the first and last blocks of the academic year, which each contained an extra day (29 days). The number of scheduled shifts per block varied from approximately 17 with an every-fourth-night call schedule to 23 with a day-night shift schedule. Most resident-blocks included outpatient clinic one afternoon per week.
Log entries from the hospital EHR (Epic Systems©) were converted into EHR-defined shifts (EDS) using a validated algorithm [19]. Briefly, we extracted all access log event timestamps recorded for eligible trainees while excluding event timestamps from workstations not located in the hospital. We calculated event intervals as the difference between subsequent timestamps. We then defined EHR shifts by setting the starting timestamp after a “long” EHR event interval and the end timestamp prior to the next “long” EHR event interval. The “long” duration heuristic and subsequent shift refinement were defined based on our prior published validation process.
Self-reported shifts (SRS) were exported from New Innovations© Resident Management Suite, a web-based self-reporting system which has been implemented in our training program for >3 years. Trainees were expected to log all clinical shifts in this system, with email reminders sent from training program administrators at regular intervals. We exported SRS for all included trainees several months following the completion of the academic year, allowing trainees sufficient time to complete duty hour logs. As this study was completed retrospectively, we did not engage specific trainees to ensure logging of all shifts but rather analyzed only the data present at the time of extraction.
Duty hour violations were computed for all shifts (EDS and SRS) across all resident-blocks. “Duration” violations were defined as trainee shifts exceeding maximum allowed shift duration, as defined at the time of this study (16 hours for interns; 24+4 hours for senior trainees). “Interval” violations were defined as inadequate time-off between shifts (<8 hours following shifts ≤16 hours; <14 hours following shifts >16 hours). We measured the number of violations by type across trainee roles for all EDS and calculated the block-by-block difference of total SRV and EDV for all resident-blocks with any SRS present. Continuous variables with multiple groups were analyzed with ANOVA followed by Tukey post-hoc testing to adjust for multiple comparisons. A multivariable regression model estimated the influence of predictors including role and source (‘EDV’ versus ‘SRV’) on the outcome of ‘total violations’. Regression coefficients are reported for each predictor or category of predictor. All analysis was completed in R Studio [20]. Computation was facilitated with the ‘dplyr’ package [21] and graphics were generated with ‘ggplot2’ and ‘cowplot’ packages [22,23].
This study was approved by the Institutional Review Board at Children’s Hospital of Philadelphia with a waiver of consent as trainee data were analyzed in aggregate.
Results
Our study cohort included 139 trainees working 771 resident-blocks. Within these resident-blocks, trainee post-graduate years were represented as: 339 (44.0%) from PGY-1 trainees, 327 (42.4%) from PGY-2 trainees, 102 (13.2%) from PGY-3 trainees and 3 (0.4%) from PGY-4 trainees. Similarly, trainee roles were represented as: 339 (44.0%) as Jr FLC, 305 (39.6%) as Sr FLC and 127 (16.5%) as Sr Suprv. A total of 168 resident-blocks (22%) from 23 trainees (17%) contained zero self-reported shifts (SRS) and were excluded when the analyses included SRS. This exclusion resulted in 603 resident-blocks (78%) from 116 trainees (83%) eligible for paired EDV-SRV analysis.
Mean total EHR-defined violations (EDV) per block for all resident-blocks varied by role (Mean±SEM: Jr FLC 0.6±0.06, Sr FLC 2.4±0.11, Sr Suprv 1.4±0.12; p <0.001) [Fig 1A]. Across all EHR-defined ‘duration’ violations, median [IQR] shift length beyond maximum allowed shift duration was 36.3 minutes [16.4, 70.8]. Counts of violations varied significantly by rotation for front-line clinician roles (Jr FLC and Sr FLC), with mean violation count ranging from 0.5±0.1 to 3.7±0.3 per resident-block [Fig 1B].
