A body weight support system includes a trolley, a powered conductor operatively coupled to a power supply, and a patient attachment mechanism. The trolley can include a drive system, a control system, and a patient support system. The drive system is movably coupled to a support rail. At least a portion of the control system is physically and electrically coupled to the powered conductor. The patient support mechanism is at least temporarily coupled to the patient attachment mechanism. The control system can control at least a portion of the patient support mechanism based at least in part on a force applied to the patient attachment mechanism.

The present disclosure relates to a gate system for an overhead lifting rail system, comprising: a first gate comprising: a rail portion for supporting a lifting carriage; and a bridging element pivotally coupled adjacent a proximal end to the rail portion; and a second gate comprising: a rail portion for suspending a lifting carriage; and a bridging element support portion. Upon the first gate engaging with the second gate, a distal end of the bridging element of the first gate engages with the bridging element support portion of the second gate to form a bridge between the first gate and the second gate; and the distal end of the bridging element and the bridging element support portion are configured such that the ends of the bridging element are substantially aligned with the respective ends of the rail portions of the first and second gates.

A hanging kit includes a supporting member having at least one fixing portion and two suspending members respectively located at two opposite sides of the supporting member. The fixing portion has two coupling portions configured for coupling with each other. Each of the two suspending members has at least one suspending part and a connecting part, and the connecting part is configured for respectively connecting the two suspending members to the supporting member.

In a first aspect, the present invention relates to a hoist for facilitating a transition between firstly a seated or lying position and secondly a standing position of an individual, comprising: a movable lifting arm for exerting a lifting force, a connecting element for transferring the lifting force from the lifting arm to the individual, and a movable handle suitable for supporting the hands of the individual during operation of the hoist, wherein the movable handle is configured to shift during operation of the hoist, wherein during operation of the hoist, the movable handle also executes a movement relative to the lifting arm.

A transfer device can transfer a care-receiving person who has difficulty in independent walking to a desired location in a comfortable posture. This transfer device is provided with front wheels and rear wheels and allows a caregiver to move a care-receiving person. The transfer device is characterized by being provided with: a support body for supporting the upper half body of the care-receiving person; a leg guidance part that comes into contact with the anterior surface of the lower legs of the care-receiving person and can be tilted forward from a substantially vertical state; and a foot placement part on which the feet of the care-receiving person are placed. The transfer device has a support body advancing and retreating mechanism that is configured such that the support body moves forward in parallel in link with a forward tilt of the leg guidance part.

A device, for grasping a limp body, such as a paraplegic or a quadriplegic patient (19), and transferring the body to another location or moving it into a different position, comprises two pivotally connected sections (12,13), one positioned to grasp the torso portion (18), the other the pelvic one (17). The sections can be kept in line with each other or pivoted toward each other to place the patient in a seated position. Each section comprises an upper frame (14) from the opposite longitudinal edges of which extends a pair of articulated grasping members positioned to move astride the torso or pelvis of the patient. The members include series of transversal cantles which can be directed to curl inwardly toward each other and securely enwrap and grab the load. The frame and the supported patient can then be hoisted, moved and deposited into a supine or seating position. Each member includes a series of successively hinged segments tilted by pulling cables.

A body weight support system includes a trolley, a powered conductor operatively coupled to a power supply, and a patient attachment mechanism. The trolley can include a drive system, a control system, and a patient support system. The drive system is movably coupled to a support rail. At least a portion of the control system is physically and electrically coupled to the powered conductor. The patient support mechanism is at least temporarily coupled to the patient attachment mechanism. The control system can control at least a portion of the patient support mechanism based at least in part on a force applied to the patient attachment mechanism.

A system for loading a patient transport apparatus into a vehicle is described. The system includes a loading and unloading system including a track and a trolley supporting a receiver movable between locked and unlocked configurations. The system also includes a patient transport apparatus for attachment to the loading and unloading system including a base, a litter, and a lift mechanism to facilitate arranging the litter at different heights relative to the base with an actuator movable between fully-retracted and fully-extended configurations, a coupler for engaging the receiver to secure the patient transport apparatus, first and second sensors configured to output a first signal and second signal and a controller to determine a target lift configuration during unloading from the emergency based on first and second values and to drive the actuator to the target lift configuration to limit relative movement between the patient transport apparatus and the trolley.

A patient repositioning device includes an upper body support and a lower body support which are generally planar and laterally spaced from one another by a spacing element. A handle can rotate in the plane of the supports, enabling a care giver to rotate a patient form a sitting to a lying position and then to roll the patient onto their back. Another embodiment provides a patient cradle for cradling a patient from a reclining to a sitting position and vice versa.

An ambulatory assistance system that facilitates independent sit to stand exercise for use in homes and therapy centers that can have a minimal structural impact. The optional parallel bars can be hinged allowing movement relative to horizontal. The parallel bars can be secured in a horizontal position and the optional securing mechanism can be remotely released. The support frame system at least partially surrounds the individual and allows the individual to turn up to 360 while in the support frame system. In some embodiments, the support frame system is collapsible and includes one or more wheels, casters, leveling casters, or other structures configured to facilitate easier movement of the system from one location to another.