Programmable ultrasound probes and methods of operation are described. The ultrasound probe may include memory storing parameter data and may also include a parameter loader which loads the parameter data into programmable circuitry of the ultrasound probe. In some instances, the ultrasound probe may include circuitry grouped into modules which may be repeatable and which may be coupled together to allow data to be exchanged between the modules.

Provided is an ultrasonic wave generating device including: a housing to seal an inside of a cartridge; a transducer disposed in the housing and to generate ultrasonic waves; a rotational force applying unit to receive a rotational force from an outside of the housing and perform a rotational motion; a conversion unit to convert the rotational motion of the rotational force applying unit into a rectilinear motion and provide the rectilinear motion to the transducer; and a controller to control an ultrasonic wave generating operation of the transducer.

In one embodiment, an ultrasonic diagnostic apparatus includes: a main body configured to generate an ultrasonic image; a body housing configured to house the main body; a display/operation panel configured to operate the main body and display the ultrasonic image; and a lifter on which the display/operation panel is placed, the lifter being attached to the body housing and configured to adjust height of the display/operation panel from a floor in each of an electric mode and a manual mode.

Intravascular systems can include a catheter having a proximal end, a distal end, a sensor located at the distal end configured to provide sensor information representative of one or more intravascular properties of a patient, and a plurality of magnetic domains A magnetic pickup can be configured to output a pickup signal based on the magnetic field at the magnetic pickup produced by the plurality of magnetic domains. An intravascular processing engine can be in communication with the catheter sensor and the magnetic pickup. The intravascular processing engine can receive sensor information from the sensor and a position signal representative of the pickup signal. The intravascular processing engine can be used to determine position information related to the position of the catheter sensor and combine the received sensor information and corresponding determined position information.

Systems can include at least one friction wheel configured to engage a catheter of an intravascular system such that proximal or distal motion of the catheter causes the friction wheel to rotate. A position sensor can include a reference element and a movable element, wherein the movable element is configured to move relative to the reference element in response to rotation of the at least one friction wheel. The position sensor can provide a position signal representative of the rotation of the at least one friction wheel. An intravascular processing engine can receive both the position signal from the position sensor and an intravascular signal from the catheter.

The present disclosure describes systems, apparatus, and methods for collecting biometric data from a patient. In some cases, this biometric data can be collected during the course of an emergency encounter using a medical device. The medical device can also perform other functions, such as monitor patient vital signs, receive and record notes and textual information, communicate with other devices, and/or deliver a therapeutic treatment. The medical device can also be configured to record and/or maintain a patient record, and to embed the patient biometric data into the patient record for use in later confirming and/or determining an identity of the patient. Some embodiments can also collect biometric data relating to one or more caregivers of the patient, and to embed the caregiver biometric data into the patient record. This caregiver biometric data can be used to confirm and/or identify one or more caregivers in a patient record.

A method of changing a user interface (UI), which is used for diagnosis of a target object via a medical device, based on user motion information. The method including obtaining motion information regarding a user; changing the UI based on the obtained motion information regarding the user; and displaying the changed UI.

Delivery systems, and methods using the same, having an ultrasound viewing window for improved imaging and a needle for ablation treatment of target tissues. In an embodiment, the target tissue is a fibroid within a female's uterus. In an embodiment, the delivery system includes a rigid shaft having a proximal end, a distal end, and an axial passage extending through the rigid shaft. In an embodiment, the axial passage is configured for removably receiving the ultrasound imaging insert having an ultrasound array disposed a distal portion.

Delivery systems, and methods using the same, having an ultrasound viewing window for improved imaging and a needle for ablation treatment of target tissues. In an embodiment, the target tissue is a fibroid within a female's uterus. In an embodiment, the delivery system includes a rigid shaft having a proximal end, a distal end, and an axial passage extending through the rigid shaft. In an embodiment, the axial passage is configured for removably receiving the ultrasound imaging insert having an ultrasound array disposed a distal portion.

A shared resource medical system for monitoring a patient during emergency situations includes a portable defibrillator and an ultrasound transducer physically and communicatively coupled to the defibrillator. The defibrillator includes sensors, a display screen, a power supply, a data storage device, and a defibrillator processor operatively coupled to the screen, the power supply, and the storage device and configured to receive and process user input, receive patient physiological data from the sensors, and generate an interface on the display screen. The ultrasound transducer is configured to obtain ultrasound physiological data of the patient and send the ultrasound physiological data to the defibrillator processor. The defibrillator processor receives and processes the ultrasound physiological data from the ultrasound transducer to generate an ultrasound image for the patient, stores the patient physiological data from the sensors together with the ultrasound image in the storage device, and presents the image on the user interface.