Abstract: This invention relates to a bone regeneration product comprising at least one stem cell, at least one scaffold, and at least one stem cell. The stem cells suitable for this invention may comprise stem cells suitable for a dense bone regeneration, stem cells suitable for a spongy bone regeneration, or a combination thereof. The bone regeneration product may further comprise a growth factor. This invention also relates to a bone regeneration method and treatment of any bone that has a critical size defect. This invention also relates to a scaffold. This invention further relates to a 3D printed scaffold comprising hydroxyapatite (HA) and tricalcium phosphate (TCP). This invention also relates to a scaffold comprising a polymer. The polymer of this invention may be prepared by using photocurable polymers and/or monomers. The scaffold of this invention may comprise a growth factor and a small molecule. The small molecule N may be a Smurf1 inhibitor.

Abstract: This invention relates to a bone regeneration product comprising at least one stem cell, at least one scaffold, and at least one stem cell. The stem cells suitable for this invention may comprise stem cells suitable for a dense bone regeneration, stem cells suitable for a spongy bone regeneration, or a combination thereof. The bone regeneration product may further comprise a growth factor. This invention also relates to a bone regeneration method and treatment of any bone that has a critical size defect. This invention also relates to a scaffold. This invention further relates to a 3D printed scaffold comprising hydroxyapatite (HA) and tricalcium phosphate (TCP). This invention also relates to a scaffold comprising a polymer. The polymer of this invention may be prepared by using photocurable polymers and/or monomers. The scaffold of this invention may comprise a growth factor and a small molecule. The small molecule N may be a Smurf1 inhibitor.