The SAGES Manual Volume 1 Basic Laparoscopy and Endoscopy PDF

Summary

The SAGES Manual, Volume 1, is a third edition textbook covering basic laparoscopic and endoscopic surgical procedures. It's aimed at surgical residents, students, and experienced surgeons alike, offering a comprehensive guide on minimally invasive techniques. Volume 1 covers procedures generally performed during surgical residency, and Volume 2 focuses on more advanced techniques.

Full Transcript

The SAGES Manual
The SAGES Manual
Volume 1 Basic Laparoscopy
and Endoscopy
Third Edition

Nathaniel J. Soper, MD
Northwestern University Feinberg School of Medicine, Chicago, IL, USA
and

Carol E.H. Scott-Conner, MD, PhD
University of Iowa Hospitals and Clinics, Iowa City, IA, USA

Editors
Editors
Nathaniel J. Soper Carol E.H. Scott-Conner
Department of Surgery Department of Surgery
Northwestern University Feinberg University of Iowa Hospitals
School of Medicine and Clinics
Chicago, IL, USA Iowa City, IA, USA

ISBN 978-1-4614-2343-0 e-ISBN 978-1-4614-2344-7
DOI 10.1007/978-1-4614-2344-7
Springer New York Dordrecht Heidelberg London

Library of Congress Control Number: 2012932411

© Springer Science+Business Media, LLC 2012
All rights reserved. This work may not be translated or copied in whole or in part without
the written permission of the publisher (Springer Science+Business Media, LLC, 233
Spring Street, New York, NY 10013, USA), except for brief excerpts in connection with
reviews or scholarly analysis. Use in connection with any form of information storage and
retrieval, electronic adaptation, computer software, or by similar or dissimilar methodology
now known or hereafter developed is forbidden.
The use in this publication of trade names, trademarks, service marks, and similar terms,
even if they are not identified as such, is not to be taken as an expression of opinion as to
whether or not they are subject to proprietary rights.
While the advice and information in this book are believed to be true and accurate at the
date of going to press, neither the authors nor the editors nor the publisher can accept any
legal responsibility for any errors or omissions that may be made. The publisher makes no
warranty, express or implied, with respect to the material contained herein.

Printed on acid-free paper

Springer is part of Springer Science+Business Media (www.springer.com)
Foreword

As the Society of American Gastrointestinal and Endoscopic Surgeons
completes its 30th year, our commitment to education burns as brightly
as ever. The first SAGES manual was published in 1998. Since then, it
has continued to be a well-organized, clear, and to the point reference in
minimally invasive surgery written by experts in the field and aimed at
the surgical resident. That said, it will also be useful to students and
attending surgeons alike. This third addition of the SAGES manual
reflects the best of what has been a leading reference in minimally
invasive surgery yet at the same time incorporating many new concepts
that have evolved since the second addition. This is mirrored by the
tireless efforts of Carol E.H. Scott Connor, MD who has overseen this
project since its inception and the addition of Ninh T. Nguyen, MD and
Nathanial (Nat) Soper, MD as editors of the third edition. Together, this
team has organized this brilliant reference in the field of minimally
invasive surgery.
Surgical residents and practicing surgeons will find this addition
completely reorganized as the field of minimally invasive surgery
continues to grow. Dividing the manual into two volumes allows for
a convenient method of keeping it handy as well as reorganizing this
book into basic (volume 1) and advanced procedures (volume 2).
Students of history, who recall that SAGES’ roots grew out of flexible
endoscopy, will also no doubt notice the increasing prominence of
flexible endoscopy in this manual. This reflects the rise in interest of
surgeon performed endoscopy as a therapeutic tool complementing
other MIS techniques. Surgical residents interested in a career in
gastrointestinal surgery should pay close attention to the increasing
role that the endoscope will play in their future. While the first two
chapters of this edition of the SAGES manual highlight the roles of
the Fundamentals of Laparoscopic Surgery (FLS) and Maintenance
of Certification (MOC) in the educational process, future editions
will clearly also include information on the Fundamentals of
Endoscopic Surgery (FES) and other key offerings as well.

v
vi Foreword

Even as this book comes to press, controversies concerning optimal
treatment strategies continue to swirl as issues of endoluminal therapies,
surgical robotics, and natural orifice translumenal endoscopic surgery
(NOTES) are debated around the world. Even the issue concerning the
optimal number and size(s) of trocars in our bread and butter commodity
procedure such as laparoscopic cholecystectomy remains unsettled.
Clearly we should get working on the fourth edition.
I have recently been asked if medical texts are destined for the same
desolate fate as ice boxes, typewriters, and mimeographs in the annals of
history, all supplanted by newer technologies. Clearly, the organization
of medical information is evolving rapidly with so much information
now available at our fingertips in digital form. The available “infostream”
is coming at us like water spouting wildly from a fire hose, but amidst all
that data, where do we find truly useful information concisely organized?
I suspect it will be in places such as the SAGES Manual, and yes, this
reference too will be available in a digital format for those who wish to
abandon paper altogether.
Whether on paper or in a digital format, I am sure that you will enjoy
using this reference (at least until the next edition comes out).

Steven D. Schwaitzberg, MD
SAGES President 2011–2012
Cambridge, MA, USA
Preface

In creating this third edition of The SAGES Manual, we have completely
restructured, reorganized, and revised the entire manual. Rather than put
the manual on a diet, we have separated it into two volumes for better
portability. Volume 1 covers the fundamentals and procedures performed
during surgical residency. We anticipate that Volume 1 will be the first
volume used by students, residents, and allied health-care professional
trainees, do not be deceived, however; we have added material to these
fundamentals and procedures that should also be of interest to experienced
surgeons. Volume 2 covers more advanced procedures, generally taught
during fellowship. If you own an old, dog-eared copy of the second
edition, you will find much that is new in both volumes.
All of the sections have been reorganized with a critical eye to the
needs of the modern minimal access surgeon. Two new editors have been
added. Although many chapters have new authors, many stalwart authors
have continued to contribute. We have also added color photographs.
As before, the manual strives to strike a balance between completeness
and conciseness. Significant additional information, including videos, is
available from the SAGES Web site (see Appendix, at the end of Volume 1).
But, as always, we want you to think of this manual as a way to take
SAGES experts along with you throughout your surgical journey.

Nathaniel J. Soper
Saint Louis, MO, USA
Ninh T. Nguyen
Orange, CA, USA
Carol E.H. Scott-Conner
Iowa City, IA, USA

vii
Contents

Foreword.......................................................................................... v
Preface.............................................................................................. vii
Contributors..................................................................................... xv

Part I Basic Laparoscopy and Endoscopy:
General Principles

1 Fundamentals of Laparoscopic Surgery (FLS)
and of Endoscopic Surgery (FES)............................................ 3
Jeffrey M. Marks
2 Maintenance of Certification.................................................... 15
Jo Buyske
3 Equipment Setup and Troubleshooting.................................... 21
Mohan C. Airan
4 Ergonomics in Operating Room Design.................................. 45
Erica R.H. Sutton and Adrian Park
5 Access to Abdomen................................................................. 61
Nathaniel J. Soper
6 Generation of Working Space: Extraperitoneal
Approaches.............................................................................. 79
David M. Brams and Amila Husic
7 Single-Site Access Surgery...................................................... 87
James A. Dickerson II, Chan W. Park,
and Aurora D. Pryor
8 Hand-Assisted Laparoscopic Surgery...................................... 99
Carol E.H. Scott-Conner
9 Laparoscopic Hemostasis: Energy Sources............................. 105
James G. Bittner IV, Michael M. Awad,
and J. Esteban Varela

ix
x Contents

10 Laparoscopic Hemostasis: Hemostatic Products
and Adjuncts............................................................................ 121
Thadeus L. Trus
11 Principles of Tissue Approximation........................................ 129
William C. Beck and Michael D. Holzman
12 Other Devices for Tissue Approximation................................ 143
Byron F. Santos and Eric S. Hungness
13 Documentation......................................................................... 163
Minh B. Luu and Daniel J. Deziel
14 Laparoscopy During Pregnancy............................................... 173
Carmen L. Mueller and Allan Okrainec
15 Previous Abdominal Surgery................................................... 183
Eric S. Hungness
16 Robotics in Laparoscopic and Thoracoscopic Surgery............ 191
W. Scott Melvin and Andreas Kirakopolous

Part II Diagnostic Laparoscopy and Biopsy
17 Emergency Laparoscopy.......................................................... 207
Brian T. Valerian and Steven C. Stain
18 Elective Diagnostic Laparoscopy and Cancer Staging............ 215
Michael D. Honaker and Frederick L. Greene
19 Lymph Node Biopsy, Dissection, and Staging
Laparoscopy............................................................................. 231
Lee L. Swanstrom

Part III Laparoscopic Cholecystectomy and Common
Duct Exploration
20 Laparoscopic Cholecystectomy............................................... 255
Pradeep Pallati and Dmitry Oleynikov
21 Laparoscopic Cholecystectomy: Avoiding Complications...... 265
Jessemae Welsh and Joseph J. Cullen
22 Cholangiography...................................................................... 273
Rahul Gupta, Daniel B. Jones, and Mark P. Callery
 Contents xi

