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Barriers to point-of-care ultrasound use in rural emergency departments

Published online by Cambridge University Press:  25 July 2016

Taft Micks*
Affiliation:
Department of Family Medicine, Memorial University of Newfoundland, St. John’s, NL
Kyle Sue
Affiliation:
Department of Family Medicine, Memorial University of Newfoundland, St. John’s, NL
Peter Rogers
Affiliation:
Department of Family Medicine, Memorial University of Newfoundland, St. John’s, NL Department of Emergency Medicine, Memorial University of Newfoundland, St. John’s, NL
*
Correspondence to: Dr. Taft Micks, Memorial University of Newfoundland, Health Sciences Centre, Room 2743, St. John’s, NL A1B 3V6, Canada; Email: [email protected]

Abstract

Over the past few decades, point-of-care ultrasound (PoCUS) has come to play a major role in the practice of emergency medicine. Despite its numerous benefits, there has been a slow uptake of PoCUS use in rural emergency departments. Surveys conducted across Canada and the United States have identified a lack of equipment, training, funding, quality assurance, and an inability to maintain skills as major barriers to PoCUS use. Potential solutions include expanding residency training in ultrasound skills, extending funding for PoCUS training to rural physicians in practice, moving PoCUS training courses to rural sites, and creating telesonography training for rural physicians. With these barriers identified and solutions proposed, corrective measures must be taken so that the benefits of PoCUS are extended to patients in rural Canada where, arguably, it has the greatest potential for benefit when access to advanced imaging is not readily available.

Résumé

Le rôle de l’échographie au point de service (EPS) a gagné beaucoup d’importance en médecine d’urgence au cours des dernières décennies. Malgré ses nombreux avantages, son utilisation dans les services des urgences en milieu rural se fait lentement. Des enquêtes menées partout au Canada et aux États-Unis ont révélé des obstacles importants à son utilisation, soit le manque d’appareils médicaux, de formation, de financement et d’assurance de la qualité ainsi que l’incapacité de garder à jour les compétences acquises. Différentes solutions possibles ont été envisagées, en particulier l’enrichissement de la formation au niveau de la résidence en ce qui concerne les compétences en échographie, l’élargissement du financement de la formation en EPS aux médecins qui pratiquent déjà en milieu rural, la possibilité d’offrir des cours de formation en milieu rural et l’élaboration de cours en télé-échographie à l’intention des médecins qui travaillent en milieu rural. Maintenant que les obstacles à l’utilisation de l’EPS ont été cernés et que des solutions ont été proposées, des mesures correctrices s’imposent afin que les malades en milieu rural, au Canada, puissent profiter, eux aussi, de ce type d’examen, là où il est permis de penser que la technologie offre le plus d’avantages et où les examens évolués par imagerie ne sont pas rapidement et facilement utilisables.

Type
Editorial/Commentary
Copyright
Copyright © Canadian Association of Emergency Physicians 2016 

INTRODUCTION

Approximately 20% of Canadians live in rural or remote regions of the country. 1 Despite the accessibility clause of the Canada Health Act, major disparities in access to diagnostic imaging exist across the country in rural emergency departments (EDs).Reference Fleet, Archambault and Plant 2 In a survey of Canadian rural EDs, 97% have access to X-ray, but only 20% have access to a CT scanner and only 28% have access to formal ultrasound services. If advanced imaging is required, 44% of these rural EDs would need to transfer their patients upwards of 300 km to a nearby trauma centre resulting in significant delays to definitive care.Reference Fleet, Poitras and Maltais-Giguere 3 This is even more concerning in the context of rural residents having a higher prevalence of acute and chronic illness as well as greater risk for trauma and trauma death compared to their urban counterparts.Reference Joynt, Harris and Orav 4 , 5 A potential solution may exist with an imaging modality that is cost-effective, noninvasive, easily accessible, contrast-free, requires no special preparation of the patient, decreases time to diagnosis,Reference Reed and Cheung 6 decreases patient ED length of stay,Reference Blaivas, Sierzenski and Plecque 7 decreases time to operative care,Reference Melniker, Lelbner and McKenney 8 and improves acute care outcomesReference McLaughlin, Collum and McGowern 9 —that is, point-of-care ultrasound (PoCUS).

