Hostname: page-component-cd9895bd7-q99xh Total loading time: 0 Render date: 2024-12-27T05:25:27.013Z Has data issue: false hasContentIssue false

START versus SALT Triage: Which is Preferred by the 21st Century Health Care Student?

Published online by Cambridge University Press:  13 July 2018

Brian N. Fink*
Affiliation:
University of Toledo, Toledo, OhioUSA
Paul P. Rega
Affiliation:
University of Toledo, Toledo, OhioUSA
Martha E. Sexton
Affiliation:
University of Toledo, Toledo, OhioUSA
Carolina Wishner
Affiliation:
University of Toledo, Toledo, OhioUSA
*
Correspondence: Brian N. Fink, PhD University of Toledo 3000 Arlington Ave., MS# 1027 Toledo, Ohio 43614 USA E-mail: [email protected]

Abstract

Introduction

While the art and science of disaster triage continue to evolve, the education of the US health care student in matters pertaining to disaster preparedness and response remains stifled. Unfortunately, these students will be assuming major decision-making responsibilities regarding catastrophes that will be complicated by climate change, nuclear threats, global terrorism, and pandemics. Meanwhile, Sort, Assess, Life-Saving Interventions, Treatment, and/or Transport (SALT) triage is being advocated over the globally popular Simple Triage and Rapid Treatment (START) algorithm for multiple reasons: (1) it’s an all-hazard approach; (2) it has four medical interventions; and (3) it has an additional triage color for victims with non-survivable injuries.

Hypothesis/Problem

As present-day threats become more ominous and health care education emphasizes the needs of vulnerable populations and palliative care, the authors hypothesize that, when given a choice, health care students will prefer SALT triage.

Methods

A convenience sample of 218 interprofessional, disaster-naïve health care students received just-in-time, unbiased education on both START and SALT triage systems. Students then completed a survey asking them to decide which triage system they believe would be most effective in their community.

Results

A total of 123 health care students (56.4%) preferred SALT while 95 (43.6%) preferred START; however, only the physician assistant students showed a statistically significantly preference (28 versus six, respectively; P=.042). Interestingly, there was also a statistically significant difference in preference by gender (Chi-square=5.02; P=.025) of the observed distribution versus expected distribution in SALT and START. The females preferred SALT (61.0%) while the males preferred START (55.9%).

Among those who preferred START, START being easier to learn was the most important reason cited. Among those who preferred SALT, the most important reason cited was that the number of patient triage categories seemed more logical, comprehensible, and consistent with traditional medical care.

Conclusion:

While SALT’s preference among females and physician assistant students was based on the addition of medical interventions and the provision of palliative care, START’s preference was related to expediency. Based on this research, incorporating disaster concepts into US health care students’ curricula encourages thoughtful consideration among the future health care leaders about the most effective approach to triage care. It is critical that further research be completed to determine, without reservation, which triage system will not only save the most lives but provide the most humane care to victims.

Fink BN, Rega PP, Sexton ME, Wishner C. START versus SALT triage: which is preferred by the 21st century health care student? Prehosp Disaster Med. 2018;33(4):381–386

Type
Original Research
Copyright
© World Association for Disaster and Emergency Medicine 2018 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

