Fundamental Use of Surgical Energy (FUSE): An Essential Educational Program for Operating Room Safety

Fundamental Use of Surgical Energy (FUSE): An Essential Educational Program for Operating Room Safety

 

Stephanie B Jones, MD; Malcolm G Munro, MD, FACOG, FRCS(c);
Liane S Feldman, MD, FACS, FRCS; Thomas N Robinson, MD, MS, FACS;
L Michael Brunt, MD, FACS; Steven D Schwaitzberg, MD, FACS;
Daniel B Jones, MD, MS, FACS; Pascal R Fuchshuber, MD, FACS

Perm J 2017;21:16-050

https://doi.org/10.7812/TPP/16-050
E-pub: 01/13/2017

ABSTRACT

Operating room (OR) safety has become a major concern in patient safety since the 1990s. Improvement of team communication and behavior is a popular target for safety programming at the institutional level. Despite these efforts, essential safety gaps remain in the OR and procedure rooms. A prime example is the use of energy-based devices in ORs and procedural areas. The lack of fundamental understanding of energy device function, design, and application contributes to avoidable injury and harm at a rate of approximately 1 to 2 per 1000 patients in the US. Hundreds of OR fires occur each year in the US, some causing severe injury and even death. Most of these fires are associated with the use of energy-based surgical devices.

In response to this safety issue, the Society of American Gastrointestinal and Endoscopic Surgeons (SAGES) developed the Fundamental Use of Surgical Energy (FUSE) program. This program includes a standardized curriculum targeted to surgeons, other physicians, and allied health care professionals and a psychometrically designed and validated certification test. A successful FUSE certification documents acquisition of the basic knowledge needed to safely use energy-based devices in the OR. By design FUSE fills a void in the curriculum and competency assessment for surgeons and other procedural specialists in the use of energy-based devices in patients.

INTRODUCTION

Adverse events caused by the use of energy-based devices in surgical operating rooms (ORs) are a daily occurrence. Millions of patient interventions occur every year in ORs and procedure suites throughout the US. Many of these invasive procedures carry a substantial risk for the patient and OR team and can lead to potentially serious complications. A large body of evidence exists on human factors underlying those risks. Many safety programs recently have been developed to address risks generated by a lack of human interaction, the increasingly challenging patient disease burden, and inadequate communications within the OR team. Heightened public awareness about safety in the OR has led to the adoption of a variety of performance-improvement programs and tools, including checklists and team training.1 Hospitals have implemented extensive training programs, and physicians and staff are required to learn the skills needed to improve clinical outcomes and optimize patient safety.

Despite these efforts, a large gap in OR safety education and training remains on the topic of safe application of energy-based devices. From the first electrosurgical instrument invented more than 100 years ago to the most modern computer-driven device, serious harm and death of patients can result from their inappropriate use because of a lack of basic understanding of design, function, and application. Hundreds of OR fires, patient harm resulting from interference with implantable cardiac devices, and latent, life-threatening intraabdominal injuries could be avoided if this gap were addressed.2-13

Historical Perspective

For millennia the only available energy device for physicians was cautery. Cautery is the direct application of heat to tissue and has been used to attain hemostasis and destroy tumors since 3000 BC.14 Approximately 100 years ago the first surgical instruments based on radiofrequency (RF) electrical energy were developed for surgical practice. The best known and one of the earliest devices successfully deployed for clinical use was developed by William T Bovie, who combined a “high-voltage” RF generator for fulguration with a lower-voltage generator designed to create a waveform that could be used to transect tissue.15 By the end of the last century, isolated RF circuits and microprocessor-enhanced instrumentation were introduced, which have dramatically improved both safety and functionality for processes such as tissue transection and the sutureless sealing of relatively large blood vessels. Surgical and technologic innovations have generated an ever-increasing demand for, and number of, energy-based surgical devices from multiple vendors with a wide range of price and cost points.