In 2005, Lyon et al. demonstrated the beneficial effects that PoCUS has on rural ED decision-making in that it clarified the clinical situation by reducing the number of differential diagnoses, altering patient management in 74% of cases. In nearly 10% of cases, PoCUS suggested diagnoses that were not originally considered and led to more definitive diagnoses, which avoided the need to transfer patients to larger centres for further imaging in 53% of cases. This also avoided the unnecessary use of ambulances required to transfer these patients in communities where ambulance services are limited.Reference Lyon, Blaivas and Brannam 10 Furthermore, numerous international studies illustrate the benefits of PoCUS in rural and remote settings, which could parallel the situation in rural Canada.Reference Blaivas, Kuhn and Reynolds 11 - Reference Nelson, Melnick and Li 13 Clearly there are multiple advantages to performing PoCUS in the rural ED; moreover, the Canadian Association of Emergency Physicians (CAEP), in their 2012 Position Statement, has encouraged access to PoCUS 24/7/365 in the ED. 14 However, despite the numerous benefits offered by PoCUS in the rural ED setting, several barriers to its use remain.

LACK OF EQUIPMENT

A survey of rural Ontario physicians conducted by Flynn et al. in 2012 (with a low response rate of 28%) reported that approximately 40% did not have an ultrasound machine available in the ED.Reference Flynn, Weppler and Theodore 15 Of the Ontario physicians surveyed, a majority (66%) believed that the ultrasound machine should be paid for by the hospital (66%), followed by the Ministry of Health and Long-Term Care (24%), and the community (8%). A needs assessment of PoCUS in rural Newfoundland conducted by Warren et al. at Memorial University in 2013 identified that 73% of category A (rural with 24-hour access) EDs had ultrasonography available, whereas category B (call back) EDs only had 4% availability.Reference Warren and Smith 16 In stark contrast to Ontario and Newfoundland, a survey of rural ED physicians in Quebec by Léger et al. in 2014 revealed that PoCUS was available in 95% of rural EDs.Reference Léger, Fleet and Maltais-Giguère 17 Variable access to bedside ultrasound in rural EDs also exists in the United States. One survey of ED directors in Colorado, Georgia, Massachusetts, and Oregon reported that only 39% of rural EDs had access to bedside ultrasound.Reference Talley, Ginde and Raja 18 However, another survey of American rural emergency physicians (with a low response rate of 18%) in the WWAMI (Washington, Wyoming, Alaska, Montana, and Idaho) region conducted by Bellows et al. in 2015 discovered that 96% had access to an ultrasound machine in the ED.Reference Bellows, Totten and Shah 19

LACK OF TRAINING

Flynn et al. revealed that 71.5% of rural Ontario emergency physicians agreed or agreed strongly that PoCUS is a skill that rural emergency medicine physicians should possess, but less than half (44.4%) knew how to perform ultrasonography, with 77.3% of these physicians stating they had inadequate training.Reference Flynn, Weppler and Theodore 15 Warren et al. identified that 98.8% of physicians in rural Newfoundland and Labrador believed that PoCUS was very or somewhat important to the practice of emergency medicine, but only 24% of those physicians in category A rural EDs and 0% in category B had formal training in PoCUS with 94% of them being very or somewhat interested in additional training.Reference Warren and Smith 16 Léger et al. discovered that 95% of respondents believed that PoCUS was essential for rural ED practice, but 24% of physicians did not use PoCUS on a regular basis with the most common reason for lack of use being limited access to training programs.Reference Léger, Fleet and Maltais-Giguère 17 In the WWAMI region of the United States, 62% of surveyed rural physicians identified a lack of training as a barrier to PoCUS use, with 35% having difficulty with image interpretation. A majority of these physicians (80%) were interested in a PoCUS course if offered at their site with many (64%) also being interested in a distance learning program.Reference Bellows, Totten and Shah 19

