Emergency Undocking in Robotic Surgery: A Simulation Curriculum

Summary

This training platform is designed to allow robotic surgeons to develop the skills necessary to lead an interprofessional team in emergency undocking of the robotic system. Training includes the utilization of the technology and equipment to perform an emergency undocking, as well as delineation of roles for such a scenario.

Abstract

The following is a training platform to allow robotic surgeons to develop the skills necessary to lead an interprofessional team in emergency undocking of a robotic system. In traditional robotic training for surgeons, a brief web based overview of performing an emergency undocking is provided during initial introductory training to the robotics system. During such a process, there is no training in delineation of interdisciplinary roles for operating room (OR) personnel. The training presented here uses formative simulation and debriefing followed by a lecture. For the simulation, a modified gynecologic simulator is draped in a steep trendelenburg position consistent with most gynecologic laparoscopic surgery. The training torso is modified using tubing hooked to pressure bags of red food colored IV fluid used to simulate a catastrophic vessel injury on demand. Positioned throughout the operating room setting is an interprofessional team consisting of embedded standardized persons (ESPs) to fulfill the roles of a circulating nurse, scrub nurse, anesthesiologist, and bedside assist surgeon. Robotic surgeons are presented a case scenario necessitating emergency undocking, and given control of the robotic instruments. The scenario is terminated following either successful completion of an emergency undock, or at five minutes due to the emergent nature of the case. A debriefing session with hands on training of the steps to emergency undocking, necessary equipment, troubleshooting techniques, and operating room personnel roles follows the simulation. The learners are presented with a short lecture reemphasizing the material presented in the debriefing for their own self-study. This training results in improved time accessing the patient, improved knowledge, confidence, and completion of critical actions, and can be replicated in most institutions. All robotic surgeons should be able to demonstrate competence in this crucial intervention. A limitation of the curriculum is ability to access the in-situ environment for training purposes.

Introduction

The purpose of this training is to improve robotic surgeons' confidence, knowledge, and proficiency of performing an emergency undocking of the robotic system, and to improve the surgeon's ability to lead an interprofessional team through effective communication of clearly delineated roles in the event of an emergency undocking. Despite the abundance of personnel and equipment in the operating room, there is a lack of experience managing these crises^1,2. Current training requirements of online course work and a short period of proctored cases leave many surgeons feeling their training is inadequate³. Regardless of these feelings of inadequacy, prior studies have established that surgeons will encounter at least 1 OR emergency in their career⁴. Strategies to improve on these feelings of inadequacy include increasing usage of simulation training⁵. It is well established that simulation training is becoming inseparable from surgical education⁶. Prior studies have determined that simulation-based team training is an invaluable tool in helping learners overcome cognitive and behavioral gaps in surgical education and is useful as a tool to allow trainees in sessions with other team members the ability to demonstrate baselines for knowledge and communication skills, while improving performance following combining simulation exercises and debriefing^{4,7,8,9,10,11}.

To improve robotic crisis management, various simulator-training scenarios have been developed^1,12,13. While there have been numerous studies examining the effects of team training, there is a dearth of research analyzing training on complex OR scenarios⁴. During complex OR emergencies, checklists and the clear delineations of roles through effective communication are of paramount importance. In robotic surgery, there is a paucity of literature available outlining protocols or training for this procedure¹⁴. Simulation has proven effective in validating checklists for use during operating-room crises to improve surgical care¹⁵. Here, we present a training curriculum to allow robotic surgeons to develop the skills necessary to lead an interprofessional team in an emergency undocking of a robotic system. Implementation of this curriculum takes place over three sessions in an in-situ environment, as laid out in Figure 1, and can be used to provide training, demonstrate skills for credentialing, and is easily reproducible in any hospital with a robotic system.

Protocol

The IRB determined that this project was exempt from IRB review in accordance with federally defined categories of exempt review per 45 CFR 46.101 Category 2.