This large and diverse armamentarium of energy-based devices has also drastically increased the susceptibility of surgeons and other proceduralists to inadvertently cause harm to patients. The incidence of injuries related to energy-based devices during laparoscopic procedures is estimated at 1 to 2 per 1000 patients, which translates into thousands of avoidable patient injuries every year in the US alone.4 Unrecognized bowel and major vascular injuries—mostly because of thermal energy—constitute many of these events, with serious consequent morbidity and mortality.4,16-19

In the 1970s, several cases of electrocution in the OR were published related to accidents with electrosurgical equipment.20,21 Although dramatic and mortal injuries from electrocution are exceedingly rare in modern ORs, intestinal thermal injuries and fires caused by energy-based devices are not uncommon. In 2010, a well-known US senator succumbed to an unrecognized intestinal injury that occurred during a routine laparoscopic cholecystectomy.22 The same year a young woman undergoing excision of a benign skin lesion on the face sustained second-degree burns from an OR fire, apparently scarring her for life.23

According to a recent study, laparoscopic bowel injuries occur at an overall rate of 0.85%, nearly 1 in 100 cases, of which one-third are unrecognized at the time they occur.24 Overall mortality is 3.13% and jumps to 8% for unrecognized injuries. One-third of these injuries is directly related to the use of surgical energy-based devices.24 Today’s OR monitors and tables, anesthesia machines, and other electrical equipment are manufactured according to strict safety standards. These technical advances have not been able to close a major knowledge gap regarding the potential risks of energy-based devices in and out of the OR among the primary users: surgeons, gastroenterologists, and interventional radiologists. We must recognize that almost all the aforementioned accidents and injuries were completely preventable.

Initial Response

Since the 1990s, health care professionals and surgical societies both in the US and internationally began responding to these safety issues. Specific complications associated with electrosurgical devices and the risks involved in their use were described. A first attempt was made to develop practical educational and engineering solutions to the described complications.25-29 These early studies included a survey conducted under the auspices of the American College of Surgeons to assess the complication rate associated with the use of electrosurgical devices.30 Notably, the survey showed that most surgeons were unfamiliar with the optimal use of electrosurgical instruments and that they used inappropriately high power settings.30 The Consortium on Electrosurgical Safety During Laparoscopy, convened in 1997, published recommendations that emphasized the acute need for training and education during residency and beyond,31 and the Association of periOperative Registered Nurses published its recommended practices for electrosurgery in 2005.32 Unfortunately, these important and timely initiatives had little impact on surgical practice at the time.

Fundamental knowledge about the correct use and inherent risks of energy-based devices in surgical practice as well as in radiologic and gastrointestinal interventions is still not systematically taught. In contrast to anesthesia and nursing textbooks, educational material that teaches surgeons about the risks and proper use of energy-based devices is lacking or inadequate. There is no specific requirement for surgeons to train on energy-based devices or to obtain certification that validates their knowledge of device-related safety issues.

NEEDS ASSESSMENT

In 2011 the Society of American Gastrointestinal and Endoscopic Surgeons (SAGES) developed and ran a postgraduate continuing medical education course on energy-based surgical devices. This comprehensive lecture and hands-on course was the first didactic effort designed to teach surgeons and other health care professionals the fundamentals of the use of energy-based devices in the OR and gastrointestinal endoscopy suite. An 11-item, multiple-choice, pre- and posttest encompassing critical knowledge points was administered to course participants and SAGES leadership.33

The survey results were sobering. The median number of correct answers was 6.5 of 11 (59%) for the SAGES leadership group. These SAGES leaders did not know how to correctly handle a fire on the patient (31%), could not identify the electrosurgical device least likely to interfere with a pacemaker (31%), did not know that thermal injury could extend beyond the jaws of a bipolar instrument (13%), and thought a dispersive electrode should be cut to fit a child (10%).33,34 Results among course participants and surgical trainees were similar to each other.33,34 This finding demonstrated that surgical “experts” do not necessarily have greater knowledge of energy-based surgical devices compared with nonexpert surgeons or even junior trainees. These results highlight the need to educate trainees and surgeons in the knowledge and understanding of safe and appropriate use of energy-based surgical devices.

