A cervical traction assembly for use with a patient support apparatus includes an adjustment carriage track member including a connecting bracket assembly that releasably connects to a mount support member of the patient support apparatus. The adjustment track member includes a track body including a pair of opposing sidewalls that are spaced-apart from each other to define an elongated channel therebetween. Each sidewall includes a guide track that extends along a length of the respective sidewall. A rope angle adjustment carriage is located within the channel. The rope angle adjustment carriage includes a first track engagement member that is received by one of the guide tracks of one of the sidewalls and a second track engagement member that is received by another of the guide tracks of another of the sidewalls. The first track engagement member has a locked configuration that inhibits movement of the rope angle adjustment carriage.

A cervical traction assembly for use with a patient support apparatus includes an adjustment carriage track member including a connecting bracket assembly that releasably connects to a mount support member of the patient support apparatus. The adjustment track member includes a track body including a pair of opposing sidewalls that are spaced-apart from each other to define an elongated channel therebetween. Each sidewall includes a guide track that extends along a length of the respective sidewall. A rope angle adjustment carriage is located within the channel. The rope angle adjustment carriage includes a first track engagement member that is received by one of the guide tracks of one of the sidewalls and a second track engagement member that is received by another of the guide tracks of another of the sidewalls. The first track engagement member has a locked configuration that inhibits movement of the rope angle adjustment carriage.

Halo vests and the construction methods thereof are provided. The halo vests are designed in unibody structures to minimize the number of components. A 3D scanner is utilized to scan a subject to obtain parameters for a modeling program, which help to construct an optimized halo vest for the subject by printing rather than assembling manually. The subject can easily put on the halo vest without miscellaneous steps.

Halo vests and the construction methods thereof are provided. The halo vests are designed in unibody structures to minimize the number of components. A 3D scanner is utilized to scan a subject to obtain parameters for a modeling program, which help to construct an optimized halo vest for the subject by printing rather than assembling manually. The subject can easily put on the halo vest without miscellaneous steps.

Portable traction splints for applying traction to an injured patient's limb may be extendable from a collapsed configuration adapted for transportation and storage towards an extended configuration adapted for applying traction to the injured patient, using telescoping members. One or more straps may be provided for securing the traction splint to the patient. One or more of such straps may include a tourniquet portion and/or may be configured to be oriented in different directions relative to the telescoping members. The disclosed traction splints may include a traction mechanism including a traction cord to apply traction to the patient's limb. The traction cord may be secured and maintained at a desired tension via a catch and a cleat in the inner member. Additionally or alternatively, a longitudinal cord groove and an inner hollow of the inner member may define a cord path for the traction cord.

Portable traction splints for applying traction to an injured patient's limb may be extendable from a collapsed configuration adapted for transportation and storage towards an extended configuration adapted for applying traction to the injured patient, using telescoping members. One or more straps may be provided for securing the traction splint to the patient. One or more of such straps may include a tourniquet portion and/or may be configured to be oriented in different directions relative to the telescoping members. The disclosed traction splints may include a traction mechanism including a traction cord to apply traction to the patient's limb. The traction cord may be secured and maintained at a desired tension via a catch and a cleat in the inner member. Additionally or alternatively, a longitudinal cord groove and an inner hollow of the inner member may define a cord path for the traction cord.

A cervical traction assembly for use with a patient support apparatus includes an adjustment carriage track member including a connecting bracket assembly that releasably connects to a mount support member of the patient support apparatus. The adjustment track member includes a track body including a pair of opposing sidewalls that are spaced-apart from each other to define an elongated channel therebetween. Each sidewall includes a guide track that extends along a length of the respective sidewall. A rope angle adjustment carriage is located within the channel. The rope angle adjustment carriage includes a first track engagement member that is received by one of the guide tracks of one of the sidewalls and a second track engagement member that is received by another of the guide tracks of another of the sidewalls. The first track engagement member has a locked configuration that inhibits movement of the rope angle adjustment carriage.

A cervical traction assembly for use with a patient support apparatus includes an adjustment carriage track member including a connecting bracket assembly that releasably connects to a mount support member of the patient support apparatus. The adjustment track member includes a track body including a pair of opposing sidewalls that are spaced-apart from each other to define an elongated channel therebetween. Each sidewall includes a guide track that extends along a length of the respective sidewall. A rope angle adjustment carriage is located within the channel. The rope angle adjustment carriage includes a first track engagement member that is received by one of the guide tracks of one of the sidewalls and a second track engagement member that is received by another of the guide tracks of another of the sidewalls. The first track engagement member has a locked configuration that inhibits movement of the rope angle adjustment carriage.

The present subject matter relates to orthotic devices, systems, and methods configured to support a lumbar spine. In some embodiments, a lumbar spinal orthosis system includes a torso belt configured to be secured about a torso of a user, a pelvic belt configured to be secured about a pelvis of the user, and a distractive force mechanism connected between the torso belt and the pelvic belt. The distractive force mechanism is configured to generate a force between the torso belt and the pelvic belt acting bi-directionally across a lumbar spine of the user to substantially offload bodyweight of the user passing through the lumbar spine.

The present subject matter relates to orthotic devices, systems, and methods configured to support a lumbar spine. In some embodiments, a lumbar spinal orthosis system includes a torso belt configured to be secured about a torso of a user, a pelvic belt configured to be secured about a pelvis of the user, and a distractive force mechanism connected between the torso belt and the pelvic belt. The distractive force mechanism is configured to generate a force between the torso belt and the pelvic belt acting bi-directionally across a lumbar spine of the user to substantially offload bodyweight of the user passing through the lumbar spine.