A biocompatible tissue graft includes a first layer of a bioremodelable collageneous material, a second layer of biocompatible synthetic or natural remodelable or substantially remodelable material attached to the first layer; and at least one fiber that is stitched in a reinforcing pattern in the first layer and/or second layer to mitigate tearing and/or improve fixation retention of the graft, and substantially maintain the improved properties while one or more of the layers is remodeling.

A biocompatible tissue graft includes a first layer of a bioremodelable collageneous material, a second layer of biocompatible synthetic or natural remodelable or substantially remodelable material attached to the first layer; and at least one fiber that is stitched in a reinforcing pattern in the first layer and/or second layer to mitigate tearing and/or improve fixation retention of the graft, and substantially maintain the improved properties while one or more of the layers is remodeling.

Scaffolds for use in bone tissue engineering include a skeleton and a host component. Methods of preparation of scaffolds include identification of biodegradation properties for the skeleton and the host component. The skeleton is constructed to form a three-dimensional shape. The skeleton is constructed of a first material and has a first rate of biodegradation. The host component fills the three-dimensional shape formed by the skeleton. The host component is constructed of a second material and has a second rate of biodegradation. The first rate of biodegradation is slower than the second rate of biodegradation.

Scaffolds for use in bone tissue engineering include a skeleton and a host component. Methods of preparation of scaffolds include identification of biodegradation properties for the skeleton and the host component. The skeleton is constructed to form a three-dimensional shape. The skeleton is constructed of a first material and has a first rate of biodegradation. The host component fills the three-dimensional shape formed by the skeleton. The host component is constructed of a second material and has a second rate of biodegradation. The first rate of biodegradation is slower than the second rate of biodegradation.

Scaffolds for use in bone tissue engineering include a skeleton and a host component. Methods of preparation of scaffolds include identification of biodegradation properties for the skeleton and the host component. The skeleton is constructed to form a three-dimensional shape. The skeleton is constructed of a first material and has a first rate of biodegradation. The host component fills the three-dimensional shape formed by the skeleton. The host component is constructed of a second material and has a second rate of biodegradation. The first rate of biodegradation is slower than the second rate of biodegradation.

The present invention relates to matrices for tissue engineering in the form of foams, fibres and/or membranes formed of polymers, ceramics, polymeric composites and/or ceramic composites containing Bixa orellana L. extract capable of inducing tissue regeneration in vivo and in vitro, preventing inflammatory processes and fungal and bacterial contamination during processes of regeneration. The matrices can be two-dimensional or three-dimensional, and have the morphology, porosity and pore size required for tissue growth and regeneration, said structure being particularly suitable for tissue growth in vitro or tissue regeneration in vivo, and the regeneration of hard or soft tissue. Methods for producing said matrices are also described, which include impregnating the materials with the extract and subsequently processing the scaffolds in the form of foams, fibres or membranes, which can be carried out by electro spinning, producing foams by leaching particles, the method of foaming, lyophilization or casting.

The invention relates to the field of tissue engineering and regenerative medicine, and particularly to a three-dimensional biomimetic tissue scaffold that exploits the use of three-dimensional print technology. Surface energy is controlled by precisely placing polymers with differing surface chemistry, and using surface texture and bulk composition to pattern absorbable and non-absorbable polymers for the purpose of promoting functional healing in a mammalian body.

The invention relates to the field of tissue engineering and regenerative medicine, and particularly to a three-dimensional biomimetic tissue scaffold that exploits the use of three-dimensional print technology. Surface energy is controlled by precisely placing polymers with differing surface chemistry, and using surface texture and bulk composition to pattern absorbable and non-absorbable polymers for the purpose of promoting functional healing in a mammalian body.

The present invention is directed to compositions containing polymer matrix, fiber and/or additives which are suitable for load bearing applications for medical devices. The matrix can be formed from a group of polymers which resorb inside the body after implantation. These compositions contain reinforcing fibers that are incorporated into a resorbable polymer matrix to improve properties such as mechanical. The reinforcing fibers can be resorbable, non-resorbable, natural, or metallic. Additives can be incorporated into the matrix material or the fibers or both to provide a secondary effect. These additives can be bioceramics to provide an osteoconductive effect; antimicrobial particles such as silver; coloring agents, and radiopaque additives to make the implants visible under fluoroscopy. The additives may also contribute to improve mechanical properties. The Composite composition with Matrix, Fibers and/or additives can provide enhanced functionality of mechanical, Osteoconductive and tailored degradation characteristics that can result in superior properties conventionally not achievable for Bioresorbable composites.

The present invention is directed to compositions containing polymer matrix, fiber and/or additives which are suitable for load bearing applications for medical devices. The matrix can be formed from a group of polymers which resorb inside the body after implantation. These compositions contain reinforcing fibers that are incorporated into a resorbable polymer matrix to improve properties such as mechanical. The reinforcing fibers can be resorbable, non-resorbable, natural, or metallic. Additives can be incorporated into the matrix material or the fibers or both to provide a secondary effect. These additives can be bioceramics to provide an osteoconductive effect; antimicrobial particles such as silver; coloring agents, and radiopaque additives to make the implants visible under fluoroscopy. The additives may also contribute to improve mechanical properties. The Composite composition with Matrix, Fibers and/or additives can provide enhanced functionality of mechanical, Osteoconductive and tailored degradation characteristics that can result in superior properties conventionally not achievable for Bioresorbable composites.