Abstract: The present invention provides an ultrasound system, which comprises: a signal acquiring unit to transmit an ultrasound signal to an object and acquire an echo signal reflected from the object; a signal processing unit to control TGC (Time Gain Compensation) and LGC (Lateral Gain Compensation) of the echo signal; a TGC/LGC setup unit adapted to set TGC and LGC values based on TGC and LGC curves inputted by a user; and an image producing unit adapted to produce an ultrasound image of the object based on the echo signal. The signal processing unit is further adapted to control the TGC and the LGC of the echo signal based on the TGC and LGC values set by the TGC/LGC setup unit.

Abstract: The present invention relates to fetal monitoring and, more particularly, to an electronic external fetal monitoring system that includes a self adhering single use dermal patch including embedded sensors that can be attached to the skin of an expectant maternal patient and is configured to record fetal heart rate, uterine activity, and uterine integrity.

Abstract: In an embodiment of the present disclosure, an optical method for determining morphological parameters and physiological properties of tissue is presented. The method includes using reflectance measurements from a tissue area for a plurality of wavelengths, using a bio-optical model, using radiative transfer modeling and using a non-linear inversion procedure.

Abstract: Apparatus for administering certain nerve blocks includes a sheath constructed from a flexible ultrasound echogenic material, a more rigid introducer/dilator for introducing the sheath into the patient, and an ultrasound echogenic catheter for inserting through the sheath once the distal end of the sheath is in place adjacent the nerve(s) to be blocked and the introducer/dilator has been withdrawn. The catheter has provisions at its proximal end for connecting to a source of local anesthetic. Methods for use of this apparatus are also described.

Abstract: Apparatus for administering certain nerve blocks includes a sheath constructed from a flexible ultrasound echogenic material, a more rigid introducer/dilator for introducing the sheath into the patient, and an ultrasound echogenic catheter for inserting through the sheath once the distal end of the sheath is in place adjacent the nerve(s) to be blocked and the introducer/dilator has been withdrawn. The catheter has provisions at its proximal end for connecting to a source of local anesthetic. Methods for use of this apparatus are also described.

Abstract: Methods for treating a human patient having a subarachnoid hematoma, such as to prevent cerebral vasospasm or to reduce the severity of cerebral vasospasm in the patient, and associated devices, systems, and methods are disclosed herein. In a particular embodiment, a thrombolytic agent is introduced extravascularly into a subarachnoid region including the hematoma. A headset configured for hands-free delivery of transcranial ultrasound energy is connected to the patient and used to deliver ultrasound energy to the subarachnoid region to enhance the thrombolytic effect of the thrombolytic agent. The type and/or dosage of the thrombolytic agent can be selected based on the enhanced thrombolytic effect. For example, the enhanced thrombolytic effect can allow the therapeutically effective use of less aggressive thrombolytic agents and/or lower dosages of thrombolytic agents. In some cases, this can reduce the clinical probability of additional cerebral hemorrhage.

Abstract: 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.

Abstract: An intravascular ultrasound imaging system with a catheter having an elongated body having a distal end and an imaging core arranged to be inserted into the elongated body. The imaging core is arranged to transmit ultrasonic energy pulses and to receive reflected ultrasonic energy pulses. The system further includes an imaging engine coupled to the imaging core and arranged to provide the imaging core with energy pulses to cause the imaging core to transmit the ultrasonic energy pulses. The energy pulses are arranged in repeated sequences and the energy pulses of each sequence have varying characteristics. The reflected pulses may be processed to provide a composite image of images resulting from each different characteristic.

Abstract: A body coil for magnetic resonance imaging includes one or more coil elements incorporated in a shell material. The body coil has a rectangular basic shape. Two opposing edge sections of the body coil may be pivoted along one pivot axis, respectively, relative to a middle section. For this purpose, movement elements that effect pivoting are arranged on an edge section side.

Abstract: A device for assisting with the handling of an instrument or tool, the device comprising a jointed mechanical structure on a support, wherein an instrument or tool may be attached, motor drives configured to actuate the jointed mechanical structure, according to a number of degrees of freedom of less than that which the structure provides to the instrument or tool, and an automatic control, wherein the automatic control drives the motor drives in order to facilitate the meeting of a constraint on position and/or velocity parameters of the instrument or tool, which constraint the motor drives by themselves, independently of handling by an operator, cannot entirely meet.

