Single-site colectomy with miniature in vivo robotic platform.

There has been a continuing push to reduce the invasiveness of surgery by accessing the abdominal cavity through a single incision, such as with laparoendoscopic single-site (LESS) surgery. Although LESS procedures offer significant benefits, added complexities still inhibit the procedures. Robotic surgery is proving to be an excellent option to overcome these limitations. This paper presents the experimental results of the single-incision in vivo surgical robot (SISR), a multifunctional, dexterous, two-armed robot capable of performing surgical tasks while overcoming the issues associated with manual LESS operations. In vivo surgical procedures have been used to demonstrate the efficacy of using a robotic platform over traditional laparoscopic tools. The most recent experimental test resulted in the first successful in vivo robotic LESS colectomy utilizing a robot completely contained within the abdominal cavity. In this test, SISR showed significant benefits including access to all quadrants in the peritoneal cavity and improved dexterity.

Miniature surgical robot for laparoendoscopic single-incision colectomy.

BACKGROUND: This study aimed to demonstrate the effectiveness of using a multifunctional miniature in vivo robotic platform to perform a single-incision colectomy. Standard laparoscopic techniques require multiple ports. A miniature robotic platform to be inserted completely into the peritoneal cavity through a single incision has been designed and built. The robot can be quickly repositioned, thus enabling multiquadrant access to the abdominal cavity. METHODS: The miniature in vivo robotic platform used in this study consists of a multifunctional robot and a remote surgeon interface. The robot is composed of two arms with shoulder and elbow joints. Each forearm is equipped with specialized interchangeable end effectors (i.e., graspers and monopolar electrocautery). RESULTS: Five robotic colectomies were performed in a porcine model. For each procedure, the robot was completely inserted into the peritoneal cavity, and the surgeon manipulated the user interface to control the robot to perform the colectomy. The robot mobilized the colon from its lateral retroperitoneal attachments and assisted in the placement of a standard stapler to transect the sigmoid colon. This objective was completed for all five colectomies without any complications. CONCLUSIONS: The adoption of both laparoscopic and single-incision colectomies currently is constrained by the inadequacies of existing instruments. The described multifunctional robot provides a platform that overcomes existing limitations by operating completely within one incision in the peritoneal cavity and by improving visualization and dexterity. By repositioning the small robot to the area of the colon to be mobilized, the ability of the surgeon to perform complex surgical tasks is improved. Furthermore, the success of the robot in performing a completely in vivo colectomy suggests the feasibility of using this robotic platform to perform other complex surgeries through a single incision.

Miniature in vivo cameras for use in single-incision robotic surgery - biomed 2011.

Single-incision surgery provides numerous benefits over traditional open and laparoscopic surgery techniques including reduced pain, shortened recovery times, and minimal tissue scarring. The use of miniature in vivo robots inserted through a single incision offers additional advantages over conventional laparoscopy in improved maneuverability and dexterity. One consequence of performing surgical procedures through a small single incision is the loss of direct visualization through a large open incision or visualization via laparoscopic cameras inserted through additional ports. For this reason, a miniature in vivo actuated camera was designed to pass through a single incision and attach to a miniature in vivo robot, providing live video feedback at the control of the surgeon. The device was tested in a lab setting and porcine model surgery and demonstrated successful movement, control, and high-quality visualization, indicating the device’s functionality and feasibility for use in single-incision robotic surgery.

Miniature in vivo robot for laparoendoscopic single-site surgery.

BACKGROUND: The aim of this study was to develop a multidexterous robot capable of generating the required forces and speeds to perform surgical tasks intra-abdominally. Current laparoscopic surgical robots are expensive, bulky, and fundamentally constrained by a small entry incision. A new approach to minimally invasive surgery places the robot completely within the patient. Miniature in vivo robots may allow surgeons to overcome current laparoscopic constraints such as dexterity, orientation, and visualization. METHODS: A collaborative research group from the Department of Surgery at the University of Nebraska Medical Center and the College of Engineering at the University of Nebraska-Lincoln designed and built a surgical robot prototype capable of performing specific surgical tasks within the peritoneal cavity. RESULTS: The basic robotic design consists of two arms each connected to a central body. Each arm has three degrees of freedom and rotational shoulder and elbow joints. This combination allows a surgeon to grasp, manipulate, cauterize, and perform intracorporeal suturing. The robot's workspace is a hollow hemisphere with an inner radius of 75 mm and an outer radius of 205 mm. Its versatility was demonstrated in four procedures performed in a porcine model: cholecystectomy, partial colectomy, abdominal exploration, and intracorporeal suturing. CONCLUSIONS: Miniature in vivo robots have the potential to address the limitations of using articulated instrumentation to perform advanced laparoscopic surgical procedures. Once inserted into the peritoneal cavity, the robot provides a stable platform for visualization with sufficient dexterity and speed to perform surgical tasks from multiple orientations and workspaces.

Laparoendoscopic single-site surgery using a multi-functional miniature in vivo robot.

BACKGROUND: Existing methods used to perform laparoendoscopic single-site surgery (LESS) require multiple laparoscopic tools that are inserted into the peritoneal cavity through a single, specialized port. These methods are inherently limited in visualization and dextrous capabilities by working through a single access point. A miniature in vivo robotic platform that is completely inserted into the peritoneal cavity through a single incision can address these limitations, providing more intuitive manipulation capabilities and improved visualization. METHODS: The miniature in vivo robotic platform for LESS consists of a multi-functional robot and a remote surgeon interface. The robot has two arms and specialized end effectors that can be interchanged to provide monopolar cautery, tissue manipulation, and intracorporeal suturing capabilities. RESULTS: This robot has been demonstrated in multiple non-survival procedures in a porcine model, including four cholecystectomies. CONCLUSION: This study demonstrates the effectiveness of using a multi-functional miniature in vivo robot platform to perform LESS.