A trolley system configured to transport a patient within an MRI environment includes a patient support portion, a base portion configured for movement relative to a floor, a lift coupled to the patient support portion and the base portion, an electric motor coupled to the lift, and an electric blower coupled to the patient transfer device. The lift is configured to change the elevation of the patient support portion relative to the base portion. The motor is mounted such that the elevation of the motor is fixed relative to base portion. The trolley system is positionable adjacent an MRI apparatus within the MRI environment and the magnetic field of the MRI does not interfere with the operation of the motor or blower. The trolley system may further include a patient transfer device having an air bearing. The blower is configured to deliver air to the air bearing.

An enhanced hinge and method pivotally and removably connects a member from a structure. In one example, the hinge and method retains the member using a first hinge piece coupled to the structure and a second hinge piece coupled to the member. The first and second hinge pieces may be configured such that the second hinge piece is retained inside the first hinge piece in a closed position and is not free to be decoupled from the first hinge piece but is free to pivot to an open position at the closed position. At the open position the second hinge piece is inverted as compared to its position in the closed position, is free to pass through the first hinge piece and is free to be decoupled from the first hinge piece.

The invention relates to an assistance terminal (5, 6a, 6b) including a housing (5) and at least one terminal (6a, 6b) for remotely monitoring a person (1) connected to a medical assistance and/or monitoring device (3). According to the invention, the housing (5) comprises: reception means (8) for receiving a signal from the medical device (3); conditioning means (9) for conditioning the signal received by the reception means (8) of the housing (5); storage means (10) for, in a learning phase prior to a phase of use of the terminal (5, 6a, 6b), storing a range of signals which are sent by the medical device (3), and which are received by the reception means (8) of the housing (5) and which are conditioned by the conditioning means (9); comparison means (11) for, during the phase of use of the terminal (5, 6a, 6b), comparing a signal sent by the medical device (3), received by the reception means (8) and conditioned by the conditioning means (9), with the signals previously stored; transmission means (12) for, during the phase of use, transmitting the signal, if the latter corresponds to a signal previously stored, to the remote terminal (6a, 6b); the terminal (6a, 6b) comprising means for playing back the signal to at least one person to notify him or her of the sending of said signal by the device.

A patient trolley configured for transporting a patient to a target modality includes a top portion having a top surface and an overhang area along at least one side of the top portion, a bottom portion supporting the top portion, and a side rail coupled to the top portion for movement between a deployed position and a stowed position. The patient trolley is configured to dock adjacent the target modality such that the overhang area is capable of extending over at least a portion of the target modality. The patient trolley may be combined with a patient transfer device to facilitate transfer of a patient from the top surface of the patient trolley to the patient support surface of the target modality. Methods of docking the patient trolley adjacent a target modality and transferring a patient from the patient trolley to the target modality are also provided.

A patient support apparatus includes a plurality of primary sensors adapted to measure different parameters used in the control of the patient support apparatus. One or more suites of secondary sensors are added to the patient support apparatus to provide data about the primary sensors. The secondary sensors may be used to detect errors in the primary sensors, to modify outputs from the primary sensors, and/or to provide usage and/or diagnostic data about the use of the patient support apparatus. The suite(s) of secondary sensors may measure parameters that affect the outputs of one or more of the primary sensors. In some embodiments, the suite(s) of secondary sensors include one or more dormant sensors that are not used on the patient support apparatus until a code modification is received from one or more external sources instructing the control system of the patient support apparatus to begin using the dormant sensor(s).

A patient support apparatus includes a plurality of primary sensors adapted to measure different parameters used in the control of the patient support apparatus. One or more suites of secondary sensors are added to the patient support apparatus to provide data about the primary sensors. The secondary sensors may be used to detect errors in the primary sensors, to modify outputs from the primary sensors, and/or to provide usage and/or diagnostic data about the use of the patient support apparatus. The suite(s) of secondary sensors may measure parameters that affect the outputs of one or more of the primary sensors. In some embodiments, the suite(s) of secondary sensors include one or more dormant sensors that are not used on the patient support apparatus until a code modification is received from one or more external sources instructing the control system of the patient support apparatus to begin using the dormant sensor(s).

A trolley system configured to transport a patient within an MRI environment includes a patient support portion, a base portion configured for movement relative to a floor, a lift coupled to the patient support portion and the base portion, an electric motor coupled to the lift, and an electric blower coupled to the patient transfer device. The lift is configured to change the elevation of the patient support portion relative to the base portion. The motor is mounted such that the elevation of the motor is fixed relative to base portion. The trolley system is positionable adjacent an MRI apparatus within the MRI environment and the magnetic field of the MRI does not interfere with the operation of the motor or blower. The trolley system may further include a patient transfer device having an air bearing. The blower is configured to deliver air to the air bearing.

The present invention is a bed for in-patients or mobility-limited or non-mobility individuals, consisting of a retractable bed that allows the patient or individual to defecate and urinate without leaving the bed. The bed is divided into two structures and comprises a special mattress, also divided into two sections, two levers located on the side of the bed, a back rest, a soft toilet seat, a plate or support structure, a basin-shaped container, a light bell, two levers on the side of the bed that transmit force and displacement and, when pulled by the patient, cause the two bed structures to separate and they lift the seatback and initiate the entry of the soft, toilet-like seat into the plate or support structure, with the container or basin.

A trolley system configured to transport a patient within an MRI environment includes a patient support portion, a base portion configured for movement relative to a floor, a lift coupled to the patient support portion and the base portion, an electric motor coupled to the lift, and an electric blower coupled to the patient transfer device. The lift is configured to change the elevation of the patient support portion relative to the base portion. The motor is mounted such that the elevation of the motor is fixed relative to base portion. The trolley system is positionable adjacent an MRI apparatus within the MRI environment and the magnetic field of the MRI does not interfere with the operation of the motor or blower. The trolley system may further include a patient transfer device having an air bearing. The blower is configured to deliver air to the air bearing.

A one hand swing down bed rail control having a handle with a rotating portion. The rotating portion draws in the proximal ends of first and second lines that in turn draw in the distal ends of the first and second lines that in turn disengage first and second catches between a frame of the bed rail apparatus and a pair of legs of the bed rail apparatus, where a bed rail of the bed rail apparatus is positioned adjacent to a side of a bed and the legs of the bed rail apparatus extend between a mattress and a mattress support. Once the first and second catches are disengaged, the bed rail may swing down.