Provided is a method of stimulating regeneration of cartilage in an area of diseased cartilage in a layer of cartilage in a first bone of a joint. The method includes forming a first recess in the first bone at the area of diseased cartilage, and positioning a first spherical implant within the first recess, where the first spherical implant is dimensioned to be smaller than the first recess so that the first spherical implant is capable of moving in two dimensions within the first recess resulting in shear forces between the first spherical implant and the cartilage and stimulates formation of fibrous tissue which subsequently transforms into cartilage.

A knee joint includes: a thigh connection portion that is provided on a thigh portion side; a lower leg portion that is connected to the thigh connection portion and rotatably provided around a knee shaft; a knee angle restrictor structured to restrict a relative rotation of the thigh connection portion and the lower leg portion such that a knee angle θ formed by the thigh connection portion with respect to the lower leg portion does not exceed a predetermined lock angle θ.sub.L; and an accommodation space that accommodates a rotational resistor applying resistance to the rotation around the knee shaft in a case where the knee angle θ is equal to or less than the lock angle θ.sub.L.

A knee joint includes: a thigh connection portion that is provided on a thigh portion side; a lower leg portion that is connected to the thigh connection portion and rotatably provided around a knee shaft; a knee angle restrictor structured to restrict a relative rotation of the thigh connection portion and the lower leg portion such that a knee angle θ formed by the thigh connection portion with respect to the lower leg portion does not exceed a predetermined lock angle θ.sub.L; and an accommodation space that accommodates a rotational resistor applying resistance to the rotation around the knee shaft in a case where the knee angle θ is equal to or less than the lock angle θ.sub.L.

A prosthetic or orthotic device (POD) can include first and second limb members coupled at a joint, an actuator, and a controller. The actuator can be configured to actuate the first limb member relative to the second limb member. The controller can cause the actuator to exhibit a force rejection behavior during a portion of stance phase and cause the actuator to exhibit a force following behavior during a portion of swing phase. The controller can, based on a determination that a gait parameter satisfies a gait parameter threshold, cause the actuator to at least one of: apply a first torque at the joint to cause the POD to flex during a portion of stance phase, decelerate flexion of the POD during at least a first portion of the swing phase, or decelerate extension of the POD during at least a second portion of the swing phase.

The invention relates to an orthopaedic joint comprising an upper part and a lower part pivotably mounted thereon and a resistance device which is located between the upper part and the lower part and provides resistance against a pivoting movement about a pivot axis, and has a resistance adjusting device coupled to a control device which is coupled to at least one sensor such that the resistance can be adjusted by means of the control device on the basis of sensor data transmitted from the at least one sensor to the control device, a function is stored in the control device in which the joint is locked against pivoting in at least one direction in accordance with the sensor data, the function can be activated for locking and deactivated for unlocking on the basis of the sensor data.

The present disclosure provides for a device and method of control for an artificial prosthetic knee. A prosthetic knee according to the present disclosure relies on strictly passive means of providing support during weight bearing and supplements a resistive swing-phase mechanism with a small powered actuator. This actuator adds power to the knee, exclusively during swing phase, to improve swing-phase behavior. In particular, the knee still relies on the resistive swing-phase mechanism to provide nominal swing-phase knee motion, but supplements that motion as needed with the small powered actuator.

A both-leg artificial knee joint device includes a first artificial knee joint worn on a first leg of a user, a second artificial knee joint worn on a second leg of the user and capable of communicating with the first artificial knee joint, and a controller structured to control at least one of the first artificial knee joint and the second artificial knee joint based on information received from the other artificial knee joint. The first artificial knee joint and the second artificial knee joint communicate via a communication device communicable with the first artificial knee joint and the second artificial knee joint.

A both-leg artificial knee joint device includes a first artificial knee joint worn on a first leg of a user, a second artificial knee joint worn on a second leg of the user and capable of communicating with the first artificial knee joint, and a controller structured to control at least one of the first artificial knee joint and the second artificial knee joint based on information received from the other artificial knee joint. The first artificial knee joint and the second artificial knee joint communicate via a communication device communicable with the first artificial knee joint and the second artificial knee joint.

A high performance, low-cost passive prosthetic knee includes one or more modules to enable able-bodied gait by transfemoral amputees to improve metabolic efficiency and reduce stigma from conspicuous abnormal gaits. A stance stability module includes a latch with a virtual lock axis that automatically locks and unlocks. An early stance flexion module enables able-bodied gait during stance. Hydraulic fluid dampers ensure reliable swing phase control. A swing extension energy storage module stores and returns energy as the knee locks and unlocks, respectively. These modules may be used together, in any combination, or individually.

A high performance, low-cost passive prosthetic knee includes one or more modules to enable able-bodied gait by transfemoral amputees to improve metabolic efficiency and reduce stigma from conspicuous abnormal gaits. A stance stability module includes a latch with a virtual lock axis that automatically locks and unlocks. An early stance flexion module enables able-bodied gait during stance. Hydraulic fluid dampers ensure reliable swing phase control. A swing extension energy storage module stores and returns energy as the knee locks and unlocks, respectively. These modules may be used together, in any combination, or individually.