Abstract: A computer-implemented method of generating a reduction coping includes receiving a digital model comprising a virtual preparation tooth, determining one or more virtual reduction regions on the virtual preparation tooth, and generating a virtual reduction coping comprising one or more exposed regions corresponding to the one or more virtual reduction regions. A method of generating a physical reduction coping includes receiving a 3D digital model of a virtual reduction coping and performing additive manufacturing to generate a physical reduction coping from the virtual reduction coping.

Abstract: An enhanced dilator includes a dilator shaft defining a lumen for receiving a functional device (e.g., a puncturing device) therethrough. The dilator shaft includes a proximal portion for manipulation by a user and a distal portion to placement in or near the heart. A dilator hub is coupled to the proximal portion of the dilator shaft and includes a rotational coupling structure for coupling to a corresponding hub of a therapy sheath.

Abstract: Methods, systems, and non-transitory computer readable storage media are disclosed for generating a machine-learning model and encoding ownership information in the machine-learning model. For example, the disclosed system can generate parameters of a machine-learning model utilizing digital content items modified by a filter. The disclosed system can then process digital content items modified by the filter to generate first outputs based on the digital content items being modified by the filter. The disclosed system can also process digital content items unmodified by the filter to generate second outputs based on the digital content items not being modified by the filter. The disclosed system can determine that the second outputs are degraded relative to the first outputs. Accordingly, the disclosed system can determine ownership of the machine-learning model based on detecting that information about the filter is embedded in parameters of the machine-learning model.

Abstract: The invention relates to binding molecules, such as antibodies, that bind to the chemokine receptor CCR9. More particularly, the invention relates to the treatment of CCR9-mediated diseases or conditions such as inflammatory bowel disease (IBD), and methods for the detection of CCR9, which make use of the binding molecules of the invention.

Abstract: A metal-supported, SOEC or SOFC fuel cell unit (10) comprising a separator plate (12) and metal support plate (14) with chemistry layers (50) overlie one another to form a repeat unit, at least one plate having flanged perimeter features (18) formed by pressing the plate, the plates being directly adjoined at the flanged perimeter features to form a fluid volume (20) between them and each having at least one fluid port (22), wherein the ports are aligned and communicate with the fluid volume, and at least one of the plates has pressed shaped port features (24) formed around its port extending towards the other plate and including elements spaced from one another to define fluid pathways to enable passage of fluid from the port to the fluid volume. Raised members (120) may receive a gasket (34), act as a hard stop or act as a seal bearing surface.

Abstract: Vascular compression devices with an inflatable chamber are disclosed. The inflatable chamber of the vascular compression devices can be inflated and then deflated with a liquid with ultrasound properties similar to biological tissues. Ultrasound waves may be applied to the vascular compression device and may propagate through the vascular compression device and into the biological tissue of the patient to produce an ultrasound image to determine the patency of the vessel.

Abstract: Disclosed is a system and a method to use the system that includes a substrate to support a film of liquid helium and an electron subsystem confined by image forces in a direction perpendicular to the surface of the film, a side gate to electrostatically define a boundary of the electron subsystem, a trap gate to electrostatically define an electron trap located outside the boundary of the electron subsystem, and a load gate to selectively open and close access from the electron subsystem to the electron trap, wherein to open access to the electron trap is to apply a first load gate voltage to the load gate to allow the electrons to access the electron trap, and wherein to close access to the electron trap is to apply a second load gate voltage to the load gate to prevent the electrons from accessing the electron trap.

Abstract: Medical containers are provided, wherein the containers may be used to transport medical devices. The medical container can include a front panel, a rear panel, and a lower panel cooperating to form a cavity. The lower panel may include an absorbent material. The medical container may also include one or more absorbent band members disposed around at least a portion of the circumference of the cavity. An insert portion including a front panel, a rear panel, and a lower panel may be coupled to or disposed within the medical container. The insert portion may be formed from an absorbent material. Methods of using the medical containers are also provided.

Abstract: Disclosed is a system and a method to use the system that includes a substrate to support a film of liquid helium and an electron subsystem confined by image forces in a direction perpendicular to the surface of the film, a side gate to electrostatically define a boundary of the electron subsystem, a trap gate to electrostatically define an electron trap located outside the boundary of the electron subsystem, and a load gate to selectively open and close access from the electron subsystem to the electron trap, wherein to open access to the electron trap is to apply a first load gate voltage to the load gate to allow the electrons to access the electron trap, and wherein to close access to the electron trap is to apply a second load gate voltage to the load gate to prevent the electrons from accessing the electron trap.

Abstract: Methods, systems, and non-transitory computer readable storage media are disclosed for generating a machine-learning model and encoding ownership information in the machine-learning model. For example, the disclosed system can generate parameters of a machine-learning model utilizing digital content items modified by a filter. The disclosed system can then process digital content items modified by the filter to generate first outputs based on the digital content items being modified by the filter. The disclosed system can also process digital content items unmodified by the filter to generate second outputs based on the digital content items not being modified by the filter. The disclosed system can determine that the second outputs are degraded relative to the first outputs. Accordingly, the disclosed system can determine ownership of the machine-learning model based on detecting that information about the filter is embedded in parameters of the machine-learning model.