TRAINING PROGRAM FOR ENERGY-BASED SURGICAL DEVICES

The SAGES leadership was in a unique position to recognize that a rigorous and standardized training program on energy-based devices was needed as a greater number of potentially harmful devices were introduced into routine clinical practice. The timing of this initiative could not have been more appropriate for three reasons:

  1. rapid innovation in the OR and procedure suite
  2. rising national awareness of OR fires
  3. transformation of the relationship between industry and physicians.

Rapid innovation in the OR and procedure suite: Today’s ORs and procedure suites are sophisticated computer-driven control centers of highly complex “point-of-care” delivery. Electronic medical records, anesthetic workstations, high-definition monitors, recording equipment, and a multitude of complex energy-based surgical devices can quickly overwhelm an OR team that is potentially unfamiliar with the basic function and designs of these instruments.

Rising national awareness of OR fires: Hundreds of preventable OR fires occur every year in the US. The ingredients of this potential disaster are present every time an operation or procedure is undertaken in a patient: the presence of fuel and an oxidizer with a spark from an energy-based device. Despite the distribution of educational materials in multiple formats highlighting the dangers of OR fires, they still occur. The US Food and Drug Administration has made prevention of OR fires one of its most important patient safety goals, but there still is no common national educational program to teach fire prevention in either the OR or the procedure suite.

Transformation of the relationship between industry and physicians: Despite many changes in health care, such as industrial relationships and the implementation of regulations and barriers, the introduction of new surgical devices into the OR remains an informal process mostly governed by industry representatives. The required knowledge regarding the use of new devices is still disseminated through industry-sponsored courses or the private interaction between the industry representative and the physicians. No standards are set to determine whether a surgeon is ready and able to use the new device safely. The Physician Payments Sunshine Act, Section 6002 of The Patient Protection and Affordable Care Act of 201035 and other regulations have placed appropriate barriers between physicians and industry influence. However, without ready access to industry representatives, it is difficult for surgeons and nurses to learn how to use new devices. Fundamental Use of Surgical Energy (FUSE) is beginning to address important questions raised by this shift away from industry-centered instruction:

  • Where will the training to master new energy-based surgical devices come from?
  • How should appropriate training and certification be structured?
  • Should there be a standard approach for how energy-based devices are introduced to those responsible for using and operating the equipment?
  • Who will create these standards?
  • Who will create a curriculum covering the function and safety profiles of new equipment?
  • How will we mandate and pay for fire safety training?

It has become clear to all involved that perhaps the best solution is a national, multidisciplinary educational program, independent of industry, that includes a validated assessment. Only in this way can we address the baseline knowledge gap as well as prepare for the introduction of new devices in a way that maximizes efficacy, efficiency, and, most importantly, patient safety.

FUNDAMENTAL USE OF SURGICAL ENERGY EDUCATIONAL PROGRAM

The FUSE educational program was created by SAGES in partnership with the Association of periOperative Registered Nurses, the American Association of Gynecologic Laparoscopists, and the American Urologic Association. Members of the FUSE team include a variety of general and subspecialty surgeons, nurses, anesthesiologists, gynecologists, and engineers.

The FUSE program has three main components (Figure 1): 1) A standardized educational curriculum that is online-based and free of charge (Figure 2); 2) continuing medical education credits or continuing education units that can be obtained as part of the online curriculum for a small fee; and 3) a high-stakes certification examination that meets rigorous psychometric and accreditation standards. This voluntary, validated, and proctored examination is administered at one of the many test centers across the nation. Successful completion of this test provides verification that the participant has the basic knowledge necessary to safely use energy-based devices in the OR and/or procedure room. If the participant fails the test, it can be retaken without additional charge. The SAGES Manual on the Fundamental Use of Surgical Energy (FUSE), a handbook published in 2012, is an additional offline resource.36