In multivariable regression analysis, there were 0.45±0.09 fewer SRV than EDV (p <0.001) per resident-block, adjusted for trainee role. Additionally, there were greater total violations among trainees in the Sr FLC role (1.38±0.1) and Sr Suprv role (0.63±0.13) compared to Jr FLC (both p <0.001). Violations plotted as SRV-EDV show 36.8% (222/603) of resident-blocks with more EDV than SRV, while 17.9% (108/603) of resident-blocks had fewer EDV than SRV [Fig 2A]. This difference in EDV and SRV was most pronounced for the Sr FLC role. Mean total self-reported violations (SRV) per block also varied by role (Mean±SEM: Jr FLC 0.5±0.06, Sr FLC 1.5±0.14, Sr Suprv 1.0±0.15; p<0.001) [Fig 2B].
Discussion
Automated ascertainment of trainee work hours using EHR logs demonstrated under-reporting of duty hour violations. To our knowledge, this is the first study to objectively examine a full academic year of trainees’ EHR- and self-reported shifts. Tracking duty hours in an automated fashion has several advantages to self-report including less onerous work for the trainee, avoiding recall bias [4,5], and limiting trainee’s disincentive to accurately report duty hours to avoid their program being placed on probation status [8]. Similar objective duty time systems are employed in the aviation industry where alertness on duty is critical, as part of Fatigue Risk Management Systems [24]. Additionally, prospective studies comparing different residency program duty-hour policies would benefit from such objective measuring of actual hours worked instead of relying on trainee reporting [25].
In this study we found 36.8% of resident-blocks had fewer SRV than EDV, consistent with survey-based studies suggesting 18–72% under-reporting [4,8,9]. Duration violations are the more frequent type of violation among all trainees, and interval violations trend towards being more common among Jr FLCs. Interval violations occur approximately once every 5 trainee blocks for Jr FLCs, and only once every 10 resident-blocks for Sr FLCs. However duration violations occur on average more than twice per resident-block among Sr FLCs, and more than once per resident-block among Sr Suprv trainees. On some rotations duration violations occurred nearly once per week, a substantial burden which can contribute to worse clinical performance [26] and increased medical errors [27].
This study was limited to a single institution and does not include out-of-hospital EHR logs by design. Because actual shifts may exceed the boundary of in-hospital EHR use, this method may under-estimate but should not over-estimate duty hours for inpatient shifts. Accordingly, we observed 18% of resident-blocks with more SRV than EDV. This may represent either over-reporting of duty hour violations using self-reporting tools, or actual shift duration exceeding the bounds of EHR use. Additionally, 22% of resident-blocks were excluded from paired analysis because no self-reported shifts were logged by trainees.
Automated duty hour tracking could provide real-time, objective assessment of the trainee work environment. Such systems would allow program directors to design and test interventions focused on improving the medical educational experience, quickly targeting rotations with more violations while simultaneously decreasing trainee non-clinical clerical tasks.
Zdroje
1. Philibert I, Friedmann P, Williams WT, Education AWG on RDHAC for GM. New requirements for resident duty hours. JAMA. Accreditation Council for Graduate Medical Education, American Medical Association, Chicago, IL 60610, USA. iphilibert@acgme.org; 2002;288: 1112–1114. Available: internal-pdf://238.253.92.129/Philibert 2002.pdf doi: 10.1001/jama.288.9.1112 12204081
