A fiber-reinforced composite article useful in supporting or immobilizing an injured body part is disclosed. The composite is a multi-layer, flexible precursor including fiber reinforcement plies, which can be rapidly cured into a rigid body using a thermosetting resin. Methods of making and using the same are also disclosed, along with kits containing such composite articles.

The system invention describes a support and improved method of application and removal. The support, comprised of a network of flexible, non-porous, multi-lumen tubing interlaces at a plurality of junctions to form a lattice structure. Apertures designed to accommodate boney prominences also permit air or water to reach the skin underneath and encourage rapid fluid flow internally through the lattice. A hydrophobic, thermal-resistant, flowable padding layer is injected within a secondary lumen to the lattice structure, spanning its complete surface area. As a result, the breathability of the support is not affected by this padding layer because it mirrors the apertures of the lattice. At least one liquid is injected into the structure and configured to transform into a solid when acted on by an external mechanical stimulus.

An animal splint for immobilizing a leg of an animal receives the back and sides of the injured leg and is angularly adjustable to the normal angle of the upper and lower part of the injured leg prior to sustaining the leg injury. The splint includes a lower leg assembly, an upper leg assembly, an adjustment member configured for setting the angle between the lower leg assembly and the upper leg assembly, and a leg retaining means that extends across the lower leg open front and the upper leg open front where the lower leg assembly and the upper leg assembly receives the back and sides of the injured leg.

Systems for immobilizing a patient are disclosed. The system includes at least one preform formed from a low melting temperature thermoplastic, the preform being configured to be formed to the anatomy of the patient, at least one frame coupled to the at least one preform, and at least one support configured to support the anatomy of the patient. The system also includes at least one lock mechanism coupled to at least one of the frame and the support and configured to couple the at least one frame to the at least one support, and at least one adjuster mechanism coupled to at least one of the at least one frame and the at least one support and configured to selectively adjust a distance between the at least one frame and the at least one support while the at least one frame is coupled to the at least one support.

A conformable body interface is fabricated using a data set representing a three-dimensional, soft tissue body surface. The conformable body interface includes a body scaffold that is divided into two or more longitudinal segments separated by axial joints. Optionally, the body scaffold is further divided into two or more circumferentially split segments separated by circumferential joints. The axial joints are circumferentially constrained by elastic bands, tabs, or similar structures and the circumferential joints are longitudinally constrained by elastic axial tethers or similar structures. In this way, the body interfaces can accommodate swelling and bending of the body surface.

Ameliorative actions are taken using a system equipped with sensors and equipment for attending to a patient. Operation of the system is controlled at a remote site or alternatively at the location of an injury. Injury assessment and the patient's affective and/or cognitive state may be facilitated through the analysis of data obtained by the sensors.

Splints for diagnostic and/or therapeutic purposes are disclosed. In one aspect, the present disclosure relates to a splint system for diagnostic and/or therapeutic functions for a patient with a vascular impairment. In one embodiment, the splint system includes a splint having: a leg supporting portion and a foot supporting portion, that are configured to support and secure the leg and foot of the patient; a locally and/or remotely controllable portion for setting a dorsiflexion angle of the foot of the patient, including electrical and/or mechanical controls and one or more actuators for setting of the dorsiflexion angle, for providing treatment to improve vascular function; and a plurality of physiological parameter sensors for measuring physiological parameters of the leg and/or foot of the patient, wherein the physiological parameters are associated with vascular function in the leg and/or foot of the patient.

A composite material 10 for forming custom fitted orthopedic and other products. The composite material is easily formable when heated to temperatures of about two hundred degrees Fahrenheit for a time of at least six to eight minutes and then is rigid at temperatures of about one hundred thirty degrees. The composite material can be sewn and formed in complex shapes when initially heated to about two hundred degrees. Closure attachments 60 can be secured to the composite material as needed on site rather than at the manufacturing facility. The composite material can be custom fitted to a patient in situ.

A shoulder immobilizer (20) includes a semi-rigid or rigid orthosis, in the form of an arm support (22), which supports the upper arm, elbow, forearm and wrist of a patient. A bolster (24) is positioned between the patient and the arm support (22). A body strap (26) extends around the patient and attaches to the arm support (22) and/or the bolster (24), holding the arm support and bolster in position against the body of the patient. In embodiments, the shoulder immobilizer (20) may utilize a shoulder strap (28), but such a shoulder strap is not necessary for shoulder immobilization of the patient.

A conformable body interface is fabricated using a data set representing a three-dimensional, soft tissue body surface. The conformable body interface includes a body scaffold that is divided into two or more longitudinal segments separated by axial joints. Optionally, the body scaffold is further divided into two or more circumferentially split segments separated by circumferential joints. The axial joints are circumferentially constrained by elastic bands, tabs, or similar structures and the circumferential joints are longitudinally constrained by elastic axial tethers or similar structures. In this way, the body interfaces can accommodate swelling and bending of the body surface.