Described are systems and methods for multi-material printing. The systems and methods can utilize a stereolithographic printing device, a moving stage, and a microfluidic device. The microfluidic device can include a plurality of reservoirs, each reservoir housing a different ink for printing, and a microfluidic chip. The microfluidic chip can include a chamber that comprises a plurality of inlets, a printing region, and one or more outlets as well as an elastic membrane.

A shaping data combining process of an external PC to which 3D data indicating a shaped object shaped by a 3D printer is input for each 3D job includes: a step of generating shaping data based on the 3D job, a step of combining a plurality of shaping data to generate combined shaping data to fill a margin region where the shaping of the shaped object is not performed with respect to a shapeable region of the 3D printer, and a step of transmitting the combined shaping data to the 3D printer.

A shaping data combining process of an external PC to which 3D data indicating a shaped object shaped by a 3D printer is input for each 3D job includes: a step of generating shaping data based on the 3D job, a step of combining a plurality of shaping data to generate combined shaping data to fill a margin region where the shaping of the shaped object is not performed with respect to a shapeable region of the 3D printer, and a step of transmitting the combined shaping data to the 3D printer.

Systems and methods in which a material or materials (e.g., a viscous material) are printed or otherwise transferred onto an intermediate substrate at a printing unit(s). The intermediate substrate having an image of material printed thereon is subsequently transferred to a sample building unit, and the image of material is transferred from the intermediate substrate to a sample at the sample building unit. Optionally, the printing unit(s) includes a coating system that creates a uniform layer of the material on a donor substrate, and the material is transferred from the donor substrate onto the intermediate substrate at the printing unit(s). Each of the printing units may employ a variety of printing or other transfer technologies. The system may also include material curing, heating, sintering, ablating, material filling, imaging and cleaning units to aid in the overall process.

Systems and methods in which a material or materials (e.g., a viscous material) are printed or otherwise transferred onto an intermediate substrate at a printing unit(s). The intermediate substrate having an image of material printed thereon is subsequently transferred to a sample building unit, and the image of material is transferred from the intermediate substrate to a sample at the sample building unit. Optionally, the printing unit(s) includes a coating system that creates a uniform layer of the material on a donor substrate, and the material is transferred from the donor substrate onto the intermediate substrate at the printing unit(s). Each of the printing units may employ a variety of printing or other transfer technologies. The system may also include material curing, heating, sintering, ablating, material filling, imaging and cleaning units to aid in the overall process.

A device for use in inspecting a test object is provided. The device can include a body including a first end and a second end. The second end can be opposite the first end. The device can also include a probe receiver located at the first end of the body. The probe receiver can be configured to receive an ultrasonic probe. The device can further include a coupling portion located at the second end of the body. The coupling portion can be configured to position the ultrasonic probe with respect to an axis of force transmission of a test object or normal to one or more material layers of the test object during an ultrasound inspection of the test object. Methods of forming the device and performing ultrasonic inspection of a test object with the device are also provided.

A method for generating a representation of a three-dimensional protective device includes accessing a scan of anatomical data of a target and identifying a reference model of a closest size or proportion to a size or proportion of the target. The method further includes creating a boundary of a three-dimensional protective device using the reference model and the scan of anatomical data of the target. Additionally, the method includes generating a representation of a continuous, three-dimensional surface of the three-dimensional protective device that corresponds to the scan of anatomical data and the reference model within the boundary of the three-dimensional protective device.

A method for generating a representation of a three-dimensional protective device includes accessing a scan of anatomical data of a target and identifying a reference model of a closest size or proportion to a size or proportion of the target. The method further includes creating a boundary of a three-dimensional protective device using the reference model and the scan of anatomical data of the target. Additionally, the method includes generating a representation of a continuous, three-dimensional surface of the three-dimensional protective device that corresponds to the scan of anatomical data and the reference model within the boundary of the three-dimensional protective device.

Systems and methods for calculating external bone loss for alignment of pre-diseased joints comprising: generating a three-dimensional (“3D”) computer model of an operative area from at least two two-dimensional (“2D”) radiographic images, wherein at least a first radiographic image is captured at a first position, and wherein at least a second radiographic image is captured at a second position, and wherein the first position is different than the second position; identifying an area of bone loss on the 3D computer model; and applying a surface adjustment algorithm to calculate an external missing bone surface fitting the area of bone loss.

Systems and methods for calculating external bone loss for alignment of pre-diseased joints comprising: generating a three-dimensional (“3D”) computer model of an operative area from at least two two-dimensional (“2D”) radiographic images, wherein at least a first radiographic image is captured at a first position, and wherein at least a second radiographic image is captured at a second position, and wherein the first position is different than the second position; identifying an area of bone loss on the 3D computer model; and applying a surface adjustment algorithm to calculate an external missing bone surface fitting the area of bone loss.