A composite lumen includes a braided structure infused with an impermeable elastic sealer. The braided structure has an inner diameter of 3 mm or less and a braid angle greater than 100°. The braided structure also has a wall thickness to inner diameter ratio greater than 0.02, picks per inch from between about 25 and about 135, and a number of ends between about 12 and about 48, with a braid pattern that is selected from 1×1, 2×2, or 2×1 and with an effective yarn denier (yarn denier×ply number) greater than 45.

A composite lumen includes a braided structure infused with an impermeable elastic sealer. The braided structure has an inner diameter of 3 mm or less and a braid angle greater than 100°. The braided structure also has a wall thickness to inner diameter ratio greater than 0.02, picks per inch from between about 25 and about 135, and a number of ends between about 12 and about 48, with a braid pattern that is selected from 1×1, 2×2, or 2×1 and with an effective yarn denier (yarn denier×ply number) greater than 45.

A prosthetic polylactide or collagen-containing scaffold material for treating osseous defects and neogenesis of bone, obtained by printing a scaffold composed of strings of polylactide and porous microstructures which allow passage and ingrowth of bone tissue. A soluble mixture of BSP and/or collagen is provided, and BSP and/or collagen is applied onto the strings and in the pores of the printed body to obtain a prosthetic material which induces tissue-directed ingrowth of bone tissue as well as repair and healing of damaged or diseased bone tissues and lesions. The prosthetic material is osseo-inductive and osseo-conductive. The BSP in the prosthetic scaffold material induces a tissue-directed growth of osseous tissue. No undirectional callous or overgrowing bone and cartilage tissue is observed.

A prosthetic polylactide or collagen-containing scaffold material for treating osseous defects and neogenesis of bone, obtained by printing a scaffold composed of strings of polylactide and porous microstructures which allow passage and ingrowth of bone tissue. A soluble mixture of BSP and/or collagen is provided, and BSP and/or collagen is applied onto the strings and in the pores of the printed body to obtain a prosthetic material which induces tissue-directed ingrowth of bone tissue as well as repair and healing of damaged or diseased bone tissues and lesions. The prosthetic material is osseo-inductive and osseo-conductive. The BSP in the prosthetic scaffold material induces a tissue-directed growth of osseous tissue. No undirectional callous or overgrowing bone and cartilage tissue is observed.

A prosthetic polylactide or collagen-containing scaffold material for treating osseous defects and neogenesis of bone, obtained by printing a scaffold composed of strings of polylactide and porous microstructures which allow passage and ingrowth of bone tissue. A soluble mixture of BSP and/or collagen is provided, and BSP and/or collagen is applied onto the strings and in the pores of the printed body to obtain a prosthetic material which induces tissue-directed ingrowth of bone tissue as well as repair and healing of damaged or diseased bone tissues and lesions. The prosthetic material is osseo-inductive and osseo-conductive. The BSP in the prosthetic scaffold material induces a tissue-directed growth of osseous tissue. No undirectional callous or overgrowing bone and cartilage tissue is observed.

The present disclosure relates to a bone graft composition, and more particularly, to a bone graft composition including: a bone graft material; a thickener having an adhesive property; and hydroxypropyl methylcellulose as a crosslinker that forms a bond with each of the bone graft material and the thickener.

The present disclosure relates to a bone graft composition, and more particularly, to a bone graft composition including: a bone graft material; a thickener having an adhesive property; and hydroxypropyl methylcellulose as a crosslinker that forms a bond with each of the bone graft material and the thickener.

Methods, systems, apparatuses and devices for implantation in a soft-tissue biological environment that include a primary layer for containing a filler substance, an interface and a secondary layer, including embodiments where the secondary layer an ePTFE layer, the primary layer is a silicone layer, the interface is mechanical or adhesive and the filler substance can include particulates and lattices.

Methods, systems, apparatuses and devices for implantation in a soft-tissue biological environment that include a primary layer for containing a filler substance, an interface and a secondary layer, including embodiments where the secondary layer an ePTFE layer, the primary layer is a silicone layer, the interface is mechanical or adhesive and the filler substance can include particulates and lattices.

Methods, systems, apparatuses and devices for implantation in a soft-tissue biological environment that include a primary layer for containing a filler substance, an interface and a secondary layer, including embodiments where the secondary layer an ePTFE layer, the primary layer is a silicone layer, the interface is mechanical or adhesive and the filler substance can include particulates and lattices.