The present invention relates to a method, such as a surgical method for assisting a surgeon for placing screws in the spine using a robot attached to a passive structure. The present invention also related to a method, such as a surgical method for assisting a surgeon for removing volumes in the body of a patient using a robot attached to a passive structure and to a device to carry out said methods. The present invention further concerns a device suitable to carry out the methods according to the present invention.

Apparatus and methods are described for use with a tool that is inserted into a portion of a body of a subject that undergoes cyclic motion. The apparatus and methods include using an imaging device, acquiring a plurality of images of the tool inside the portion of the body, at respective phases of the cyclic motion. Using at least one computer processor, an extent of movement of the tool with respect to the portion of the body that is due to the cyclic motion of the portion of the body is determined. In response thereto, an output is generated that is indicative of the determined extent of the movement of the tool with respect to the portion of the body. Other applications are also described.

A system including an instrument adapted to be manually supported and moved by a user. The instrument having a hand-held portion, a working portion movably coupled to the hand-held portion, and a plurality of actuators operatively coupled to the working portion for moving the working portion in a plurality of degrees of freedom relative to the hand-held portion. The instrument having a tracking device attached to the hand-held portion. The system including a navigation system for determining a position of the working portion relative to a target volume, and a control system in communication with the actuators to control the actuators to move the working portion relative to the hand-held portion such that the working portion autonomously follows a path defined in the control system to remove material of the target volume while the user maintains the hand-held portion in a gross position relative to the target volume.

A method of deploying an interventional instrument comprises identifying a target structure within a patient anatomy in an anatomic frame of reference. The method further comprises determining a target region representing a location of the target structure in the the anatomic frame of reference with respect to a current location of the interventional instrument and recording a first engagement location of the interventional instrument within the target. Determining the target region includes determining a probabilistic distribution of the location of the target structure relative to the current location of the interventional instrument and associating each of the plurality of target points with a probability of engaging the target structure.

This disclosure provides a system (100) for determining patient (P) movement for a medical imaging system, comprising at least one marker (110), and at least one data processing unit (120), wherein the marker (110) is a solid configured to be swallowed by the patient (P). The marker (110) comprises a landmark forming component (111) configured to be detectable within the patient during a medical imaging procedure to determine the movement of the patient. The at least one data processing unit (120) is configured to obtain patient information data and/or medical imaging information data at least indicative for a type of medical imaging procedure intended for the patient. The at least one data processing unit (120) utilizes a computational model to estimate, based on one or more of the patient information data, the medical imaging information data and a configuration of the at least one marker, a position and/or distribution of the at least one marker inside the patient to a certain time and/or over a period of time after swallowing by the patient (P). The data processing unit (120) is configured to generate, based on the estimation of a distribution of the at least one marker, control data for timely controlling the medical imaging procedure.

Systems, methods, and devices are provided for assisting or performing guided interventional procedures using. The system uses pre-procedure scans of a patient's anatomy to identify targets and critical structures. A measurement device containing position indicating elements or fiducials is placed in a pre-existing or physician created conduit or lumen whose geometry is known from a scan. During a procedure, the pre-procedure scans may be registered to the patient using the position indicating elements or fiducials and the geometry of the conduit. This registration may be used in an intervention to guide instruments that can obtain diagnostic information or provide therapy to the identified targets. During the procedure, the position indicating elements may be used to dynamically compensate for motion to further improve accuracy.

A surgical system includes an arm extending from the base and having a distal end configured to be coupled to a tool, a first marker coupled in fixed relation to the base, and a tracking system. The tracking system is configured to collect first data indicative of a position of the first marker and collect second data indicative of a position an anatomical feature of a patient. The surgical system also includes a processor configured to calculate a position of the tool relative to the anatomical feature based on the first data and the second data.

Apparatus and methods are described for imaging a tool inside a portion of a subject's body that undergoes motion. A plurality of image frames are acquired of the portion of the subject's body. The image frames are image tracked by (a) automatically identifying at least a feature of the tool in at least a portion of the image frames, and (b) aligning the tool in image frames of the portion of the image frames, based on the automatic identifying. The image-tracked image frames of the portion of the subject's body are displayed as an image stream. Other embodiments are also described.

A system for dynamic registration of autonomy using augmented reality can include an augmented reality system, an imaging system, a measuring system, and a computer system. The augmented reality system can be configured to display an augmented representation. The imaging system can be configured to image an anatomical feature of the patient and can generate anatomical imaging data. The measuring system can be configured to measure an anatomical movement of the patient and can generate an anatomical movement data. The computer system can be configured to receive the anatomical imaging and positional data and the anatomical movement data, generate the augmented representation based on the anatomical imaging data, associate the augmented representation with the anatomical movement data, render the augmented representation on the augmented reality system, and selectively update the augmented representation based on the anatomical movement data.

Apparatus and methods are described for use with an imaging device (12) configured to acquire a set of angiographic images of a lumen. At least one processor (10) includes blood-velocity-determination functionality (16) that determines blood velocity within the lumen, via image processing. Current-flow-related-parameter-determination functionality (18) determines a value of a flow-related parameter at the location based upon the determined blood velocity. Flow-related-parameter-receiving functionality (19) receives an indication of a value of a second flow-related parameter of the subject, and index-determination functionality (21) determines a value of a luminal-flow-related index of the subject at the location, by determining a relationship between the value of the current flow-related parameter and the value of the second flow-related parameter. Other applications are also described.