An ultrasound imaging probe (204) includes a transducer array (210). The transducer array includes one or more transducer elements (212). The ultrasound imaging probe further includes an illumination component (218) and an optical imaging component (220). The ultrasound imaging probe further includes an elongated housing (302) with a long axis (304). The elongated housing includes a proximal end region (306) affixed to a handle (308) and a distal end region (310) with a tip region (312). The elongated housing houses the transducer array, the illumination component, and the optical imaging component in the distal end region.

The present disclosure relates generally to positioning elongate members at a target site within a body lumen, such as for acquiring a biopsy from a peripheral airway. Some embodiments are particularly directed to an elongate member with an embedded transducer positioned at a predefined rotational angle with respect to a projected position of an instrument extended out of a distal opening of a first lumen in the elongate member. In many such embodiments, a rotational transducer may be positioned within a second lumen in the elongate member to generate a radial image including indicia of the embedded transducer. Accordingly, an operator may determine a projected position of the instrument prior to extending the instrument out of the lumen. In several embodiments, the embedded transducer may include a forward imaging transducer, such as a fiber optic.

An ultrasound image system is provided. The ultrasound image system includes an ultrasound probe and a processing circuit. The ultrasound probe includes a substrate, a first transducer array and a second transducer array. The first transducer array is fixed disposed on the substrate and configured to receive a first ultrasound signal The second transducer array is fixed disposed on the substrate and configured to receive a second ultrasound signal. Each of the first transducer array and the second transducer array includes a plurality of ultrasound transducer elements arranged along a first direction. The ultrasound transducer elements of the first transducer array are interleaved with the ultrasound transducer elements of the second transducer array. The processing circuit is coupled to the first transducer array and the second transducer array and is configured to generate an ultrasound image signal according to the first ultrasound signal and the second ultrasound signal.

A diagnostic imaging catheter is disclosed, which is capable of preventing a solution from an internal space of a hub from flowing into a portion communicating with the internal space of the hub and to which the signal lines such as the optical fiber and the electric signal cable are electrically or optically connected. The optical diagnostic catheter includes a rotatable drive shaft, an elongated sheath configured to be inserted into a biological lumen, a hub that includes a port connected to the sheath for supplying the solution, a connector portion that includes an optical connector accommodated in an internal space of the hub and optically connected to an external optical connector, a first seal portion that prevents the solution from the port from flowing into a first connection portion, and a second seal portion that prevents the solution from the port from flowing into a second connection portion.

Ultrasound imaging systems and methods for generated clutter-reduced images are provided. For example, an ultrasound imaging system can include an array of acoustic elements in communication with a processor. The processor is configured to activate the array to perform a scan sequence to obtain a plurality of signals, identify off-axis signals from the plurality of signals by comparing the right subaperture and the left subaperture, and create a clutter-reduced image based on the comparison. Because off-axis signals are more likely to create image clutter, reducing the influence of off-axis signals on the image can therefore improve the quality of the image. Accordingly, embodiments of the present disclosure provide systems, methods, and devices for generating ultrasound images that have reduced or minimized clutter, even for images obtained using arrays that do not satisfy the Nyquist criterion.

An ultrasound probe and method for using the same are described. In one embodiment, the ultrasound probe comprises: a probe array assembly having a probe tip; a first enclosure disposed around a portion of the probe array assembly, where the first enclosure has first and second openings and comprises a thermally conductive material; and one or more thermally conductive fins contained within the first enclosure, each of the one or more thermally conductive fins having one end enclosed within the probe array assembly and a portion extending away from the probe array assembly and in thermal contact with an inner surface of the first enclosure to create a thermal path from the first opening to the second opening in the first enclosure.

A system and method for acquiring standard ultrasound scan plane views is provided. The method includes acquiring a scan plane by an ultrasound probe positioned at a scan position over a region of interest. The method includes identifying the scan plane as a first standard view. The method includes automatically adjusting a scan acquisition angle until a second standard view is determined. The adjusting the scan acquisition angle includes rotating and/or tilting the scan acquisition angle. The method includes acquiring, by the ultrasound probe positioned at the scan position, an additional scan plane at the adjusted scan acquisition angle until the second standard view is determined. The method includes automatically determining whether the additional scan plane is the second standard view. The method includes presenting the additional scan plane having the second standard view at a display system.

Various approaches for delivering ultrasound energy to a target region during a therapeutic or diagnostic procedure includes implementing an adjustment mechanism having a machine-learning model that has been trained, based on input vectors corresponding to a difference and/or a ratio of parameter values between multiple transducer elements, to generate, for each of the transducer elements, one or more parameter value to compensate for expected beam aberration resulting for an intervening tissue; and activating the transducer elements in accordance with the corresponding parameter values so as to generate an optimized focal zone at the target region during the therapeutic or diagnostic procedure.

A rotational intravascular ultrasound probe for insertion into a vasculature and a method of manufacturing the same. The rotational intravascular ultrasound probe comprises an elongate catheter having a flexible body and an elongate transducer shaft disposed within the flexible body. The transducer shaft comprises a proximal end portion, a distal end portion, a drive shaft extending from the proximal end portion to the distal end portion, an ultrasonic transducer disposed near the distal end portion for obtaining a circumferential image through rotation, and a transducer housing molded to the drive shaft and the ultrasonic transducer.

A system comprising a stent and a stent delivery device configured with a tiny intravascular ultrasound (“IVUS”) transducer on the tip of a delivery catheter which can image the interior of blood vessels. Methods for treating ostial or bifurcated lesions using the system.