Abstract: A mattress formed with a base layer, a plurality of sidewalls extending from the base layer to form a void space above the base layer and between the sidewalls, and a top layer positioned atop the sidewalls to enclose the void space; and fill material compressed within the void space; wherein the fill material comprises constituents of at least one of shredded foam memory foam, shredded conventional foam, shredded memory foam and conventional foam mixed, shredded memory foam and fiber mixed, shredded conventional foam and fiber mixed, and shredded memory foam and conventional foam and fiber mixed.

Abstract: An imaging system and methods including a gantry defining a bore and an imaging axis extending through the bore, and at least one support member that supports the gantry such that the imaging axis has a generally vertical orientation, where the gantry is displaceable with respect to the at least one support member in a generally vertical direction. The imaging system may be configured to obtain a vertical imaging scan (e.g., a helical x-ray CT scan), of a patient in a weight-bearing position. The gantry may be rotatable between a first position, in which the gantry is supported such that the imaging axis has a generally vertical orientation, and a second position, such that the imaging axis has a generally horizontal orientation. The gantry may be displaceable in a horizontal direction and the system may perform a horizontal scan of a patient or object positioned within the bore.

Abstract: An imaging system and methods including a gantry defining a bore and an imaging axis extending through the bore, and at least one support member that supports the gantry such that the imaging axis has a generally vertical orientation, where the gantry is displaceable with respect to the at least one support member in a generally vertical direction. The imaging system may be configured to obtain a vertical imaging scan (e.g., a helical x-ray CT scan), of a patient in a weight-bearing position. The gantry may be rotatable between a first position, in which the gantry is supported such that the imaging axis has a generally vertical orientation, and a second position, such that the imaging axis has a generally horizontal orientation. The gantry may be displaceable in a horizontal direction and the system may perform a horizontal scan of a patient or object positioned within the bore.

Abstract: A multi-axis imaging system and methods for imaging a human or animal using a multi-axis imaging system.

Abstract: A detector system for an imaging system includes an airflow cooling system. The detector system includes a detector chassis, a duct extending along the length of the chassis, and a manifold that couples the duct to the interior of the chassis. A vacuum source, such as a suction fan, is coupled to the duct and generates a vacuum force within the duct. The chassis includes a plurality of inlet openings, with an airflow path being defined through the interior of the chassis between the inlet openings and the manifold. The suction fan pulls cooling air through the inlet openings, through the chassis and manifold to the duct, and then expels the air through an exhaust opening. The airflow is directed into thermal contact with detector elements and associated electronics in the detector chassis to provide cooling of these components.

Abstract: An imaging system and methods including a gantry defining a bore and an imaging axis extending through the bore, and at least one support member that supports the gantry such that the imaging axis has a generally vertical orientation, where the gantry is displaceable with respect to the at least one support member in a generally vertical direction. The imaging system may be configured to obtain a vertical imaging scan (e.g., a helical x-ray CT scan), of a patient in a weight-bearing position. The gantry may be rotatable between a first position, in which the gantry is supported such that the imaging axis has a generally vertical orientation, and a second position, such that the imaging axis has a generally horizontal orientation. The gantry may be displaceable in a horizontal direction and the system may perform a horizontal scan of a patient or object positioned within the bore.

Abstract: A mobile diagnostic imaging system includes a battery system and charging system. The battery system is located in the rotating portion of the imaging system, and includes one or more battery packs comprising electrochemical cells. Each battery pack includes a control circuit that controls the state of charge of each electrochemical cell, and implements a control scheme that causes the electrochemical cells to have a similar charge state. The battery system communicates with a charging system on the non-rotating portion to terminate charge when one or more of the electrochemical cells reach a full state of charge. The imaging system also includes a docking system that electrically connects the charging system to the battery system during charging and temporarily electrically disconnects the rotating and non-rotating portions during imaging, and a drive mechanism for rotating the rotating portion relative to the non-rotating portion.

Abstract: A mobile diagnostic imaging system includes a battery system and charging system. The battery system is located in the rotating portion of the imaging system, and includes one or more battery packs, comprising electrochemical cells. Each battery pack includes a control circuit that controls the state of charge of each electrochemical cell, and implements a control scheme that causes the electrochemical cells to have a similar charge state. The battery system communicates with a charging system on the non-rotating portion to terminate charge when one or more of the electrochemical cells reach a full state of charge. The imaging system also includes a docking system that electrically connects the charging system to the battery system during charging and temporarily electrically disconnects the rotating and non-rotating portions during imaging, and a drive mechanism for rotating the rotating portion relative to the non-rotating portion.

Abstract: A noise dampened re-drive assembly for an imaging device. The re-drive assembly includes a two position, pivotally mounted diverter gate that is driven by a reversible motor coupled to a sector gear fixedly mounted to the diverter gate. A slot is provided in the sector gear with a stop pin positioned in the slot. An end of the slot strikes the stop pin as the diverter gate reaches one of its positions. A cantilevered mounted T-shaped dampener having a dampening finger at each of its free ends is mounts in the slot. As the end of the slot nears the stop pin when the diverter gate approaches one of its two positions, the dampening finger adjacent thereto engages the stop pin and reduces the acoustical impulse of the slot end striking the stop pin. A pair of dampeners mounted in a mirror image fashion may be provided in the slot.

