The present invention relates to an apparatus, method and system for detecting and locating dental cavitations in jawbones using Through-Transmission Alveolar Ultrasonography (TAU). The apparatus comprises a measuring unit comprising an ultrasonic transducer and a round ultrasonic receiver. The apparatus is a handhold and is configured to define the geometric position of the ultrasonic transducer and the ultrasonic receiver with respect to each other so as to achieve a high-resolution ultrasound image of the jawbone with minimal errors and in order to improve diagnosis of dental cavitations.

Parametric model based computer implemented methods for determining the stiffness of a bone, systems for estimating h the stiffness of a bone in vivo, and methods for determining the stiffness of a bone. The computer implemented methods include determining a complex compliance frequency response function Y(f) and an associated complex stiffness frequency response function H(f) and independently fitting a parametric mathematical model to Y(f) and to H(f), and using a first measure of conformity and a second measure of conformity of the collected data to determine accuracy and repeatability of measurements. The systems include a device for measuring the stiffness of the bone in vivo and a data analyzer to determine a complex compliance frequency response function Y(f) and an associated complex stiffness frequency response function H(f).

Automated ultrasound image labeling and quality grading systems and methods are provided. An ultrasound system includes an ultrasound imaging device configured to acquire ultrasound images of a patient. An anatomical structure recognition and labeling module receives the acquired ultrasound images from the ultrasound imaging device, and automatically recognizes anatomical structures in the received ultrasound images. The anatomical structure recognition and labeling module automatically labels the anatomical structures in the images with information that identifies the anatomical structures. The acquired ultrasound images and the labeled anatomical structures are displayed on a display of the ultrasound imaging device.

A guidance system for guiding insertion of a needle into a body of a patient utilizes ultrasound imaging or other suitable imaging technology. The guidance system can include an imaging device including a probe for producing an image of the internal body portion target, such as a blood vessel. The imaging device can be configured to provide at least one indication of status via sensory feedback based on a determined position of the needle, for example via a plurality of light-emitting diodes located on the device. One or more sensors can be included with the probe that can sense a magnetic field associated with the needle. The system may include a processor that can receive magnetic field data sensed by the at-least-one sensor to determine the position of the needle. The system can also include a display that depicts the determined position of the needle.

Disclosed herein is a probe head-cover applicator and method for applying a probe-head cover to a probe head of an ultrasound probe. A probe head-cover applicator can include a tray including a cavity, an insert of a compressible material suspended over the cavity, and a probe-head cover adhered to the insert. The insert can include a first adhesive on an outward-facing surface of the insert facing away from the cavity. The probe-head cover can be adhered to the insert by the first adhesive. The probe-head cover can include a second adhesive on an outward-facing surface of the probe-head cover facing away from the insert. The second adhesive can be configured to adhere the probe-head cover to a probe head of an ultrasound probe when the probe head is inserted into the cavity.

An integrated device of a patch and sensor assembly detects extravasation or infiltration. A transmitter is positioned to direct power into a body portion. A sensor is positioned to receive the power transmitted through the body portion. A substrate is attachable to an outer surface of the body portion and supports the transmitter and the sensor. A signal processor is coupled to the transmitter and the sensor for detecting a change in a fluid level in the body portion from extravasation or infiltration based on the power received by the sensor. A power supply is coupled to the transmitter and the sensor. An indicator is responsive to the signal processor to indicate a detected change in a fluid level in the body portion from extravasation or infiltration.

A system for detecting blood velocity within a blood vessel includes a piezoelectric transducer supported on a ceramic substrate. The ceramic substrate supports the piezoelectric transducer at a fixed angle of incidence that is greater than 0 and less than 90. The ceramic substrate is formed of steatite ceramic and is configured to couple an ultrasonic signal emitted by the transducer to skin underlying the substrate.

An ultrasound probe according to an embodiment includes a plurality of piezoelectric transducer elements and a substrate. The plurality of piezoelectric transducer elements is divided in grid sections. The piezoelectric transducer elements have an ultrasound wave transmitting/receiving surface. The substrate is provided on a rear surface of the plurality of piezoelectric transducer elements. The substrate has a wiring configured to connect a plurality of electrodes for a group of piezoelectric transducer elements to driving circuitry. The group of piezoelectric transducer elements is located in a substantially concentric circle among the plurality of piezoelectric transducer elements. The rear surface of the plurality of piezoelectric transducer elements is a surface opposite to the ultrasound wave transmitting/receiving surface.

Disclosed is an ultrasound system having a monitoring pad for application to a patient, an ultrasound probe that connects to the monitoring pad and has a plurality of ultrasound transducers, and an ultrasound beamforming device configured to control the ultrasound transducers to focus an ultrasound beam into the patient and to read resulting reflections of the ultrasound beam. The monitoring pad has an ultrasound gel pad and a support structure that holds the ultrasound gel pad. In accordance with an embodiment of the disclosure, the support structure is geometrically configured to receive the ultrasound probe and to hold it in a fixed arrangement against the ultrasound gel pad, such that the ultrasound gel pad is sandwiched between the patient and the ultrasound transducers. In some implementations, the monitoring pad has electrocardiogram electrodes and/or other sensor(s) unrelated to ultrasound, and the ultrasound beamforming device receives readings from the same.

A vascular monitoring system includes a collar configured to be positioned about a patient's vessel and a transducer coupled to the collar. The collar may be formed by a strap that is wrapped around the patient's vessel and maintained in a closed configuration. The transducer is configured to emit an ultrasonic signal that is transmitted through the patient's vessel.