23 Laparoscopic Ultrasound of the Biliary Tree........................... 291
Michael Lalla and Maurice E. Arregui
24 Laparoscopic Common Bile Duct Exploration:
Transcystic Duct Approach...................................................... 311
Joseph B. Petelin and Timothy Mayfield
25 Laparoscopic Common Bile Duct Exploration
via Choledochotomy................................................................ 331
Richard A. Alexander, Karla Russek,
and Morris E. Franklin

Part IV Basic Laparoscopic Gastric Surgery
26 Laparoscopic Gastrostomy....................................................... 345
Sajida Ahad and John D. Mellinger
27 Laparoscopic Plication of Perforated Ulcer............................. 353
I. Bulent Cetindag and John D. Mellinger

Part V Basic Laparoscopic Procedures
of the Small Intestine, Appendix, Colon
28 Small Bowel Resection, Enterolysis,
and Enteroenterostomy............................................................ 361
Bruce David Schirmer
29 Laparoscopic Placement of Jejunostomy Tube........................ 379
Bruce David Schirmer
30 Laparoscopic Appendectomy................................................... 389
Jessica K. Smith
31 Laparoscopic Colostomy......................................................... 403
John Byrn

Part VI Hernia Repair
32 Laparoscopic Inguinal Hernia Repair: Transabdominal
Preperitoneal and Totally Extraperitoneal Approaches........... 413
Nathaniel Stoikes and L. Michael Brunt
33 Laparoscopic Repair of Ventral Hernia.................................... 431
Michael J. Rosen
xii Contents

Part VII Pediatric Laparoscopy and Endoscopy
34 Pediatric Minimally Invasive Surgery: General
Considerations.......................................................................... 443
John J. Meehan
35 Pediatric Minimally Invasive Surgery: Specific Surgical
Procedures................................................................................ 449
John J. Meehan
36 Complications in Pediatric MIS............................................... 479
John J. Meehan

Part VIII Flexible Endoscopy: General Principles
37 Flexible Endoscopes: Characteristics, Troubleshooting,
and Equipment Care................................................................. 497
Gary C. Vitale and Brian R. Davis
38 Endoscopy Handling................................................................ 509
Kevin El-Hayek, John Rodriguez, and Bipan Chand
39 Monitoring, Sedation, and Recovery....................................... 525
Jennifer Hrabe and Joseph J. Cullen
40 Flexible Endoscopy: Principles of Documentation.................. 531
Raphael Sun and Joseph J. Cullen

Part IX Flexible Endoscopy: Basic Upper
Gastrointestinal Endoscopy
41 Diagnostic Upper Gastrointestinal Endoscopy........................ 539
Jarrod Wall and John D. Mellinger
42 Percutaneous Endoscopic Feeding Tube Placement................ 557
Melissa S. Phillips, Bipan Chand, and Jeffrey L. Ponsky
43 Capsule Enteroscopy................................................................ 571
Jeremy A. Warren and Bruce V. MacFadyen Jr.
 Contents xiii

Part X Flexible Endoscopy: Basic Lower
Gastrointestinal Endoscopy
44 Flexible Sigmoidoscopy........................................................... 581
John A. Coller
45 Diagnostic Colonoscopy.......................................................... 597
Aman Banerjee, Melissa S. Phillips,
and Jeffrey M. Marks
46 Therapeutic Colonoscopy and Its Complications.................... 611
Aaron S. Fink
Appendix.......................................................................................... 627
Index................................................................................................ 631
Contributors

Sajida Ahad, MD
Department of Surgery, Southern Illinois University
School of Medicine, Springfield, IL, USA
Mohan C. Airan, MD, FACS
Advocate Good Samaritan Hospital, Lombard, IL, USA
Richard A. Alexander Jr., MD
Department of General Surgery, South East Baptist Hospital,
San Antonio, TX, USA
Maurice E. Arregui, MD
Department of General Surgery, St. Vincent’s Hospital and Healthcare
Center, Indianapolis, IN, USA
Michael M. Awad, MD, PhD, FACS
Section of Minimally Invasive Surgery, Division of General Surgery,
Department of Surgery, Washington University in St. Louis
School of Medicine, St. Louis, MO, USA
Aman Banerjee, MD
Department of Surgery, University Hospitals Case Medical Center,
Cleveland, OH, USA
William C. Beck, MD
Department of Surgery, Vanderbilt University Medical Center,
Nashville, TN, USA
James G. Bittner IV, MD
Department of Surgery, Medical College of Georgia
School of Medicine, Augusta, GA, USA
David M. Brams, MD
Department of Surgery, Lahey Clinic, Burlington, MA, USA

xv
xvi Contributors

L. Michael Brunt, MD
Department of Surgery, Washington University School of Medicine,
St. Louis, MO, USA
Jo Buyske, MD
American Board of Surgery, Philadelphia, PA, USA
John Byrn, MD
Department of Surgery, University of Iowa Carver College
of Medicine, Iowa City, IA, USA
Mark P. Callery, MD
Department of Surgery, Division of General Surgery, Beth Israel
Deaconess Medical Center, Boston, MA, USA
I. Bulent Cetindag, MD
Department of Surgery, Southern Illinois University School
of Medicine, Springfield, IL, USA
Bipan Chand, MD, FACS
Department of Bariatric and Metabolic Surgery, Cleveland
Clinic Foundation, Cleveland, OH, USA
John A. Coller, MD
Department of Colon & Rectal Surgery, Lahey Clinic,
Burlington, MA, USA
Joseph J. Cullen, MD, FACS
Department of Surgery, University of Iowa Carver College
of Medicine, Iowa City, IA, USA
Brian R. Davis, MD
Department of Surgery, Paul L. Foster School of Medicine,
Texas Tech University, El Paso, TX, USA
Daniel J. Deziel, MD
Department of General Surgery, Rush University Medical Center,
Chicago, IL, USA
James A. Dickerson II, MD
Department of Surgery, Duke University Medical Center,
San Antonio, TX, USA
Kevin El-Hayek, MD
Department of General Surgery, Cleveland Clinic, Cleveland, OH, USA
 Contributors xvii

Aaron S. Fink, MD
VA Medical Center Atlanta, Emory University School of Medicine,
Decatur, GA, USA
Morris E. Franklin Jr., MD, FACS
Texas Endosurgery Institute, San Antonio, TX, USA
Frederick L. Greene, MD, FACS
Department of Surgery, Carolinas Medical Center, Charlotte, NC, USA
Rahul Gupta, MBBS, MS, DNB
Division of General Surgery, Department of Surgery,
Beth Israel Deaconess Medical Center, Boston, MA, USA
Michael D. Holzman, MD, MPH
Department of Surgery, Vanderbilt University Medical Center,
Nashville, TN, USA
Michael D. Honaker, MD
Department of General Surgery, Carolinas Medical Center,
Charlotte, NC, USA
Jennifer Hrabe, MD
Department of Surgery, University of Iowa Carver College
of Medicine, Iowa City, IA, USA
Eric S. Hungness, MD, FACS
Department of Surgery, Northwestern University Feinberg School
of Medicine, Northwestern Memorial Hospital, Chicago, IL, USA
Amila Husic, MD
Department of General Surgery, Lahey Clinic, Burlington, MA, USA
Daniel B. Jones, MD, MS
Department of Surgery, Division of General Surgery, Beth Israel
Deaconess Medical Center, Boston, MA, USA
Andreas Kirakopolous, MD
Department of Minimally Invasive Surgery, The Ohio State University,
Columbus, OH, USA
Michael Lalla, MD
Department of Surgery, St. Vincent’s Hospital, Indianapolis, IN, USA
Minh B. Luu, MD
Department of General Surgery, Rush University Medical Center,
Chicago, IL, USA
xviii Contributors

Bruce V. MacFadyen Jr., MD, FACS
Department of Surgery, Medical College of Georgia,
Augusta, GA, USA
Jeffrey M. Marks, MD, FACS
Department of General Surgery, Case Western Reserve Medical Center,
University Hospitals of Cleveland, Cleveland, OH, USA
Timothy Mayfield, MD
Surgix Minimally Invasive Surgery Institute, Shawnee Mission
Medical Center, Shawnee Mission, KS, USA
John J. Meehan, MD
Robotic Surgery Center, Seattle Children’s Hospital, Seattle, WA, USA
John D. Mellinger, MD, FACS
Department of Surgery, Southern Illinois University School
of Medicine, Springfield, IL, USA
W. Scott Melvin, MD, FACS
Department of Surgery, The Ohio State University,
Columbus, OH, USA
Carmen L. Mueller, BSc, MD
Division of General Surgery, University of Toronto, Toronto,
ON, Canada
Allan Okrainec, MD, MHPE, FRCSC, FACS
Department of Surgery, University of Toronto, Toronto, ON, Canada
Dmitry Oleynikov, MD
Department of Surgery, University of Nebraska Medical Center,
Omaha, NE, USA
Pradeep Pallati, MBBS
Department of Surgery, University of Nebraska Medical Center,
Omaha, NE, USA
Adrian Park, MD, FRCSE, FACS, FCS (ECSA)
Department of Surgery, Anne Arundel Health System,
Annapolis, MD, USA
Chan W. Park, MD
Department of Surgery, Duke University Medical Center,
Durham, NC, USA
 Contributors xix