The FUSE online curriculum37 includes ten sections that teach the basic principles underlying energy-based surgical devices and the application of those principles to safe and effective use of the devices (see Sidebar: Ten Sections of the Fundamental Use of Surgical Energy Online Curriculum). For example, Section 1, Fundamentals of Electrosurgery, starts with the basic physics concepts, nomenclature, and the difference between “cut” and “coag” (coagulation), monopolar vs bipolar RF instrumentation, and active vs dispersive electrodes. The different tissue effects—desiccation, coagulation, and fulguration—achieved by the physical effects of temperature and alternating current on cells and tissue are explained, laying the groundwork for a discussion of specific energy applications. Section 2 describes a crucial safety issue, current diversion in the form of direct and capacitive coupling and insulation failure, as well as prevention and response to OR fires. A similar format emphasizing core principles and safe application is used in the subsequent device sections: monopolar RF, bipolar RF, ultrasonic energy, RF ablation, microwave, and devices designed for use in the alimentary tract. Special considerations for use of energy-based devices in pediatric patients and in patients with other medical devices, most notably cardiac implantable electronic devices, are addressed as well. The FUSE manual also contains supplemental hands-on chapters describing in detail how to set up “live” demonstration and teaching stations.36

Fundamental Use of Surgical Energy (FUSE): An Essential Educational Program for Operating Room Safety

The FUSE curriculum includes an optional structured interactive benchtop simulation component that is available on demand from SAGES. This goal-directed, hands-on training session has been shown to improve learning and retention of key knowledge points in surgical trainees three months after the session.38 It also includes a novel virtual reality-based simulation station.39

The FUSE curriculum was designed to provide surgeons with the knowledge they need to pass the FUSE certifying examination. The curriculum and examination underwent a development process specifically designed to meet the stringent design and validation requirements for professional certification.40 Psychometricians conducted an iterative process with 15 FUSE content experts, defining the competencies to be taught and tested. A total of 72 learning objectives were identified for the entire curriculum, 2 to 20 per section. Table 1 lists the objectives from Sections 1 and 2. Leaders from SAGES, the Association of periOperative Registered Nurses, and the American Association of Gynecologic Laparoscopists were used to rank each objective, which in turn helped determine the number of test items for each objective on the written examination. Draft versions of the examination underwent further iterative scrutiny by the FUSE committee, and beta testing was completed in April 2014. The FUSE certification test is now available to all health care professionals at 30 national and international FUSE test centers. More than 400 practicing surgeons and residents are certified.

Until standard mandatory surgical education curricula address the teaching of safe use of energy devices, FUSE remains one of the most comprehensive voluntary options for surgical training program administrators to add this essential component of surgical teaching to their curriculum. The FUSE program office at SAGESa welcomes any request to establish FUSE testing centers at individual hospitals and teaching institutions and will guide you through the process.

Fundamental Use of Surgical Energy (FUSE): An Essential Educational Program for Operating Room Safety

Fundamental Use of Surgical Energy (FUSE): An Essential Educational Program for Operating Room Safety

Fundamental Use of Surgical Energy (FUSE): An Essential Educational Program for Operating Room Safety

CONCLUSION

The FUSE program was developed to provide a standardized educational tool for all physicians and staff who interface in the OR and procedural and interventional suites to bridge a knowledge gap in best-practice use of energy devices. It encompasses the safe and appropriate use of the most common energy devices employed in the operative and endoscopic field, as well as their contribution to OR fire risk and impact on implantable electronic devices. FUSE is the first educational tool of its kind that addresses patient and OR team safety for energy devices.

Ongoing development will ensure that the FUSE program will continue to evolve and fill the curricular, regulatory, safety, and competency assessment needs that exist for the use of energy devices by surgeons, endoscopists, anesthesiologists, and nurses worldwide.

a Contact Jessica Mischna, FUSE Program Manager, SAGES, 11300 W Olympic Blvd, Suite 600, Los Angeles, CA 90064; phone: 310-437-0544 extension 139; fax: 310-437-0585; e-mail: jessica@fuseprogram.org.

Disclosure Statement

The author(s) have no conflicts of interest to disclose.

Acknowledgements

Fundamental Use of Surgical Energy (FUSE) is funded by unrestricted educational grants to the Society of American Gastrointestinal and Endoscopic Surgeons (SAGES) FUSE Consortium Education Fund from the SAGES Educational & Research Foundation, Los Angeles, CA; Covidien (now Medtronic Minimally Invasive Therapies), Minneapolis, MN; and Olympus America Inc, Center Valley, PA. All authors are members of the SAGES FUSE Task Force.

