Abstract: A telerobotic surgery system includes a robotic surgery station having a first pair of robot arms, each carrying a laparoscopic tool and each having a robot arm drive. A first controller is connected to each robot arm drive. Harvested animal tissue is at the robotic surgery station. A remote surgeon station includes a second pair of robot arms, each carrying a laparoscopic tool and each having a robot arm drive. A second controller receives data regarding movement of the second pair of robot arms and respective laparoscopic tool based on user manipulation of each laparoscopic tool at the remote surgeon station. A communications network couples the first and second controllers with the second controller operative as a master and the first controller configured to control each robot arm drive and effect one-to-one movement of the first pair of robot arms and carried laparoscopic tools as a slave.
Abstract: A surgical simulation device includes a support structure and animal tissue carried in a tray. A simulated human skeleton is carried by the support structure above the animal tissue and includes simulated human skin. A camera images the animal tissue and an image processor receives images of markers positioned on the ribs and animal tissue and forms a three-dimensional wireframe image. An operating table is adjacent a local robotic surgery station as part of a robotic surgery station and includes at least one patient support configured to support the patient during robotic surgery. At least one patient force/torque sensor is coupled to the at least one patient support and configured to sense at least one of force and torque experienced by the patient during robotic surgery.
Abstract: A surgical simulation device may include a support structure, a tray carried by the support structure, and animal tissue carried by the tray. A simulated human skeleton portion may be carried by the support structure above the animal tissue, and simulated human skin covers the simulated human skeleton portion. The support structure may permit selective horizontal and vertical positioning of the tray relative to the support structure to thereby permit selective horizontal and vertical positioning of the animal tissue relative to the simulated human skeleton portion and simulated human skin.
Type:
Grant
Filed:
September 15, 2016
Date of Patent:
February 5, 2019
Assignee:
KINDHEART, INC.
Inventors:
Allen Wendell Moore, Samuel D. Drew, W. Andrew Grubbs, Kevin R. Simpson, Samuel C. Felts, Jr.
Abstract: A surgical simulation assembly is provided for simulating realistic surgery on animal organs or human cadavers. The surgical simulation assembly comprises a generally flat tray having a central indentation for receiving an organ, at least one drainage aperture and at least one indented trough extending from the central indentation for receiving at least one tube. The tray is assembled with a simulator heart and lungs prepped for connection to a variable speed double action air pump assembly that creates both positive pressure and a vacuum on the heart to simulate a beating heart. The tray is supported on a basket having a lower containment portion for containing fluid waste collected during the simulated surgery. The basket is elevated by risers over a base designed to support the assembly.
Type:
Grant
Filed:
July 24, 2014
Date of Patent:
October 31, 2017
Assignee:
KINDHEART, INC.
Inventors:
Richard H. Feins, Tom Birchard, W. Andrew Grubbs, Don Aikin, Daniel C. Fuccella