Joseph B. Petelin, MD, FACS
Department of Surgery, University of Kansas School of Medicine,
Shawnee Mission, KS, USA
Melissa S. Phillips, MD
Department of Surgery, University of Tennessee Graduate
School of Medicine, Knoxville, TN, USA
Jeffrey L. Ponsky, MD, FACS
Department of Surgery, University Hospitals Case Medical Center,
Cleveland, OH, USA
Aurora D. Pryor, MD
Department of Surgery, Duke University Medical Center,
Durham, NC, USA
John Rodriguez, MD
Department of General Surgery, Cleveland Clinic Foundation,
Cleveland, OH, USA
Michael J. Rosen, MD
Department of Surgery, University Hospitals Case Medical Center,
Cleveland, OH, USA
Karla Russek, MD
Texas Endosurgery Institute, San Antonio, TX, USA
Byron F. Santos, MD
Department of Surgery, Northwestern University Feinberg School
of Medicine, Northwestern Memorial Hospital, Chicago, IL, USA
Bruce David Schirmer, MD, FACS
Department of Surgery, University of Virginia,
Charlottesville, VA, USA
Carol E.H. Scott-Conner, MD, PhD
Department of Surgery, University of Iowa Hospitals and Clinics,
Iowa City, IA, USA
Jessica K. Smith, MD
Department of Surgery, Iowa City VA Medical Center,
University of Iowa Hospitals and Clinics, Iowa City, IA, USA
Nathaniel J. Soper, MD
Department of Surgery, Northwestern University Feinberg School
of Medicine, Chicago, IL, USA
xx Contributors

Steven C. Stain, MD
Department of Surgery, Albany Medical School, Albany, NY, USA
Nathaniel Stoikes, MD
Department of Surgery, Washington University School of Medicine,
St. Louis, MO, USA
Raphael Sun, MD
Department of Surgery, University of Iowa Carver College
of Medicine, Iowa City, IA, USA
Erica R.H. Sutton, MD
University of Louisville School of Medicine, Louisville, KY, USA
Lee L. Swanstrom, MD, FACS
Department of Surgery, Oregon Health Sciences University, Portland,
OR, USA
Thadeus L. Trus, MD
Department of Surgery, Dartmouth-Hitchcock Medical Center,
Lebanon, NH, USA
Brian T. Valerian, MD
Department of Surgery, Albany Medical School, Albany, NY, USA
J. Esteban Varela, MD, MPH, FACS
Division of General Surgery, Section of Minimally Invasive Surgery,
Department of Surgery, Washington University in St. Louis School
of Medicine, St. Louis, MO, USA
Gary C. Vitale, MD
Department of Surgery, University of Louisville, Louisville, KY, USA
Jarrod Wall, MB, BCh, PhD
Department of Surgery, Southern Illinois University School
of Medicine, Springfield, IL, USA
Jeremy A. Warren, MD
Department of Surgery, Georgia Health Sciences University,
Augusta, GA, USA
Jessemae Welsh, MD
Department of Surgery, University of Iowa Carver College
of Medicine, Iowa City, IA, USA
Part I
Basic Laparoscopy and Endoscopy:
General Principles
1. Fundamentals of Laparoscopic
Surgery (FLS) and of Endoscopic
Surgery (FES)

Jeffrey M. Marks, M.D., F.A.C.S.

The Fundamentals of Laparoscopic surgery (FLS) is a validated
program for the teaching and evaluation of the basic knowledge and
skills required to perform laparoscopic surgery. The educational compo-
nent includes didactic, Web-based material and a simple, affordable
physical simulator with specific tasks and a recommended curriculum.
FLS certification requires passing both a written multiple-choice exami-
nation and a proctored manual skills examination in the FLS simulator.
The metrics for the FLS program has been rigorously validated to meet
the highest educational standards and certification is now a requirement
for the American Board of Surgery. This chapter summarizes the valida-
tion process and the FLS related research that has been done to date.
The FLS program was developed by surgeons, educators, and
administrators, under the leadership of the Society of American
Gastrointestinal and Endoscopic Surgeons (SAGES). The impetus to
create this curriculum was born out of the need to safely introduce
laparoscopic techniques into clinical practice and by the demand to
demonstrate basic competence in the application of this new technology.
In the early years of laparoscopy, some surgeons integrated these
techniques into their practices after cursory weekend courses or animal
labs. Unfortunately, an increase in bile duct injuries and other complica-
tions occurred during the early experience with laparoscopic cholecys-
tectomies. This critical issue of patient safety was the initial driver for
the FLS effort. Around the same time, the concept of simulation in medi-
cine was also starting to gain popularity, especially in light of restricted
resident work hours and limited operating room resources.

N.J. Soper and C.E.H. Scott-Conner (eds.), The SAGES Manual: Volume 1 3
Basic Laparoscopy and Endoscopy, DOI 10.1007/978-1-4614-2344-7_1,
© Springer Science+Business Media, LLC 2012
4 J.M. Marks

A. Program Description and Components
The FLS Program is not procedure or discipline-specific. It includes
both teaching and assessment components.

1. Web-Based Study Guide
a. Didactic modules (Fig. 1.1)
i. Preoperative considerations
ii. Intraoperative considerations
iii. Basic laparoscopic procedures
iv. Postoperative care and complications
v. Manual skills practice
b. Patient scenarios
c. Technical skills explanations

Fig. 1.1. Web-based study guide for FLS.
 1. Fundamentals of Laparoscopic Surgery (FLS)… 5

2. Assessment Tool
The assessment of this didactic material is done in the form of a 90-min
multiple-choice examination of 75 questions. The computer-based test
must be taken in a proctored setting at designated testing centers. It includes
standard multiple-choice questions as well as case-based scenarios, and
sometimes asks the examinee to interpret digital images.

3. Manual Skills (Fig. 1.2)
a. Five tasks performed in a box trainer with a built-in camera that
is connected to a monitor (not included).
b. The kit also contains a set of instruments and disposable sup-
plies. FLS is modeled after the original program developed by
Fried et al., and previously referred to as the McGill Inanimate
System for the Training and Evaluation of Laparoscopic Skills
(MISTELS).

Fig. 1.2. Manual skills tests for FLS.
6 J.M. Marks

c. The tasks are scored for efficiency and precision, and each
task has a predetermined cutoff time. The scores have been
normalized and are equally weighted. A higher score indicates
superior performance.
i. Peg transfer
ii. Precision cutting
iii. Placement of a ligating loop
iv. Suturing using extracorporeal knot tying
v. Suturing using intracorporeal knot tying

4. Global Operative Assessment
of Laparoscopic Skills (GOALS)
The Global Operative Assessment of Laparoscopic Skills (GOALS)
is a validated measure of intraoperative laparoscopic skill, and a high
positive correlation exists between FLS manual skill performance and
GOALS scores in the operating room during dissection of the gallblad-
der from the liver bed.

B. FLS Simulator Practice Improves Operating
Room Performance
The true test regarding the effectiveness of the FLS manual skills
program as a training program is whether or not the skills acquired and
measured in the simulator transfer to the operating room. Sroka et al.
recently conducted a randomized controlled trial examining the effects
of training using the FLS proficiency based curriculum described by
Ritter and Scott on operating room performance as measured by GOALS.
The FLS-trained group achieved the proficiency goals and improved
significantly (increased by 6.1 ± 1.3, p < 0.01) in the operating room com-
pared to the control group whose GOALS scores remained unchanged
(increased by 1.8 ± 2.1, p = 0.47). After 2.5 h of supervised practice, and
5 h of individual deliberate practice, the simulator group, composed of
first and second year residents performed at the level of third and fourth
year residents in a previous study. They acquired skills in the simulator
in 7.5 h that they may have otherwise acquired during 1 or 2 years of
residency training!
 1. Fundamentals of Laparoscopic Surgery (FLS)… 7

C. Fundamentals of Endoscopic Surgery
(GOALS)
Many of the same issues that prompted the development of FLS are
apparent in the training of competent flexible endoscopists both in the
fields of gastroenterology and gastrointestinal surgery. The importance
of these skills for surgeons is rapidly increasing as we work toward
the development of increasingly less invasive methods to treat gastroin-
testinal disease. In response to the need for an objective way to teach and
assess the knowledge and skills required to perform basic flexible
endoscopy, members of SAGES began to discuss the possibility of
developing a flexible gastrointestinal endoscopy teaching and evaluation
program, similar to FLS, that could serve as a benchmark for physicians
of all specialties. Through this discussion, Fundamentals of Endoscopic
Surgery (FES) was born. At the time of preparation of this chapter, the
program is still being developed and validated, with the intention to
launch the program by Fall 2011.
Similar to FLS, the FES Program is not procedure or discipline-
specific and includes teaching and assessment components.