Abstract: Disclosed is a system and a method to use the system that includes a substrate to support a film of liquid helium and an electron subsystem confined by image forces in a direction perpendicular to the surface of the film, a side gate to electrostatically define a boundary of the electron subsystem, a trap gate to electrostatically define an electron trap located outside the boundary of the electron subsystem, and a load gate to selectively open and close access from the electron subsystem to the electron trap, wherein to open access to the electron trap is to apply a first load gate voltage to the load gate to allow the electrons to access the electron trap, and wherein to close access to the electron trap is to apply a second load gate voltage to the load gate to prevent the electrons from accessing the electron trap.

Abstract: Disclosed is a system and a method to use the system that includes a substrate to support a film of liquid helium and an electron subsystem confined by image forces in a direction perpendicular to the surface of the film, a side gate to electrostatically define a boundary of the electron subsystem, a trap gate to electrostatically define an electron trap located outside the boundary of the electron subsystem, and a load gate to selectively open and close access from the electron subsystem to the electron trap, wherein to open access to the electron trap is to apply a first load gate voltage to the load gate to allow the electrons to access the electron trap, and wherein to close access to the electron trap is to apply a second load gate voltage to the load gate to prevent the electrons from accessing the electron trap.

Abstract: Medical containers are provided, wherein the containers may be used to transport medical devices. The medical container can include a front panel, a rear panel, and a lower panel cooperating to form a cavity. The lower panel may include an absorbent material. The medical container may also include one or more absorbent band members disposed around at least a portion of the circumference of the cavity. An insert portion including a front panel, a rear panel, and a lower panel may be coupled to or disposed within the medical container. The insert portion may be formed from an absorbent material. Methods of using the medical containers are also provided.

Abstract: A method and system are disclosed for puncturing tissue, comprising a puncture device for puncturing tissue and a supporting member for supporting the puncture device. The puncture device is capable of being insertable within the supporting member and being selectively usable in co-operation therewith during a portion of a procedure for puncturing tissue and wherein the puncture device is usable independently therefrom during another portion of the procedure.

Abstract: Medical containers are provided, wherein the containers may be used to transport medical devices. The medical container can include a front panel, a rear panel, and a lower panel cooperating to form a cavity. The lower panel may include an absorbent material. The medical container may also include one or more absorbent band members disposed around at least a portion of the circumference of the cavity. An insert portion including a front panel, a rear panel, and a lower panel may be coupled to or disposed within the medical container. The insert portion may be formed from an absorbent material. Methods of using the medical containers are also provided.

Abstract: Vascular compression devices with an inflatable chamber are disclosed. The inflatable chamber of the vascular compression devices can be inflated and then deflated with a liquid with ultrasound properties similar to biological tissues. Ultrasound waves may be applied to the vascular compression device and may propagate through the vascular compression device and into the biological tissue of the patient to produce an ultrasound image to determine the patency of the vessel.

Abstract: Data is routed within a data network (8), for example a mobile ad hoc network (MANET), comprising at least one wireless network node (10), typically having a router (11). A processor (18) analyzes characteristics of a wireless link (12ab) between a pair of nodes (10a, 10b) within the network (8). Following such analysis, the processor (18) assigns a link class to the wireless link (12ab), the link class being chosen from a predefined set of link classes. A first link class represents that the link (for example link 12ab) is suitable for carrying one or more types of traffic (for example real-time audio and text), but not suitable for one or more other types of traffic (for example real-time video of a certain quality). A second link class represents that a link (for example link 12ac) is suitable for two or more types of traffic (for example real-time audio and real-time video) including at least one type of traffic (for example real-time video) not supported by the first link class.

Abstract: Medical containers are provided, wherein the containers may be used to transport medical devices. The medical container can include a front panel, a rear panel, and a lower panel cooperating to form a cavity. The lower panel may include an absorbent material. The medical container may also include one or more absorbent band members disposed around at least a portion of the circumference of the cavity. An insert portion including a front panel, a rear panel, and a lower panel may be coupled to or disposed within the medical container. The insert portion may be formed from an absorbent material. Methods of using the medical containers are also provided.

Abstract: Data is routed within a data network (8), for example a mobile ad hoc network (MANET), comprising at least one wireless network node (10), typically having a router (11). A processor (18) analyses characteristics of a wireless link (12ab) between a pair of nodes (10a, 10b) within the network (8). Following such analysis, the processor (18) assigns a link class to the wireless link (12ab), the link class being chosen from a predefined set of link classes. A first link class represents that the link (for example link 12ab) 10b is suitable for carrying one or more types of traffic (for example real-time audio and text), but not suitable for one or more other types of traffic (for example real-time video of a certain quality). A second link class represents that a link (for example link 12ac) is suitable for two or more types of traffic (for example real-time audio and real-time video) including at least one type of traffic (for example real-time video) not supported by the first link class.