2. Accreditation Council for Graduate Medical Education: Common Program Requirements [Internet]. 2017. https://www.acgme.org/Specialties/Program-Requirements-and-FAQs-and-Applications/pfcatid/16/Pediatrics
3. Petre M, Geana R, Cipparrone N, Harrison L, Hartzen M, Sulo S, et al. Comparing Electronic and Manual Tracking Systems for Monitoring Resident Duty Hours. Ochsner J. Medical Education, Advocate Lutheran General Hospital, Park Ridge, IL. Operational Integration and Communication/Clinical Affairs, Cancer Treatment Centers of America, Schaumburg, IL. Illinois Bone & Joint Institute, Morton Grove, IL. Psychiatry Residency; 2016;16: 16–21. Available: internal-pdf://200.7.214.144/Petre 2016.pdf 27046398
4. Gonzalo JD, Yang JJ, Ngo L, Clark A, Reynolds EE, Herzig SJ. Accuracy of residents’ retrospective perceptions of 16-hour call admitting shift compliance and characteristics. J Gr Med Educ. 2013;5: 630–633. doi: 10.4300/JGME-D-12-00311.1 24455013
5. Saunders DL, Kehoe KC, Rinehart VH, Berg BW. Self-reporting of internal medicine house staff work hours. Hawaii Med J. Medical Corps, US Army, Internal Medicine Resident, Tripler Army Medical Center, Honolulu, HI 96859, USA.; 2005;64: 14–16. Available: https://www.ncbi.nlm.nih.gov/pubmed/15751754 15751754
6. Carpenter RO, Spooner J, Arbogast PG, Tarpley JL, Griffin MR, Lomis KD. Work hours restrictions as an ethical dilemma for residents: a descriptive survey of violation types and frequency. Curr Surg. Department of General Surgery, Vanderbilt University Medical Center, Nashville, Tennessee 37232–2730, USA. robert.carpenter@vanderbilt.edu; 2006;63: 448–455. 17084777
7. Lo V, Ward C. 2011 ACGME duty hour week proposal—a national survey of family medicine residents. Fam Med. San Joaquin Family Medicine Residency, A University of California Davis Primary Care Network Program, French Camp, CA, USA. vincent.lo@chw.edu; 2011;43: 318–324. Available: internal-pdf://94.96.218.137/Lo 2011.pdf 21557100
8. Ruff J. Surgical Resident Duty Hours. N Engl J Med. 7362 Palmleaf Ln., Columbus, OH ruffjm@gmail.com.; 2016;374: 2402. doi: 10.1056/NEJMc1604659
9. Byrne JM, Loo LK, Giang DW. Duty Hour Reporting: Conflicting Values in Professionalism. J Gr Med Educ. 2015;7: 395–400. doi: 10.4300/JGME-D-14-00763.1 26457145
10. Bennett CL, McDonald DA, Chang Y, Finch A, Vuong K, Rennie S, et al. A National Cross-Sectional Study of Surgery Residents Who Underreport Duty Hours. J Surg Educ. Massachusetts General Hospital, Harvard Medical School, Boston, Massachusetts. Electronic address: cbennett@bwh.harvard.edu. Duke University, Durham, North Carolina. Massachusetts General Hospital, Harvard Medical School, Boston, Massachusetts. The Mayo C; 2017; doi: 10.1016/j.jsurg.2017.05.008 28529194
11. Bilimoria KY, Quinn CM, Dahlke AR, Kelz RR, Shea JA, Rajaram R, et al. Use and Underlying Reasons for Duty Hour Flexibility in the Flexibility in Duty Hour Requirements for Surgical Trainees (FIRST) Trial. J Am Coll Surg. Surgical Outcomes and Quality Improvement Center, Department of Surgery and Center for Healthcare Studies, Feinberg School of Medicine and Northwestern Medicine, Northwestern University, Chicago, IL; American College of Surgeons, Chicago, IL. Electronic a; 2017;224: 118–125. doi: 10.1016/j.jamcollsurg.2016.10.046 27884805
12. Fletcher KE, Visotcky AM, Slagle JM, Tarima S, Weinger MB, Schapira MM. The composition of intern work while on call. J Gen Intern Med. Clement J. Zablocki VAMC, Milwaukee, WI, USA. Kathlyn.fletcher@va.gov; 2012;27: 1432–1437. doi: 10.1007/s11606-012-2120-7 22865015
13. Chen L, Guo U, Illipparambil LC, Netherton MD, Sheshadri B, Karu E, et al. Racing Against the Clock: Internal Medicine Residents’ Time Spent On Electronic Health Records. J Gr Med Educ. 2016;8: 39–44. doi: 10.4300/JGME-D-15-00240.1 26913101