LACK OF FUNDING

Currently, physicians must pay to complete training courses such as Emergency Department Targeted Ultrasound (EDTU), Emergency Department Echo (EDE), or Emergency and Critical Care Ultrasound (ECCU). These courses can be costly (Table 1). Of the Ontario physicians surveyed, 11.8% identified cost as a barrier to training, whereas Bellows et al. discovered cost to be an issue for nearly 20% of the surveyed physicians in the WWAMI region.Reference Bellows, Totten and Shah 19 More than two-thirds of the Ontario survey respondents believed that funding for PoCUS training should come from a source other than the physician, including the Ministry of Health and Long-Term Care, hospital, Ontario Medical Association, community, or other sources. Of the physicians who paid for training out of their own pockets, 59% received training from EDE, 15% received training from CAEP, and 20% received training from other sources.Reference Flynn, Weppler and Theodore 15 The numbers identified by Léger et al. were similar, with 64% receiving training from the Canadian Emergency Ultrasound Society (CEUS), 13% receiving training from CAEP, and 23% receiving training from other courses. Interestingly, only 40% of rural PoCUS users received training within their medical curriculum.Reference Léger, Fleet and Maltais-Giguère 17

Table 1 Approximate cost of point-of-care ultrasound training courses

* EDE Bootcamp and EDTU allow participants to complete all 200 scans required for PoCUS competency. EDE Bootcamp also allows for completion of the required practical, visual, and written examinations for CEUS IP certification.

INABILITY TO MAINTAIN SKILLS

Another major hurdle was the maintenance of skills in PoCUS after rural physicians completed their initial training and returned to their respective practices. With lower patient volume, rural physicians may not have the opportunity to obtain competency in the learned skills or maintain them over time.Reference Woo, Frank and Lee 20 CEUS and other PoCUS certifying courses, such as EDTU and ECCU, require at least 50 determinate scans in each of the four domains of focused assessment with sonography in trauma (FAST), subxiphoid cardiac view for pericardial effusion, transabdominal scan for abdominal aortic aneurysm, and pelvic scan for confirming intrauterine pregnancy. Physicians must then complete visual, written, and practical exams to achieve independent practitioner (IP) status. Flynn et al. discovered that 44% of the rural ED physicians surveyed did not perform PoCUS because of the difficulty maintaining skills. Only 12% of physicians used PoCUS more than once per week, with 31% using it less than once per week and 21% at least once per shift.Reference Flynn, Weppler and Theodore 15 Warren et al. identified that 73.9% of physicians performed less than 10 scans per month, whereas only 3.4% performed more than 30 scans.Reference Warren and Smith 16 Similarly, Léger et al. discovered only 76% of physicians reported using PoCUS regularly.Reference Léger, Fleet and Maltais-Giguère 17

LACK OF QUALITY ASSURANCE

It has been noted in the literature that physicians may avoid using PoCUS due to a fear of litigation.Reference Alexander 21 This may be partly due to the lack of quality assurance programs available in EDs using PoCUS where physicians are not able to receive feedback with the quality of scans produced and the integration of findings into clinical decision-making. This issue was addressed in the CAEP 2006 Position Paper, but many rural EDs continue to lack any formal quality assurance programs. 22 Concerns about liability were identified as a major barrier to PoCUS use for 33% of American rural ED physicians in the WWAMI region, with 63% reporting no formal quality assurance process for image review.Reference Bellows, Totten and Shah 19 This has been a major concern for radiologists who cite a possible lack of appropriate training, assessment, and quality image generation with the widespread use of PoCUS resulting in compromised patient safety.Reference Chang and Munk 23 , Reference Ross, Bromley and Carter 24 Interestingly, two studies spanning over 25 years of American legal cases did not report a single case against an emergency physician who failed to interpret or made a misdiagnosis using PoCUS but did report six successful cases against physicians who failed to perform PoCUS when it was within their scope of practice, leading to the delayed diagnoses and patient demise.Reference Blaivas and Pawl 25 , Reference Stolz, O’Brien and Miller 26 Although it is inevitable that a physician error will eventually occur with the use of ultrasound by inexperienced physicians, it is also clear that the benefits seem to greatly outweigh the purported harm. Physicians are encouraged to use PoCUS with the standards set by CEUS, CAEP, and other local associations to minimize the risk of error.

