An ergonomic ultrasound handle device can include a handle body. An ergonomic ultrasound handle device can include a clamp body connected to the handle for engaging an ultrasound transducer, the clamp body including a top end and a bottom end, with a clip disposed on the top end of the clamp body for maintaining the ultrasound transducer in engagement with the handle body. A method of ergonomically controlling an ultrasound transducer can provide the ergonomic ultrasound handle device. The method can include removably attaching the handle device to the handle of an ultrasound transducer. The method can include controlling the ultrasound transducer by applying pressure and motion to the handle, whereby the handle transmits the motion and pressure to the transducer.

The present invention provides a mobile imaging system for imaging of patients in medical interventions comprising a ring gantry with a plurality of independently rotating rings whereas a first rotating ring positions an X-ray source with collimator and a second rotating ring positions an image detector such that the region of interest (patient) can be positioned off-centered with respect to the ring center. The system supports planar X-ray imaging and Computed Tomography (CT) and Cone beam CT (CBCT) acquisitions of three dimensional (3D) volumes with variable X-ray field of views (FOVs) adapted to regions of interest (ROIs), which are not required to be of cylindrical shape. The mobile system can be equipped with stereoscopic cameras integrated in the gantry an on moving rings to support optical tracking and navigation of instruments within the same co-ordinate system of X-ray information. The gantry can be equipped with additional sensors and robotic manipulators on further rings operating in said co-ordinate system on mobile platform. The gantry provides a generic mechanical and electrical interface to a supporting structure, which can be attached to a variety of mobility platforms to support robotic positioning of the system in various orientations of scanner in treatment rooms to accommodate a wide range of patient setups, including the possibility for inclined and vertical scans of patients in upright position.

The present invention generally improves image guidance during interventional procedures by imaging and tracking an interventional device using two or more imaging elements with different field of views.

A surgical instrument includes a housing having an elongated body extending distally therefrom. The elongated body defines a first articulating portion and a second articulating portion. The elongated body defines a lumen therein. An end effector is supported at a distal end portion of the elongated body. A flexible waveguide extends through the lumen of the elongated body. A proximal end portion of the flexible waveguide connects to an ultrasonic transducer. A distal end portion of the flexible waveguide is connected with the end effector. the flexible waveguide defines a first articulating portion having a narrower thickness than a thickness of other portions of the flexible waveguide and a second articulating portion having a narrower thickness than a thickness of other portions of the flexible waveguide.

An intraluminal medical imaging interface device includes an arm assembly comprising one or more longitudinal members and one or more joints coupled to the one or more longitudinal members, and a head assembly coupled to a distal portion of the arm assembly and comprising a proximal portion coupled to the distal portion of the arm assembly and a distal portion. The distal portion of the head assembly includes a mechanical coupling and an electrical coupling configured to separably connect to an intraluminal imaging catheter and to transmit electrical signals between a console and the intraluminal imaging catheter. The arm assembly is configured to couple to a surface to maintain the head assembly at a first position and an orientation with respect to a patient without continued support by an operator. Associated devices, systems, and methods are also provided.

Systems and methods for introducing and driving flexible members in a patient's body are described herein. In one embodiment, a robotic method includes positioning a flexible elongated member that has a preformed configuration, wherein at least a part of the flexible elongated member has a first member disposed around it, and wherein the first member includes a first wire for bending the first member or for maintaining the first member in a bent configuration, releasing at least some tension in the first wire to relax the first member, and advancing the first member distally relative to the flexible elongated member while the first member is in a relaxed configuration.

A robotic surgical system comprising at least two robotic arms having co-ordinate systems known relative to each other, one of the arms carrying an X-ray source, and the other an imaging detector plate. The arms are disposed to enable an image to be generated on the region of interest of a subject. One of the arms can additionally or alternatively carry a surgical tool or tool holder, such that the pose of the tool is known in the same co-ordinate system as that of an image generated by the X-ray source and detector. Consequently, any surgical procedure planned on such an X-ray image can be executed by the tool with high accuracy, since the tool position is known in the image frame of reference. This enables the surgeon to accurately position his tool in a real-time image without the need for an external registration procedure.

A controller changes a position and/or orientation of a treatment head by controlling an operation of a robot arm according to an external input. A probe driver changes a projection amount of a diagnostic probe with respect to an irradiator. Further, the controller performs synchronous control to synchronize the probe driver and the robot arm with each other so that the relative position between the irradiator and the distal end of the diagnostic probe changes while holding the distal end position of the diagnostic probe.

A clamping apparatus for an ultrasonic detection device is disclosed. A remote control device for remotely controlling a first motor to control a rotational position of a base. The remote control device for remotely controlling a second motor to control a moving position of a movable base relative to a first arc-shaped rack. The remote control device for remotely controlling a third motor to control a moving position of a second arc-shaped rack relative to the movable base, so as to achieve the technical effect of providing an accurate three-dimensional detection angle to the ultrasonic detection device.

An imaging probe is covered with a stiff sheath, which allows the imaging probe to move while the stiff sheath remains in a substantially fixed location for at least a portion of the surgical procedure while the probe moves within the stiff sheath. The stiff sheath may comprise sufficient stiffness to resist deformation as the imaging probe moves along an internal channel of the sheath. The sheath can be sized and shaped in many ways and may comprise one or more openings to allow fluid to move within the channel in which the probe is located.