The present disclosure relates to a 3D bioprinter (1) comprising a base unit (2). The base unit (2) has a support (3) adapted for mounting of at least one toolhead (4), a communication interface part (5) for communication of data with the at least one toolhead (4), when mounted, and a base unit processing element (7) adapted to communicate with a toolhead processing element (8) of the at least one toolhead over said communication interface part (5). The present disclosure relates further to a 3D bioprinter toolhead. The present disclosure relates further to a method for bioprinting a construct.

Stapling assemblies for use with a surgical stapler and methods for manufacturing the same are provided. Three dimensional adjuncts for use with a surgical stapling assembly and methods for manufacturing the same are also provided.

There is provided a method of making a fluidic system that comprises assembling a fluidic system comprising a first plate, a second plate and a membrane disposed between the first plate and the second plate; applying laser energy to the fluidic system to cause the first plate, the second plate and the membrane to melt at bonding areas; and allowing the bonding areas to cool down such that the first plate, the second plate and the membrane are bonded together.

An implant for the stabilization of bones or vertebrae is provided, the implant being a solid body including a longitudinal axis that defines a longitudinal direction and including a flexible section that has a surface and has a length in the longitudinal direction, the flexible section including at least one cavity located near the surface and having a width in the longitudinal direction that is smaller than the length of the flexible section, the at least one cavity being connected to the surface through at least one slit, and a width of the slit in the longitudinal direction being smaller than the width of the cavity.

An apparatus for forming a weld between a first portion of a biocompatible conductive thermoplastic material and a second portion of a biocompatible conductive thermoplastic material comprises a first electrode, a second electrode, and a structure for holding said first and second electrodes in opposition to one other with a space therebetween for receiving said first portion and said second portion in contact with one another. The structure is electrically non-conductive and an electrical circuit comprising a power source and a switch arranged such that closure of said switch applies a voltage potential across said first electrode and said second electrode so as to generate heat via electrical resistance, the heat being sufficient to melt regions of said first and second portions.

Embodiments of the present disclosure include methods of simultaneously manufacturing two or more hydrogel constructs (e.g., tubular hydrogel constructs). In some embodiments, the method comprises one or more of the following steps: providing a vat comprising a bio-ink composition containing one or more monomers and/or one or more polymers; applying electromagnetic radiation from an electromagnetic radiation source to cure a layer of the hydrogel constructs (e.g., tubular hydrogel constructs); and applying electromagnetic radiation from the electromagnetic radiation source one or more additional times to produce one or more additional layers of the hydrogel constructs (e.g., tubular hydrogel constructs).

The present disclosure provides reinforced hydrogel structures, methods of reinforcing hydrogel structures, and methods of treating ischemic disorders using the reinforced hydrogel structures.

A method of making a catheter includes obtaining a hollow tube having a proximal section, a distal section, an elongated conduit, and one or more fluid openings formed in the distal section of the hollow tube that are in fluid communication with the elongated lumen. The method includes inserting a mandrel within the elongated lumen, positioning a first visible marker over an outer surface of the hollow tube at a junction of the proximal and distal sections of the hollow tube, and placing a sacrificial material over the first visible marker to completely cover the first visible marker. Heat is applied for shrinking the sacrificial material, which, in turn, compresses the first visible marker against the outer surface of the hollow tube, and for least partially melting the first visible marker for fusing the first visible marker to the outer surface of the hollow tube.

The invention relates to a robot-mounted 3D printing apparatus for printing biocompatible materials for performing in-situ surgical repairs and comprises one UV curable reagent container and one cell supporting reagent container which are co-axially extruded from a tip and cured to perform in-situ repairs.

The present invention relates to a porous scaffold having excellent tissue engineering properties, and a method for manufacturing same. The scaffold of the present invention can be manufactured by a simple process, and exhibits high tensile strength and biocompatibility, as well as an excellent cell engraftment rate, and thus can be useful as a support composition for various of human transplantation, for example, as a support for artificial ligaments or abdominal wall reinforcement.