1. Web-Based Study Guide
a. Didactic modules (Figs. 1.3 and 1.4)
i. Technology
ii. Patient preparation
iii. Sedation and analgesia
iv. Upper gastrointestinal endoscopy
v. Lower gastrointestinal endoscopy
vi. Performing lower GI procedures
vii. Lower GI anatomy, pathology, and complications
viii. Didactic Endoscopic Retrograde Cholangiopancreato-
graphy (ERCP)
ix. Hemostasis
x. Tissue removal
xi. Enteral access
xii. Endoscopic therapies
8 J.M. Marks

Fig. 1.3. Web-based study guide pages for FES.

Fig. 1.4. Web-based study guide pages for FES.
 1. Fundamentals of Laparoscopic Surgery (FLS)… 9

2. Assessment Tool
The assessment of this didactic material is done in the form of a 90-min
multiple-choice examination of 75 questions. The computer-based test must
be taken in a proctored setting at designated testing centers. It includes stan-
dard multiple-choice questions as well as case-based scenarios, and some-
times asks the examinee to interpret digital images.

3. Manual Skills
a. It consists of five separate modules administered on the
Simbionix GI Mentor II platform (Fig. 1.5).
b. Because of the cost of this platform, it is envisioned that the test
will initially be given at regional testing centers around the
world. Eventually, the goal is to develop a desktop testing

Fig. 1.5. Simbionix GI Mentor II for FES hands on skills (GI Mentor, Simbionix,
USA).
10 J.M. Marks

platform, which could be more easily distributed to individual
training programs.
i. Module 1—Navigation (traversal, tip deflection, and
torque) (Fig. 1.6a)
ii. Module 2—Loop reduction
iii. Module 3—Retroflexion (Fig. 1.6b)
iv. Module 4—Mucosal evaluation (Fig. 1.6c)
v. Module 5—Targeting (Fig. 1.6d)

4. Global Assessment of Gastrointestinal
Endoscopic Skills (GAGES)
The Global Assessment of Gastrointestinal Endoscopic Skills
(GAGES) was developed by expert endoscopists and educators. The
fundamental skills required for flexible endoscopy were identified and

Fig. 1.6. Manual skills tests for FES. (a) Navigation (traversal, tip deflection,
and torque); (b) Retroflexion; (c) Mucosal evaluation; (d) Targeting (GI Mentor,
Simbionix, USA).
Fig. 1.6. (continued)
12 J.M. Marks

Fig. 1.6. (continued)

then distilled into two global assessments: GAGES Upper Endoscopy
(GAGES-UE) and GAGES Colonoscopy (GAGES-C). The assessments
were modeled after the Objective Structured Assessment of Technical
Skills (OSATS) for open surgery and the GOALS for laparoscopic sur-
gery and consist of itemized skills rated on a 5-point Likert scale with
anchors at 1, 3, and 5.

D. Conclusion
The concept that merits reiteration is the notion that passing FLS, and
eventually FES, does not indicate that an individual is a competent sur-
geon or endoscopist, but that they have demonstrated competence in the
basic knowledge and technical skills required to safely perform these
procedures. Just as one would expect that a trainee learn the differences
 1. Fundamentals of Laparoscopic Surgery (FLS)… 13

between needle drivers and suture materials and how to suture and tie
knots outside of the operating room, these programs attempt to assure a
basic level of knowledge and skill before entering the clinical arena.
Overall, the goal is to optimize patient safety and the utilization of
operating room resources while improving the efficiency and quality of
surgical education.

Selected References
Clarke JR. Making surgery safer. J Am Coll Surg. 2005;200:229.
Derossis AM, Antoniuk M, Fried GM. Evaluation of laparoscopic skills: a 2-year follow-
up during residency training. Can J Surg. 1999;42:293.
Fried GM, Feldman LS, Vassiliou MC, et al. Proving the value of simulation in laparoscopic
surgery. Ann Surg. 2004;240:518–25. discussion 525–8.
McCluney AL, Vassiliou MC, Kaneva PA, et al. FLS simulator performance predicts
intraoperative laparoscopic skill. Surg Endosc. 2007;21:1991–5.
Sroka G, Feldman LS, Vassiliou MC, et al. Fundamentals of Laparoscopic Surgery simu-
lator training to proficiency improves laparoscopic performance in the operating
room—a randomized controlled trial. Am J Surg. 2010;199(1):115–20.
Strasberg SM, Hertl M, Soper NJ. An analysis of the problem of biliary injury during
laparoscopic cholecystectomy. J Am Coll Surg. 1995;180:101.
2. Maintenance of Certification

Jo Buyske, M.D.

A. Introduction
1. Definition of Maintenance of Certification
Maintenance of Certification (MOC) is the documentation of a personal
program of continuous learning and improvement. MOC is required for
ongoing certification by the American Board of Surgery and starts
immediately upon initial certification or recertification. MOC crosses
all specialties. It was established in 2002 by the American Board of
Medical Specialties, a federation of 24 member boards. It is the logical
continued growth of the process of board certification and also answers
the public demand for demonstration of quality and ongoing acquisition
of knowledge.

2. History of Board Certification
Board certification in the USA has evolved since its inception in
1917. The American Board of Ophthalmology was the first board formed,
inspired by a 1908 speech to the American Academy of Ophthalmology
and Otolaryngology by Derrick Vail, an ophthalmologist. He stated:
I hope to see the time when ophthalmology will be taught in this country as
it should be taught. That day will come when we demand… that a certain
amount of preliminary education and training be enforced before a man
may be licensed to practice ophthalmology. After a sufficiently long term
of service in an ophthalmic institution … he should be permitted to appear
before a proper examining board for examination… and if he is found com-
petent let him then be permitted and licensed to practice ophthalmology.

N.J. Soper and C.E.H. Scott-Conner (eds.), The SAGES Manual: Volume 1 15
Basic Laparoscopy and Endoscopy, DOI 10.1007/978-1-4614-2344-7_2,
© Springer Science+Business Media, LLC 2012
16 J. Buyske

That speech inspired the formation of the American Board of
Ophthalmology in 1917, and in 1937 the American Board of Surgery
was formed. The original mission statement of the ABS notes that the
Board is formed to “protect the public and improve the specialty”
which was to be accomplished by the establishment of a comprehen-
sive, standardized certification process, including periodic assessment
of individual hospitals as appropriate places of training, the require-
ment of 5 years of training beyond internship, and the development of
an examination process designed to assess both knowledge and
judgment.

3. Background of MOC
From 1937 until 1976 certification was lifelong: once certified, noth-
ing further was required for the duration of one’s surgical career. In 1976,
the American Board of Surgery formally recognized that surgery is a
field that requires ongoing active engagement in learning and that this
should be supported by requiring recertification. Recertification require-
ments included: submission of a case log, assessment of knowledge by a
broad-based multiple choice exam with a passing score, proof of active
license and hospital privileges, and testimonials from hospital officials
including the chief of surgery. The decision to implement intermittent
reassessment for recertification was supported by the outcome. The
results of those first recertification exams confirmed that the body of
knowledge of surgeons 20 or 30 years out of training was not the same as
that of surgeons within 10 years of their training; the former group failed
the exam in high numbers.
A confluence of events at the turn of the century caused the specialty
boards to revisit the duration of certification yet again. Increased public
scrutiny of patient safety, the issuance of the IOM report “To Err is
Human” in 1999, and the highly successful safety campaign by the air-
line industry all drove focus towards more oversight of knowledge and
training. In addition, surgery underwent a series of rapid changes, includ-
ing the widespread adoption of laparoscopy, the development of endo-
vascular surgery, the introduction of sentinel node technology, the
discovery of Helicobacter pylori, the penetration of interventional endos-
copy, and the increased use of noninvasive management of blunt trauma.
All these things combined to make it clear that surgical training and
practice were dynamic arenas that required ongoing attention and self-
education.
 2. Maintenance of Certification 17

B. Defining MOC
MOC is a result of that reassessment. MOC changes the emphasis
from a burst of studying every 10 years to that of an ongoing process of
learning and assessment. It is broken into four categories, based upon the
ABMS/ACGME Six Competencies, adopted in 1999. The Six
Competencies are a rubric for resident education and assessment across
all specialties. Programs are required to demonstrate that their curricu-
lum addresses these arenas.
The competencies are as follows:
Patient Care and Procedural Skills: Provide care that is com-
passionate, appropriate and effective treatment for health prob-
lems and to promote health.
Medical Knowledge: Demonstrate knowledge about estab-
lished and evolving biomedical, clinical, and cognate sciences
and their application in patient care.
Interpersonal and Communication Skills: Demonstrate
skills that result in effective information exchange and teaming
with patients, their families, and professional associates (e.g.,
fostering a therapeutic relationship that is ethically sound,
uses effective listening skills with nonverbal and verbal com-
munication; working as both a team member and at times as a
leader).
Professionalism: Demonstrate a commitment to carrying out
professional responsibilities, adherence to ethical principles and
sensitivity to diverse patient populations.
Systems-Based Practice: Demonstrate awareness of and
responsibility to larger context and systems of health care.
Be able to call on system resources to provide optimal care
(e.g., coordinating care across sites or serving as the primary
case manager when care involves multiple specialties, profes-
sions or sites).
Practice-Based Learning and Improvement: Able to investi-
gate and evaluate their patient care practices, appraise and
assimilate scientific evidence, and improve their practice of
medicine.
18 J. Buyske

C. Components of MOC
1. Categories/Components of MOC for Surgeons
MOC combines the Six Competencies and condenses them into four
categories. The components of MOC are as follows:
Part 1—Professional standing through maintenance of an
unrestricted medical license, hospital privileges and satisfactory
references.
Part 2—Lifelong learning and self-assessment through con-
tinuing education and periodic self-assessment.
Part 3—Cognitive expertise based on performance on a secure
examination.
Part 4—Evaluation of performance in practice through tools
such as outcome measures and quality improvement programs,
and the evaluation of behaviors such as communication and
professionalism.