The authors would like to thank Jessica Mischna, Sallie Matthews, Brenda Castaneda, and Carla Bryant from the SAGES headquarters for their invaluable support of the FUSE program and the members of the SAGES FUSE Task Force for their contributions.

Kathleen Louden, ELS, of Louden Health Communications provided editorial assistance.

How to Cite this Article

Jones SB, Munro MG, Feldman LS, et al. Fundamental use of surgical energy (FUSE): An essential educational program for operating room safety. Perm J 2017;21:16-050. DOI: https://doi.org/10.7812/TPP/16-050.

References
1.    Banki F, Ochoa K, Carrillo ME, et al. A surgical team with focus on staff education in a community hospital improves outcomes, costs and patient satisfaction. Am J Surg 2013 Dec;206(6):1007-14. DOI: https://doi.org/10.1016/j.amjsurg.2013.08.015.
    2.    ECRI Institute announces its top 10 health technology hazards for 2012 [Internet]. Plymouth Meeting, PA: ECRI Institute; 2011 Nov 8 [cited 2014 Apr 14]. Available from: www.ecri.org/press/Pages/Top-10-Health-Technology-Hazards-2012.aspx.
    3.    Govekar HR, Robinson TN, Varosy PD, et al. Effect of monopolar radiofrequency energy on pacemaker function. Surg Endosc 2012 Oct;26(10):2784-8. DOI: https://doi.org/10.1007/s00464-012-2279-3.
    4.    Nduka CC, Super PA, Monson JR, Darzi AW. Cause and prevention of electrosurgical injuries in laparoscopy. J Am Coll Surg 1994 Aug;179(2):161-70.
    5.    Sankaranarayanan G, Resapu RR, Jones DB, Schwaitzberg S, De S. Common uses and cited complications of energy in surgery. Surg Endosc 2013 Sep;27(9):3056-72. DOI: https://doi.org/10.1007/s00464-013-2823-9. Erratum in: Surg Endosc 2013 Dec;27(12):4758. DOI: https://doi.org/10.1007/s00464-013-3221-z.
    6.    Agarwal BB, Gupta M, Agarwal S, Mahajan K. Anatomical footprint for safe laparoscopic cholecystectomy without using any energy source: A modified technique. Surg Endosc 2007 Dec;21(12):2154-8. DOI: https://doi.org/10.1007/s00464-007-9320-y. Erratum in: Surg Endosc. 2010 Jun;24(6):1514. DOI: https://doi.org/10.1007/s00464-009-0717-7.
    7.    Gol M, Kizilyar A, Eminoglu M. Laparoscopic hysterectomy with retroperitoneal uterine artery sealing using LigaSure: Gazi hospital experience. Arch Gynecol Obstet 2007 Oct;276(4):311-4. DOI: https://doi.org/10.1007/s00404-007-0353-1.
    8.    Kriplani A, Garg P, Sharma M, Lal S, Agarwal N. A review of total laparoscopic hysterectomy using LigaSure uterine artery-sealing device: AIIMS experience. J Laparoendosc Adv Surg Tech A 2008 Dec;18(6):825-9. DOI: https://doi.org/10.1089/lap.2008.0034.
    9.    Polychronidis A, Tsaroucha AK, Karayiannakis AJ, Perente S, Efstathiou E, Simopoulos C. Delayed perforation of the large bowel due to thermal injury during laparoscopic cholecystectomy. J Int Med Res 2005 May-Jun;33(3):360-3. DOI: https://doi.org/10.1177/147323000503300312.
    10.    Siperstein A, Garland A, Engle K, et al. Local recurrence after laparoscopic radiofrequency thermal ablation of hepatic tumors. Ann Surg Oncol 2000 Mar;7(2):106-13. DOI: https://doi.org/10.1007/s10434-000-0106-x.
    11.    Darai E, Ackerman G, Bazot M, Rouzier R, Dubernard G. Laparoscopic segmental colorectal resection for endometriosis: Limits and complications. Surg Endosc 2007 Sep;21(9):1572-7. DOI: https://doi.org/10.1007/s00464-006-9160-1.