Footnotes

Conflicts of interest: none

References

1. Skandalakis, NP, Panagiotis, L, Zoras, O, Skandalakis, JE, Mirilas, P. “To afford the wounded speedy assistance:” Dominique Jean Larrey and Napoleon. World J Surg. 2006;30(8):1392-1399.Google Scholar
2. Munroe, AR. Baron Larrey-Surgeon General to Napoleon’s Army. Can Med Assoc J. 1943;48(2):145-148.Google Scholar
3. Lerner, EB, Schwartz, RB, Coule, PL, et al. Mass-casualty triage: an evaluation of the data and development of a proposed national guideline. Disaster Med Public Health Prep. 2008;2(Suppl 1):S25-S34.Google Scholar
4. Arshad, FH, Williams, A, Asaeda, G, et al. A modified Simple Triage and Rapid Treatment algorithm from the New York City (USA) Fire Department. Prehosp Disaster Med. 2015;30(2):199-204.Google Scholar
5. Sapp, RF, Brice, JH, Myers, JB, Hinchey, P. Triage performance of first-year medical students using a multiple-casualty scenario, paper exercise. Prehosp Disaster Med. 2010;25(3):239-245.Google Scholar
6. Kahn, CA, Schultz, CH, Miller, KT, Anderson, CL. Does START triage work? An outcomes assessment after a disaster. Ann Emerg Med. 2009;54(3):424-430.Google Scholar
7. Claudius, I, Kaji, AH, Santillanes, G, et al. Accuracy, efficiency, and inappropriate actions using JumpSTART triage in MCI simulations. Prehosp Disaster Med. 2015;30(5):457-460.Google Scholar
8. Badiali, S, Giugni, A, Marcus, L. Testing the START triage protocol: can it improve the ability of nonmedical personnel to better triage patients during disasters and mass casualty incidents? Disaster Med Public Health Prep. 2017;11(3):305-309.Google Scholar
9. Hong, R, Sierzenski, PR, Bollinger, M, Durie, CC, O’Connor, RE. Does the Simple Triage and Rapid Treatment method appropriately triage patients based on trauma injury severity score? Am J Disaster Med. 2008;3(5):265-271.Google Scholar
10. Jenkins, JL, McCarthy, ML, Sauer, LM, et al. Mass-casualty triage: time for an evidence-based approach. Prehosp Disaster Med. 2008;23(1):3-8.Google Scholar
11. Lee, CWC, McLeod, SL, Van Aarsen, K, et al. First responder accuracy using SALT during mass-casualty incident Simulation. Prehosp Disaster Med. 2016;31(2):150-154.Google Scholar
12. Silvestri, S, Field, A, Mangalat, N, et al. Comparison of START and SALT triage methodologies to reference standard definitions and to a field mass-casualty simulation. Am J Disaster Med. 2017;12(1):27-33.Google Scholar
13. Bhalla, MC, Frey, J, Rider, C, Nord, M, Hegerhorst, M. Simple Triage Algorithm and Rapid Treatment and Sort, Assess, Lifesaving Interventions, Treatment and Transportation mass-casualty triage methods for sensitivity, specificity, and predictive values. Am J Emerg Med. 2015;33(11):1687-1691.Google Scholar
14. Deluhery, MR, Lerner, EB, Pirrallo, RG, Schwartz, RB. Paramedic accuracy using SALT triage after a brief initial training. Prehosp Emerg Care. 2011;15(4):526-532.Google Scholar
15. Cone, DC, Serra, J, Kurland, L. Comparison of the SALT and SMART triage systems using a virtual reality simulator with paramedic students. Eur J Emerg Med. 2011;18(6):314-321.Google Scholar
16. Lerner, EB, Scwartz, RB, Coule, PL, Pirrallo, RG. Use of SALT in a simulated mass-casualty incident. Prehosp Emerg Care. 2010;14(1):21-25.Google Scholar
17. Cone, DC, Serra, J, Burns, K, MacMillan, DS, Kurland, L, Van Gelder, C. Pilot test of the SALT mass-casualty triage system. Prehosp Emerg Care. 2009;13(4):536-540.Google Scholar
18. Lee, CW, McLeod, SL, Peddle, MB. First responder accuracy using SALT after brief initial training. Prehosp Disaster Med. 2015;30(5):447-451.Google Scholar
19. Jones, N, White, ML, Tofil, N, et al. Randomized trial comparing two mass-casualty triage systems (JumpSTART versus SALT) in a pediatric simulated mass-casualty event. Prehosp Emerg Care. 2014;18(3):417-423.Google Scholar
20. American Association of Medical Colleges. Training Future Physicians About Weapons of Mass Destruction: Report of the Expert Panel on Bioterrorism Education for Medical Students. https://members.aamc.org/eweb/upload/Training%20Future%20Physicians%20About%20Weapons.pdf. Published 2003. Accessed September 12, 2017.Google Scholar
21. Owens, MP, Buffington, C, Frost, MP, Waldner, RJ. The South Dakota Model: health care professions student disaster preparedness and deployment training. Disaster Med Public Health Prep. 2017;11(6):735-740.Google Scholar
22. Pfenninger, EG, Domres, BD, Stahl, W, Bauer, A, Houser, CM, Himmelseher, S. Medical student disaster medicine education: the development of an educational resource. Int J Emerg Med. 2010;16;3(1):9-20.Google Scholar
23. Kim, TE, Shankel, T, Reibling, ET, et al. Health care students interprofessional critical event/disaster response course. Am J Disaster Med. 2017;12(1):11-26.Google Scholar
24. Lynch, JS. Disaster response: physician assistant skills are an important asset. JAAPA. 2009;22(1):36-39.Google Scholar
25. Littleton-Kearney, MT, Slepski, LA. Directions for disaster nursing education in the United States. Crit Care Nurs Clin North Am. 2008;20(1):103-109.Google Scholar
26. Markenson, D, Woolf, S, Redlener, I, Reilly, M. Disaster medicine and public health preparedness of health professions students: a multidisciplinary assessment of knowledge, confidence, and attitudes. Disaster Med Public Health Prep. 2013;7(5):499-506.Google Scholar
27. Kaiser, HE, Barnett, DJ, Hsu, EB, Kirsch, TD, James, JJ, Subbarao, I. Perspectives of future physicians on disaster medicine and public health preparedness: challenges of building a capable and sustainable auxiliary medical workforce. Disaster Med Public Health Prep. 2009;3(4):210-216.Google Scholar
28. Jasper, E, Berg, K, Reid, M, et al. Disaster preparedness: what training do our interns receive during medical school? Am J Med Qual. 2013;28(5):407-413.Google Scholar
29. Pollard, KA, Bachmann, DJ, Greer, M, Way, DP, Kman, NE. Development of a disaster preparedness curriculum for medical students: a pilot study of incorporating local events into training opportunities. Am J Disaster Med. 2015;10(1):51-59.Google Scholar
30. Kaji, AH, Coates, W, Fung, CC. A disaster medicine curriculum for medical students. Teach Learn Med. 2010;22(2):116-122.Google Scholar
31. Jasper, EH, Wanner, GK, Berg, D, Berg, K. Implementing a disaster preparedness curriculum for medical students. South Med J. 2017;110(8):523-527.Google Scholar
32. Smith, J, Levy, MJ, Hsu, EB, Lee Levy, J. Disaster curricula in medical education: pilot survey. Prehosp Disaster Med. 2012;27(5):492-494.Google Scholar
33. Leong, SL, Cangiarella, J, Fancher, T, et al. Roadmap for creating an accelerated three-year medical education program. Med Educ Online. 2017;22(1):1-10.Google Scholar