2. Fulfilling the MOC Requirements for Surgery
As is true of the field of surgery, MOC is an evolving field. Parts I and
3 are straightforward. Part 1 includes submission of documentation of an
unrestricted license, and hospital privileges, as well as a testimonial form
filled out by the chief of surgery and chair of the credentials committee.
This is to be submitted once every 3 years.
Part 3 is the familiar “recertification” examination, which still must
be taken once every 10 years. Admissibility to that exam will include
timely fulfillment of all other MOC requirements, as well as a case log.
Parts 2 and 4 have a lot of promise, and are both more complicated
and more interesting. Part 2 is self-assessment. In surgery, this will be
fulfilled by CME I credits, especially those that require self-assessment.
30 credits will be required each year, 20 of which must be self-assess-
ment. Standards for satisfactory self-assessment are under development
by the ABS. Standards currently include CME 1 products that include
a self test, which must be passed with a minimum 75% correct.
Live activities, enduring materials, journal-based reading, and skills
training are all offerings eligible for self-assessment. SAGES offers
vehicles for self-assessment, both at the annual meeting and via the
online SAGES University (http://www.sages.org/education/university.php).
 2. Maintenance of Certification 19

SAGES University is available free to SAGES members and includes
SAGES Journal Club, Online Self-Assessment Program (OSAP), and
my CME/MY MOC Web page. A partial list of other self-assessment
vehicles are listed on the ABS Web page (http://home.absurgery.org/
default.jsp?exam-moccme). Part II MOC reporting to the ABS will be
required each 3-year cycle, along with Parts 1 and 4. Future plans for Part
2 MOC include linking the CME subject areas to case logs and practice,
as well as using this venue for continuing education in ethics, profession-
alism, and perhaps systems-based practice. Ideally, Part 2 requirements
will eventually link to requirements of other certifying and licensing
groups, such as state licensing boards, hospital credential committees,
the Joint Commission, and others. Professional societies including
SAGES are providing multiple pathways to achieve those self-assessments
credits that are meaningful to an individual’s learning and pertinent to his
or her practice.
Part 4 is the evaluation of performance in practice. To fulfill Part IV,
the ABS currently requires participation in an outcomes database. At
present a wide variety of databases fulfills this requirement, including the
American College of Surgeons National Surgical Quality Improvement
Program (ACS NSQIP), the American College of Surgeons Case Log,
Mastery of Breast Surgery (The American Society of Breast Surgeons),
participation in the United Network for Organ Sharing (UNOS), partici-
pation in bariatric surgery databases offered either by the American
College of Surgeons or the American Society of Metabolic and Bariatric
Surgery, and many others (for a partial list see http://home.absurgery.org/
default.jsp?exam-mocpa). Currently, participation alone is adequate to
fulfill requirements; practice data does not need to be provided. Although
the ABS recognizes that actual analysis of one’s own practice and out-
comes compared those of one’s peers is ideal, at present no one perfect
database exists that allows for such a requirement. Therefore, for now,
participation alone is adequate, on the theory that the process of record-
ing one’s own practices is valuable in and of itself. Future plans for Part
4 MOC include a single, unified database for ABS use that is currently
under development by the American College of Surgeons. In addition, a
requirement of assessment of communication skills based upon patient
surveys will likely be included in Part IV as well (Table 2.1).
MOC, when mature, will provide both a vehicle and a requirement
for surgeons to structure their learning and measure their practices and
outcomes. In practice, the ABS Web site will guide practitioners through
the existing requirements, as well as updates as high-quality vehicles for
Parts 2 and 4 continue to emerge.
20 J. Buyske

Table 2.1. ABS MOC requirements timeline.
MOC year MOC requirement
0 Year of certification or recertification
1 Yearly CME (30 h Category I, 50 overall)
2 Yearly CME
3 Yearly CME
→ Diplomate submits information through the ABS Web site
regarding medical license, hospital privileges, references,
CME and practice assessment participation
4 Same as Year 1
5 Same as Year 2
6 Same as Year 3
7 Same as Year 1
8 Same as Year 2
9 Same as Year 3
8–10 Secure examination (application and 12-month operative log
required)
MOC Year July 1 to June 30, starting July 1 following certification or recertification
Used with permission of the American Board of Surgery

Selected References
ACGME Outcomes Project. http://www.acgme.org/outcome/comp/GeneralCompetencies
Standards21307.pdf. Accessed 6 July 2011.
Maintenance of Certification. http://home.absurgery.org/default.jsp?exam-moc. Accessed
6 July 2011.
SAGES ACCME Compliance. http://www.sages.org/education/university.php. Accessed
6 July 2011.
To Err is Human: 1999 Reports Brief. http://www.iom.edu/~/media/Files/Report%20
Files/1999/To-Err-is-Human/To%20Err%20is%20Human%201999%20%20
report%20brief.pdf. Accessed 6 July 2011.
3. Equipment Setup
and Troubleshooting

Mohan C. Airan, M.D., F.A.C.S.

A. Room Layout and Equipment Position
1. General considerations include the size of the operating room,
location of doors, outlets for electrical and anesthetic equip-
ment, and the procedure to be performed. The time required to
position the equipment and operating table is well spent. Arrive
at the operating room sufficiently early to assure proper setup
and to ascertain that all instruments are available and in good
working order. This is particularly important when a procedure
is being done in an operating room not normally used for lap-
aroscopic operations, or when the operating room personnel are
unfamiliar with the equipment (e.g., an operation performed
after hours).
2. Determine the optimum position and orientation for the
operating table. If the room is large, the normal position for
the operating table will work well for laparoscopy.
3. Small operating rooms will require diagonal placement of the
operating table and proper positioning of the laparoscopic
accessory instruments around the operating table.
4. Robotic systems and their effect on operating room space.
If used, the da Vinci® robot requires significant space for sur-
geon console, slave CRT screens for operating room team view-
ing, as well as the surgical arm cart.
5. An equipment checklist helps to ensure that all items are
available and minimizes delays once the patient has arrived in
the operating room. The following is an example of such a
checklist. Most of the equipment and instruments listed here
will be needed for operative laparoscopy. Additional equipment

N.J. Soper and C.E.H. Scott-Conner (eds.), The SAGES Manual: Volume 1 21
Basic Laparoscopy and Endoscopy, DOI 10.1007/978-1-4614-2344-7_3,
© Springer Science+Business Media, LLC 2012
22 M.C. Airan

may be needed for advanced procedures. This is discussed in
subsequent sections.
a. Anesthesia equipment
b. Electric operating table with remote control if available
c. Two video monitors
d. Suction irrigator
e. Electrosurgical unit, with grounding pad equipped with
current monitoring system
f. Ultrasonically activated scissors, scalpel, or other special-
ized unit if needed
g. Laparoscopic equipment, generally housed in a cart on
wheels:
i. Light source
ii. Insufflator
iii. Videocassette recorder (VCR), other recording
system, tapes
iv. Color printer (optional)
v. Monitor on articulating arm
vi. Camera-processor unit
h. C-arm X-ray unit (if cholangiography is planned) with
remote monitor
i. Mayo stand or table with the following instruments:
i. #11, #15 scalpel blades and handles
ii. Towel clips
iii. Veress needle or Hasson cannula
iv. Gas insufflation tubes with micropore filter
v. Fiber-optic cable to connect laparoscope with light
source
vi. Video camera with cord
vii. Cords to connect laparoscopic instruments to the
electrosurgical unit and other energy sources
viii. 6-in. curved hemostatic forceps
ix. Small retractors (Army-Navy or S-retractors)
x. Trocar cannulae (size and numbers depend on the
planned operation, with extras available in case of
accidental contamination)
xi. Laparoscopic instruments
Atraumatic graspers
Locking toothed jawed graspers
Needle holders
 3. Equipment Setup and Troubleshooting 23

Dissectors: curved, straight, right angled
Bowel grasping forceps
Babcock clamp
Scissors: Metzenbaum, hook, microtip
Fan retractors: 10 mm, 5 mm
Specialized retractors, such as endoscopic curved
retractors
Biopsy forceps
Tru-Cut biopsy-core needle
xii. Port site closure devices
xiii. Monopolar electrocautery dissection tools
L-shaped hook
Spatula tip dissector/coagulator
xiv. Ultrasonically activated scalpel (optional)
Scalpel
Ball coagulator
Hook dissector
Scissors dissector/coagulator/transector
xv. Endocoagulator probe (optional)
xvi. Basket containing:
Clip appliers
Endoscopic stapling devices
Pretied suture ligatures—endoloops, etc.
Endoscopic suture materials
Extra trocars
j. Robot holder if available

