Shape Deposition Manufacturing of a Soft, Atraumatic, Deployable Surgical Grasper1
Joshua B. Gafford, Ye Ding, Andrew P. Harris, Terrence McKenna, Panagiotis Polygerinos, Dónal Holland, Conor J. Walsh
- Year
- 2014
- Citations
- 38
Abstract
Laparoscopic pancreaticoduodenectomy (also known as the Whipple procedure) is a highly-complex minimally-invasive surgical (MIS) procedure used to remove cancer from the head of the pancreas. While mortality rates of the MIS approach are comparable with those of open procedures, morbidity rates remain high due to the delicate nature of the pancreatic tissue, proximity of high-pressure vasculature, and the number of complex anastomoses required [1]. The sharp, rigid nature of the tools and forceps used to manipulate these structures, coupled with lack of haptic feedback, can result in leakage or hemorrhage, which can obfuscate the surgeon's view and force the surgeon to convert to an open procedure.We present a deployable atraumatic grasper (103 mm long and 14 mm outer diameter when closed) with on-board pressure sensing, allowing a surgeon to grasp and manipulate soft tissue during laparoscopic pancreatic surgery. Created using shape deposition manufacturing, with pressure sensors embedded in each finger enabling real-time grip force monitoring, the device offers the potential to reduce the risk of intraoperative hemorrhage by providing the surgeon with a soft, compliant interface between delicate pancreatic tissue structures and metal laparoscopic forceps that are currently used to manipulate and retract these structures on an ad hoc basis. Initial manipulation tasks in a simulated environment have demonstrated that the device can be deployed though a 15 mm trocar and develop a stable grasp on a pancreas analog using Intuitive Surgical's daVinci™ robotic end-effectors.Functional requirements of the system were informed by interviews with physicians and procedural observations. The manipulator prototype, shown in Fig. 1, consists of: (1) multijointed, cable-actuated fingers, (2) the quick-release handle, and (3) the sensing system and light-emitting diode (LED) visualization for active grasping force feedback.A three-finger design where fingers mutually oppose each other at a 120 deg angle was selected that allows for a high surface area for each finger to better distribute grasping force and enable a grasped object to be completely constrained. This configuration also has the advantage of maximizing the surface area of each finger given a 15 mm diameter size constraint as imposed by the port size.The fingers were designed deterministically using a combination of analytical and experimental tools, as shown in Fig. 2. An analytical model was built in matlab (Natick, MA) to assist in parametric optimization via brute-force methods. Once optimum finger parameters were short-listed, empirical finger models were fabricated using shape deposition manufacturing. A series of tests were performed wherein fingers were evaluated according to their transmission ratio and “jamming score” (i.e., the ability of the finger to geometrically “trap” material within its distal joint). Thus, a finger with three joints, and proportionally decreasing joint stiffness (from proximal to distal joint) was chosen.The handle design features a “reversible” ratcheting mechanism, as illustrated in Fig. 3. The surgeon, using two manual or robotic forceps, pulls on a cable to engage a ratchet with a cantilevered pawl. Positive engagement establishes and maintains tension in the cable to close the grasper. Once deployed, the surgeon needs only one end-effector to interface with the grasper and manipulate tissue. To release the grasper, the surgeon rotates the handle by 45 deg from the finger base to disengage the ratchet and pawl, and a compressive spring returns the ratchet to its original position, relieving tension in the fingers and allowing the grasper to be removed.The distal segment of each finger has a rubber-encapsulated MEMS pressure sensor (TakkTile LLC) directly integrated into it, enabling real-time monitoring of the grasping force. Force information is relayed to the surgeon via a glowing red-green-blue LED ring, which turns from green to red once
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