Usage of the Original Device Broken Down: The original device was created to stabilize a unilateral (one leg) closed mid shaft femur fracture by the use of held in place mechanical traction. The device has parallel telescoping rails, made from the frame itself, these rails allow the device to be adjusted and size appropriate for all heights of patients requiring this device. These rails lock in the position the medical provider deems correct. To start the application process, a medically trained individual must first apply an ankle brace (if no ankle fracture is present) to the injured leg, this brace has a loop attached to the bottom of it (this loop is used later), the provider will then pull manual traction using the ankle of the injured leg in a directional manner meant to realign the broken femur to its normal position prior to the break. The goal is to stretch the shortened injured leg until it meets the length of the non-injured leg. The force needed to reach this position is then matched by the devices mechanical ability to recreate the same amount of force the provider used to hold the leg in proper place. The original device then uses a strap that wraps around the whole upper portion of the injured leg (ischium/groin/thigh area), this strap secures the upper leg to the device and now becomes the anchor point the device will use to pull traction against. After this groin strap is secured, the device has a ratchet strap that can now be attached to the ankle brace loop mentioned above. Traction is now applied by pulling the leg taught until it matches the manual force applied by the provider; this is done by using a hand turned dial located on the device end. Once the desired outcome is reached, the device is then secured in place to inhibit any further movement until further medical care is required.

Usage of the Modified BTSD Broken Down: The BTSD will serve the same function as the original, being a tool that is specific for a unilateral closed mid shaft femur fracture; but will also come optional to be outfitted with two fixed in place ratchet assemblies for treating a bilateral femur fracture. The key differences the BTSD will have over the original will be (1) better overall stabilization to the injured leg, (2) the BTSD design change to the original frame offers a simpler and a more practical application which now allows the uninjured leg to be part of stabilization process, (3) the BTSD offers a less painful, more effective and overall safer means of traction being applied, (4) the BTSD ratchet assembly housing will come optional with one ratchet strap housing assembly being able to slide and lock into grooved/notched positions found on

An improved finger splint includes an outer frame that partly surrounds an inner comfort sleeve. The outer frame is a substantially tubular shape with an oblong opening that cooperates with a patient's knuckle when the patient wears the splint around his finger and a pair of spine areas that extend along the underside of the patient's finger to encourage extension. The inner comfort sleeve includes a channel on its outer surface for receiving the outer frame, ridges along its inner surface, and holes and slots extending between its outer and inner surfaces to facilitate adjustment and breathability. Optionally, a fingertip guard can be removable attached to the inner sleeve with a series of protrusions that cooperate with the holes positioned around the inner sleeve. When assembled, the outer frame and inner comfort sleeve create a low profile, comfortable, and attractive and customizable splint.

A thermoplastic article for orthopaedic application comprising a substrate, the substrate including in the range 57 to 95 wt % of a thermoplastic polymer and in the range 5 to 30 wt % of a wax; wherein, the article is plastic at a temperature in the range 40° C. to 60° C. Together with a method of a thermoplastic article for orthopaedic application comprising a substrate, the substrate including in the range 57 to 95 wt % of a thermoplastic polymer and in the range 5 to 30 wt % of a wax; wherein, the article is plastic at a temperature in the range 40° C. to 60° C. and a use of the article together with a computer readable medium which when executed on a processor allows the article to be made.

A thermoplastic article for orthopaedic application comprising a substrate, the substrate including in the range 57 to 95 wt % of a thermoplastic polymer and in the range 5 to 30 wt % of a wax; wherein, the article is plastic at a temperature in the range 40° C. to 60° C. Together with a method of a thermoplastic article for orthopaedic application comprising a substrate, the substrate including in the range 57 to 95 wt % of a thermoplastic polymer and in the range 5 to 30 wt % of a wax; wherein, the article is plastic at a temperature in the range 40° C. to 60° C. and a use of the article together with a computer readable medium which when executed on a processor allows the article to be made.

A brace may include a body portion and a finger portion. The body portion may include a first flexible sheet configured to receive at least portions of a user's wrist and hand and may restrict movement of the wrist. The finger portion may include a second flexible sheet and a rigid stabilizing member. The finger portion may be configured to receive at least one of the user's fingers and may restrict movement of the at least one finger relative to the wrist and hand. Further, the body portion be configured to releasably receive the finger portion.

An articular support for supporting bones connected to one another by joints, includes at least one support splint, which is structured in at least two segments. The support splint has at least one guide per segment to receive a reinforcing element for longitudinal coupling of the at least two segments and coupling means for transverse coupling of this support splint to at least one additional neighboring support splint.

The invention relates to a dynamic correction splint (1) with two splint parts (5, 6) connected to each other via a joint (2). Spring bases (25, 26) of a spring device (27) are each coupled to a splint part (5, 6) in such a way that pivoting the splint parts (5, 6) leads to an altered biasing of the spring device (27). The spring device (27) exerts a correction moment onto the splint parts (5, 6) acting in the direction of a correction position of the splint parts (5, 6). The spring device (27) is configured and coupled to the splint parts (5, 6) in such a way that the absolute value of the correction moment increases as the correction position of the splint parts (5, 6) is approached. It is possible that a switching mechanism (40) is present. The switching mechanism (40) is actuated in a motion-controlled way by the pivoting of the splint parts (5, 6) and at its actuation changes the coupling of the splint parts (5, 6) with the spring device (27).

The invention relates to a dynamic correction splint (1) with two splint parts (5, 6) connected to each other via a joint (2). Spring bases (25, 26) of a spring device (27) are each coupled to a splint part (5, 6) in such a way that pivoting the splint parts (5, 6) leads to an altered biasing of the spring device (27). The spring device (27) exerts a correction moment onto the splint parts (5, 6) acting in the direction of a correction position of the splint parts (5, 6). The spring device (27) is configured and coupled to the splint parts (5, 6) in such a way that the absolute value of the correction moment increases as the correction position of the splint parts (5, 6) is approached. It is possible that a switching mechanism (40) is present. The switching mechanism (40) is actuated in a motion-controlled way by the pivoting of the splint parts (5, 6) and at its actuation changes the coupling of the splint parts (5, 6) with the spring device (27).

A support and corresponding system and method of using and producing the support, the support being for supporting a joint or body part of a wearer, the support having at least one rigid first support member, at least one fixing device for attaching the support to the wearer, and at least one second support member extending at an angle from the first support member. Optionally, the joint is a joint between first and second body parts, and the first body part is movable or pivotable relative to the second body part via the joint, and the support is arranged such that at least one of the fixing devices is operable to fix the support to the first body part, the at least one rigid support member covers at least part of at least one side of the first body part and extends over at least part of at least one side of the joint, the second support member is configured to extend to another side of the second body part to the first support member, the first support member is adapted to limit motion of the second body part and/or joint in a first direction, and the second support member is configured to limit motion of the second body part in a second direction.

Various orthopaedic brace configurations and elements to be applied to the lower leg and foot are disclosed here, which include a rigid monocoque exoskeleton, foam padded interior, a plurality of retention devices, a plurality of stabilizers extendable through a spring loaded ratcheting mechanism, and a plurality of smaller stabilizer structures. This orthopaedic brace limits inversion, eversion and planterflexion of the ankle and limits flexion, extension, medial rotation and lateral rotation of the knee and hip joint.