A photocurable device injection system for creating in situ polymerization via light or free-radical to enable fractured bone fixation. The system comprises a photosensitive polymeric resin sensitive to light, temperature, oxygen, enzymes, or a combination thereof. The photosensitive polymeric resin may be configured to cure at room temperature or physiological temperature with a light source. The photosensitive polymeric resin may be configured to depolymerize with ultrasonication, sonication, or a combination thereof. The system further comprises an implantable 3-dimensional biocompatible pouch comprising an optical light guide. The system further comprises one or more micro-sized ultrasonication probes configured to contact a three-dimensional pouch by one or more openings. The one or more probes may be configured to enable polymer outflow.

An orthopedic intramedullary sleeve apparatus for internal bone fixation for bone fracture treatment of a patient. The apparatus may comprise a multilayer sleeve component comprising one or more access valves disposed on a surface of the sleeve. Each access valve may comprise one or more resealable ports for injecting polymers or monomers or resins or any curable types of cement. The sleeve component may be positioned inside the intramedullary cavity in a minimally invasive way and removed from the intramedullary cavity.

A multi-component frame includes a first component made from a rigid structural material and a second component connected to at least an end portion the first component. The first component is constructed from a metal or metal alloy, and the second component is constructed from a material different from the first component. The first and second components form at least part of a length of the multi-component frame.

A multi-component frame includes a first component made from a rigid structural material and a second component connected to at least an end portion the first component. The first component is constructed from a metal or metal alloy, and the second component is constructed from a material different from the first component. The first and second components form at least part of a length of the multi-component frame.

A medical fixing brace, wherein at least one surface is provided with a plurality of step holes for mounting snap-fit seats and posts; the thickness of the mesh plate is made thinner at the step holes; and each of the step holes is assembled with some parts of the snap-fit seats and posts. According to the invention, the fixing brace can be used for both the left body and the right body, convenient for the doctor; the product does not absorb water and has no pad structure, so it is quick in drying after bathing, and it is good in comfort for the wearer; any pruritus and dermatitis can be avoided; and the external fixing brace according to the invention can be used for bone support of the upper limb, the neck, the chest, the waist, the lower limb and the like.

A medical fixing brace, wherein at least one surface is provided with a plurality of step holes for mounting snap-fit seats and posts; the thickness of the mesh plate is made thinner at the step holes; and each of the step holes is assembled with some parts of the snap-fit seats and posts. According to the invention, the fixing brace can be used for both the left body and the right body, convenient for the doctor; the product does not absorb water and has no pad structure, so it is quick in drying after bathing, and it is good in comfort for the wearer; any pruritus and dermatitis can be avoided; and the external fixing brace according to the invention can be used for bone support of the upper limb, the neck, the chest, the waist, the lower limb and the like.

An orthopedic precast comprises a knitted shell portion and a knitted flexible portion. The precast is positioned about a limb or other mold, and heat or other hardening agent is used to harden the shell portion, while retaining flexibility in the flexible portion. Contemplated hardening agents include light, heat, and chemical polymerizing agents. In some embodiments the shell portion includes threads or yarns comprising a thermoplastic, which is then hardened by heating the thermoplastic sufficiently to at least partially melt, and thereby fuse together some of the threads or yarns, and then cooling to ambient temperature. In other embodiments, the precast is contained in a bag or other airtight container, along with a self-heating composition that is triggered to release heat upon contact with oxygen. In still other embodiments, the precast includes a prepolymer of other polymerizable composition, which is polymerized by effective application of light, heat, and/or chemical agent(s).

An orthopedic precast comprises a knitted shell portion and a knitted flexible portion. The precast is positioned about a limb or other mold, and heat or other hardening agent is used to harden the shell portion, while retaining flexibility in the flexible portion. Contemplated hardening agents include light, heat, and chemical polymerizing agents. In some embodiments the shell portion includes threads or yarns comprising a thermoplastic, which is then hardened by heating the thermoplastic sufficiently to at least partially melt, and thereby fuse together some of the threads or yarns, and then cooling to ambient temperature. In other embodiments, the precast is contained in a bag or other airtight container, along with a self-heating composition that is triggered to release heat upon contact with oxygen. In still other embodiments, the precast includes a prepolymer of other polymerizable composition, which is polymerized by effective application of light, heat, and/or chemical agent(s).

A composite moldable splint and method for using the same is described. In some embodiments, the splint has at least a partially fluid-filled inner volume, which in some embodiments may include foam, rubber, water, or pelletized material, enclosed by a flexible liner, surrounded by a thermoplastic layer that is flexible and moldable when heated. The inner volume, which may include a thermoactive adhesive having differing viscosity characteristics at a plurality of temperatures, provides the ability to mold the cushion into a wide range of shapes and contours, such as when forming around a body part. The thermoplastic layer provides the ability of the cushion to be molded when heated, while the inner volume tends to maintain a shape, and allows the thermoplastic layer to stay in its formed shape as the cushion cools. The cushion may be used in a range of medical applications for stabilizing patients and body parts.

A composite moldable splint and method for using the same is described. In some embodiments, the splint has at least a partially fluid-filled inner volume, which in some embodiments may include foam, rubber, water, or pelletized material, enclosed by a flexible liner, surrounded by a thermoplastic layer that is flexible and moldable when heated. The inner volume, which may include a thermoactive adhesive having differing viscosity characteristics at a plurality of temperatures, provides the ability to mold the cushion into a wide range of shapes and contours, such as when forming around a body part. The thermoplastic layer provides the ability of the cushion to be molded when heated, while the inner volume tends to maintain a shape, and allows the thermoplastic layer to stay in its formed shape as the cushion cools. The cushion may be used in a range of medical applications for stabilizing patients and body parts.