Abstract: A device, method, and system are provided for measuring the fit and mechanical properties of an intended ligament or tendon graft during a surgical procedure. The device includes a sensor body, a set of temporary fixation securements that terminate a set of opposing sides of the sensor body, and electronic circuitry in communication with the sensor body, where the electronic circuitry generates electric signals in proportion to the mechanical properties experienced by the sensor body. The set of temporary fixation securements are adapted to attach to at least one of: (i) one or more patient bones, or (ii) permanent fixation hardware assembled to one or more patient bones.

Abstract: A system and method are described herein for designating a precise location for a bone tunnel to receive a ligament or tendon graft and guiding a robotic drill for creating the bone tunnel. The system includes a tracking system, a digitizer, a computing system, and a robotic drill. The digitizer designates a start point for the tunnel entry site and an end point where the tunnel terminates. The start point and end point are recorded in the computing system and a vector is calculated between the start point and the end point. The vector is supplied to a robotic drill to drill the tunnel in the bone. A ligament or tendon graft may be placed in the tunnel and secured to the bone to complete the procedure.

Abstract: A device for checking post cut plane accuracy and alignment following bone removal in a bone of a patient during a computer-assisted surgical procedure to create a bone surface is provided. The device includes a body having an axis and adapted to contact the bone surface. One or more alignment features are associated with the body and are accessible when the body is in contact with the bone surface. Each of the one or more alignment features has a known orientation and position relative to the axis. A method for checking post cut plane accuracy and alignment following removal of bone from a patient to create a bone surface during a computer-assisted surgical procedure is also provided. A computer-assisted surgical system is provided that includes a tracking system, a tracked digitizer probe, the aforementioned device, a tracked surgical device, and one or more computers with software for determining the orientation.

Abstract: A saw guide for guiding a surgical saw or drill includes a guide portion having one or more guide slots, the one or more guide slot or hole configured to guide a surgical saw or drill. The guide portion has an attachment portion forming a clamping slot between the guide portion and the attachment portion. A clamp locking mechanism is assembled to the guide portion and has one or more cams in contact with the attachment portion. An alignment system for surgical bone cutting procedures is provided that includes bone pins inserted within a virtual plane relative to a cut plane to be created on a subject's bone. One of the aforementioned guides is configured to be received onto the bone pins, one or more guide slots within said guide, said one or more guide slots configured to guide a surgical saw to make surgical cuts on the subject's bone.

Abstract: A saw guide for guiding a surgical saw or drill includes a guide portion having one or more guide slots, the one or more guide slot or hole configured to guide a surgical saw or drill. The guide portion has an attachment portion forming a clamping slot between the guide portion and the attachment portion. A clamp locking mechanism is assembled to the guide portion and has one or more cams in contact with the attachment portion. An alignment system for surgical bone cutting procedures is provided that includes bone pins inserted within a virtual plane relative to a cut plane to be created on a subject's bone. One of the aforementioned guides is configured to be received onto the bone pins, one or more guide slots within said guide, said one or more guide slots configured to guide a surgical saw to make surgical cuts on the subject's bone.

Abstract: Methods and systems to optimize ligament reconstruction surgical outcomes by enabling bone tunnel(s) to be precisely and optimally placed through the use of pre-operative planning systems coupled with precision control bone evacuation machines, such as robotic drills are provided. The methods generally include receiving and processing scan data of a patient's bone(s); pre-determining the optimal tunnel placement parameter(s) with the scan data; placing registration marker(s) on the patient's bone(s) percutaneously; and creating a tunnel in the patient's bone(s) with a system coupled to receive and execute according to the pre-determined optimal tunnel placement parameter(s).

Abstract: Methods and systems to optimize ligament reconstruction surgical outcomes by enabling bone tunnel(s) to be precisely and optimally placed through the use of pre-operative planning systems coupled with precision control bone evacuation machines, such as robotic drills are provided. The methods generally include receiving and processing scan data of a patient's bone(s); pre-determining the optimal tunnel placement parameter(s) with the scan data; placing registration marker(s) on the patient's bone(s) percutaneously; and creating a tunnel in the patient's bone(s) with a system coupled to receive and execute according to the pre-determined optimal tunnel placement parameter(s).