B. Room and Equipment Setup
1. With the operating table positioned, and all equipment in the
room, reassess the configuration. Once the patient is anesthe-
tized and draped, it is difficult to reposition equipment. Consider
the room size (as previously discussed), location of doors (par-
ticularly if a C-arm is to be used), and the quadrant of the abdo-
men in which the procedure will be performed. Figure 3.1
shows a typical setup for a laparoscopic cholecystectomy or
other procedure in the upper abdomen. Figure 3.2 illustrates a
typical setup in a small operating room.
24 M.C. Airan

Fig. 3.1. Basic room setup. This is the typical setup for laparoscopic cholecys-
tectomy. The room must be sufficiently large to accommodate all of the equip-
ment (see Fig. 3.2 for setup for smaller room). A similar setup can be used for
hiatus hernia repair or other upper abdominal surgery. In these cases, one 21-in.
or larger monitor can be used in the center where the anesthesiologist usually
sits, with the anesthesiologist positioned to the side. The position of the surgeon
(S), camera holder (C), and the assistant (A) depends on the procedure that is
planned. The best position for the monitor is opposite the surgeon in his line of
sight. A C-arm, if used, should be placed perpendicular to the operating table. A
clear pathway to the door facilitates placement of the C-arm, and should be
planned when the room is set up.
 3. Equipment Setup and Troubleshooting 25

Fig. 3.2. Laparoscopic cholecystectomy, small operating room. The moni-
tors, anesthesia machine, and relative position of surgeon and first assistant have
been adapted to the diagonal operating table placement.
26 M.C. Airan

2. Set up the equipment before bringing the patient into the
operating room. A systematic approach, starting at the head of
the table, is useful.
a. There should be sufficient space to allow the anesthesiolo-
gist to position the anesthesia equipment and work safely.
b. Next, consider the position of the monitors and the paths
that connecting cables will take. Try to avoid “fencing in”
the surgeon and assistants. This is particularly important if
surgeon and assistant need to change places or move (for
example, during cholangiography).
c. The precise setup must be appropriate to the planned pro-
cedure. The setup shown is for laparoscopic cholecystec-
tomy or other upper abdominal procedures. Room and
equipment setups for other laparoscopic operations are dis-
cussed with each individual procedure in the chapters that
follow. A useful principle to remember is that the laparo-
scope must point toward the quadrant of the abdomen with
the pathology, and the surgeon generally stands opposite
the pathology and looks directly at the main monitor.
d. If a C-arm or other equipment will need to be brought in
during the procedure, plan the path from the door to the
operating table in such a manner that the equipment can be
positioned with minimal disruption. This will generally
require that the cabinet containing the light source, VCR,
insufflator, and other electronics be placed at the side of the
patient farthest from the door. Consider bringing the C-arm
into the room before the procedure begins.
e. Additional tables should be available so that water, irrigat-
ing solutions, and other items are not placed on any electri-
cal units where spillage could cause short circuits, electrical
burns, or fires.
3. Check the equipment and ascertain the following:
a. If no piped-in lines are available, there should be two full
carbon dioxide cylinders in the room. One is used for the
procedure, and the second is a spare in case the pressure in
the first cylinder becomes low. The cylinder should be
hooked up to the insufflator and the valve turned on. The
pressure gauge should indicate that there is adequate gas in
the cylinder. If the cylinder does not appear to fit properly,
do not force it. Each type of gas cylinder has a unique kind
 3. Equipment Setup and Troubleshooting 27

of fitting, and failure to fit properly may indicate that the
cylinder contains a different kind of gas (e.g., oxygen).
The piped-in lines should be color coded and connected to
appropriate intake valves.
b. If the carbon dioxide cylinder needs to be changed during
a procedure:
i. Close the valve body with the proper handle to shut
off the gas (old cylinder).
ii. Unscrew the head fitting.
iii. Replace the gasket in the head fitting with a new gas-
ket, which is always provided with a new tank of gas.
iv. Reattach the head fitting so that the two prongs of the
fitting are seated in the two holes in the carbon diox-
ide gas tank valve body.
v. Firmly align and tighten the head fitting with the inte-
gral pointed screw fixture.
vi. Open the carbon dioxide gas tank valve body, and
pressure should be restored to the insufflator.
c. Look inside the back of the cabinet housing the laparo-
scopic equipment. Check to be certain that the connections
on the back of the units are tightly plugged in (Fig. 3.3).
4. Attention to detail is important. The following additional items
need careful consideration, and can be checked as the patient is
brought into the room and prepared for surgery:
a. Assure table tilt mechanism is functional, and that the table
and joints are level and the kidney rest down.
b. Consider using a footboard and extra safety strap for large
patients.
c. Position patient and cassette properly on operating table
for cholangiography.
d. Notify the radiology technologist with time estimate.
e. Assure proper mixing and dilution of cholangiogram con-
trast solution for adequate image.
f. Assure availability of Foley catheter and nasogastric tube,
if desired.
g. Assure all power sources are connected and appropriate
units are switched on. Avoid using multiple sockets or
extension cords plugged into a single source, as circuits
may overload.
h. Check the insufflator. Assure that insufflator alarm is set
appropriately.
28 M.C. Airan

Fig. 3.3. Connections on rear panel. The actual configuration of connections
on the rear panels varies, but there are some general principles that will help
when tracing the connections. The video signal is generated by the camera box.
A cable plugs into the “video out” port of the camera box and takes the video
signal to the VCR or monitor by plugging into a “video in” port. A common
arrangement takes the signal first to the VCR, and then from the “video out” port
of the VCR to the “video in” port of the monitor. (see Chap. 9, Documentation).
Some cameras have split connectors that must be connected to the proper ports.
Once connected, these should not be disturbed. The surgeon should be familiar
with the instrumentation, as connections frequently are loose or disconnected.
The last monitor plugged in should have an automatic termination of signal port
to avoid deterioration of the picture quality.

i.Assure full volume in the irrigation fluid container (recheck
during case).
j. Assure adequate printer film and video tape if documenta-
tion is desired.
k. Check the electrosurgical unit; make sure the auditory
alarm of the machine is functioning properly and the
grounding pad is appropriate for the patient, properly
placed, and functioning.
l. The surgeon should specify the electrosurgical unit that he
uses.
m. Apply S.C.D.’s
 3. Equipment Setup and Troubleshooting 29

5. Once you are gowned and gloved, connect the light cable and
camera to the laparoscope. Focus the laparoscope and white
balance it. Place the laparoscope in warmed saline or electrical
warmer. Verify the following:
a. Check Veress needle for proper plunger/spring action and
assure easy flushing through stopcock and/or needle
channel.
b. Assure closed stopcocks on all ports.
c. Check sealing caps for cracked rubber and stretched
openings.
d. Check to assure instrument cleaning channel screw caps
are in place.
e. Assure free movements of instrument handles and jaws.
f. If Hasson cannula to be used, assure availability of stay
sutures and retractors.

C. Types of Equipment Available
1. Electrosurgical Units
a. Simple E.S.U.—coagulation and cut features—use AEM tech-
nology overlay machine.
b. Complex E.S.U.—ForceTriad™ energy platform comprises
monopolar, bipolar, and proprietary functions utilizing
LigaSure™ tissue fusion technology, the Force Triverse™
electrosurgical device, and Valleylab™ mode (Figs. 3.4–3.6).
c. Ultrasonic machines.

D. Troubleshooting
1. Laparoscopic procedures are inherently complex. Many
things can go wrong. The surgeon must be sufficiently familiar
with the equipment to troubleshoot and solve problems.
Table 3.1 gives an outline of the common problems, their cause,
and suggested solutions.
30 M.C. Airan

Fig. 3.4. ForceTriad™ energy platform front panel. ©2010 Covidien. All
rights reserved. Image reprinted with permission from the Energy-based Devices
division of Covidien. The ForceTriad™ is an electrosurgical all in one unit. The
bipolar device allows surgeons, urologists, gynecologists to perform in a saline
environment. Tissue fusion technology permanently fuses vessels up to 7 mm,
lymphatic and tissue bundles. The devices can divide the structures as soon as
fusion is accomplished. Valleylab™ mode provides equal or superior hemostasis
than standard valley lab E.S.U. The touch screens’ screen displays change based
on instrument recognition technology. Each instrument has its own electronic
signature recognized by the unit.

Fig. 3.5. Force TriVerse™ electrosurgical device. ©2010 Covidien. All rights
reserved. Image reprinted with permission from the Energy-based Devices
division of Covidien. The surgeon can change the settings from the sterile field
freeing up the circulating RN for other duties.
 3. Equipment Setup and Troubleshooting 31

Fig. 3.6. LigaSure™ Impact instrument. ©2010 Covidien. All rights reserved.
Image reprinted with permission from the Energy-based Devices division of
Covidien. Used for open surgery to fuse and divide. The function is more
economical than using vascular staplers for small vessels.

