A scanning table includes an upper pallet, a lower pallet, a support device, a driving device, an opening belt and an endless belt. The opening belt is fixedly coupled with the lower pallet. The endless belt is fixedly coupled with the upper pallet. A front end of the opening belt is provided with a first driving wheel coupled to the driving device. The lower pallet is driven by the first driving wheel to move in a front-back direction relative to the support device. The endless belt is sleeved on the lower pallet. When the lower pallet moves in the front-back direction relative to the support device, the endless belt moves synchronously with the lower pallet to drive the upper pallet to move in the same direction back and forth relative to the lower pallet.

Systems and methods are disclosed for monitoring a patient by positioning the patient for a predetermined medical mission; sensing biometric and physical conditions of a patient during the mission, and displaying a multimedia interaction with the patient to keep the patient in a predetermined position to improve efficacy of a medical mission.

Upon detecting a body-motion before starting a main-imaging, a sequence-switching control-unit controls operation so as to switch from a usual-imaging sequence to a body-motion adaptive-sequence corresponding to an imaging-portion of a subject P by referring to a body-motion adaptive-sequence storage-unit. Moreover, upon detecting a body-motion during the main-imaging according to the usual-imaging sequence, the sequence-switching control-unit refers to a collected-data storage-unit, and controls operation so as to perform a retake by switching to the body-motion adaptive-sequence if an already-collected data-volume is less than a predetermined volume. By contrast, if the already-collected data-volume is equal to or more than the predetermined volume at a time of detecting a body-motion during the main-imaging, the sequence-switching control-unit stops the main-imaging, and controls a data-processing unit so as to reconstruct a magnetic resonance image only with collected data.

In the current diagnostic imaging workflow, transfer of handicapped patients between a hospital bed to a patient support of an imaging system and back is performed manually, which may be physically exhausting for staff and uncomfortable for the patient being transferred. Furthermore, this should be avoided in an autonomous scanning environment. Accordingly, the present application proposes an approach for enabling patient pain detection and reduction when using a patient transfer device configured to transfer a patient between a first and a second patient support.

The invention relates to medical therapy of detrimental lesions. A system treats with non-invasive arrays of non-ionizing energy-radiation sources. The external sources focus energy dose distribution to a selected volume in a body. Energy output is directed towards a pathologic location and quenched around other sites or healthy tissue. Beam aiming is done without source movement. Targeted, volumetrically discrete energy deposition can beneficially manipulate lesions within the body. The purpose of the focused and enhanced energy deposition is to repair or disable pathologic physiology or structures, nerve pathways, extracellular fluid, and misfolded proteins. Locally augmented energy is used to enhance immunity, release pharmaceutical compounds from energy-sensitive vesicles and reconfigure or eliminate misfolded proteins and their aggregates. Targeted tissue may have enhanced sensitivity to received energy via a non-ionizing-radiation, treatment-localizing agent. This system optimizes delivery of non-ionizing, non-ablating electromagnetic or mechanical energy, degrading or repairing an abnormality upon interaction with it.

A framework for sensor-based patient treatment support. In accordance with one aspect, one or more sensors are used to acquire sensor data of one or more objects of interest. The sensor data is then automatically interpreted to generate processing results. One or more actions may be triggered based on the processing results to support treatment of a patient, including supporting medical scanning of the patient.

Devices, systems, and methods for patient support include arrangements of patient support tops, that are selectively connectible with a connection assembly, through a slide assembly allowing particular arrangement of the patient support tops. The patient support tops can be arranged for flip rotation to assist in positioning a patient's body.

Aspects of the invention are directed to coil positioning apparatuses, systems, and methods of employing the same. One portable head coil apparatus is provided for use with a magnetic resonance imaging system. The portable head coil apparatus includes a base having at least one coil array comprising at least two coil elements. The base is positionable relative to the patients head and has a receiving portion defining a receiving surface positionable adjacent the patient positioning device. The portable head coil apparatus includes an extension movable relative to the base and having at least one coil array comprising at least two coil elements. The extension defines an inner surface having a curvature the degree of which is greater than that of the receiving surface of the base. The inner surface of the extension and the receiving surface of the base together at least partially define an imaging region therebetween.

The present invention relates to a patient lift for assisting a patient onto an examination table that includes: a lift plate positioned between a first handle assembly and a second handle assembly; a plurality of alignment rollers at each corner of the lifting plate, where the alignment rollers are adapted to vertically guide the lifting plate during use; an electrical actuator on each side of the patient lift within each handle assembly, wherein the electrical actuator engages the lifting plate; a power source associated with each electrical actuator; an actuator shaft, where the actuator shaft extends from the electrical actuator and is adapted to engage the lifting plate for the vertical movement of the lifting plate; and a base that provides support for the lifting plate when not in use. A first handle and a second handle extend from the base and are substantially u-shaped with vertical bars.

A sensor selection facility is described. In an embodiment, the sensor selection facility includes an image capture unit for acquiring image data from a patient; a position ascertainment unit for ascertaining positions of the capacitive sensor electrodes relative to the body of the patient based upon the image data; an evaluation unit for ascertaining the anticipated quality of a sensor signal from the capacitive sensor electrodes based upon the ascertained positions; and a combination unit for defining a combination strategy for combining the sensor signals from the respective capacitive sensor electrodes based upon the ascertained signal quality of the capacitive sensor electrodes. A differential voltage measurement system is also described. A method and computer readable medium for adapting a differential voltage measurement system are moreover described.