Abstract: Systems and methods for wirelessly controlling medical devices are provided. One system includes a portable user interface having a housing and a communication module within the housing configured to wirelessly communicate with at least one medical device. The portable user interface also includes a display displaying a graphical user interface to control the at least one medical device remotely, wherein the displayed graphical user interface corresponds to a control interface of the at least one medical device.

Abstract: Methods and systems for providing auditory messages for medical devices are provided. One method includes receiving semantic rating scale data corresponding to a plurality of sounds and medical message descriptions and performing semantic mapping using the received semantic rating scale data. The method also includes determining profiles for audible medical messages based on the semantic mapping and generating audible medical messages based on the determined profiles.

Abstract: A patient transport apparatus having a table configured to support a patient, a base attached to the table, a docking system attached to the base, the docking system configured to couple to a mating docking system of an MR imaging system, and a plurality of bays formed in the base, with each bay configured to receive a patient care module therein. The patient transport apparatus further includes a control system configured to be electrically coupled to each patient care module received within the plurality of bays and configured to centrally control each patient care module.

Abstract: Systems and methods for wirelessly controlling medical devices are provided. One system includes a portable user interface having a housing and a communication module within the housing configured to wirelessly communicate with at least one medical device. The portable user interface also includes a display displaying a graphical user interface to control the at least one medical device remotely, wherein the displayed graphical user interface corresponds to a control interface of the at least one medical device.

Abstract: Systems and methods for wirelessly controlling medical devices are provided. One system includes a portable user interface having a housing and a communication module within the housing configured to wirelessly communicate with at least one medical device. The portable user interface also includes a display displaying a graphical user interface to control the at least one medical device remotely, wherein the displayed graphical user interface corresponds to a control interface of the at least one medical device.

Abstract: Methods and systems for providing auditory messages for medical devices are provided. One system includes at least one medical device configured to generate a plurality of medical messages and a processor in the at least one medical device configured to generate an auditory signal corresponding to one of the plurality of medical messages. The auditory signal is configured based on a functional relationship linking psychological sound perceptions in a clinical environment to acoustic and musical sound variables.

Abstract: Methods and systems for providing auditory messages for medical devices are provided. One method includes receiving semantic rating scale data corresponding to a plurality of sounds and medical message descriptions and performing semantic mapping using the received semantic rating scale data. The method also includes determining profiles for audible medical messages based on the semantic mapping and generating audible medical messages based on the determined profiles.

Abstract: Systems and methods for wirelessly controlling medical devices are provided. One system includes a portable user interface having a housing and a communication module within the housing configured to wirelessly communicate with at least one medical device. The portable user interface also includes a display displaying a graphical user interface to control the at least one medical device remotely, wherein the displayed graphical user interface corresponds to a control interface of the at least one medical device.

Abstract: Methods and apparatuses for generating hyperpolarized materials are disclosed. In one embodiment, a flexible fluid path is provided for use in a polarizer system. In a further embodiment, a polarizer system is provided with an electromechanical assembly for controlling the movement of a fluid path, when present, within a sample path of the polarizer system. In a further embodiment, a polarizer system is provided having a sample path entry point at a convenient height for use by a user standing on the ground.

Abstract: In one embodiment, an ultrasound probe is provided including a probe body with a sensing face arranged to be held in contact with a subject by a user. The probe also provides a tactile interface located on a side of the probe body sufficiently close to the sensing face so that a user can depress the tactile interface with a finger while the probe is grasped by the user via the thumb of the same hand and at least two other fingers of the same hand rest in contact with the subject. The probe includes at least one switch which is activated by depression of the tactile interface.

Abstract: In one embodiment, an interventional guidance method includes generating an ultrasound image of a subject anatomy of interest. The method also includes superimposing on the ultrasound image a visual indication of at least one of projection of a position of an interventional device, trajectory of the interventional device, and a location at which the interventional device will intercept an ultrasound imaging plane. The interventional guidance method also includes dynamically altering an aspect of the superimposed visual indication during a interventional procedure. The dynamic altering includes altering a dynamic indication of a trajectory of the interventional instrument transverse to the imaging plane or an interception location of the trajectory of the interventional instrument with the imaging plane.

Abstract: A device for monitoring physiological parameters of a medical patient includes a pneumatic system configured to be coupled to a patient to provide a regulated gas thereto, a computer coupled to the pneumatic system and configured to regulate gas to the patient via the pneumatic system, and a touchscreen monitor coupled to the computer. The touchscreen monitor includes a first graphical user interface (GUI) having a first display, and a second GUI having a second display different from the first display and configured having interaction fields to enable parameters to be input therewith. The device includes a first trigger configured to switch at least from the first GUI to the second GUI.

Abstract: A system and method for management of personal health and wellness is disclosed. The system receives an input for generating a user profile for a user, with the user profile having an initial health status goal associated therewith including target physiological parameter levels, nutritional uptake, and physical fitness activity. Physiological data, nutritional data, and physical fitness data are received by the system over a period of time on measured physiological parameters, dietary consumption, and physical activity of the user, with the system then analyzing and comparing the received data to the physiological parameters, nutritional uptake, and physical fitness activity associated with the initial health status goal. The system communicates to the user a personalized health and wellness status update that is based on the analysis of the received data and the comparison of such data to the physiological, nutritional, and physical activity metrics associated with the initial health status goal.

Abstract: Methods and systems for interacting with datasets for display are provided. One method includes displaying information on a display having a surface viewable by a user and receiving a user input at a surface of a multi-touch sensitive device. The surface of the multi-touch sensitive device is a different surface than the surface of the display viewable by the user. The method further includes manipulating the displayed information in response to the received user input.

Abstract: Methods and apparatuses for generating hyperpolarized materials are disclosed. In one embodiment, a flexible fluid path is provided for use in a polarizer system. In a further embodiment, a polarizer system is provided with an electromechanical assembly for controlling the movement of a fluid path, when present, within a sample path of the polarizer system. In a further embodiment, a polarizer system is provided having a sample path entry point at a convenient height for use by a user standing on the ground.

Abstract: Methods and apparatus to enhance healthcare information analyses are disclosed herein.

Abstract: A patient transport apparatus having a table configured to support a patient, a base attached to the table, a docking system attached to the base, the docking system configured to couple to a mating docking system of an MR imaging system, and a plurality of bays formed in the base, with each bay configured to receive a patient care module therein. The patient transport apparatus further includes a control system configured to be electrically coupled to each patient care module received within the plurality of bays and configured to centrally control each patient care module.

Abstract: A method for regenerating deactivated sulfonated cation exchange catalysts comprises washing the deactivated catalyst with phenol-water mixtures comprising about 5-20 wt. % of water in phenol at a temperature of about 70-95° C.

Abstract: A method for regenerating deactivated sulfonated cation exchange catalysts comprises washing the deactivated catalyst with phenol-water mixtures comprising about 5-20 wt. % of water in phenol at a temperature of about 70-95° C.