Abstract: An impactor and methods of operation of an impactor. The impactor includes an electromagnetic component that has a stationary electromagnetic housing and a moving magnet actuator, a striker, and one or more strike plates. The striker is coupled to an object. The stationary electromagnetic housing includes a coil that receives an electric current. The moving magnet actuator includes one or more magnets. The magnets generate a high potential magnetic field that interacts with the electric current applied to the coil disposed within the stationary electromagnetic housing and trigger translation movement of the moving magnet actuator. The electromagnetic field, generated as a result of application of the electric current to the coil, forces the moving magnet actuator to translate. Translation of the moving magnet actuator causes the moving magnet actuator to strike at least one of the strike plates to thereby translate the striker.

Abstract: A system (200) and method (600) for identifying cutting tools for use during a surgical procedure are described. For example, the system includes a cutting tool assembly (210) including a shaft (212) having a cutting element (214) and at least one identifying feature (216) that uniquely corresponds to the cutting element. The system further includes a drive assembly (220) including a reference pin (224), a motor (230) mechanically connected to the drive assembly, a control unit (240) configured to activate the motor to move the cutting tool assembly such that the reference pin engages with the at least one identifying feature, a sensor system (226) configured to determine positioning information related to the reference pin when the reference pin engages the at least one identifying feature, and a computing unit (250) configured to receive the positioning information from the sensor system and identify the cutting element based upon the position information.

Abstract: Methods of measuring a force using a tracking system are disclosed. A first vector is determined between a first tracking array and a second tracking array on a tool. The tool has a flexible portion that has a known modulus of elasticity and moment of inertia. A force is applied to the tool, and a second vector is determined between the first tracking array and the second tracking array. An amount of deflection is determined for the tool, and the magnitude and direction of the applied force are determined based on at least the amount of deflection, the modulus of elasticity and the moment of inertia. Information pertaining to the magnitude and direction of the applied force is provided to a user.

Abstract: The present disclosure provides a surgical navigation system that utilizes multimodal tracking along with low profile/small diameter bone pins to fix FBG sensors to a patient. With some embodiments, a multi-core fiber optic cable having both an infrared (IR) tracking sensor disposed at a known location in the multi-core fiber optic cable and FBGs. The FBGs can be used to locate the tip of the cable relative to the IR marker, where the tip of the cable is embedded in a bone, the location of the done can be determined.

Abstract: Methods and systems for preparing a bone for a cementless joint implant are described. A first bone removal operation is performed using a burring device that has a first plurality of settings. The settings for the burring device are adjusted to a second plurality of settings, and a second bone removal operation is performed using the burring device. The adjustment to the settings may allow a surgeon to perform bulk bone removal in the first instance and fine bone removal in the second instance. The process of adjusting and performing subsequent bone removal operations may be performed any number of times during the bone preparation process. The adjustments to the settings may be received automatically from a computer-assisted surgical system, manually entered by a medical professional, or a combination of the two.

Abstract: A rotary tool includes a tool body and a powered rotary cutting tooltip that is oriented and positioned relative to the tool body by a plurality of processor-controlled actuators that provide degrees of freedom. The processor uses a surgical tracking system to identify the pose of the tool body and the tooltip relative to a patient's anatomy and controls the actuators to maintain the tooltip within a predetermined cutting plan to compensate for deviation of a surgeon's hand or a robotic arm controlling the tool body during a cutting operation.

Abstract: Methods of measuring a force using a tracking system are disclosed. A first vector is determined between a first tracking array and a second tracking array on a tool. The tool has a flexible portion that has a known modulus of elasticity and moment of inertia. A force is applied to the tool, and a second vector is determined between the first tracking array and the second tracking array. An amount of deflection is determined for the tool, and the magnitude and direction of the applied force are determined based on at least the amount of deflection, the modulus of elasticity and the moment of inertia. Information pertaining to the magnitude and direction of the applied force is provided to a user.

Abstract: A system (200) and method (600) for identifying cutting tools for use during a surgical procedure are described. For example, the system includes a cutting tool assembly (210) including a shaft (212) having a cutting element (214) and at least one identifying feature (216) that uniquely corresponds to the cutting element. The system further includes a drive assembly (220) including a reference pin (224), a motor (230) mechanically connected to the drive assembly, a control unit (240) configured to activate the motor to move the cutting tool assembly such that the reference pin engages with the at least one identifying feature, a sensor system (226) configured to determine positioning information related to the reference pin when the reference pin engages the at least one identifying feature, and a computing unit (250) configured to receive the positioning information from the sensor system and identify the cutting element based upon the position information.

