Abstract: A system for generating MR images for segmentation and/or use in correcting attenuation in subsequent images using other modalities (e.g., PET, SPECT, etc.) is described. A surrogate soft tissue device is provided and positioned on the patient near the artifact source to provide a surrogate soft tissue boundary that can be imaged and interpreted during segmentation to mitigate the deleterious effects of a local susceptibility artifact in the MR image.

Abstract: An imaging system collects a plurality of images of an extremity of a subject, each collected at a unique spectral band. A physiologic arterial parameter of the extremity is determined from the plurality of images upon image registration. A record of the physiological arterial parameter is recorded in an electronic data store and an indication of the parameter is outputted. The method is performed by a medical professional associated with a temporal clinical expenditure cost in an epoch, for an entity. The product of the (i) epoch and the (ii) temporal clinical expenditure cost is less than a difference between (a) an average or absolute reimbursement associated with the current procedural terminology code by the entity and (b) incidental expenditures associated with the performance of the method.

Abstract: An ultrasonic probe includes a tip part, an operation part and a middle part. A motor is disposed in a cantilever system in a front portion in the middle part. The motor extends in a direction of a central axis of a shaft-like part. A driving force generated by the motor is transferred to a scanning mechanism. A vibrator part vibrates by the scanning mechanism.

Abstract: A medical probe, consisting of a flexible insertion tube, having a distal end for insertion into a body cavity of a patient, and a distal tip, which is disposed at the distal end of the flexible insertion tube is configured to be brought into contact with tissue in the body cavity. The probe also includes a coupling member, which couples the distal tip to the distal end of the insertion tube and which consists of a tubular piece of an elastic material having a plurality of intertwined helical cuts therethrough along a portion of a length of the piece.

Abstract: A method of mapping includes receiving inputs measured by a probe at respective locations inside a body cavity of a subject. At each of the respective locations, a respective contact quality between the probe and a tissue in the body cavity is measured. The inputs for which the respective contact quality is outside a defined range are rejected, and a map of the body cavity is created using the inputs that are not rejected.

Abstract: An ultrasonic therapy system delivers ultrasonic therapy energy to a therapy site in the body which is infused with microbubbles. A system without an image guidance capability has an array transducer which delivers therapy energy, a therapy transducer driver which causes the array transducer to deliver therapeutic energy, a control for controlling the intensity of the therapeutic energy, and a display of the sonotherapy signal strength of the energy and the concentration of microbubbles at the therapy site. A system with ultrasonic imaging capability will display an ultrasound image for therapeutic guidance and a measure of the microbubble concentration. The method of the present invention is performed as an adjunct to a standard drug therapy or other treatment regimen, following such treatment with an infusion of ultrasound and delivery of ultrasound therapy energy.

Abstract: Systems and methods are provided to incorporate an off-resonance correction into the pulse labeling train of PCASL/VEPCASL. In one or more aspects, the systems and methods are based on a method for generating an encoding scheme for any number and arrangement of blood vessels. The off-resonance correction can be incorporated into the generation of optimized encodings to acquire arterial spin labeling (ASL) data, such as PCASL and VEPCASL data.

Abstract: In some embodiments, ultrasound receive beamforming yields beamformed samples, based upon which spatially intermediate pixels (232, 242, 244) are dynamically reconstructed. The samples have been correspondingly derived from acquisition through respectively different acoustic windows (218, 220). The reconstructing is further based on temporal weighting of the samples. In some embodiments, the sampling is via synchronized ultrasound phased-array data acquisition from a pair of side-by-side, spaced apart (211) acoustic windows respectively facing opposite sides of a central region (244) to be imaged. In particular, the pair is used interleavingly to dynamically scan jointly in a single lateral direction in imaging the region. The acquisition in the scan is, along a synchronization line (222) extending laterally across the region, monotonically progressive in that direction. Rotational scans respectively from the window pair are synchronizable into a composite scan of a moving object.

Abstract: An ultrasound imaging system includes a biplane ultrasound probe and a console. The biplane ultrasound probe includes a sagittal array and a transverse array. The console includes a transmit circuit, a receive circuit, and an image generator. The transmit circuit is configured to control the sagittal and transverse arrays to emit ultrasound signals while the probe is manually rotated and translated. The receive circuit is configured to receive electrical signal produced by the sagittal and transverse arrays in response to the sagittal and transverse arrays receiving echoes produced in response to the corresponding ultrasound signals interreacting with structure. The image generator is configured to construct a three-dimensional image with the electrical signals from the sagittal or transverse array using the electrical signals from both the sagittal and transverse arrays to track the motion of the probe and align scanplanes.

Abstract: A multimodal intravascular catheter system includes a catheter with an optical channel and an electrical channel. A distal end of the catheter includes an optical element and an ultrasonic transducer, which are oriented orthogonally to a rotational axis of the catheter. A motor drive unit (MDU) is coupled to a proximal end of the catheter and includes a drive motor to rotate the catheter. The optical channel directs light from a pulsed UV laser source to the optical element, and returns an optical fluorescence signal from the optical element. A photodetector converts the returned optical fluorescence signal into an electrical fluorescence signal. An intravascular ultrasound (IVUS) processor is coupled to the ultrasonic transducer through the electrical channel, wherein the IVUS processor generates a drive signal for the ultrasound transducer, and processes echo information returned from the ultrasound transducer. Finally, a digitizer samples the electrical fluorescence signal and associated echo information.

