Devices, Systems, and Methods for detecting a 3-dimensional position of an object, and surgical automation involving the same. The surgical robot system may include a robot having a robot base, a robot arm coupled to the robot base, and an end-effector coupled to the robot arm. The end-effector, surgical instruments, the patient, and/or other objects to be tracked include active and/or passive tracking markers. Cameras, such as stereophotogrammetric infrared cameras, are able to detect the tracking markers, and the robot determines a 3-dimensional position of the object from the tracking markers.

An automated positioning device and associated method for use in a medical procedure is provided. The automated positioning device comprises a computing device having a processor coupled to a memory, a multi-joint positioning arm electrically coupled to the computing device and controlled by the computing device, and a sensor module attached to the multi-joint positioning arm and providing a proximity signal to the computing device indicating proximity of a target. The computing device provides a control signal to the multi-joint positioning arm to move the multi-joint positioning arm in response to the proximity signal.

A method for guiding resection of local tissue from a patient includes generating at least one image of the patient, automatically determining a plurality of surgical guidance cues indicating three-dimensional spatial properties associated with the local tissue, and generating a visualization of the surgical guidance cues relative to the surface. A system for generating surgical guidance cues for resection of a local tissue from a patient includes a location module for processing at least one image of the patient to determine three-dimensional spatial properties of the local tissue, and a surgical cue generator for generating the surgical guidance cues based upon the three-dimensional spatial properties. A patient-specific locator form for guiding resection of local tissue from a patient includes a locator form surface matching surface of the patient, and a plurality of features indicating a plurality of surgical guidance cues, respectively.

A stereotactic surgery robot according to the present disclosure may include: a rotating unit that is configured to have a surgical instrument that is able to be attached thereto, and is configured to rotate the surgical instrument on at least one of two rotational axes according to an entry posture of the surgical instrument; a moving unit that is configured to move the rotating unit in the direction of at least one of three linear axes according to the position of a surgical target; and a surgical portion support unit that is configured to be connected to the moving unit, and is configured to be detachable with respect to an operating table, wherein the moving unit may move the rotating unit such that an intersection point of the two rotational axes matches the surgical target.

A cannula system and method for accessing a blood mass in the brain. The system comprises a cannula with a camera mounted on the proximal end of the cannula with a view into the cannula lumen and the surgical field below the lumen. A prism, reflector or other suitable optical element is oriented between the camera and the lumen of the cannula to afford the camera a view into the cannula while minimizing obstruction of the lumen. The system may also include an obturator with a small diameter shaft and a large diameter tip which is optically transmissive, so that a surgeon inserting or manipulating the assembly can easily see that the obturator tip is near brain tissue (which is white) or blood (which is red).

Dynamic reference arrays use markers and trackers to register a patient's anatomy to computer system. Wherein the dynamic reference array may be screwed into a patient's spinous process, clamped on to a spinous process, or attached to the spinous process using posts. In embodiments, a dynamic reference array may comprise a single structure comprising and attachment member and a scaffold. In alternate embodiments, the dynamic reference array may comprise distinct structures that allow the dynamic reference array to swivel and collapse in order to facilitate registration, while not interfering with a surgical procedure.

A 3D navigation system and methods for enhancing feedback during a medical procedure, involving: an optical imaging system having an optical assembly comprising movable zoom optics and movable focus optics, a zoom actuator for positioning the zoom optics, a focus actuator for positioning the focus optics, a controller for controlling the zoom actuator and the focus actuator in response to received control input, at least one detector for capturing an image of at least one of a target and an obstacle, the at least one detector operable with the optical assembly, and a proprioception feature operable with the optical imaging system for generating a 3D perception, the proprioception feature comprising a communication feature for providing 3D information, the 3D information comprising real-time depth information in relation to real-time planar information within an interrogation volume.

A system for imaging a knee joint of a patient and/or co-registering 2D images of a knee joint of a patient is provided. The system comprises a plurality of rigid bands and one or more temporary tattoos. The plurality of rigid bands comprises at least a first rigid band and a second rigid band. Each rigid band comprises a base configured to be affixed to the skin of the patient and a plurality of metal fiducial markers disposed along the base in a planar arrangement. The metal fiducial markers of the first rigid band are configured to be arranged on the skin in a horizontal plane and the metal fiducial markers of the second rigid band are configured to be arranged on the skin in a vertical plane. Each temporary tattoo comprises a flexible substrate and a radiopaque material printed on the flexible substrate in a grid pattern. The temporary tattoo is configured to contact the skin to affix the grid pattern to the skin.

Exemplary methods, apparatus, and systems are disclosed for automated registration and motion compensation of patient-mounted needle guide medical devices using fiducial markers, and processing algorithms where a re-registration step is provided. These methods, apparati, and systems adaptively compensate for the displacement of the medical device and/or target location due to the patient movement or internal organ motion.

An in-vivo dental surgical guide verification method including: receiving first information including: dental surgical guide information of a dental surgical guide, and hard structure information of a hard structure of a patient's mouth; positioning the surgical guide within the patient's mouth; contacting a stylus to a surface of the hard structure of the patient mouth; acquiring image information corresponding to an image which includes at least a portion of the stylus and a portion of the dental surgical guide therein using an imager; and comparing the image information with the first information.