    12.    Peterson HB, Ory HW, Greenspan JR, Tyler CW Jr. Deaths associated with laparoscopic sterilization by unipolar electrocoagulating devices, 1978 and 1979. Am J Obstet Gynecol 1981 Jan 15;139(2):141-3. DOI: https://doi.org/10.1016/0002-9378(81)90435-x.
    13.    Willson PD, van der Walt JD, Moxon D, Rogers J. Port site electrosurgical (diathermy) burns during surgical laparoscopy. Surg Endosc1997 Jun;11(6):653-4. DOI: https://doi.org/10.1007/s004649900414.
    14.    Schwaitzberg SD. Evolution and revolutions in surgical energy. In: Feldman LS, Fuchshuber PR, Jones DB, editors. The SAGES manual on the fundamental use of surgical energy (FUSE). New York, NY: Springer; 2012. p 3-14.
    15.    O’Connor JL, Bloom DA. William T. Bovie and electrosurgery. Surgery 1996 Apr;119(4):390-6. DOI: https://doi.org/10.1016/s0039-6060(96)80137-1.
    16.    Cormier B, Nezhat F, Sternchos J, Sonoda Y, Leitao MM Jr. Electrocautery-associated vascular injury during robotic-assisted surgery. Obstet Gynecol 2012 Aug;120(2 Pt 2):491-3. DOI: https://doi.org/10.1097/aog.0b013e31825a6f60.
    17.    LeBlanc KA, Elieson MJ, Corder JM 3rd. Enterotomy and mortality rates of laparoscopic incisional and ventral hernia repair: A review of the literature. JSLS 2007 Oct-Dec;11(4):408-14.
    18.    Bishoff JT, Allaf ME, Kirkels W, Moore RG, Kavoussi LR, Schroder F. Laparoscopic bowel injury: Incidence and clinical presentation. J Urol 1999 Mar;161(3):887-90. DOI: https://doi.org/10.1097/00005392-199903000-00039.
    19.    Market engineering research for the U. S. market for general surgery laparoscopy access and closure instruments. Medical and healthcare marketplace guide, 1999 [Internet]. London, United Kingdom: Frost & Sullivan; 1999 [cited 2016 Aug 11]. Available from: www.dialogselect.com/business/cgi/present.
    20.    Chambers JJ, Saha AK. Electrocution during anaesthesia. Anaesthesia 1979 Feb;34(2):173-5. DOI: https://doi.org/10.1111/j.1365-2044.1979.tb06273.x.
    21.    Wills JH, Ehrenwerth J, Rogers D. Electrical injury to a nurse due to conductive fluid in an operating room designated as a dry location. Anesth Analg 2010 Jun 1;110(6):1647-9. DOI: https://doi.org/10.1213/ane.0b013e3181a89627.
    22.    Hefling K. Congressman: Murtha’s intestine damaged in surgery. The Washington Post 2010 Feb 8.
    23.    Carroll L. Operating room fires hurt hundreds each year [Internet]. New York, NY: Today.com; updated 2011 May 11 [cited 2016 May 7]. Available from: www.today.com/id/45117440/ns/today-today_health/t/operating-room-fires-hurt-hundreds-each-year/.
    24.    Cassaro S. Delayed manifestations of laparoscopic bowel injury. Am Surg 2015 May;81(5):478-82.
    25.    Voyles CR, Tucker RD. Education and engineering solutions for potential problems with laparoscopic monopolar electrosurgery. Am J Surg 1992 Jul;164(1):57-62. DOI: https://doi.org/10.1016/s0002-9610(05)80648-8.
    26.    Tucker RD, Voyles CR. Laparoscopic electrosurgical complications and their prevention. AORN J 1995 Jul:62(1): 51-3, 55, 58-9 passim. DOI: https://doi.org/10.1016/s0001-2092(06)63683-1.
    27.    Harrell GJ, Kopps DR. Minimizing patient risk during laparoscopic electrosurgery. AORN J 1998 Jun;67(6):1194-6, 1199-205. DOI: https://doi.org/10.1016/s0001-2092(06)62606-9.
    28.    Wu MP, Ou CS, Chen SL, Yen EY, Rowbotham R. Complications and recommended practices for electrosurgery in laparoscopy. Am J Surg 2000 Jan;179(1):67-73. DOI: https://doi.org/10.1016/s0002-9610(99)00267-6.
