A medical puncture needle includes: a metal needle body formed in a tubular shape, the needle body including: a blade surface located at a distal end portion of the needle body, a planar reflection portion located at an inner surface of the needle body and configured to reflect light, and a transmission window located proximal of the blade surface and configured to transmit reflected light reflected by the planar reflection portion.

An ultrasonic probe of an embodiment includes a head part. The head part includes a plurality of ultrasonic elements that output ultrasonic waves and receive reflected waves of the output ultrasonic waves. The head part is provided with a through hole for guiding a puncture needle and a slit for guiding the puncture needle to the through hole.

A device and system for and methods of using an ultrasound probe housing containing ultrasound probes configured to produce images inside the body of a patient for procedures requiring needle or probe insertion. The ultrasound probe housing can be configured with a guide channel cut-out or aperture between the ambient side and body side of a patient. A needle guide assembly may be pivotally connect internal to the guide channel cut-out or aperture of the ultrasound probe housing at a pivot point such that during use the needle enters the patient through the needle guide assembly within the ultrasonic probe housing so that the needle can be visualized by the ultrasonic probes in real time. The ultrasound probe housing may also provide an adhesion or suction quality to the body side of the device to facilitate aspects of the invention.

Surgical robot systems, anatomical structure tracker apparatuses, and US transducer apparatuses are disclosed. A surgical robot system includes a robot, a US transducer, and at least one processor. The robot includes a robot base, a robot arm coupled to the robot base, and an end-effector coupled to the robot arm. The end-effector is configured to guide movement of a surgical instrument. The US transducer is coupled to the end-effector and operative to output US imaging data of anatomical structure proximately located to the end-effector. The least one processor is operative to obtain an image volume for the patient and to track pose of the end-effector relative to anatomical structure captured in the image volume based on the US imaging data.

Disclosed herein are devices (e.g., needles (e.g., hollow needles), hollow staples, articles, apparatuses, and systems), kits, and methods for treating skin and skin conditions, for example, by promoting skin tightening, such as by reducing skin laxity and reducing tissue area or volume.

An introducer guide includes a guiding assembly to guide insertion an instrument, such as a biopsy needle, through a selected insertion point on a patient's body and along a selected insertion path. An imaging system, such as a CT scanner, is used to visualize portions of the guiding assembly in relation to the patient's tissues as the insertion path is adjusted. The guiding assembly includes a semicircular arch connected with a base plate by sliding hinges with a center of curvature of the arch centered on the insertion point. A guide body is slidably connected with the arch. Rotation of the arch about the hinges adjusts a first angle of the insertion path. Motion of the guide body along the arch adjusts a second angle of the insertion path. Linkages, such as linear actuation cables, rotary cables, or pneumatic or hydraulic actuators, connect the arch and guide body with remote operators. A practitioner aligns the guide assembly with the insertion point and fixes the base to the patient's skin. The practitioner uses the remote operators to adjust the orientation of the insertion path while visualizing the insertion path using the imaging system. The length of the cables is selected to allow the practitioner to adjust the guiding assembly at a safe distance from ionizing radiation emitted by the imaging system.

A method for performing a surgical procedure includes generating, by a computing device, an anatomical map of a patient from a plurality of images; positioning a trocar obturator adjacent to the patient; calculating, by the computing device, a projected path of the trocar obturator; overlaying, by the computing device, the projected path of the trocar obturator with the anatomical map of the patient; and displaying the projected path of the trocar obturator and the anatomical map of the patient on a display device to define an augmented image.

A surgical system for use in establishing and maintaining an opening to an anatomical space of a body, the system comprising an obturator assembly having a cutting portion at a distal end and a cannula, the cannula being detachably coupled to the cutting portion and deployable into the anatomical space of a patient, the cannula comprises a locking portion, and a lengthwise extendable body; a valve assembly comprising a passage for receiving the cannula, a first end for coupling to a fluid extraction device and a second end for placement external and adjacent the anatomical space; a base comprising a plate for placement on a patient external and adjacent the anatomical space, the plate has an aperture configured for receiving the obturator assembly and coupling means located about the aperture for coupling with the valve assembly; and wherein, in use, the locking portion of the cannula is configured to be retained in the valve assembly with the extendable body extended into the anatomical space to facilitate a path for fluid extraction, and wherein the cannula comprises means for retaining the cannula in its extended state.

In some embodiments, an apparatus and methods for inserting a needle into a patient is disclosed. An apparatus can include a base having a cavity for receiving an ultrasound probe, a swing arm, a first linear position sensing track, a second linear position sensing track, an angle sensor disposed about a pivot point, a needle holder configured to move along the first linear position sensing track, and an insertion depth slider configured to move along the second linear position sensing track.

An apparatus for determining alignment between a source device and a target device includes the source device, the target device, and a processing system. The source device includes a first spatially variant field generator for generating a first spatially variant electric field, and a second spatially variant field generator for generating a second spatially variant electric field. The second spatially variant electric field is angularly offset with respect to the first spatially variant electric field. The target device includes a sensor configured to detect a first signal from the first spatially variant electric field and a second signal from the second spatially variant electric field. The processing system is configured to determine alignment between the first source device and the target device based on the first and second signals from the first and second spatially variant electric fields by the target device.