CORRECTIVE MEASURES

As of 2012, 100% of Royal College and 88% of College of Family Physicians emergency medicine programs have included formal PoCUS training as part of their curriculum.Reference Kim, Theoret and Liao 27 As emergency medicine residents graduate from these programs and become champions for PoCUS in their respective rural EDs, this is likely to increase the availability of PoCUS in rural hospitals. Furthermore, of the emergency physicians surveyed nationwide by Woo et al., more than 80% predicted future use of PoCUS.Reference Woo, Frank and Lee 20

An area that needs to be addressed is the training of rural family medicine residents in PoCUS. Of the Quebec physicians working in rural EDs responding to Léger et al., 93% were family physicians.Reference Léger, Fleet and Maltais-Giguère 17 The American Academy of Family Physicians (AAFP) released a statement in 2013 addressing ultrasound use as an area of competency for rural family physicians, but the College of Family Physicians of Canada has yet to make a similar statement for Canadian family physicians.Reference Schmitz, Crouse and Epperly 28 Despite the statement made by the AAFP, in 2014 the Council of Academic Family Medicine Educational Research Alliance surveyed family medicine residency program directors to discover that only 2% of residency programs reported an established ultrasound curriculum. However, it is promising that 29% of the programs reported establishing a curriculum within the past year with a further 11% in the process of developing ultrasound training.Reference Hall, Holman and Bornemann 29 As of October 2014, the Memorial University of Newfoundland (MUN) began to integrate a formal PoCUS curriculum into the family medicine residency program with positive outcomes for rural patients already being realized.Reference Micks, Smith and Parsons 30

In addition to training new family medicine graduates in PoCUS, there should also be a concerted effort by various entities, from rural communities/hospitals to health authorities to residency training programs, to encourage existing rural physicians to receive training in PoCUS. This can include subsidies for physicians to attend PoCUS courses as well as moving these courses from tertiary centres to rural sites. These costs can be justified by the savings seen when PoCUS is used. Although financial data is lacking for the ED setting, Testa et al. (2015) performed an economic analysis of bedside ultrasonography use in the internal medicine department that demonstrated overall cost savings after 734 ultrasound examinations had been performed, which occurred after 406 days of use.Reference Testa, Francesconi and Giannuzzi 31

Another possible solution is the implementation of telesonography, whereby a rural health care provider untrained in ultrasound is coached remotely in real-time by a trained physician to produce images and guide patient care. This was first piloted by the National Aeronautics and Space Agency (NASA) at the International Space Station before being tested terrestrially.Reference Pian, Gillman and McBeth 32 Assuming instant availability of a trained physician at any time to “tele-mentor,” this method could be both accurate and feasible.Reference Song, Shin and Hong 33 - Reference Dyer, Cusden and Turner 39 However, limitations include mentor availability, a need for high-bandwidth Internet or cellular connections to maintain image quality, and technical problems such as image freezing.Reference Dyer, Cusden and Turner 39 , Reference Paulus and Thompson 40 Its effectiveness in clinical use has not yet been studied in rural Canada. In fact, one of our authors (KS) can confirm that in Nunavut, neither high-bandwidth Internet nor data-capable cellular connections are available.

CONCLUSION

Despite the numerous benefits of PoCUS, there have been many challenges in translating its use to rural EDs. Recent surveys highlight multiple reasons for this, including a lack of available hardware, lack of physician training, lack of funding, an inability to maintain learned skills, and lack of quality assurance. Potential solutions include expanding residency training in ultrasound skills, extending funding for PoCUS training to rural physicians already in practice, and creating telesonography training for rural physicians. With these barriers identified and solutions proposed, corrective measures must be taken to ensure that the benefits of PoCUS are extended to patients in rural Canada where, arguably, it has the greatest potential for benefit when access to advanced imaging is not readily available.

Competing interests: None declared.

