An ultrasound probe (104) includes a probe head (134). The probe head includes a transducer array (136) with a transducing surface (137), an instrument guide (142), and a light source (140). A method includes emitting a light beam, from a light source disposed on and adjacent to a transducer array of an ultrasound imaging probe, in a direction opposite of a transducing surface of the transducer array, at an inside wall of a cavity of a subject or object. A laparoscopic ultrasound imaging probe includes a shaft, a body, an articulating member that couples the probe head, and a handle coupled to the elongate shaft. The articulating probe head includes a transducer array that generates an ultrasound signal that traverses an image plane of the transducer array, an instrument guide, and a light source arranged to emit light in a direction opposite of the image plane.

A surgical instrument navigation system and method of use is provided that visually simulates a virtual volumetric scene of a body cavity of a patient from a point of view of a surgical instrument residing in the cavity of the patient, wherein the surgical instrument, as provided, may be a steerable surgical catheter with a biopsy device and/or a surgical catheter with a side-exiting medical instrument, among others. Additionally, systems, methods and devices are provided for forming a respiratory-gated point cloud of a patient's respiratory system and for placing a localization element in an organ of a patient.

A system for preparing an ablation procedure is disclosed. The system comprises a generator for generating electrical pulses, a plurality of probes for delivering the electrical pulses to a target tissue, one or more sensors for indicating a position of the probes, a display device, and a processor. The processor is configured to receive an image of the target tissue, obtain a planned probe arrangement for the plurality of probes, identify a projected position for an origin probe based on the image and the planned probe arrangement, and determine a real-time position of the origin probe based on signals from the sensors. The processor is further configured to display the projected position and the real-time position for the origin probe superimposed over the image on a display device, and determine a placed position of the origin probe based on the real-time position.

In an example, a system includes an ultrasound sensor configured to transmit ultrasound energy and receive ultrasound energy reflected in a region of a patient and one or more processors configured to generate a reference ultrasound image of the region of the patient based on a portion of the ultrasound energy that was received by the ultrasound sensor prior to a medical instrument or medical device causing obstruction in the received ultrasound energy, generate a live ultrasound image based on a current portion of the received ultrasound energy obtained by the ultrasound sensor, register the reference ultrasound image and the live ultrasound image, and control a display device to display the reference ultrasound image with at least a portion of the live ultrasound image.

A system and method for guidance of a device having a curved needle to a target tissue includes a tracking system having an imaging component, a processor, and a curved needle with known geometric parameters. The processor is configured to calculate a needle trajectory based on geometric considerations of the needle and the target tissue. Additional features and methods of the invention include a display with an annotated overlay for directing and tracking the curved device.

Provided in accordance with the present disclosure are systems and methods for identifying a percutaneous tool in image data. An exemplary method includes receiving image data of at least a portion of a patient's body, identifying an entry point of a percutaneous tool through the patient's skin in the image data, analyzing a portion of the image data including the entry point of the percutaneous tool through that patient's skin to identify a portion of the percutaneous tool inserted through the patient's skin, determining a trajectory of the percutaneous tool based on the identified portion of the percutaneous tool inserted through the patient's skin, identifying a remaining portion of the percutaneous tool in the image data based on the identified entry point and the determined trajectory of the percutaneous tool, and displaying the identified portions of the percutaneous tool on the image data.

A medical apparatus including an ultrasonic information acquisition unit that acquires ultrasonic information of inside of a living body obtained from an ultrasonic probe that has an ultrasonic sensor and emits ultrasonic waves inside the living body, a device magnetic field information acquisition unit that acquires device magnetic field information relating to a magnetic field generated from a medical device inserted in a blood vessel inside the living body, an echo image generation unit that generates an ultrasonic echo image of the blood vessel from the ultrasonic information, and a device position image generation unit that generates a device position image indicating the position of the medical device inside the blood vessel, based on the ultrasonic echo image and the device magnetic field information.

A system and method are presented for treating targeted tissue using cryoablation. An introducer canula and a cryoprobe are inserted the targeted tissue. The cryoprobe is cooled and an ice ball is formed. The cryoprobe is removed while the ice ball is still frozen, and an ultrasound catheter is inserted. Ultrasound generated within the ice ball is used to determine the distance from the ultrasound catheter to a perimeter of the ice ball. This is repeated at different angles to model a slice of the ice ball. The ultrasound catheter is moved radially, and the process is repeated to create a model of at least a portion of the ice ball. The ice ball model can be displayed on a registered set of images representing the targeted tissue to ensure that the tissue lies within the treatment zone of the ice ball.

An ultrasonic imaging system includes an ultrasonic probe and a processing unit. The ultrasonic probe is operable at multiple different tilt angles to perform ultrasonic measurement and to obtain a plurality 2D ultrasonic images corresponding respectively to the different tilt angles. The processing unit calculates a 3D ultrasonic images based on the 2D ultrasonic images and the corresponding tilt angles.

Apparatus and methods are described including an endoluminal device configured to move along a portion of a lumen of a subject's body, an extraluminal imaging device, and at least one computer processor. While the endoluminal device moves along the portion of the lumen, a display displays an extraluminal image of the lumen in which a first indication of a location of the lumen is shown. The extraluminal imaging device acquires a sequence of extraluminal images of the endoluminal device moving along the portion of the lumen. The indication of the location of the lumen that is displayed is updated based upon the acquired sequence of extraluminal images, and the acquired sequence of images is displayed with the updated indication of the location of the lumen overlaid upon the images. Other applications are also described.