2. General Troubleshooting Guidelines—ForceTriad™ energy
platform. If the Force Triad™ energy platform malfunctions,
check for obvious conditions that may have caused the
problem:
a. Check the system for visible signs of physical damage.
b. Make sure the fuse drawer is tightly closed.
c. Verify that all cords are connected and attached properly.
d. If an error code is displayed on the touch screens, note the
code along with all information on the error screen, then
turn the system off and turn it back on.
 32

Table 3.1. Common problems, causes, and solutions.
Problem Cause Solution
1. Poor insufflation/loss CO2 tank empty or volume low Change tank
M.C. Airan

of pneumoperitoneum Accessory port stopcock(s) open Inspect all accessory ports. Open/close stopcock(s) as
needed
Leak in sealing cap, reducer Change cap or stopcock cannula
Excessive suctioning pressure Allow time to reinsufflate, lower suction
Loose, disconnected, or kinked insufflation tubing Tighten connections or reconnect at source or at port,
unkink tubing
Hasson stay sutures loose Replace or secure sutures
CO2 flow rate set too low Adjust flow rate
Valve on CO2 tank not fully open Use valve wrench to open fully
Leak at skin where port enters cavity Apply penetrating towel clip or suture around port
2. Excessive pressure Veress needle or cannula tip not in peritoneal space Reposition needle or cannula under visualization if
required for insuffla- possible
tion (initial or Occlusion of tubing (kinking, table joints, etc.) Inspect full length of tubing
subsequent) CO2 port stopcock turned off Fully open stopcock
Patient is “light” Communicate to anesthesia
Morbidly obese patient Use longer Veress needle
3. Inadequate lighting Light is dim Increase gain. Check scope for adequate fiber-optics
(partial/complete loss) Replace light cable and/or camera
Light is on standby Take light off standby
Loose connection at source or at scope Adjust connection
Light is on “manual-minimum” Go to “automatic”
Fiber-optics is damaged Replace light cable
Problem Cause Solution
Automatic iris adjusting to bright reflection from Reposition instruments, or switch to “manual”
instruments
Monitor brightness turned down Readjust brightness setting, adjust gain
Room brightness floods monitors Dim room lights
Bulb is burned out Replace bulb
Scope dark Check white balance
4. Lighting too bright Light is on “manual-maximum” “Boost” on light source activated
Monitor brightness turned up Go to “automatic,” deactivate “boost,” readjust setting
5. No picture on Camera control or other components (VCR, printer, Make sure all power sources are plugged in and
monitor(s) light source, monitor) “not on” turned on
Cable connector between camera control unit and/or Cable should run from “video out” on camera control
monitors not attached properly unit to “video in” on primary monitor. Use
compatible cables for camera unit and light source
Cable between monitors not connected Cable should run from “video out” on primary
monitor to “video in” on secondary monitor
Input selection button on monitor doesn’t match Assure matching selection
“video in” choice
Input selection button on monitor or video peripher- Adjust input selection
als (e.g., VCR, digital capture, printer) not
selected
6. Poor-quality picture Flickering electrical interference, poor cable Replace cautery cables, switch camera head, make
shielding sure cables don’t cross, use different plug points
Color problems White balance camera, monitor chrome on monitor,
check printer, VCR, digital capture cables
3. Equipment Setup and Troubleshooting

Glare not caused by lighting Check for loose cables not plugged in
(continued)
33
 34
M.C. Airan

Table 3.1. (continued)
Problem Cause Solution
a. Fogging, haze Condensation on lens from cold scope entering Use antifog solution or warm water, wipe lens
warm abdomen externally
Condensation on scope eyepiece, camera lens Detach camera from scope (or camera from coupler);
inspect, and clean lens as needed
b. Flickering, Moisture in camera cable connecting plug Use suction or compressed air to dry out moisture
electrical (don’t use cotton-tip applicators on multipronged
interference plug)
Poor cable shielding Move electrosurgical unit to different circuit or away
from video equipment, make sure cables don’t
cross, switch camera head; replace cables as
necessary
Insecure connection of video cable between Reattach video cable at each monitor
monitors
c. Blurring, Incorrect focus Adjust camera focus ring
distortion Cracked lens, internal moisture Inspect scope/camera, replace if needed
Too grainy Adjust enhancement and/or grain setting for units
with this option
Problem Cause Solution
7. Inadequate suction/ Occlusion of tubing (kinking, blood clot, etc.) Inspect full length of tubing. If necessary, detach from
irrigation instrument and flush tubing with sterile saline
Occlusion of valves in suction/irrigator device Detach tubing, flush device with sterile saline
Not attached to wall suction Inspect and secure suction and wall source connector
Irrigation fluid container not pressurized Inspect pressure bag or compressed gas source,
connector, pressure dial setting
8. Absent or “weak” Patient not grounded properly Assure adequate grounding pad contact
cauterization Connection between electrosurgical unit and Inspect both connecting points
instrument loose
Foot pedal or hand-switch not connected to Make connection
electrosurgical unit
Wrong output selected Correct output choice
Connected to the wrong socket on the Check that cable is attached to endoscopic socket
electrosurgical unit
Instrument insulations failure outside of the Use new instrument and inspect insulation
surgeon’s view
Reprinted with permission from the Society of American Gastrointestinal and Endoscopic Surgeons (SAGES)
3. Equipment Setup and Troubleshooting
35
36 M.C. Airan

e. If a solution is not readily apparent, refer to Table 3.2,
Correcting Malfunctions, to help identify and correct spe-
cific malfunctions. After the malfunction is corrected, verify
that the system completes a prescribed self-test. If the mal-
function persists, the system may require service. Contact
the institution’s biomedical engineering department.
3. REM Alarms. If the ForceTriad™ energy platform does not
sense the correct impedance for the connected REM patient return
electrode, monopolar energy will be disabled, the REM symbol
will illuminate red and enlarge on both the center and left touch-
screen displays, and an alarm tone will sound twice. The REM
symbol will return to its smaller size but will remain red, and RF
energy will remain disabled until the REM alarm is corrected.
When the REM alarm is corrected, the system is enabled and the
REM alarm indication illuminates green. Valleylab recommends
the use of Valleylab REM patient return electrodes. Return elec-
trodes from other manufacturers may not provide proper imped-
ance to work correctly with the ForceTriad™ energy platform. To
correct a REM alarm condition, follow these steps:
a. Inspect the return electrode plug and cord. If there is evi-
dence of cracks, breaks, or other visible damage, replace
the return electrode and/or the cord.
b. Verify that the patient return electrode cord is correctly
connected to the energy platform.
c. Verify that the return electrode is in good contact with the
patient. Follow the instructions for use provided with the
Valleylab REM patient return electrode.
d. If the REM alarm persists it may be necessary to use more
than one patient return electrode. Refer to the troubleshoot-
ing flow chart in the Valleylab REM patient return elec-
trode instructions for use.

E. Patient Safety Issues—Thermal Injury
1. The surgeon must be aware of the possibility of thermal injury
when utilizing any of these devices.
2. Unintended radiofrequency burns—Visceral burns may
occur by inadvertent direct coupling, capacitative coupling,
and/or insulation failures. This can happen during da Vinci®
robotic surgery, single port surgery, or NOTES surgery.
Table 3.2. Correcting malfunctions.
Situation Possible causes Solution
Abnormal neuromus- Metal-to-metal sparking Check all connections to the energy platform, patient
cular stimulation return electrode, and active electrodes
(stop surgery Can occur during coagulation Use a lower power setting for the Fulgurate and Spray
Immediately) modes
Abnormal 50–60 Hz leakage currents Contact your biomedical engineering department or a
Valleylab technical service representative for
assistance
Energy platform does Disconnected power cord or faulty wall outlet Check power cord connections (energy platform and
not respond when wall outlet). Connect the power cord to a functional
turned on outlet
Faulty power cord Replace the power cord
Fuse drawer is open or fuses are blown Replace the blown fuses(s). Close the fuse drawer
Refer to the ForceTriadEnergy Platform Manual
Internal component malfunction Use a backup energy platform. Contact your biomedi-
cal Engineering department or a Valleylab technical
service representative for assistance
System is on, but did not Software malfunction Turn off, then turn on the system
complete the self-test Internal component malfunction Note the code along with all information on the error
screen
Note the number and refer to System Alarms in the
User’s manual
Use a backup energy platform. Contact your biomedi-
3. Equipment Setup and Troubleshooting

cal Engineering department or a Valleylab technical
service representative for assistance
(continued)
37
 38