Abstract: A drive mechanism for a mobile imaging system comprises a main drive geared into a drive wheel for propelling the imaging system, including a base and one or more imaging components, across a surface. The drive mechanism can also include a scan drive that moves the drive mechanism and the one or more imaging components along an axis relative to the base to provide an imaging scan, and a suspension drive that extends the drive wheel relative to a bottom surface when the imaging system is in a transport mode and retracts the drive wheel relative to the bottom surface of the base when the imaging system is in an imaging mode. The drive wheel supports the weight of the imaging components, but does not directly support the base assembly, which can include pedestal and tabletop support. One or more casters located on the base can support the weight of the base assembly.

Abstract: An imaging system and methods including a gantry defining a bore and an imaging axis extending through the bore, and at least one support member that supports the gantry such that the imaging axis has a generally vertical orientation, where the gantry is displaceable with respect to the at least one support member in a generally vertical direction. The imaging system may be configured to obtain a vertical imaging scan (e.g., a helical x-ray CT scan), of a patient in a weight-bearing position. The gantry may be rotatable between a first position, in which the gantry is supported such that the imaging axis has a generally vertical orientation, and a second position, such that the imaging axis has a generally horizontal orientation. The gantry may be displaceable in a horizontal direction and the system may perform a horizontal scan of a patient or object positioned within the bore.

Abstract: Imaging systems having multiple radiation sources, such as x-ray sources, and multiple radiation detectors, such as flat-panel x-ray detectors and/or diagnostic-quality CT detectors, housed within an imaging gantry, for obtaining simultaneous images of an object positioned within a bore of the gantry in multiple imaging planes.

Abstract: A connector is provided for connecting a pneumatic hose having an end to a structural member of an agricultural implement. A tubular grommet extends through a port in the structural member. A flange extends radially from the outer surface from the tubular grommet and is engageable with a first side of the structural member. A locking barb also extends from the outer surface from the tubular grommet adjacent a second end thereof. The locking barb is engageable with a second side of the structural member with the second end of the tubular grommet received within the interior of structural member.

Abstract: A diagnostic imaging system, which can be a mobile or stationary surgical CT imaging system or an MRI system, comprises an internal airflow cooling system that includes an air intake opening and an air outtake opening that are positioned near the ground and direct air flow away from the sterile surgical field.

Abstract: The present invention relates to an improved glenoid anchor for a shoulder joint prosthesis, in particular a convertible prosthesis, of the type intended to be fixed to the glenoid cavity of the shoulder blade and comprising: a pin with an internally hollow and essentially thimble-like conical sleeve, which has a tapered distal end and an open proximal end; an annular recess formed inside the cavity of the pin in the vicinity of said open proximal end, for receiving by means of snap-engagement an edge of a lug of a prosthesis component; at least one pair of oppositely arranged anti-rotation notches in the proximity of said annular groove for receiving by means of snap fit oppositely arranged teeth of the same lug intended to be snap-engaged together with said pin.

Abstract: A connector is provided for connecting a pneumatic hose having an end to a structural member of an agricultural implement. A tubular grommet extends through a port in the structural member. A flange extends radially from the outer surface from the tubular grommet and is engageable with a first side of the structural member. A locking barb also extends from the outer surface from the tubular grommet adjacent a second end thereof. The locking barb is engageable with a second side of the structural member with the second end of the tubular grommet received within the interior of structural member.

Abstract: A drive mechanism for a mobile imaging system comprises a main drive geared into a drive wheel for propelling the imaging system, including a base and one or more imaging components, across a surface. The drive mechanism can also include a scan drive that moves the drive mechanism and the one or more imaging components along an axis relative to the base to provide an imaging scan, and a suspension drive that extends the drive wheel relative to a bottom surface when the imaging system is in a transport mode and retracts the drive wheel relative to the bottom surface of the base when the imaging system is in an imaging mode. The drive wheel supports the weight of the imaging components, but does not directly support the base assembly, which can include pedestal and tabletop support. One or more casters located on the base can support the weight of the base assembly.

Abstract: A detector system for an imaging system includes an airflow cooling system. The detector system includes a detector chassis, a duct extending along the length of the chassis, and a manifold that couples the duct to the interior of the chassis. A vacuum source, such as a suction fan, is coupled to the duct and generates a vacuum force within the duct. The chassis includes a plurality of inlet openings, with an airflow path being defined through the interior of the chassis between the inlet openings and the manifold. The suction fan pulls cooling air through the inlet openings, through the chassis and manifold to the duct, and then expels the air through an exhaust opening. The airflow is directed into thermal contact with detector elements and associated electronics in the detector chassis to provide cooling of these components.

Abstract: A modular construction system that is adapted to create structures and comprises a link, a first beam, and a second beam. The first beam includes sides and ends, wherein the sides of the first beam each include an engagement slot adapted to receive the link and maintain engagement therewith through a friction fit. Furthermore, the ends of the first beam each include a cross-slot adapted to receive the link and maintain engagement therewith through a friction fit. The second beam including sides and ends, wherein the sides of the second beam each include an engagement slot adapted to receive the link and maintain engagement therewith through a friction fit. In addition, the ends of the second beam each include a cross-slot adapted to receive the link and maintain engagement therewith through a friction fit such that the link connects the first beam with the second beam.