An otoscope uses differential reflected response of optical energy at an absorption range and an adjacent wavelength range to determine the presence of water (where the wavelengths are water absorption wavelength and adjacent non-absorption excitation wavelengths). In another example of the invention, the otoscope utilizes OCT in combination with absorption and non-absorption range for bacteria and water.

Ultrasound devices and guidance systems for ultrasound devices for subdermal devices (e.g., needles) used in conjunction with the ultrasound devices are described. The guidance systems can includes features for easy release of a device from the system following targeting to a subdermal site. A guidance system can be ambidextrous such that a needle can be released by use of either the left or right hand and by use of either a thumb or a finger of an operator. Embodiments that include guidance tracks and slidable guidance cartridges that grasp the hub of a subdermal device are also described.

Described herein are methods and apparatuses for packaging an ultrasound-on-a-chip. An ultrasound-on-a-chip may be coupled to a redistribution layer and to an interposer layer. Encapsulation may encapsulate the ultrasound-on-a-chip device and first metal pillars may extend through the encapsulation and electrically couple to the redistribution layer. Second metal pillars may extend through the interposer layer. The interposer layer may include aluminum nitride. The first metal pillars may be electrically coupled to the second metal pillars. A printed circuit board may be coupled to the interposer layer.

Ultrasound imaging systems for automatically adjusting settings according to an position and/or orientation of one or more interfaces. The ultrasound imaging systems can include a probe configured to send and receive ultrasound signals for performing a medical exam, a medical procedure, or both; and a processor configured to: select a diagnostics mode or a procedural mode based on an operating orientation of the ultrasound imaging system or a portion thereof, and adjust one or more settings of the imaging system according to the selected diagnostics mode or the selected procedural mode.

Probe assembly includes an ultrasound probe and a cable assembly configured to communicatively couple the ultrasound probe to a control system and transmit signals therethrough. The cable assembly includes a cable jacket surrounding a channel of the cable assembly. The cable assembly also includes a plurality of wire pairs extending through the channel. The channel being sized and shaped to permit the wire pairs to move relative to one another within the channel when the probe assembly is moved. The wire pairs and the channel are configured to have a designated pack ratio (Area.sup.WPS/Area.sup.C). The Area.sup.WPS includes a collective cross-sectional area of the wire pairs, and the Area.sup.C is equal to a cross-sectional area of the channel.

A system for detecting/quantifying the conductance of a right-to-left cardiac shunt includes a mouthpiece assembly, a solenoid-driven vacuum/pressurization assembly; a controller for operating the solenoid-driven vacuum/pressurization assembly; and a monitor for displaying the instructions from the controller. A microbubble counting cell and digital image sensor are combined with software-based image analysis to determine a number of microbubbles contained in a microbubble counting zone. A monitor enables operator specification of total volume of contrast agent to be injected into the patient. One or more first Doppler ultrasound transducer arrays are positioned adjacent to targeted intracranial arteries at one side of the skull or a pair of first Doppler ultrasound transducer arrays positioned adjacent to targeted intracranial arteries at both sides of the skull. A second Doppler ultrasound transducer is positioned on the precordium of the patient to detect the arrival of microbubble-containing contrast agent in the right atrium of the patient.

A probe cable support (146) includes a leg (202) with a top side (208) and a bottom side (210). The leg further includes a plurality of supports (216.sub.1, 216.sub.2, . . . , 216.sub.N) protruding from the bottom side and intermittently arranged with non-zero gaps there between. The leg further includes an arm (226) protruding from the top side. A system (101) includes an ultrasound imaging system (100) configured with at least one probe (102) and a console (104), a cable (116) configured to electrically connect the probe and the console, a cart (106) configured to support the ultrasound imaging system, and a probe cable support (146) configured to support the cable.

A method and apparatus of generating a sequence of pulses by a transmit signal generator. The transmit signal generator has a multiplexer that is connected to a binary counter and one of the output lines of the binary counter provides the sequence of pulses.

According to one embodiment, an ultrasound diagnostic apparatus can be connected with an ultrasound probe including a plurality of elements adapted to transmit ultrasound signals and to receive reflected wave signals from a subject or from the air. The ultrasound diagnostic apparatus includes processing circuitry. The processing circuitry diagnoses states of the elements based on a feature value of the reflected wave signal. The processing circuitry also prepares, based on the states, deterioration degree information indicative of the deterioration degrees of the elements. The processing circuitry superimposes the deterioration degree information onto an ultrasound image of the subject and causes a display to display a resultant image.

The present disclosure relates to an apparatus for controlling movement of an ultrasonic wave generating unit, the apparatus characterized by comprising: a transfer unit for moving the ultrasonic wave generating unit; and a control unit for controlling the operation of the ultrasonic wave generating unit and the transfer unit, wherein the control unit controls the ultrasonic wave generating unit such that, when the ultrasonic wave generating unit moves, ultrasonic waves are irradiated at intervals to the skin on a movement path of the ultrasonic wave generating unit.