"Harvey" mannequin

Harvey
Inventor Michael Gordon MD
Launch year 1968
Company University of Miami
Availability Currently Available
Current supplier Laerdal Corporation
http://www.gcrme.miami.edu/#/harvey-major-changes

Harvey was one of the earliest medical simulators available for training of health care professionals.[1] Harvey was created in 1968 by Dr. Michael Gordon at the University of Miami. Harvey is currently sold by the Laerdal Corporation.[2]

Contents

Background

Considered one of the groundbreaking products in medical simulation, the cardiopulmonary patient simulator Harvey provides a method of standardized testing for real-time procedures, and skills of the trainee, usually a medical student or resident.[1][3]

First demonstrated in 1968, the Harvey simulator is a mannequin that performs more than 25 different cardiac functions of the human body, varying blood pressure, breathing, pulse, heart sounds and heart murmurs.[1][4][5] As years have passed, Harvey has been upgraded with the addition of more advanced cardiac functions, with the intention of creating a general and also in-depth program in cardiology.[1]

Harvey is used to teach all levels of medical education. For beginners, the simulator is used to teach blood pressure measurement techniques and help students recognize a heart murmur. For more senior level medical students, Harvey can mimic heart sound variation with respiration, along with a variety of cardiac issues, such as carotid or jugular venous pulsations.[6]

Medical students and cardiologists are not the only people who use mannequins such as Harvey to learn bedside techniques. Other specialties, such as anesthesiology,[4] internal medicine, and Emergency Medicine,[7] have also seen benefit from the trainer. Combat medics and other military personnel also use this technology to improve their skills.[8]

Educational rationale

The Harvey Simulator is a tool for medical education. Harvey was created mainly to improve cardiovascular bedside skills in medical personnel. By mimicking the basic cardiac functions of the human body, Harvey provides a much more realistic training exercise than a traditional classroom lecture.[1] By removing the risk of working on a real patient, simulators prepare medical students, or anyone else who uses the device, for real-world situations.[1][9]

As the medical world becomes more complex, more demand is placed on the need for training techniques that do not rely upon living patients, and Harvey is one of the answers to this demand.[5] It and other similar simulators are very effective teaching tools, since medical students are more willing to attempt to learn on a mannequin than on a patient volunteer, and this saves both the teacher and the student valuable time.[7][10]

Studies with medical students have shown a significant difference between cardiology elective scores for students who used Harvey and students who did not.[11]

History

The Harvey mannequin was named after W. Proctor Harvey, a physician at Georgetown University and mentor of the Mannequin’s creator, Dr. Michael Gordon.[1][6][12]

Before the Harvey simulator, there were other models such as Resusci Anne, designed to teach mouth-to-mouth ventilation, which did not actually simulate much of anything, and the lesser known Sim One, one of the first computer-driven simulators designed to simulate an entire human patient.[1]

Originally, three Harvey simulators were created, each representing a different disease. Since then, Harvey has been advanced to the point where it can simulate multiple diseases.[6]

Harvey's inner functions went though three main stages of development. The prototype used telephone relays and a four track tape to create heart movement and sounds, respectively. The first commercial model used a series of cams and levers instead of telephone relays, but kept the 4-track tape recordings for sound. When the manufacturer of the tape recorder (Ampro Corp) went out of business, a sound card was integrated to mimic heart sounds. The third and current version of this simulator uses a servo motor and a sound card to mimic the cardiovascular functions of the human body.[6][13][14]

The first version of Harvey cost around $100,000, but the upgrades of a sound card and a servo motor cut the cost to around $50,000.[12][15]

Along with the second version of Harvey came a set of slides to show images of echoes and other medical imaging pieces helpful when diagnosing the disease. These slide programs were around 1998 replaced with software that allowed for video recordings. This software came in 1985, around the time of the first aortic stenosis, and was designed around that case. Part of diagnosing aortic stenosis is listening to sounds in the neck, which in the first Harvey version was not possible because it had no neck sounds.[16] The software also contains the images and videos from the original slide programs, along with the history of the patient.[15]

Description

The current version of the Harvey simulator can mimic six different breath sounds, nine different cardiac auscultation areas, 30 different cardiac diseases, and 12 digitally driven impulses. The amplitude and intensity of the heartbeat is changeable.[2] The trainees utilize a built-in stethoscope to listen to the sounds. Trainees may also manually palpate the pulses.

