CPC Class B33Y

Computer implemented methods of producing a mesh implant having a compartment to enclose a bone material therein are provided. These methods include generating a 3D digital model of the mesh implant having the compartment, the 3D digital model including a virtual volume of the compartment and a virtual depth, thickness and volume of the mesh implant; generating a 3D digital model of a covering configured for closing the compartment of the mesh implant, the 3D digital model including a virtual volume of the covering for closing the compartment of the mesh implant; and instructing a 3D printer coupled to a computer to generate the mesh implant based on the 3D digital models. A computer system for making a mesh implant and a delivery system including the mesh implant are also provided.

A method of fusing a sacroiliac joint including delivering a screw across the sacroiliac joint and into the sacrum and the ilium, the screw including a body having helical spiral threads and spiral flutes extending into the body of the screw.

A method of fusing a sacroiliac joint including delivering a joint fixation screw into engagement with the sacroiliac joint, the screw having either: 1) a body including helical spiral threads, an anti-migration surface feature including at least one ridge extending distally from the proximal end at least partially the length, and a plurality of openings extending into the body; or 2) a body including a hollow interior, helical spiral threads and a plurality of openings extending into the hollow interior, wherein the helical spiral threads have a thread cross-section including: a height extending between a connection point with the body and a radial termination, a first thickness at the radial termination extending between opposite thread walls, and a second thickness located between the connection point and the radial termination extending between opposite thread walls, the first thickness being substantially greater the second thickness.

An interface is provided for storing microfluidic samples in a nanoliter sample chip. A fluid access structure provides a fluid access region to a selected subset of sample wells from an array of sample wells. A fluid introduction mechanism introduces a sample fluid to the fluid access region so that the sample wells in the selected subset are populated with the sample fluid without the unselected sample wells being populated with the sample fluid.

The invention discloses metal powder for a 3D printer. The metal powder for 3D printers is 10-50-micron metal powder made by agglomerating many submicron order metal particles through a granulating process. As the metal powder is combined by submicron order metal particles, the metal powder is low in melting point and high in melting speed, so that the printing speed of the metal 3D printer can be increased and the precision of a printing member can be improved. Meanwhile, the average grain size of the metal powder is equivalent to existing atomized metal powder for 3D printers, and the metal powder has good dispersibility and conveying property, and can be suitable for existing 3D printer equipment.

The present application provides a combined additive manufacturing and machining system. The combined additive manufacturing and machining system may include an outer chamber, an additive manufacturing tool positioned within the outer chamber, a machining tool positioned within the outer chamber, and a cryogenic fluid source in communication with the machining tool.

The adjustable build envelope for powder bed fusion machines includes a frame in the build chamber having four movable sides, a base and two motors with lead screws. The motors are placed at an angle of 45° with respect to the side of the frame, so that as the motors rotate the lead screws, the two sides of the frame slide in opposite directions. The sides move inward with the help of guide pins and dovetail grooves, thereby reducing the build envelope volume. For large builds, both motors rotate in the reverse direction to increase the build envelope volume. By changing the build envelope volume according to the given build size, powder waste is reduced.

The present disclosure provides three-dimensional (3D) printing methods, apparatuses, systems, and non-transitory computer-readable medium. The disclosure delineates real time manipulation of three-dimensional printing to reduce deformation. The present disclosure further provides 3D object formed using the methods, apparatuses, and systems.