Abstract: The present invention provides a fixating means (200) adapted for use in hernia repair surgeries in attaching a mesh (2) and mesh deployment means (3); said fixating means are attached to said mesh deployment means (3); said fixating means (200) comprising: (a) a first portion (200a) coupled to said deployment means (3); and, (b) a second portion (200b), comprising a coil (252) having a predetermined retracted shape; said coil is reconfigurable from a plurality of unretracted positions to a plurality of retracted positions and from said plurality of retracted positions to said plurality of unretracted positions; wherein said attachment between said deployment means (3) and said mesh (2) is obtained by reconfiguration of said coil (252) from at least one of said unretracted positions to at least one of said retracted positions.

Abstract: The present invention discloses a system for handling a surgical instrument, useful for observation and/or intervention with respect to a patient's body. The system comprising a fixed support; hinge which enable changing of the inclination of the system; actuators system that produce the rotation movement utilized by handling surgical instrument mechanism; a flexible power transmission system; gear housing adapted to change the direction of the motors rotation transmitted by the flexible power transmission system; and, handling surgical instrument mechanism, said mechanism comprising: a first small size moveable element, connected to the gear housing is adapted to simultaneous maneuver of a second moveable element to the four main directions, and/or any other maneuver, e.g.

Abstract: An interface between a surgeon and an automated assistant, including: at least one array comprising N RF transmitters, where N is a positive integer; at least one RF receiver provided with at least two directional antenna; means for attaching said RF transmitter array to at least one surgical tool; and a computerized operating system adapted to record the received signal strength (RSS) received by each antenna of the one RF receiver and to calculate therefrom the position of each of the N RF transmitters, and further adapted to provide automatically the results of the calculation to the surgeon.

Abstract: An elongate open-bored applicator (EOBP) adapted to deploy a mesh comprising (a) at least one inflatable contour-balloon; (b) at least one inflatable dissection balloon. The inflatable contour-balloon and the inflatable dissection balloon are adjustable and located at the distal portion; and, (c) at least one actuating means located at the proximal portion. The actuating means is in communication with the inflatable contour-balloon and the inflatable dissection balloon. The actuating means is adapted to provide the inflatable contour-balloon and the inflatable dissection balloon with independent activation and/or de-activation.

Abstract: It is one object of the present invention to provide an endoscope positioning system (EPS) for maneuvering, orienting and positioning an endoscope relatively to an organ being operated within a patient's body. The EPS is especially used during orthopedic operations such that the organ is constantly moved during the operation. The EPS includes: at least four freedom degree mechanisms (FDFM) that are adapted to actuate the distal portion of the endoscope by maneuvering the proximal portion of the endoscope; and at least one body adapter gripper adapted to reversibly and firmly attach the EPS to the patient's body. The FDFM includes at least a first, second, third and fourth means for providing the four degrees of freedom. The means of first degree of freedom is a rotation sub-mechanism adapted to rotate the endoscope around its longitudinal axis. The means of second degree of freedom is a tilting sub-mechanism. The means of third degree of freedom is an arch sub-mechanism.

Abstract: An improved interface between the surgeon and an endoscope system for laparoscopic surgery, holding a laparoscopic came and/or controlling an automated endoscope assistant includes at least one wireless transmitter with at least one operating key (12a). at least one wireless receiver (11), at least one conventional laparoscopy computerized system (15) loaded with conventional surgical instrument spatial location software, and conventional automated assistant maneuvering software, software loaded onto to the conventional laparoscopy system that enables a visual response to the depression of at least one key on the wireless transmitter as well as an interface with the conventional automated assistant maneuvering software so as to achieve movement of the endoscope, and at least one video screen (30).

Abstract: An improved interface between the surgeon and an endoscope system for laparoscopic surgery, holding a laparoscopic came and/or controlling an automated endoscope assistant includes at least one wireless transmitter with at least one operating key (12a). at least one wireless receiver (11), at least one conventional laparoscopy computerized system (15) loaded with conventional surgical instrument spatial location software, and conventional automated assistant maneuvering software, software loaded onto to the conventional laparoscopy system that enables a visual response to the depression of at least one key on the wireless transmitter as well as an interface with the conventional automated assistant maneuvering software so as to achieve movement of the endoscope, and at least one video screen (30).

Abstract: A method of treating hernia by means of implanting at least one collapsible mesh comprising plane body at least partially enveloped by one or more elastic collar, said rolled in an elongate open-bored applicator comprising anterior portion terminated outside the body and posterior portion located inside the body, comprising: inserting the posterior end of the applicator throughout the hernia into the wall of the abdominal cavity; releasing said mesh into said cavity while helically deploying the same such that said mesh is laying in parallel to said wall; and, ejecting said applicator.

Abstract: Process for generating the image of a 3-dimensional rigid body on a computer screen. a system of 3-dimensional space coordinates is defined in the space in which the body moves. Software, which defines the way in which the body appears when viewed at a given angle and distance to one of the coordinate planes is established and the coordinates are determined in the coordinates system of a number of points. The coordinates of the points of the rigid body and the software are transmitted to the computer, which creates the image of the rigid body when in any specific position in space and viewed at any specific angle. The points of the rigid body, the coordinates of which are determined, may be in the number of three. The rigid body may have symmetries and the points thereof, the coordinates of which are determined, may be less than three.