References

1. Statistics Canada. Canada’s rural population since 1851; 2011. Available at: http://www12.statcan.gc.ca/census-recensement/2011/as-sa/98-310-x/98-310-x2011003_2-fra.cfm.Google Scholar
2. Fleet, R, Archambault, P, Plant, J, et al. Access to emergency care in rural Canada: should we be concerned? CJEM 2013;15(4):191-193.CrossRefGoogle ScholarPubMed
3. Fleet, R, Poitras, J, Maltais-Giguere, J, et al. A descriptive study of access to services in a random sample of Canadian rural emergency departments. BMJ Open 2013;3(11):e003876, doi:10.1136/bmjopen-2013-003876.CrossRefGoogle Scholar
4. Joynt, KE, Harris, Y, Orav, EJ, et al. Quality of care and patient outcomes in critical access rural hospitals. JAMA 2011;306(1):45-52.Google ScholarPubMed
5. Canadian Institute for Health Information. How healthy are rural Canadians? An assessment of their health status and health determinants; 2006. Available at: https://secure.cihi.ca/free_products/rural_canadians_2006_report_e.pdf.Google Scholar
6. Reed, MJ, Cheung, LT. Emergency department led emergency ultrasound may improve the time to diagnosis in patients presenting with a ruptured abdominal aortic aneurysm. Eur J Emerg Med 2014;21(4):272-275.CrossRefGoogle ScholarPubMed
7. Blaivas, M, Sierzenski, P, Plecque, D, et al. Do emergency physicians save time when locating a live intrauterine pregnancy with bedside ultrasonography? Am Emerg Med 2000;7:988-993.Google ScholarPubMed
8. Melniker, LA, Lelbner, E, McKenney, MG, et al. Randomized controlled clinical trial of point-of-care, limited ultrasonography for trauma in the emergency department: the first sonography outcomes assessment program trial. Ann Emerg Med 2006;48(3):227-235.CrossRefGoogle ScholarPubMed
9. McLaughlin, R, Collum, N, McGowern, S, et al. Emergency department ultrasound (EDU): clinical adjunct or plaything? Emerg Med J 2005;22(5):333-335.CrossRefGoogle ScholarPubMed
10. Lyon, M, Blaivas, M, Brannam, L. Use of emergency ultrasound in a rural ED with limited radiology services. Am J Emerg Med 2005;23(2):212-214.CrossRefGoogle Scholar
11. Blaivas, M, Kuhn, W, Reynolds, B, et al. Change in differential diagnosis and patient management with the use of portable ultrasound in a remote setting. Wilderness Environ Med 2005;16(1):38-41.CrossRefGoogle Scholar
12. Exadaktylos, A, Sadowski-Cron, C, Mader, P, et al. Decision making in patients with acute abdominal pain at a university and at a rural hospital: does the value of abdominal sonography differ? World J Emerg Surg 2008;3:29.CrossRefGoogle Scholar
13. Nelson, BP, Melnick, ER, Li, J. Portable ultrasound for remote environments, part II: current indications. J Emerg Med 2001;40(3):313-321.CrossRefGoogle Scholar
14. Canadian Association of Emergency Physicians. Use of point-of-care ultrasonography by emergency physicians. CAEP position statement. CJEM 2012;14(2):106-112.CrossRefGoogle Scholar
15. Flynn, CJ, Weppler, A, Theodore, D, et al. Emergency medicine ultrasonography in rural communities. Can J Rural Med 2012;17(3):99-104.Google ScholarPubMed
16. Warren, Z, Smith, A. The need for expanded point-of-care ultrasound training in rural emergency departments across Newfoundland and Labrador [abstract]. CJEM 2013;15(Suppl 1):S69.Google Scholar
17. Léger, P, Fleet, R, Maltais-Giguère, J, et al. A majority of rural emergency departments in the province of Quebec use point-of-care ultrasound: a cross-sectional survey. BMC Emerg Med 2015;15:36.CrossRefGoogle ScholarPubMed
18. Talley, BE, Ginde, AA, Raja, AS, et al. Variable access to immediate bedside ultrasound in the emergency department. West J Emerg Med 2011;12(1):96-99.Google ScholarPubMed
19. Bellows, B, Totten, J, Shah, S, et al. Perceived barriers in the use of point-of-care ultrasound in the WWAMI Region. J Emerg Med Crit Care 2015;1(1):4.Google Scholar
20. Woo, MY, Frank, JR, Lee, AC. Point-of-care ultrasonography adoption in Canada: using diffusion theory and the Evaluation Tool for Ultrasound Skills Development and Education (ETUDE). CJEM 2014;16(5):345-351.CrossRefGoogle ScholarPubMed
