A system for providing navigational guidance to a sonographer acquiring images is disclosed. The system may provide haptic feedback to the sonographer. The haptic feedback may be provided through an ultrasonic probe or a separate device. Haptic feedback may include vibrations or other sensations provided to the sonographer. The system may analyze acquired images and determine the location of acquisition and compare it to a desired image and a location for obtaining the desired image. The system may calculate the location for obtaining the desired image based, at least in part, on the acquired image. The system may then provide the haptic feedback to guide the sonographer to move the ultrasonic probe to the location to acquire the desired image.

An ultrasound imaging system and method includes acquiring ultrasound image data while moving an ultrasound probe, automatically identifying a plurality of segments of interest in the ultrasound image data, automatically applying temporal scaling to at least one of the plurality of segments of interest, and displaying the ultrasound image data as a panoramic view comprising a plurality of videos, where each of the plurality of videos is based on a different one of the plurality of the segments of interest, and where, based on the temporal scaling, each of the plurality of videos in the panoramic view takes the same amount of time to play.

Systems, apparatuses, methods, and non-transitory computer-readable media related to a tool for determining presence or absence of a neurological condition in a subject are provided. The tool includes an ultrasound device configured to collect ultrasound data from a head of the subject. The tool further includes a processing circuit configured to calculate a curvature metric based on the ultrasound data. The processing circuit is further configured to calculate a velocity asymmetry metric based on the ultrasound data. The tool is further configured to determine presence or absence of the neurological condition in the subject based on the curvature metric and the velocity asymmetry metric.

The invention relates to an industrial testing device communicating with a data center located in a remote computer network, such as the cloud. Disclosed is a method of registering the device to the cloud and specifying the geographical location of the data center. The method includes selecting a data center from a list of available data centers based on regulations specific to a device type of the industrial testing device. Features are configured for communication between the device and the selected data center.

Disclosed are systems, devices, and methods for using sensor sleeves with surgical tools. In an aspect of the present disclosure, a sensor sleeve includes a tubular body defining a central longitudinal axis and having a lumen defined therethrough, the tubular body being configured to receive a tool, a plurality sensors attached to the tubular body, a cabling extending distally from the tubular body, and an interface connector coupled to the cabling and configured to interface with a navigation system.

A method and system of neural stimulation and imaging of nervous system of a subject. The method includes the steps of providing an interface device operable to generate an ultrasonic beam for neuroniodulation and imaging of a targeted neural structure of a subject, implanting the interface device in the subject, and providing and disposing an external coil array over the targeted neural structure of the subject, wherein the external coil array is wirelessly powering and communicating with the interface device.

An ultrasound imaging system and method includes acquiring ultrasound image data while moving an ultrasound probe, automatically identifying a plurality of segments of interest in the ultrasound image data, automatically applying temporal scaling to at least one of the plurality of segments of interest, and displaying the ultrasound image data as a panoramic view comprising a plurality of videos, where each of the plurality of videos is based on a different one of the plurality of the segments of interest, and where, based on the temporal scaling, each of the plurality of videos in the panoramic view takes the same amount of time to play.

System for non-invasive measuring of an intracranial reserve space (ICRS) parameter of a mammalian subject, comprising a multi-frequency ultrasound probe configured, beginning at a start time, to emit and receive ultrasound waves into and from the subject's head and to produce a signal of brain tissue pulsation; an instrument configured to non-invasively partially occlude an internal jugular vein (IJV) starting at the start time and including a second ultrasound probe producing a second signal; and a computer system configured to receive the signal, the second signal and the start time, the computer system also configured, using one or more processors, to derive from the signal an intracranial brain tissue pulsation waveform and from the second signal images of the IJV, and to determine a length of time from the start time to a subsequent time at which the waveform is sufficiently compressed so as to exhibit a predefined decline in variability.

Systems, methods and devices are provided for performing diagnostic or therapeutic transcranial procedures using a patient-specific transcranial headset. The patient-specific headset may include a patient-specific frame that is fabricated, according to volumetric image data, to conform to an anatomical curvature of a portion of a patient's head. The patient-specific frame is configured to support a plurality of transducers in pre-selected positions and orientations, which may be spatially registered to the volumetric image data. This spatial registration may be employed to control at least a portion of the transducers to focus energy at a pre-selected tissue region.

Systems, devices, and methods for using an intraluminal sensing device are provided. The intraluminal sensing device may include a ferrous element disposed at a distal portion of an elongate flexible member configured to be placed in a body lumen of a patient. An external electromagnetic field device may be used to produce an electromagnetic field that may be used to direct the movement of the flexible elongate member within the body lumen.