Abstract: Systems and methods for displaying a predicted outcome of a lung volume reduction procedure for a patient including a user interface, a processor, and programing operable on the processor for displaying a predicted outcome of the bronchoscopic lung volume reduction procedure on the user interface, wherein displaying the predicted outcome of the lung volume reduction procedure includes receiving patient data comprising volumetric images of the patient, analyzing the volumetric images to identify one or more features correlated to treatment outcome prediction, predicting an outcome for a treatment modality or treatment device using the one or more identified features, and displaying the predicted outcome on the user interface.

Abstract: MR imaging and intervention functions are localized within a single device. At least one integrated coil device which has at least one RF coil, a housing which encases the RF coil and provides an anatomically conformal surface, and a plurality of apertures. The integrated coil device slides along a guide rail system to adjust the size of a patient anatomical imaging region. The apertures in the integrated coil device are available to secure tool holder grid plate inserts or other interventional device guides. The inserts assist in holding the soft tissue for diagnostic imaging and provide support for biopsy/interventional instrument guides. The integrated MR imaging and interventional coil device works in combination with a prone patient support structure, an adaptive torso sling, and also features an open architecture design for improved patient access. The device also works for supine or side imaging procedures.

Abstract: An ultrasound imaging system provides coronal and transverse images for guiding a superior temporal artery guidewire (STA guidewire) through a tortuous region of the STA to an aortic arch region for snaring by a femoral artery catheter snare and pulling through for “through and through” guidewire access. The STA guidewire includes a knob at a distal end which is advanced into a superficial temporal artery (STA) using multi-plane ultrasound guidance, and the STA guidewire is guided through the tortuous region using transverse and coronal images provided by the multi-plane ultrasound imager. The transverse and coronal images indicate the rotational direction for the wire tip to advance the knob end of the STA guidewire within the STA to the external carotid artery.

Abstract: A method and system for acquiring a series of medical images includes a plurality of detectors configured to be arranged to acquire gamma rays emitted from a subject as a result of an advanced radionuclide administered to the subject and communicate signals corresponding to acquired gamma rays. A data processing system is configured to receive the signals from the plurality of detectors, determine double coincidence event dataset and a multiple coincidence event dataset, separate the multiple coincidence event dataset into at least one of a standard lines of response dataset and a nonstandard lines of response dataset, and apply a background correction to the double coincidence event dataset based on the non-standard lines of response dataset and/or the standard lines of response dataset to obtain a standard coincidence dataset.

Abstract: An extracorporeal shock wave lithotripter and a charging and discharging circuit for an extracorporeal shock wave lithotripter are disclosed. The charging circuit is formed by a resistor and a capacitor, and the discharging circuit is formed by the capacitor, a high-voltage switch and a shock wave source apparatus. The capacitance of the capacitor is 1.5 ?F˜2.5 ?F, the pressure peak value of the focus of shock waves generated by discharging to the shock wave source apparatus by the capacitor is 6 Mpa˜30 MPa, a positive pressure period of the bottom pulse width is 3 ?s and a negative pressure period is 5 ?s.

Abstract: The present disclosure provides methods of generating a conductivity map of an in vivo tissue. The present disclosure provides systems for generating a conductivity map of an in vivo tissue.

Abstract: There is provided a method, apparatus, computer program product and wearable device for monitoring volumetric change of a lung during a breathing cycle by using an electronic signal. The method comprises: receiving by a receiver an electronic signal transmitted from a transmitter, wherein at least part of a path of the signal contours at least part of a chest wall of the lung; determining by the receiver measurements of an attribute of the signal received at the beginning and the end of a time interval during the breathing cycle; calculating by a processor a change in length of the signal path during the time interval based on the measurements of the attribute of the signal received at the beginning and the end of the time interval; and calculating by the processor a volumetric change during the time interval based on the change in signal path length.

Abstract: Guidance is provided in stress echocardiography. The recovery time after cessation of the stress is predicted using patient-specific information. The prediction may assist the user in acquiring images of the heart for stress echocardiography during the patient-relevant period, avoid unnecessary rush, and/or avoid acquisition of less useful images.

Abstract: A multimodality imaging system including ultrasound, optical coherence tomography (OCT), photoacoustic (PA) imaging, florescence imaging and endoscopic catheter for imaging inside the gastrointestinal tract with real-time automatic image co-registration capability, including: an ultrasound subsystem for imaging; an optical coherence tomography (OCT) subsystem for imaging, a PA microscopy or tomography subsystem for imaging and a florescence imaging subsystem for imaging. An invasive interventional imaging device is included with an instrumentality to take a tissue biopsy from a location visible on the ultrasound subsystem for imaging, on the optical coherence tomography (OCT) subsystem for imaging, photoacoustic (PA) subsystem for imaging and florescence subsystem for imaging. The instrumentality takes a tissue biopsy from a visible location simultaneously with the visualization of the tissue about to be biopsied so that the tissue biopsy location is visualized before, during and after the biopsy.

Abstract: A fluorescence endoscopy video system includes a multi-mode light source that produces light for white light and fluorescence imaging modes. A filter is positioned at the distal end of an imaging endoscope so that the endoscope can produce fluorescence and white light images of a tissue sample.

Abstract: A dual modality probe is disclosed having both a gamma probe sensor and an ultrasound sensor. A dual imaging system is provided having the probe and at least one external gamma imaging detector and a data acquisition computer system for collecting data simultaneously from the gamma probe sensor, the gamma imaging detector, and the ultrasound sensor of the probe. A method for evaluating a target organ of a patient utilizing the probe and imaging system, and performing a biopsy of the organ is disclosed.

