A joint for an orthopedic device which has a first articulated arm and a second articulated arm, which are mounted about a swivel axis such that they can be swiveled relative to one another, and a blocking device which can be moved into a release position and a blocking position. The blocking device, when in the blocking position, blocks the swiveling of the first articulated arm relative to the second articulated arm in the first swivel direction, independently of a swivel angle between the first articulated arm and the second articulated arm, insofar as the swivel angle is in a predetermined range, and allows the swiveling in the first swivel direction, insofar as the swivel angle is outside of the predetermined range.

An orthopedic device for supporting a lower back of a user includes a mechanical energy store, a pelvic element, an upper body element with a first force transmission element and an upper leg element with a second force transmission element The upper leg element is arranged on the pelvic element such that it can be swivelled about a first swivel axis, the upper body element is movably arranged relative to the pelvic ele-ment, the first force transmission element can be engaged and disengaged with the second force transmission element by moving the upper body element relative to the pelvic element, and the mechanical energy store can be charged and discharged by swiv-elling the upper leg element relative to the upper body element when the first force transmission element is engaged with the second force transmission element.

An orthopedic device for supporting a lower back of a user includes a mechanical energy store, a pelvic element, an upper body element with a first force transmission element and an upper leg element with a second force transmission element. The upper leg element is arranged on the pelvic element such that it can be swivelled about a first swivel axis, the upper body element is movably arranged relative to the pelvic element, the first force transmission element can be engaged and disengaged with the second force transmission element by moving the upper body element relative to the pelvic element, and the mechanical energy store can be charged and discharged by swivelling the upper leg element relative to the upper body element when the first force transmission element is engaged with the second force transmission element.

An orthopedic device for supporting a lower back of a user includes a mechanical energy store, a pelvic element, an upper body element with a first force transmission element and an upper leg element with a second force transmission element. The upper leg element is arranged on the pelvic element such that it can be swivelled about a first swivel axis, the upper body element is movably arranged relative to the pelvic element, the first force transmission element can be engaged and disengaged with the second force transmission element by moving the upper body element relative to the pelvic element, and the mechanical energy store can be charged and discharged by swivelling the upper leg element relative to the upper body element when the first force transmission element is engaged with the second force transmission element.

Wearable devices protect against musculoskeletal injuries and enhance performance. Systems and methods provide wearable devices to assist with human motion during physical activities, such as performing movements (e.g., lifting) and holding static poses (e.g., crouching, or holding a tool while working overhead). Materials, constructions, and system architectures allow the wearable devices to be worn over, under, or integrated into clothing for extended periods of time to improve performance or reduce risk of injury. Sensors may be included in the wearable devices to detect various activities, motions, and postures of the wearer, and various active and semi-active controls approaches may leverage sensor information to provide tailored assistance to individual users. Various controls optimization techniques ensure the wearable devices operate at peak efficiency.

A joint for an orthopedic device which has a first articulated arm and a second articulated arm, which are mounted about a swivel axis such that they can be swiveled relative to one another, and a blocking device which can be moved into a release position and a blocking position. The blocking device, when in the blocking position, blocks the swiveling of the first articulated arm relative to the second articulated arm in the first swivel direction, independently of a swivel angle between the first articulated arm and the second articulated arm, insofar as the swivel angle is in a predetermined range, and allows the swiveling in the first swivel direction, insofar as the swivel angle is outside of the predetermined range.

A range of motion (ROM) removeable cast walker (RCW) has an ankle hinge that may be locked and unlocked by the user. A first sensor is responsive to the locked/unlocked condition of the RCW. A second sensor is responsive to the presence of a limb within the RCW. A third sensor is responsive to weight borne by the RCW. If the ankle hinge is unlocked, the ROM RCW is being worn and weight is being borne, a warning is provided to the patient to remind the patient to lock the ankle hinge to conform to the therapeutic regimen. A radio transmitter may report the state of the ROM RCW to a smart phone and to a remote storage facility for use by a physician.

A prosthesis or orthosis for a joint, such as an ankle, which includes a first body, a second body, and an articulated joint between the first and second bodies, the articulated joint allowing the rotation of the first and second bodies with respect to one another around a joint rotation axis. It further includes a locking mechanism configured to selectively lock the rotation between the first and second bodies in one direction, when it is in a locked configuration, and a transmission mechanism such that a rotation of the joint rotation axis generates a movement of a lockable part of the locking mechanism. The axis of the movement of the lockable part is shifted relative to the joint rotation axis and the transmission mechanism includes a reducer configured to reduce effort to lock the rotation of the first body with respect to the second body.

A passive artificial knee includes a knee hinge assembly defining a knee axis, a locking hinge assembly defining a locking axis, and a post linking the knee hinge assembly and the locking hinge assembly. A ground reaction force applied to the artificial knee posterior to the locking axis causes an interfering relation by compression of the locking hinge assembly and the knee hinge assembly during heel strike at early-stance gait phase of an individual wearing the artificial knee, thereby locking rotation of the post about the knee axis. Shifting of ground reaction force anterior to the locking axis during a mid-stance to late-stance gait phase of the individual causes rotation of the post about the locking axis, thereby unlocking rotation of the post about the knee axis and enabling flexion and subsequent swing phase extension of the passive artificial knee joint. The artificial knee is a passive joint that can be fabricated and maintained at low expense.

An ankle foot orthopaedic device (56) includes a first part (58) for association with a leg engaging item (72), a second part (60) for association with a foot engaging item (86) and a connector (62) for connecting the first part (58) to the second part (60). The connector (62) includes a first adjuster (66), which, in an adjustment condition, permits a first adjustment relative movement of the first part (58) and the second part (60) around a first device axis (150) of rotation. The connector (62) includes a second adjuster (64), which, in an adjustment condition, permits a second adjustment relative movement of the first part (58) and the second part (60) around a second device axis (144) of rotation. In use in a fitted condition in which the device (56) is fitted to a user's leg and foot, the first device axis (150) substantially corresponds with a dominant anatomical axis (50) of rotation of the sub talar joint and the second device axis (144) substantially corresponds with a dominant anatomical axis (44) of rotation of the tibio-talar joint.