1. Gather and Prepare Materials

1. Collect materials for the training curriculum, including a robotic system with 2 training arms (see Table of Materials), 3 trocars, and a laparoscope.
2. In the hollow training torso, create at least 3 separate incisions with a scalpel to place laparoscopic instrument trocars. Ensure that the incisions are consistent with those found in robotic surgery, i.e., one above the umbilicus, and one in each the right and left lower quadrant large enough to accommodate a trocar.
3. To simulate a vessel and subsequent vessel injury, create a vessel using rubber tubing. Tubing from a water seal chest drain functions well.
   1. Cut a separate tube for the vena cava and descending aorta.
   2. Connect two shorter pieces replicating the right and left common iliac veins and two shorter pieces replicating the common iliac arteries to the vena cava and aorta, respectively, using a Y-connector.
   3. Create a notch at the distal end of the common iliac artery to allow for simulated blood to escape in the case of a vessel injury.
   4. Place the vessels against the posterior wall of the torso and secure using glue. Protrude the access point to the vessel through the cephalad portion of the torso to allow for instillation of red food colored fluid.
   5. Color as necessary for realism with oil base red and blue paint for artery and vein respectively. Coat with a protective clear enamel spray for durability.
4. Obtain a 1-liter bag of IV fluid. Inject red food coloring until the fluid has a color consistent with blood. Hook this bag to the previously assembled vessel.
5. Drape the torso with operating room drapes used for laparoscopic surgery or laparotomy. Ensure that the drape covers the entire OR table.
6. Have embedded standardized persons (ESPs) or confederates fulfill the roles laid out in the emergency undocking protocol (Figure 2). A minimum of 4 individuals is required. Alternatively, OR personnel can be employed to perform their actual roles.

2. Setup of the Operating Room

1. Place the training torso, complete with vessel and IV tubing, and connect it to an IV fluid bag on the OR table. Place the table in a steep trendelenburg position, then drape using OR drapes.
2. Place the laparoscopic trocars into the training torso through the incisions made previously. Move the robotic patient side cart to the bedside, and attach robotic arms to trocars. Once attached, dock robotic training instrument and camera to torso using trocars.
3. Place ESPs or OR staff in desired roles as described in Figure 2. Have the surgeon console on and ready for surgeon to assume control of robotic instruments.

3. Simulation and Debriefing

1. Have the surgeon enter the room and position at the surgeon's console. Instruct the surgeon to adjust positional settings, but not take control of the instruments until completion of orientation to the case.
2. Introduce the ESPs or OR staff to the surgeon. Read one of the case stems presented in Figure 3. Then, instruct the surgeon to take control of the instruments following completion of the case stem.
3. Have the anesthesia ESP initiate bleeding from the vessel via pressure bag or manual pumping of fluid bag once the case stem is completed. The IV tubing should be wide open, allowing for brisk bleeding. Allow the surgeon up to 5 minutes to complete emergency undocking.
4. Following the case (or after 5 minutes), proceed with debriefing and didactic component of the scenario and procedure. During the debriefing emphasize key points of personnel roles as listed in Figure 2, key equipment including instrument arms and patient side cart, and use of closed loop communication.
5. Reposition ESPs or OR staff, and run a second case to reinforce the lessons taught during debriefing. Following the case, reiterate any points missed during the second case.

Results

By incorporating this curriculum as outlined in Figure 1 and the undocking protocol outlined in Figure 2 during training in robotic-assisted surgery, our study demonstrated an overall improvement in the confidence, knowledge, and critical actions performed by the surgeon as demonstrated in Figure 3. Baseline measurements in knowledge and confidence were collected on all participants immediately prior...

Discussion

Incorporating this curriculum into training necessitates adherence to the protocol as outlined previously. Ensuring practice through hands on training of both the technical aspects of emergency undocking, as well as delineation of roles of OR personnel, is essential towards successful training. All three sessions of pre-training simulation, debriefing, and post-training simulation are likely required to ensure maximal benefit to the learner.

An attempt should be made to create as realistic a l...

Materials

Name	Company	Catalog Number	Comments
ZOE Gynecologic Simulator	Gaumard	S504.100	Incisions placed above umbilicus and in right and left lower quadrants large enough to pass trochars through. Vessels as detailed below. Tubing used to make aorta spliting into common iliacs as well as inferior vena cava.
da Vinci Si Robotic System	Intuitive Surgical
Tubing from Atrium Water Seal Chest Drain	Atrium		Suction tubing removed an colored
Chest Tube Y-connector	Sorin Group	050525-000	Connected to suction tubing for split from descending aorta to right and left iliac vessels
Reeve's Oil Colour Paint Set	Reeves		Coloring for venous and arterial vessel (Red and Blue)
Rust-oleum Clear Coat Enamel Spray	Rust-oleum		Coating for protection of vessels coloring