Abstract: An ultrasound flashlight (USFL) configured to present an ultrasound image of a needle inserted in an animal body to deliver a treatment solution to a target structure location, where the image is used to guide a practitioner's positioning a delivery end of the needle. The ultrasound flashlight (USFL) includes a needle with a delivery opening for delivering the treatment solution and an access end opposite the delivery end. An insert is inserted in a lumen extending along a longitudinal axis of the needle housing between the access end and the delivery opening. The insert includes piezoelectric elements that are aligned in the lumen at communication ports in the needle housing, which ports are configured to pass ultrasound energy from inside to outside without passing the treatment solution. The energy from the elements is presented in a display image.

Abstract: The invention relates to a device with a sensor arrangement, which is able to detect magnetic or magnetized oral administration forms after oral take-up, moreover tracks the dissolution thereof via the reduction or disappearance of the magnetic field of the oral administration form, and with a log function, which records a subjective evaluation on the part of the human wearer of the sensor arrangement during or after the oral take-up.

Abstract: The present invention discloses a neuronavigation-guided focused ultrasound system and a method for the same, which are used to guide focused ultrasound energy to a target point. The system of the present invention comprises a focused ultrasound device, a neuronavigation system and a fixture. According to an image of an interested region of an individual, a focus point of the focused ultrasound device, and tracking points provided by the neuronavigation system, the neuronavigation system performs a calibration process and establishes a positional relationship between the focus point and the image of the interested region. Thereby, the neuronavigation system can recognize the focus point and guide focused ultrasound to the target point.

Abstract: An ultrasound imaging system comprising a multi-use electronic display device and an ultrasound imaging device. The multi-use electronic display device is capable of communicating with one or more ultrasound imaging devices and selecting which to connect with based on at least one of previously store information, user input, and information gathered from the ultrasound imaging devices. The multi-use electronic display device may communicate with the ultrasound imaging devices while they are in a low power standby state. This approach reduces the complexity of the pairing process and provides a means for quickly and easily selecting between multiple ultrasound imaging devices.

Abstract: A method of more easily determining a measurement object that may be provided from a standard view for a user who is a doctor to read an ultrasound image in an ultrasound diagnosis. A data acquisition unit acquires ultrasound data of a target object. An image processor generates an ultrasound image by using the ultrasound data, acquires a standard view based on the ultrasound image, acquires measurement information that is information regarding measurement objects measurable within the standard view based on the standard view, and acquires at least one of the measurement objects based on the acquired measurement information.

Abstract: Provided is a method and system for delivering a diagnostic agent to a site in the brain of a subject for imaging at least a portion of the brain site on a medical imaging system. The method and system includes a catheter device with associated lumens having diagnostic agent ports for delivering the diagnostic agent (e.g., infusate) through the lumens and advancing the diagnostic agent so as to exit out from the lumens to at least a portion of the brain site and while sealing a portion of the brain site thereby preventing the exited diagnostic agent from travelling proximally beyond the sealing location, and at the same time imaging at least a portion of the brain site during at least a portion of the sealing duration so that the brain site can be visualized on a medical imaging system. The diagnostic agent (infusate) is able to highlight borders and internal patterns of the deep structures of the brain thereby enabling direct targeting.

Abstract: A personal information system is provided. The system may include a portable information device having a housing including a top surface defined at least partially by a display, a bottom surface configured with a central region in which an optical sensor, electrical connector, and data connector are positioned, the housing enclosing an internal volume in which a processor is provided, the top surface and bottom surface being coupled by a perimeter side edge extending therebetween, and a mounting structure formed at least partially around the perimeter side edge of the housing. The system may further include a frame, which may be connected to a band, the frame surrounding a void and configured to receive the mounting structure, the frame and mounting structure being releasably securable via a tongue and groove connection. The system may further comprise a dock to which the information device may be connected.

Abstract: Novel methods and systems to map the structure of blood vessels and monitor the flow of blood through these vascular networks using thermal imaging techniques. To obtain high contrast thermal images of the vascular structure in tissue, there must be a temperature difference between the blood/blood vessels and surrounding tissue. If the blood and blood vessels are warmer than the surrounding tissue, the vessels will appear brighter in thermal infrared images. A temperature contrast between blood vessels and the surrounding tissue can be achieved through selective heating of the blood. Hemoglobin has major absorption peaks near 420 and 530 nm, while absorption due to water (the dominant component of soft tissue) is significantly lower at these wavelengths. Irradiation of blood and tissue at these wavelengths produces selective heating of the blood compared to the surrounding soft tissue.

Abstract: A robotic surgery method includes coupling a first element of a fluoroscopic imaging system to a first robotic arm fixed relative to an operating room. The first robotic arm includes a mounting fixture configured to be interchangeably coupled to a surgical tool and the first element of the fluoroscopic imaging system. The method further includes mounting a second element of the fluoroscopic imaging system in a position and orientation relative to the first element such that a targeted patient tissue structure may be positioned there between. The method further includes utilizing a sensing system and one or more sensing elements coupled to each of the first and second elements of the imaging system to determine a relative spatial positioning between each of the first and second elements of the fluoroscopic imaging system. The first and second elements of the fluoroscopic imaging system are a source element and a detector element.