Abstract: A method includes obtaining load-deformation data for a joint, the load-deformation data being gathered via joint testing implemented by robotic test equipment, the robotic test equipment being configured for movement of the joint and comprising sensors to gather the load-deformation data during the movement. A load-deformation curve function for the load-deformation data is generated, the load-deformation curve function defining a curve fitted to the load-deformation data. A feature of the curve defined by the load-deformation curve function is quantified. A biomechanical characteristic of the joint is identified based on the quantified feature of the curve defined by the load-deformation curve function.

Abstract: A knee examination method includes the steps of situating a patient on a patient support adjacent a robotic knee testing apparatus, setting up the robotic knee testing apparatus, further setting up the leg of the patient relative to the robotic knee testing apparatus, and, after the steps of setting up and further setting up, examining knee laxity of a knee of the patient. The step of examining includes operating the robotic knee testing apparatus to manipulate the tibia positioning assembly.

Abstract: A method comprises obtaining rotational data and translational data for a joint. The rotational and translational data is indicative of rotational and translational movement of the joint during rotational and translational joint testing, respectively. The rotational and translational joint testing is implemented by a robotic testing apparatus. Respective zero torque points are determined for the rotational and translational movement based on the rotational data and the translational data. The respective zero torque points are combined for the rotational and translational movement to determine an equilibrium position for the joint. A biomechanical characteristic of the joint is ascertained based on an analysis of the equilibrium position.

Abstract: A knee examination method includes situating a patient on a patient support adjacent a robotic knee testing apparatus, the apparatus having a motion tracking system. The robotic knee testing apparatus is set up including defining a world coordinate system based on a fixed location of a transmitter of the motion tracking system. The patient is set up including determining one or more local coordinate systems each based on setting up the patient and on one or more robot based points. The robotic knee testing apparatus is operable to manipulate a leg of the patient.

Abstract: A joint manipulation and evaluation apparatus has a mechanism configured to manipulate a first bone of a joint relative to a second bone of the joint. The apparatus has a joint stabilizer arranged to engage the joint and hold the second bone in place as the first bone is manipulated. A sensor is coupled to the joint stabilizer and is configured and arranged to detect residual movement of a clamped portion of the joint relative to the joint stabilizer as the first bone is manipulated.

Abstract: A method includes disposing an object relative to a first body, positioning a second body within a field of view of an imaging system such that the object is within the field of view and the first body is outside the field of view, and capturing, by the imaging system, data indicative of the object and the second body.