21. Alexander, R. Emergency ultrasound in Canada. UBCMJ 2013;5(1):19-21.Google Scholar
22. Emergency department targeted ultrasound interest group. Canadian Association of Emergency Physicians. Emergency department targeted ultrasound: 2006 update. CJEM 2006;8(3):170-171.CrossRefGoogle Scholar
23. Chang, SD, Munk, PL. The changing landscape of radiology: ultrasound training for nonradiologists. Can Assoc Radiol J 2014;65(1):1.CrossRefGoogle ScholarPubMed
24. Ross, P, Bromley, M, Carter, J, et al. The view from the other side. Can Assoc Radiol J 2014;65(3):287-288.CrossRefGoogle ScholarPubMed
25. Blaivas, M, Pawl, R. Analysis of lawsuits filed against emergency physicians for point-of-care emergency ultrasound examination performance and interpretation over a 20-year period. Am J Emerg Med 2012;30(2):338-341.CrossRefGoogle Scholar
26. Stolz, L, O’Brien, KM, Miller, ML, et al. A review of lawsuits related to point-of-care emergency ultrasound applications. West J Emerg Med 2015;16(1):1-4.CrossRefGoogle ScholarPubMed
27. Kim, DJ, Theoret, J, Liao, MM, et al. The current state of ultrasound training in Canadian emergency medicine programs: perspectives from program directors. Acad Emerg Med 2012;19(9):1073-1078.CrossRefGoogle ScholarPubMed
28. Schmitz, D, Crouse, B, Epperly, T, et al. Rural practice: graduate medical education for (Position Paper). American Academy of Family Physicians; 2013. Available at: http://www.aafp.org/about/policies/all/rural-practice.html.Google Scholar
29. Hall, JWW, Holman, H, Bornemann, P, et al. Point-of-care ultrasound in family medicine residency programs: a CERA study. Fam Med 2015;47(9):706-711.Google ScholarPubMed
30. Micks, T, Smith, A, Parsons, M, et al. Point-of-care ultrasonography training for rural family medicine residents – its time has arrived. Can J Rural Med 2016;21(1):28-29.Google ScholarPubMed
31. Testa, A, Francesconi, A, Giannuzzi, R, et al. Economic analysis of bedside ultrasonography (US) implementation in an internal medicine department. Intern Emerg Med 2015;10(8):1015-1024.CrossRefGoogle Scholar
32. Pian, L, Gillman, LM, McBeth, PB, et al. Potential use of remote telesonography as a transformational technology in underresourced and/or remote settings. Emerg Med Int 2013;2013:986160.CrossRefGoogle ScholarPubMed
33. Song, KJ, Shin, SD, Hong, KJ, et al. Clinical applicability of real-time, prehospital image transmission for FAST (focused assessment with sonography for trauma). J Telemed Telecare 2013;19(8):450-455.CrossRefGoogle ScholarPubMed
34. Nelson, BP, Melnick, ER, Li, J. Portable ultrasound for remote environments, part I: feasibility of field deployment. J Emerg Med 2011;40(2):190-197.CrossRefGoogle ScholarPubMed
35. Levine, AR, McCurdy, MT, Zubrow, MT, et al. Tele-intensivists can instruct non-physicians to acquire high-quality ultrasound images. J Crit Care 2015;30(5):871-875.CrossRefGoogle ScholarPubMed
36. Crawford, I, McBeth, PB, Mitchelson, M, et al. How to set up a low cost tele-ultrasound capable videoconferencing system with wide applicability. Crit Ultrasound J 2012;4:13.CrossRefGoogle Scholar
37. Boniface, KS, Shokoohi, H, Smith, ER, et al. Tele-ultrasound and paramedics: real-time remote physician guidance of the focused assessment with sonography for trauma examination. Am J Emerg Med 2011;29(5):477-481.CrossRefGoogle ScholarPubMed
38. Biegler, N, McBeth, PB, Tiruta, C, et al. The feasibility of nurse practitioner-performed telementored lung telesonography with remote physician guidance – ‘a remote virtual mentor.’ Crit Ultrasound J 2013;5(1):5.CrossRefGoogle ScholarPubMed
39. Dyer, D, Cusden, J, Turner, C, et al. The clinical and technical evaluation of a remote telementored telesonography system during the acute resuscitation and transfer of the injured patient. J Trauma 2008;65(6):1209-1216.Google ScholarPubMed
40. Paulus, YM, Thompson, NP. Inexpensive, real-time tele-ultrasound using a commercial, web-based video streaming device. J Telemed Telecare 2012;18(4):185-188.CrossRefGoogle Scholar
Figure 0

Table 1 Approximate cost of point-of-care ultrasound training courses