When using Harvey, trainees also use the slide programs, which provide additional sources of instruction by giving patient history, examples of laboratory findings from real patients who had the disease, as well as therapeutic decisions, pathologic data, and epidemiological data. Slide programs have since been replaced with computer programs that provide video instead of still pictures.[17]

Both the hardware and the software for this simulator were developed at the Medical Training and Simulation Laboratory at the University of Miami School of Medicine.[13]

References

  1. ^ a b c d e f g h Cooper Jeffery B, Taqueti VR (2008-11). "A brief history of the development of mannequin simulators for clinical education and training". Postgrad Med J. 84 (997): 563–570. doi:10.1136/qshc.2004.009886. PMID 19103813. http://pmj.bmj.com/content/84/997/563.long. Retrieved 2011-05-18. 
  2. ^ a b Staff. "Harvey the Cardiopulmonary Patient Simulator". University of Miami. http://www.laerdal.com/doc/172/Harvey-The-Cardiopulmonary-Patient-Simulator. Retrieved 2011-05-18. 
  3. ^ Rosen, Katherine R (2008-06). "The history of Medical Simulation". J Crid Care 23 (2): 157–166. doi:10.1016/j.jcrc.2007.12.004. PMID 18538206. http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B7590-4SNPY8G-5&_user=38557&_coverDate=06%2F30%2F2008&_rdoc=1&_fmt=high&_orig=gateway&_origin=gateway&_sort=d&_docanchor=&view=c&_acct=C000004358&_version=1&_urlVersion=0&_userid=38557&md5=20c9aef6045bdee6365518a0a3acc364&searchtype=a. Retrieved 2011-05-18. 
  4. ^ a b Wong SH, Ng KF, Chen PP (2002). "The application of clinical simulation in crisis management training". Hong Kong Med J. 8 (2): 131–135. PMID 11937668. http://www.hkmj.org/abstracts/v8n2/131.htm. Retrieved 2011-05-18. 
  5. ^ a b Maran NJ, Glavin RJ (2003-11). "Low- to high-fidelity simulation - a continuum of medical education?". Med Educ. 37 (Suppl): 22–28. doi:10.1046/j.1365-2923.2003.01408.x. PMID 14641635. 
  6. ^ a b c d Issenburg SB, Scalese RJ (2008). "Simulation in Healthcare Education". Perspect Biol Med. 51 (1): 31–46.. PMID 18192764. http://muse.jhu.edu/journals/perspectives_in_biology_and_medicine/v051/51.1issenberg.html. Retrieved 2011-05-18. 
  7. ^ a b Oddone EZ, Waugh Robert A, Samsa G, Corey R, Feussner JR (1993-10). "Teaching cardiovascular examination skills: results from a randomized control trial.". Am J Med. 95 (4): 389–396. doi:10.1016/0002-9343(93)90308-C. PMID 8213871. http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6TDC-4CM9480-4C&_user=38557&_coverDate=10%2F31%2F1993&_rdoc=1&_fmt=high&_orig=gateway&_origin=gateway&_sort=d&_docanchor=&view=c&_acct=C000004358&_version=1&_urlVersion=0&_userid=38557&md5=e6cc61cef7ea04feda83eb95471021ae&searchtype=a. Retrieved 2011-05-18. 
  8. ^ "Local soldiers get realistic combat medical training". WTAM 1100 Radio Cleveland. 2011-05-22. http://www.wtam.com/cc-common/news/sections/newsarticle.html?feed=122520&article=8605886. Retrieved 2011-05-23. 
  9. ^ Kinney, David (1999-08-01). "Is It a Standard Man, or Stan D. Ardman?". LA Times. http://articles.latimes.com/1999/aug/01/news/mn-61471. Retrieved 2011-05-24. 
  10. ^ Woolliscroft JO, Calhoun JG, Tenhaken JD, Judge RD (1987). "Harvey: the impact of a cardiovascular teaching simulator on student skill acquisition". Med Teach. 9 (1): 53–57. PMID 3669990. 
  11. ^ Issenburg SG, McGaghie WC, Hart IR, Mayer JW, Felner JM, Petrusa Emil R, Waugh Robret A, Brown DD, Safford RR, Gessner IH, Gordon DL, Ewy GA (1999-10). "Simulation technology for health care professional skills training assessment". JAMA 282 (9): 861–866. PMID 10478693. http://jama.ama-assn.org/content/282/9/861.long#ref-24. Retrieved 2011-05-20. 
  12. ^ a b Associated Press (1981-10-31). "Harvey Teaches Students, Doctors About Health Care". The Ledger. 
  13. ^ a b Jones JS, Hunt SJ, Carlson SA, Seamon JP (1997-10). "Assessing bedside cardiologic examination skills using "Harvey", a cardiology patient simulator.". Acad Emerg Med. 4 (10): 980–985. doi:10.1111/j.1553-2712.1997.tb03664.x. PMID 9332631. 
  14. ^ Gordon, Michael (1997). "All New Harvey, Major Changes". University of Miami. http://www.gcrme.miami.edu/#/harvey-major-changes. Retrieved 2011-05-18. 
  15. ^ a b "Personal discussion with Robert Waugh, MD and User:Gene Hobbs, May 20th, 2011". Personal communication (Duke Human Simulation and Patient Safety Center). 2011-05-20. 
  16. ^ Agabegi, Elizabeth D; Agabegi, Steven S. (2008). "Step-Up to Medicine (Step-Up Series)". Chapter 1: Diseases of the Cardiovascular system Section: Valvular Heart Disease (Hagerstwon, MD: Lippincott Williams & Wilkins). ISBN 0-7817-7153-6. 
  17. ^ Cardiology Patient Simulator Harvey Instruction Manual. Maimi, Florida: University of Miami. 1995. pp. I1-III1.