Abstract: A system (200) and method (600) for identifying cutting tools for use during a surgical procedure are described. For example, the system includes a cutting tool assembly (210) including a shaft (212) having a cutting element (214) and at least one identifying feature (216) that uniquely corresponds to the cutting element. The system further includes a drive assembly (220) including a reference pin (224), a motor (230) mechanically connected to the drive assembly, a control unit (240) configured to activate the motor to move the cutting tool assembly such that the reference pin engages with the at least one identifying feature, a sensor system (226) configured to determine positioning information related to the reference pin when the reference pin engages the at least one identifying feature, and a computing unit (250) configured to receive the positioning information from the sensor system and identify the cutting element based upon the position information.

Abstract: A system (200) and method (600) for identifying cutting tools for use during a surgical procedure are described. For example, the system includes a cutting tool assembly (210) including a shaft (212) having a cutting element (214) and at least one identifying feature (216) that uniquely corresponds to the cutting element. The system further includes a drive assembly (220) including a reference pin (224), a motor (230) mechanically connected to the drive assembly, a control unit (240) configured to activate the motor to move the cutting tool assembly such that the reference pin engages with the at least one identifying feature, a sensor system (226) configured to determine positioning information related to the reference pin when the reference pin engages the at least one identifying feature, and a computing unit (250) configured to receive the positioning information from the sensor system and identify the cutting element based upon the position information.

Abstract: A system (200) and method (600) for identifying cutting tools for use during a surgical procedure are described. For example, the system includes a cutting tool assembly (210) including a shaft (212) having a cutting element (214) and at least one identifying feature (216) that uniquely corresponds to the cutting element. The system further includes a drive assembly (220) including a reference pin (224), a motor (230) mechanically connected to the drive assembly, a control unit (240) configured to activate the motor to move the cutting tool assembly such that the reference pin engages with the at least one identifying feature, a sensor system (226) configured to determine positioning information related to the reference pin when the reference pin engages the at least one identifying feature, and a computing unit (250) configured to receive the positioning information from the sensor system and identify the cutting element based upon the position information.

Abstract: A system (200) and method (600) for identifying cutting tools for use during a surgical procedure are described. For example, the system includes a cutting tool assembly (210) including a shaft (212) having a cutting element (214) and at least one identifying feature (216) that uniquely corresponds to the cutting element. The system further includes a drive assembly (220) including a reference pin (224), a motor (230) mechanically connected to the drive assembly, a control unit (240) configured to activate the motor to move the cutting tool assembly such that the reference pin engages with the at least one identifying feature, a sensor system (226) configured to determine positioning information related to the reference pin when the reference pin engages the at least one identifying feature, and a computing unit (250) configured to receive the positioning information from the sensor system and identify the cutting element based upon the position information.

Abstract: A storage unit comprising a cover adapted to be mounted on a support surface wherein the cover is pivotally attached to the support surface to allow selective displacement of the cover between a tilted condition and an un-tilted condition. wherein the cover comprises a front end, a rear end and two sides, wherein the front end is pivotally attached to the support surface.

Abstract: Collagen compositions, methods for preparing those collagen compositions, and graft compositions formed from those collagen compositions are provided. In particular, methods of isolating collagen that exhibits an enhanced rate of polymerization and enhanced microstructural and mechanical properties upon polymerization, such collagen compositions, and graft compositions formed from such collagen compositions are provided.

Abstract: Collagen compositions, methods for preparing those collagen compositions, and graft compositions formed from those collagen compositions are provided. In particular, methods of isolating collagen that exhibits an enhanced rate of polymerization and enhanced microstructural and mechanical properties upon polymerization, such collagen compositions, and graft compositions formed from such collagen compositions are provided.

Abstract: Collagen compositions, methods for preparing those collagen compositions, and graft compositions formed from those collagen compositions are provided. In particular, methods of isolating collagen that exhibits an enhanced rate of polymerization and enhanced microstructural and mechanical properties upon polymerization, such collagen compositions, and graft compositions formed from such collagen compositions are provided.

Abstract: Collagen compositions, methods for preparing those collagen compositions, and graft compositions formed from those collagen compositions are provided. In particular, methods of isolating collagen that exhibits an enhanced rate of polymerization and enhanced microstructural and mechanical properties upon polymerization, such collagen compositions, and graft compositions formed from such collagen compositions are provided.

Abstract: A system for establishing communications between a central lighting controller and a series of electronic dimming ballasts uses an AC power supply line as a communication medium. A MOSFET switched by a control circuit selectively shorts the AC power lines when a rectified version of the power line signal indicates that the power line signal is nearing a zero crossing to create notches in the AC power signal. A simple receiver in each of the ballasts detects the presence or absence of notches in the power signal and interprets the results as digital data indicating a desired dimming level for each of the ballast. The ballasts then adjust their light output accordingly.