    29.    Alkatout I, Schollmeyer T, Hawaldar NA, Sharma N, Mettler L. Principles and safety measures of electrosurgery in laparoscopy. JSLS 2012 Jan-Mar;16(1):130-9. DOI: https://doi.org/10.4293/108680812X13291597716348.
    30.    Tucker RD. Laparoscopic electrosurgical injuries: Survey results and their implications. Surg Laparosc Endosc 1995 Aug;5(4):311-7.
    31.    Brill AI, Feste JR, Hamilton TL, et al. Patient safety during laparoscopic monopolar electrosurgery—principles and guidelines. Consortium on Electrosurgical Safety During Laparoscopy. JSLS 1998 Jul-Sep;2(3):221-5.
    32.    Recommended practices for electrosurgery. In: AORN. Perioperative standards and recommended practices. 2011 edition. Denver, CO: Association of periOperative Registered Nurses; 2011. p 99-118.
    33.    Feldman LS, Brunt LM, Fuchshuber P, et al; SAGES FUSE Committee. Rationale for the fundamental use of surgical energy (FUSE) curriculum assessment: Focus on safety. Surg Endosc 2013 Nov;27(11):4054-9. DOI: https://doi.org/10.1007/s00464-013-3059-4.
    34.    Feldman LS, Fuchshuber P, Jones DB, Mischna J, Schwaitzberg SD; FUSE (Fundamental Use of Surgical Energy) Task Force. Surgeons don’t know what they don’t know about the safe use of energy in surgery. Surg Endosc 2012 Oct;26(10):2735-9. DOI: https://doi.org/10.1007/s00464-012-2263-y. Erratum in: Surg Endosc 2013 Jan;27(1):349. DOI: https://doi.org/10.1007/s00464-012-2668-7.
    35.    The Patient Protection and Affordable Care Act of 2010. Public Law 111-148, 111th Congress, 124 Stat 119, HR 3590, enacted 2010 Mar 23.
    36.    Feldman LS, Fuchshuber PR, Jones DB, editors. The SAGES manual on the fundamental use of surgical energy (FUSE). New York, NY: Springer; 2012.
    37.    Surgical fundamentals online didactics [Internet]. Los Angeles, CA: Society of American Gastrointestinal and Endoscopic Surgeons; 2002-2016 [cited 2016 Aug 11]. Available from: www.fusedidactic.org.
    38.    Madani A, Watanabe Y, Vassiliou MC, et al. Impact of a hands-on component on learning in the Fundamental Use of Surgical Energy (FUSE) curriculum: A randomized-controlled trial in surgical trainees. Surg Endosc 2014 Oct;28(10):2772-82. DOI: https://doi.org/10.1007/s00464-014-3544-4.
    39.    Allen BF, Schwaitzberg SD, Jones DB, De S. Toward the development of a virtual electrosurgery training simulator. Stud Health Technol Inform 2014;196:11-3.
    40.    Robinson TN, Olasky J, Young P, et al. Fundamental Use of Surgical Energy (FUSE) certification: Validation and predictors of success. Surg Endosc 2016 Mar;30(3):916-24. DOI: https://doi.org/10.1007/s00464-015-4334-3.

Click to join the E-TOC list or text TPJ to 22828. You will receive an e-mail notice with the Table of Contents of each issue.

TPJ20Years

 

The Permanente Journal is celebrating it's 20th anniversary year. We look forward to continuing to bring you more high-quality content during the next 20 years.

Subscriptions

Sponsored by the National Permanente Medical Groups, The Permanente Press publishes The Permanente Journal and books related to Kaiser Permanente and health care.

Circulation

25,000 print readers per quarter, 7,628 eTOC readers, and in 2016, 1.4 million page views on TPJ articles in PubMed from a broad international readership.

Letters

Articles, editorials, letters to the editor, and other material represent the opinion of the authors. Send your comments to permanente.journal@kp.org.


Copyright 2017 The Permanente Journal - Kaiser Permanente. All Rights Reserved.