A bed leveling system for a surgical table, which incorporates a platform adapted for a patient to lie down upon, includes an energy emitting device and a first spacer. The energy emitting device is configured and dimensioned to be positioned on a platform of a surgical table. The first spacer is configured to be positioned on a platform of a surgical table to support a portion of a patient's body. The first spacer has a thickness such that a top surface of the first spacer is substantially flush with a top surface of the energy emitting device when disposed adjacent the energy emitting device on a platform of a surgical table.

A device for fixing the outer boundaries of a region of body tissue in a secondary plane (and optionally in a tertiary plane) during medical imaging, examination, and/or intervention. The caliper device includes a caliper bar with two sliding caliper arms that provide fixation of the region of tissue in the secondary plane. One embodiment provides tertiary fixation with a center plate fixator that extends from a center plate positioner. The caliper device is positioned around the region of body tissue within the primary plane fixation instrumentation. The caliper arms (and optionally, the center plate fixator) move together to “thicken” the region of tissue between them. The device is preferably constructed of radiotransparent material and for single-use applications.

A system is provided. The system includes a tank, a holder, a transducer array and an actuator. The tank is configured to contain fluid and allow a hand to be immersed in the fluid. The holder is located in the tank and configured to hold the hand. The transducer array is positioned adjacent to the tank and operable in at least two imaging modes. The actuator is coupled to the transducer array and configured to move the transducer array in the at least two imaging modes. And an ultrasound system is also provided, which includes a processing unit for generating images in the different imaging modes.

A positioning system (10) for positioning a patient (101) for diagnostic imaging is provided. The system comprises a sensor arrangement (12) with at least one sensor (14, 16) configured to provide a sensor signal indicative of at least one body parameter of the patient (101), a controller (18) configured to determine a value of the at least one body parameter based on the sensor signal of the at least one sensor (14, 16), and at least one actuatable support (20) configured to move at least one of an arm (105) and a leg (107) of the patient with respect to a torso of the patient. Therein, the controller (18) is configured to actuate the at least one actuatable support (20) depending on the determined value of the at least one body parameter to move at least one of the arm and the leg relative to the torso of the patient, such that the patient is guided to a posture for diagnostic imaging.

Systems and methods can include a system for positioning an ultrasound probe proximal to anatomy of a patient on a radiation couch including a substantially planar base including engagement features to directly or indirectly index the substantially planar base to the radiation couch and a centrally located guide extending longitudinally along a top side of the base, a probe holder, configured to be coupled to, to translate longitudinally, and to be user-accessed and user-controlled from within, a central region of the substantially planar base, a clamp, configured to localize the probe holder at a specified location along a translation path in the central region of the substantially planar base, leg supports shaped to accommodate a patient's legs from behind, the pair of leg supports being shaped and arranged to provide a space therebetween that can accommodate an ultrasound probe holder.

Systems and methods for medical imaging diagnoses are provided. The methods may include detecting an entrance of the scan platform into a scanning room by a signal emission device, moving the scan platform to a joint area according to connection interface of the medical imaging device by a driving device. The method may also include adjusting the scan platform to connect to the medical imaging device by a position adjusting device. The method may also include connecting the scan platform to the medical imaging device by a physical interface. The method may further include moving the scanning object to a scanning area of the medical imaging device by the driving device.

The present disclosure is directed to a method and apparatus for holding an eyelid open and preventing involuntary blinking during an ultrasound imaging procedure while ensuring patient safety and comfort. Eyelids can be taped up to the forehead or down to the cheek with common medical tape; however, this does not provide the instrument operator with the ability to adjust or control the amount of eye lid opening very well, nor allow the patient to relax the eyelids between scanning sessions. The present disclosure includes a speculum that can be placed in an eye piece such as used in a precision ultrasound device or other imaging device wherein the optical acoustic and transmission path between the eye and instrument is formed by a fluid such as saline solution and distilled water.

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.

An innovative method is disclosed for merging images of an organ in vivo captured through a first imaging technique and a second imaging technique, this latter using an endocavity ultrasound probe inserted into a cavity associated with the organ under investigation. For superimposing the images on one another with greater accuracy, the images captured through the first imaging technique, that is different than the ultrasound technique, a dummy probe is inserted into the cavity associated with the organ under investigation. The dummy probe may be applied both using prior art biplane endocavity probes and innovative electronic scanning endocavity probes. Therefore, two types of endorectal probe are described: a biplane probe, that shall be rotated and translated for capturing biplane images; and a new electronic scanning ultrasound probe delivering the two-dimensional images for the merging without the need for moving the endocavity probe.