A device and system for and methods of using an ultrasound probe housing containing ultrasound probes configured to produce images inside the body of a patient for procedures requiring needle or probe insertion. The ultrasound probe housing can be configured with a guide channel cut-out or aperture between the ambient side and body side of a patient. A needle guide assembly may be pivotally connect internal to the guide channel cut-out or aperture of the ultrasound probe housing at a pivot point such that during use the needle enters the patient through the needle guide assembly within the ultrasound probe housing so that the needle can be visualized by the ultrasonic probes in real time. The ultrasound probe housing may also provide an adhesion or suction quality to the body side of the device to facilitate aspects of the invention.

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.

An ultrasound probe (“probe”) for use with an ultrasound imaging system is disclosed. In particular, the probe is sized and configured so as to be supported and readily used with as little as one finger on a single hand of a user of the imaging system. This configuration enables remaining fingers on the hand of the user to be employed for other purposes, such as skin traction and patient contact. In one embodiment, therefore, an ultrasound probe is disclosed, comprising a body, a lens included on head portion of the body, a stabilizing portion extending from the body and configured to stabilize the body on a skin surface of a patient without user assistance, and a finger grip portion configured to enable a user of the probe to grasp and maneuver the probe during use thereof with no more than two fingers on a single hand of the user.

An ultrasound imaging probe includes a housing, a circuit board assembly disposed within the housing including a microcontroller, and a motion sensor operably connected to the microcontroller and capable of sensing motion of the housing based on at least one operator interaction with the housing to generate sensor data, a memory chip disposed within the housing and storing information regarding particular operational configurations for the ultrasound imaging probe associated with stored sensor data representing types of stored operator interactions, and a power source disposed at least partially within the housing and operably connected to the assembly. The microcontroller is configured to receive sensor data from the motion sensor in response to the operator interaction with the housing, to compare the received sensor data with the stored sensor data, and to change an operational configuration of the ultrasound probe in response to matching the received sensor data with stored sensor data.

Exemplary embodiments provide systems and methods for portable medical ultrasound imaging. Preferred embodiments utilize a hand portable, battery powered system having a display and a user interface operative to control imaging and display operations. A keyboard control panel can be used alone or in combination with touchscreen controls to actuate a graphical user interface. The system includes a transducer assembly to image, measure and monitor a condition of a patient

A fusion imaging system co-registers and fuses real time ultrasound images with reference images such as those produced by MRI or CT imaging. In an illustrated implementation, previously acquired CT or MRI or ultrasound images are loaded into the system. An ultrasound system is operated in conjunction with a tracking system so that the ultrasound probe and images can be spatially tracked. A computerized image processor registers the probe position with a reference image of the anatomy being scanned by the probe and determines whether the probe appears to be inside the skin line of the subject. If that is the case it is due to probe compression of the subject, and the reference image is modified to locate the skin line in the reference image in front of the ultrasound probe. The modified reference images can then be readily co-registered and fused with the ultrasound images produced by the probe.

Methods for providing real-time, three-dimensional (3D) augmented reality (AR) feedback guidance to a user of an equipment system to achieve improved diagnostic or treatment outcomes, including comparing sensed, real-time user positioning data and data received from the equipment system during use to reference positioning and procedure outcome data, and generating and providing to a user real-time position-based and outcome-based 3D AR feedback based on comparing the sensed and reference data.

Systems and methods for ultrasound shear wave elastography (SWE) are described. According to examples, an ultrasound SWE system includes an ultrasound probe (120), an actuation assembly (130) coupled to the probe and configured to apply an external force against a subject for generating a shear wave within a target region, a controller (140) coupled to the actuation assembly to control the actuation assembly to apply the force responsive to a trigger signal, and ultrasound scanner (110) configured to generate the trigger signal, and further configured to generate an elastography image based at least in part on echo signals received from the target region.

The technology relates to a methods and systems for improving medical imaging procedures. An example method includes receiving a first set of quality metrics for a plurality of medical images acquired at a first imaging facility; receiving a second set of quality metrics for a second plurality of medical images acquired at a second imaging facility; comparing the first set of quality metrics to the second set of quality metrics; based on the comparison of the first set of quality metrics to the second set of quality metrics, generating a benchmark for at least one metric in the first set of quality metrics and the second set of quality metrics; generating facility data based on the generated benchmark and the first set of quality metrics; and sending the facility data to the first imaging facility.

In one embodiment, a probe adapter includes: a holder configured to be detachably attached to an ultrasonic probe; a marker configured to be disposed at a predetermined position in an array direction of the ultrasonic probe and mark a surface of an object which the ultrasonic probe is brought into contact with, under a state where the holder is attached to the ultrasonic probe; and a wiper configured to remove an ultrasonic medium coated on the surface of an object.