Abstract: Disclosed is a new 3D bioprinting method of soft polymeric material such as a hydrogel or elastomer and/or cells for scaffolds or devices with structures. The method utilizes in one aspect extrusion based printing of polymer solutions, hydrogels and cells referred as direct ink writing (DIW) or BioPlotting that is modified to offer break-through advantages. The method may utilize sequential printing of a photocurable polymer solution or matrix material, and a functional hydrogel and/or cells. Printing within or inside of a viscous non-cured layer is accomplished by printing cells directly into the functional hydrogel. The viscous layer does not need to be shear thinning and thus allows use of a wide variety of bioinks never before allowed because of shear thinning and recovery requirement of commonly utilized extrusion based embedded bioprinting approach. Complex printing patterns never before allowed for bioinks are now possible utilizing this new printing method.

Abstract: Disclosed is a new 3D bioprinting method of soft polymeric material such as a hydrogel or elastomer and/or cells for scaffolds or devices with structures. The method utilizes in one aspect extrusion based printing of polymer solutions, hydrogels and cells referred as direct ink writing (DIW) or BioPlotting that is modified to offer break-through advantages. The method may utilize sequential printing of a photocurable polymer solution or matrix material, and a functional hydrogel and/or cells. Printing within or inside of a viscous non-cured layer is accomplished by printing cells directly into the functional hydrogel. The viscous layer does not need to be shear thinning and thus allows use of a wide variety of bioinks never before allowed because of shear thinning and recovery requirement of commonly utilized extrusion based embedded bioprinting approach. Complex printing patterns never before allowed for bioinks are now possible utilizing this new printing method.

Abstract: Disclosed is a new 3D bioprinting method of soft polymeric material such as a hydrogel or elastomer and/or cells for scaffolds or devices with structures. The method utilizes in one aspect extrusion based printing of polymer solutions, hydrogels and cells referred as direct ink writing (DIW) or BioPlotting that is modified to offer break-through advantages. The method may utilize sequential printing of a photocurable polymer solution or matrix material, and a functional hydrogel and/or cells. Printing within or inside of a viscous non-cured layer is accomplished by printing cells directly into the functional hydrogel. The viscous layer does not need to be shear thinning and thus allows use of a wide variety of bioinks never before allowed because of shear thinning and recovery requirement of commonly utilized extrusion based embedded bioprinting approach. Complex printing patterns never before allowed for bioinks are now possible utilizing this new printing method.