Abstract: A medical system comprises an instrument, a position acquisition apparatus, a data processing and image generating apparatus and an image display and control unit. The position acquisition apparatus is configured to acquire a position and orientation of the instrument in relation to a reference coordinate system. The data processing and image generating apparatus is configured to generate an image of a body part from currently recorded or stored data representing a body part, which image reproduces a view of the body part together with a representation of the position, and preferably also the orientation of the instrument so that an observer can gather the position and orientation of the instrument in the body part from the image of the body part.

Abstract: A method of operating a shape sensing apparatus comprises receiving first shape data from a first shape sensor section including a first elongated optical fiber section extending between a first location coupled to a reference fixture and a second location coupled to a first target fixture. The method further comprises receiving second shape data from a second shape sensor section including a second elongated optical fiber section extending between a third location coupled to the reference fixture and a fourth location coupled to the first target fixture. The first and third locations are maintained in a first known kinematic relationship, and the second and fourth locations are maintained in a second known kinematic relationship. The method further comprises determining a position of an end portion of the first shape sensor section using the second shape data and using the first and second known kinematic relationships.

Abstract: Provided is a pulmonary edema monitoring apparatus, which is always attached to the body and is capable of continuously monitoring whether a pulmonary edema occurs, for a patient with advanced disease or a shock patient. This pulmonary edema monitoring apparatus includes: an ultrasound frequency module which is attached to the chest of a patient, generates an ultrasound, and receives a reflection wave reflected from the inside of a human body; and a control module which measures the intensity (this is referred to as “ultrasound radio frequency data”) of the reflection wave, determines whether a pulmonary edema occurs on the basis of an increasing rate of the ultrasound radio frequency data according to a degree of multiple reflection, and provides an alarm.

Abstract: The present invention relates to a pregnancy monitoring system (10) and to a method for detecting medical condition information from a pregnant subject of interest (12).

Abstract: The system includes an instrument for determining the anatomical, biomechanical, and physiological properties of a body segment that includes one or more force sensitive probes is provided. A human operator actuates one or more force sensitive probes, wherein the force sensitive probes are positioned at the surface of the body segment. The operator pushes on the force sensitive probes with varying force applied on the body segment to measure tissue deflection forces. The instrument may include one or more of gyroscopes, accelerometers, and magnetometers capable of measuring changes in tissue deflection caused by the force sensitive probes relative to a grounded reference frame in 3-D space, wherein the tissue deflection force data and the change in tissue deflection data are used to compute segment tissue viscoelastic properties. The instrument may also be untethered or wireless.

Abstract: An MR imaging method with an imaging workflow is provided. Within the scope of the MR imaging method, at least one breath-holding command is output to a patient. An MR imaging is performed with an MR imaging method that may be used with free breathing. A breathing movement of the patient is detected based on measured data acquired when performing the MR imaging method. A time relationship is determined between the breathing movement of the patient and the breath-holding command. The imaging workflow is modified as a function of the determined time relationship. A breathing monitoring device and a magnetic resonance imaging system are also provided.

Abstract: A method (94) for aligning a cardiac model can include receiving (95) an initial position signal from three position sensors (17, 39, 40) disposed along a distal end of a coronary sinus catheter (13) positioned in a coronary sinus (41) of a heart (10). The method (94) can include receiving (96) a subsequent position signal from the three position sensors (17, 39, 40). The method (94) can include determining (97) a positional change vector based on a change in position between an initial position associated with the initial position signal and a subsequent position associated with the subsequent position signal. The method (94) can include shifting (98) a point of interest associated with a cardiac model, using the positional change vector. The method (94) can include dynamically aligning (100) the cardiac model based on an updated position of the three position sensors (17, 39, 40).

Abstract: In an example, this document discloses an apparatus for insertion into a body lumen, the apparatus comprising an optical fiber pressure sensor. The optical fiber pressure sensor comprises an optical fiber configured to transmit an optical sensing signal, a temperature compensated Fiber Bragg Grating (FBG) interferometer in optical communication with the optical fiber, the FBG interferometer configured to receive a pressure and modulate, in response to the received pressure, the optical sensing signal, and a sensor membrane in physical communication with the FBG interferometer, the membrane configured to transmit the received pressure to the FBG interferometer.

Abstract: A system, particularly a photo-plethysmographic system, determines vital sign information of a subject. A marker includes a marker area such as fluorescent or luminescent pigments, that emits light towards a skin of the subject. Light reflected by the skin is encoded with information about blood in the skin. An attachment layer attaches the marker to the subject. A detector, such as an optical camera, detects radiation reflected from the skin of the subject, and an analysis processor determines the vital sign information, such as heart rate and blood oxygen (SpO2), of the subject from the detected radiation reflected from the skin of the subject.

Abstract: Provided herein are systems, methods and apparatuses for an integrated system and architectures comprising a central processing unit (CPU) located a substantial physical distance from a sample.