Table 3.2. (continued)
Situation Possible causes Solution
M.C. Airan

Energy platform is on Malfunctioning footswitch or handswitching Turn off the energy platform. Check and correct all
and instrument is instrument instrument connections
activated but system Turn on the energy platform. Replace the instrument
does not deliver if it continues to malfunction
output
Power is set too low Increase the power setting
An alarm conditions exists Note the code along with all information on the error
screen. Note the number and refer to System
Alarms in the User’s manual
In case of a REM alarm, refer to Correcting a REM
Alarm Condition in the User’s manual
Internal component malfunction Contact your biomedical engineering department or a
Valleylab technical service representative for
assistance
System does not detect tissue fusion instrument Firmly insert the LigaSmart connector into the
appropriate receptacle on the energy platform front
panel. Ensure the vessel fusion touch screen
indicates that it has detected the instrument
System does not detect monopolar instrument Firmly insert the Smart connector into the appropriate
receptacle on the energy platform front panel.
Ensure the monopolar touch screen indicates that it
has detected the instrument
Situation Possible causes Solution
System does not detect bipolar instrument Firmly insert the connector into the appropriate
receptacle on the energy platform front panel.
Ensure the bipolar touch screen indicates that it has
detected the instrument
CHECK INSTRUMENT Excessive tissue/eschar on electrode tips or jaws Clean electrode tips and jaws with a wet gauze pad
screen appears, a Electrodes have come loose from the instrument Reinsert the electrode into the instrument jaws
six-pulsed tone jaws making sure that all the electrode pins are firmly
sounds, and RF Electrode pins may have been compromised seated
output is disabled or bent during assembly to the instrument
and may need to be replaced
Metal or other foreign object is grasped Avoid grasping objects, such as staples, clips, or
within jaws encapsulated sutures in the jaws of the instrument
Tissue grasped within jaws is too thin Open the jaws and confirm that a sufficient amount of
tissue is inside the jaws. If necessary, increase the
amount of tissue and repeat the procedure
Pooled fluids around instrument tip Minimize or remove excess fluids
REACTIVATE screen The seal cycle was interrupted before completion. Reactivate the seal cycle without removing or
appears, a four-pulsed The handswitch or footswitch was released repositioning the instrument
tone sounds, and RF before the end tone activated
output is disabled Additional time and energy are needed to complete
the fusion cycle
Continuous monitor Malfunctioning monitor Replace the monitor
(continued)
3. Equipment Setup and Troubleshooting
39
 40
M.C. Airan

Table 3.2. (continued)
Situation Possible causes Solution
Interference Faulty chassis-to-ground connections Check and correct the chassis ground connections for
the monitor and for the energy platform
Check other electrical equipment in the room for
defective grounds
Electrical equipment is grounded to different Plug all electrical equipment into line power at the
objects rather than a common ground. The same location. Contact your biomedical engineer-
energy platform may respond to the resulting ing department or a Valleylab representative for
voltage differences between grounded objects assistance
Interference with other Metal-to-metal sparking Check all connections to the energy platform, patient
devices only when return electrode, and instruments instrument
the energy platform is High settings used for fulguration Use lower power settings for fulguration
activated Electrically inconsistent ground wires in the Verify that all ground wires are as short as possible
operating room and go to the same grounded metal
If interference continues when the energy platform Some manufacturers offer RF choke filters for use in
is activated, the monitor is responding to radiated monitor leads. The filters reduce interference when
frequencies the energy platform is activated and minimize the
potential for an electrosurgical burn at the site of
the monitor electrode
Situation Possible causes Solution
Pacemaker interference Intermittent connections or metal-to-metal Check the active and patient return electrode cord
sparking connections
It may be necessary to reprogram the pacemaker
Current traveling from active to return electrode Consult the pacemaker manufacturer or hospital
during monopolar electrosurgery is passing too cardiology department for further information when
close to pacemaker use of electrosurgical appliances is planned in
patients with cardiac pacemakers
Use bipolar instruments, if possible
If you must use a monopolar instrument, place the
patient return electrode as close as possible to the
surgical site. Make sure the current path from the
surgical site to the patient return electrode does not
pass through the vicinity of the heart or the site
where the pacemaker is implanted
Always monitor patients with pacemakers during
surgery and keep a defibrillator available
Internal Cardiac ICD is activated by energy platform Stop the procedure and contact the ICD manufacturer
Defibrillator (ICD) for instructions
activation
Copyright ©2010 Covidien. All rights reserved. Reprinted with the permission of the Energy-based Devices division of Covidien.
3. Equipment Setup and Troubleshooting
41
42 M.C. Airan

Fig. 3.7. Encision® active electrode monitoring unit. ©2010 Encision.
All rights reserved. Image reprinted with permission from Encision, Inc.

3. These injuries can be avoided by use of bipolar RF, harmon-
ics, or laser or use of active electrode monitoring system such as
Encision® (Fig. 3.7).
a. Monopolar devices—Thermal injuries can occur at the tip
of monopolar instruments.
b. Bipolar devices—Bipolar instruments usually do not have
an extensive spread around the operating tip if the current
used is brief.
c. Valleylab ForceTriad™ energy platform—LigaSure™
platform also limits the thermal spread at the operating tip.
d. Ultrasonic scalpels can also have thermal spread at the
operating tip.
4. Operating room fires.
a. Be aware that the light cord tip can become very hot, i.e.,
the end that goes into the light generator. Do not disconnect
hot light cord from light generator if it is close to an oxy-
gen source, i.e., nasal cannula, masks, oropharyngeal tube,
endotracheal tubes. This hazard is deadly during extuba-
tion. Many patients have been burned.
b. Chlora-Prep has alcohol base. The vapors from the prepa-
ration can be ignited by Bovie tips, hot ultrasonic tips, etc.
 3. Equipment Setup and Troubleshooting 43

Acknowledgments
Berdelle, Susan. Office Manager, Mohan C Airan, MD SC. Riechert,
John Brian. Energy Based Sales Representative. Covidien.

Selected References
Podnos Y, Williams R. Fires in the operating room. American College of Surgeons,
Committee on Perioperative Care. http://www.facs.org/about/committees/cpc/
oper0897.html. Accessed 28 Mar 2011.
Encision Inc. Developer and manufacturer of the patented AEM technology. http://www.
encision.com. Accessed 19 Jan 2011.
Energy Based Division, Covidien. User’s Guide ForceTriad™ energy platform. Boulder,
CO; 2008.
ForceTriad Web site. http://www.forcetriad.com. Accessed 19 Jan 2011.
SAGES Continuing Education Committee. Laparoscopy Troubleshooting Guide. SAGES,
Santa Monica, CA; 2006. http://www.sages.org/publications/troubleshooting/.
Accessed 4 Mar 2011.
Sony Corporation. Rear panel diagram for Trinitron color video monitor. 1995.
4. Ergonomics in Operating
Room Design

Erica R.H. Sutton, M.D.
Adrian Park, M.D., F.R.C.S.E., F.A.C.S., F.C.S. (ECSA)

A. The Human–Machine Interface
The operating room (OR) is a complex working environment reliant
on high-stakes decision-making that increasingly must take into account
interfaces between humans and machines. With the opportunities for
error frequent and the consequences potentially grave, the gathering of
full, accurate, applicable knowledge regarding these interfaces must be
considered of utmost importance. As nearly three decades of minimally
invasive surgical advancements have indicated, the cost of conditions
ergonomically unfavorable to the surgeon cannot safely be disregarded,
for the resulting consequences are surely borne by doctor and patient
alike. Achievement of optimal human–machine interfaces in the OR
depends on the systematic discovery and implementation of ergonomi-
cally sound principles in this challenging workspace.

B. Ergonomics Defined
The objective of the applied science of ergonomics is ensuring that
efficient and safe interaction is possible between things and persons.
Ergonomics seeks—as suggested by its Greek roots translatable as “the
natural laws of work”—to establish and define people’s relationship to
work, which may at once be both physical and cognitive.
Ergonomics as applied to OR design is still taking shape as an infor-
mative, evidence-based field of research. A good number of mechanical
ergonomics studies have appeared that take as their focus the optimal

N.J. Soper and C.E.H. Scott-Conner (eds.), The SAGES Manual: Volume 1 45
Basic Laparoscopy and Endoscopy, DOI 10.1007/978-1-4614-2344-7_4,
© Springer Science+Business Media, LLC 2012
46 E.R.H. Sutton and A. Park

physical and technological working conditions of the OR—monitor
placement and display characteristics, table height, instrument design
and capability, surgical workflow. Standard ergonomic research into OR
design and equipment has elucidated many shortcomings of the working
environment, thus far with particular regard to open surgery performance.
The research to date, however, primarily offers only suggestions as to
what a prototype might do or how it and its end user should interface.
Ergonomics, theoretical and applied, has not yet determined what consti-
tutes an ideal OR suite or even the most advantageous prototypes needed
for efficacious research.
Similarly, while staples of our evidence-based literature, the
metrics by which we assess cognitive ergonomics—subjective reports
of well-being or psychological stress, gaze and attention disruptions,
heart-rate variability, or complex indices of mental workload—are not
well or often defined in relation to one another and even more rarely in
terms of consequence to surgeon or surgical outcome. Correlations to
professional longevity and patient safety are often suggested but infre-
quently measured. While the definitions of mechanical ergonomics
and cognitive ergonomics have gained consensus, their component
metrics are at present subjective and substantially lacking validation in
the field of medicine.

C. Influence of Nonsurgical Ergonomics
Given the reality of the significant consideration that must be accorded
to the human–machine interface, the introduction of ergonomics as a pri-
mary consideration in the design of the OR suite has been in many ways
as unsystematic as was the introduction of MIS itself. Prior to its recent
acceptance of the potentials to be gained by obtaining and applying ergo-
nomic data gathered in its environments and from its staffs, the medic