Abstract: The invention relates to a medical tomosynthesis system (10) having an interventional device (15) and an image acquisition device (11, 12) for acquiring images of a subject volume in a plurality of angular positions around the subject volume. In the system, a three-dimensional geometrical model of the interventional unit is used to identify the projection angles of the image acquisition device that actually can be used. Preferably, this three-dimensional model is achieved by reconstructing it from projection images acquired with the X-ray image acquisition device. The invention also relates to a method for acquiring images with such a system.

Abstract: Implantation imaging techniques are presented herein to provide a surgeon with visual feedback during implantation of an implantable medical device in a recipient. The implantation imaging techniques may include the generation of a magnetic field that induces a voltage at a coil positioned in the recipient. The induced voltage is used to determine the orientation of the coil positioned in the recipient relative to direction of the magnetic field.

Abstract: An ultrasound apparatus according to the present embodiments includes a receiving unit and a probe controlling unit. The receiving unit receives settings in relation to the aperture of the ultrasound probe and the region of interest of the subject with a contrast agent injected. The probe controlling unit controls the ultrasound probe based on the settings received by the receiving unit in such a manner as to transmit an ultrasound wave from the vibrator arranged in the aperture to the region of interest.

Abstract: Methods and systems for producing an electrophysiological map of a heart of a patient are disclosed. An example method may include determining a target location and an orientation of a catheter tip, confirming that the tip is located at the target location, measuring the heart parameter value at each of the target locations, and superimposing a plurality of representations of the heart parameter value. Confirmation that the tip of the catheter is located at a target location can be accomplished by comparing the current location of the tip with the target location, a corresponding heart parameter value being measured at each of the target locations by a heart parameter sensor, and the representations of the heart parameter value being superimposed on an image of the heart at the target location to produce the electrophysiological map.

Abstract: A treatment device and methods for HIFU treatment of thyroid and parathyroid disorders are provided. The treatment device comprises the first sensor for detecting swallowing motion and the second sensor for tracking the motion of the thyroid and parathyroid tissue with ultrasound imaging. Thus, the treatment device allows for safe and non-invasive use of HIFU on thyroid and parathyroid tissue of patients by synchronizing HIFU pulse delivery with patient swallowing and/or directing the applicator of HIFU energy to follow the appropriate tissue when the patient moves.

Abstract: The present invention relates to the field of e.g. ultra-sound imaging. In particular the present invention relates to a device for supporting an ultrasound probe or probe with other contrast imaging technology, preferably during heart imaging. The device comprises a fixation part comprising an aperture for receiving the probe. The device also comprises at least two skin supports (2, 3) for supporting the probe against a tissue of a human or animal bodily organ. The fixation part is positioned above the skin supports and a cavity (4) between the skin supports (2,3) are provided for allowing the probe to perform measurements of the organ. In addition the invention relates to a handle for operating the device a system comprising a probe, the device and the handle.

Abstract: In some preferred embodiments, a medical imaging system with an integrated body monitoring device is disclosed which includes: a movable platform for supporting a patient during image acquisition; an image acquisition device for the acquisition of images of the patient upon the platform; a body monitoring device for the monitoring of a body function of the patient during image acquisition; the body monitoring device being adapted to transmit body function signals to the image acquisition device and the image acquisition device being adapted to effect image acquisition based on the signals received from the body monitoring device; wherein the body monitoring device is integrated with the image acquisition system. In the preferred embodiments, the medical imaging system is a nuclear medical imaging system and the body monitoring device is an ECG device.

Abstract: According to one embodiment, an ultrasonic diagnostic apparatus according to one embodiment transmits an ultrasonic wave into a predetermined region including a diagnosis target of an object, receives a reflected wave from the predetermined region, and acquires ultrasonic image data based on the reflected wave and comprises a correction unit which executes tone correction of the ultrasonic image data, and in the tone correction, the correction unit calculates a histogram associated with brightness of the image data and calculates a brightness distribution range corresponding to the diagnosis target and a tone correction function using the histogram.

Abstract: A system and method of delivering a radiation therapy treatment plan to a patient. The treatment plan is delivered using a radiation therapy system including a moveable support for supporting a patient, a gantry moveable relative to the support and supporting a radiation source and multi-leaf collimator for modulating the radiation source. The support and gantry are moved during delivery of the treatment plan.

Abstract: An EIT device has a plurality of electrodes (4) that can be arranged on a body in order to reconstruct the impedance distribution of the body with a reconstruction algorithm. The control unit (10) of the EIT device is set up by suitable programming to continuously determine at least one property (e1, . . . , eM) each from the measured signals (U1, . . . , UM) of all measuring channels and to correct measured signals of the measuring channels on the basis of the properties or to adapt the reconstruction algorithm on the basis of the properties.