14. Hripcsak G, Vawdrey DK, Fred MR, Bostwick SB. Use of electronic clinical documentation: time spent and team interactions. J Am Med Inf Assoc. Department of Biomedical Informatics, Columbia University Medical Center, New York, USA. hripcsak@columbia.edu; 2011;18: 112–117. doi: 10.1136/jamia.2010.008441 21292706
15. Hanauer DA, Zheng K, Commiskey EL, Duck MG, Choi SW, Blayney DW. Computerized prescriber order entry implementation in a physician assistant-managed hematology and oncology inpatient service: effects on workflow and task switching. J Oncol Pr. University of Michigan, Ann Arbor, MI; and Stanford University, Stanford, CA.; 2013;9: e103–14. doi: 10.1200/JOP.2012.000655 23942926
16. Gilleland M, Komis K, Chawla S, Fernandez S, Fishman M, Adams M. Resident duty hours in the outpatient electronic health record era: inaccuracies and implications. J Gr Med Educ. 2014;6: 151–154. doi: 10.4300/JGME-D-13-00061.1 24701327
17. Wang JK, Ouyang D, Hom J, Chi J, Chen JH, Chen Id JH. Characterizing electronic health record usage patterns of inpatient medicine residents using event log data. PLoS One. 2019;14: e0205379. doi: 10.1371/journal.pone.0205379 30726208
18. Shine D, Pearlman E, Watkins B. Measuring resident hours by tracking interactions with the computerized record. Am J Med. Department of Medicine, New York University Langone Medical Center, New York, 10016, USA. daniel.shine@nyumc.org; 2010;123: 286–290. doi: 10.1016/j.amjmed.2009.10.009 20193841
19. Dziorny AC, Orenstein EW, Lindell RB, Hames NA, Washington N, Desai B. Automatic Detection of Front-Line Clinician Hospital Shifts: A Novel Use of Electronic Health Record Timestamp Data. Appl Clin Inform. 2019;10: 28–37. doi: 10.1055/s-0038-1676819 30625502
20. Team Rs. RStudio: Integrated Development Environment for R [Internet]. Boston, MA: RStudio, Inc; 2016. http://www.rstudio.com/
21. Wickham H, Francois R, Henry L, Müller K. dplyr: A Grammar of Data Manipulation [Internet]. 2017. https://cran.r-project.org/package=dplyr
22. Wilke CO. cowplot: Streamlined Plot Theme and Plot Annotations for “ggplot2” [Internet]. 2017. https://cran.r-project.org/package=cowplot
23. Wickham H. ggplot2: Elegant Graphics for Data Analysis [Internet]. Springer-Verlag New York; 2016. http://ggplot2.org
24. Caldwell JA, Mallis MM, Caldwell JL, Paul MA, Miller JC, Neri DF, et al. Fatigue countermeasures in aviation. Aviat Space Environ Med. Alexandria, VA : Aerospace Medical Association; 2009;80: 29–59. doi: 10.3357/asem.2435.2009 19180856
25. Desai S V, Asch DA, Bellini LM, Chaiyachati KH, Liu M, Sternberg AL, et al. Education Outcomes in a Duty-Hour Flexibility Trial in Internal Medicine. N Engl J Med. From the Departments of Medicine (S.V.D.), Epidemiology (A.L.S., J.T., D.M.S.), and Biostatistics (J.T.), Johns Hopkins University, Baltimore; the Departments of Medicine (D.A.A., L.M.B., K.H.C., M.L., A.M.Y., J.M.A., J.A.S.), Psychiatry (M.B., D.F.D.), a; 2018;378: 1494–1508. doi: 10.1056/NEJMoa1800965 29557719
26. Gordon JA, Alexander EK, Lockley SW, Flynn-Evans E, Venkatan SK, Landrigan CP, et al. Does simulator-based clinical performance correlate with actual hospital behavior? The effect of extended work hours on patient care provided by medical interns. Acad Med. Gilbert Program in Medical Simulation, Harvard Medical School, Boston, Massachusetts, USA. jgordon3@partners.org; 2010;85: 1583–1588. doi: 10.1097/ACM.0b013e3181f073f0 20881679
27. Landrigan CP, Rothschild JM, Cronin JW, Kaushal R, Burdick E, Katz JT, et al. Effect of reducing interns’ work hours on serious medical errors in intensive care units. N Engl J Med. Division of Sleep Medicine, Brigham and Women’s Hospital, Boston, MA 02115, USA. clandrigan@rics.bwh.harvard.edu; 2004;351: 1838–1848. doi: 10.1056/NEJMoa041406 15509817
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