An position sensor such as an IMU is removably positioned on a patient bed used to support a patient during a robotic surgical procedure in which a robotic manipulator is used to manipulate a surgical instrument. When the bed is moved during the course of surgery, signals corresponding to a sensed changed in the bed's position are received by a processor, which causes a corresponding repositioning of the robotic manipulator.

A multi-stage dilator and cannula assembly for use in surgical procedures, including minimally invasive surgical procedures, to provide tissue dilation and opening of a portal to enable the surgeon to access and provide treatment to anatomical feature of interest.

A surgical system for assisting a user in performing a surgical procedure at a surgical site, comprising a tool having a checkpoint, a pointer having a tip, and a localizer to determine a position of the pointer within a field of view. A memory comprises identification data associated with a plurality of tools. A controller is configured to prompt the user to position the tip of at the checkpoint, to receive position data from the localizer associated with the pointer within the field of view, to compare position data associated with the pointer against the identification data of the memory to determine an identity of the tool, and to present the user with the identity of the tool.

A dual mode augmented reality surgical system configured to operate in both a tracking and a non-tracking mode includes a head mounted display configured to provide an optical view of a patient and to inject received data content over top of the optical view to form an augmented reality view of the patient, and comprising internal tracking means configured to determine a surgeon's position as well as angle and direction of view relative to the patient. The system further includes an augmented reality computing system comprising one or more processors, one or more computer-readable tangible storage devices, and program instructions stored on at least one of the one or more storage devices for execution by at least one of the one or more processors.

A surgical robot includes a controller configured or programmed to control a display to superimpose guide information indicating a moving direction of a medical cart based on a steering angle of a steering device on an image captured by an imaging device and display the guide information.

A tracker 30 for a Head-Mounted Display, HMD, unit is provided. The tracker 30 comprises a carrier element 10 carrying one or more markers 16a, 16b that are configured to permit determining a position of the tracker 30. The carrier element 10 comprises at least one magnetic element 32 configured to cooperate with at least one magnetic element 22 provided on the HMD unit 62, or on a base element 20 that is to be fixed to the HMD unit 62, for detachably attaching the carrier element 10 to the HMD unit 62.

The invention relates to a medical system for use in interventional radiology, adapted to be coupled to a navigation system, comprising: a needle (1) to be inserted into a patient's body toward a target, said needle comprising a distal tip (10) and a proximal stop (110); a needle guide (2), the needle (1) being able to slide within said guide (2) along a longitudinal axis thereof, said needle guide (2) comprising a tracker for navigating the needle guide (2) with respect to a 3D medical image of a patient; a processor configured to detect a contact between the needle guide (2) and the proximal stop (110) and to determine, from navigation data of the needle guide when said needle guide (2) is in contact with the proximal stop (110) of the needle and from the length of said needle, a position of the distal needle tip (10) with respect to the 3D medical image; and a user interface coupled to said processor and configured to display, on at least one image (I) of the patient, a representation of the needle and a point on said representation of the needle to represent the needle tip (10) in said determined position.

A passive end effector of a surgical system includes a base connected to a rotational disk, and a saw attachment connected to the rotational disk. The base is attached to an end effector coupler of a robot arm positioned by a surgical robot, and includes a base arm extending away from the end effector coupler. The rotational disk is rotatably connected to the base arm and rotates about a first location on the rotational disk relative to the base arm. The saw attachment is rotatably connected to the rotational disk and rotates about a second location on the rotational disk. The first location on the rotational disk is spaced apart from the second location on the rotational disk. The saw attachment is configured to connect to a surgical saw including a saw blade configured to oscillate for cutting. The saw attachment rotates about the rotational disk and the rotational disk rotates about the base arm to constrain cutting of the saw blade to a range of movement along arcuate paths within a cutting plane.

A surgical navigation system for providing computer-aided surgery. The surgical navigation system includes a handheld surgical tool with computer-aided navigation, a graphical user interface module, and optionally an imaging device. The handheld surgical tool includes a handle that may comprise at least one sensor for detecting orientation of the. A computing device and at least one display device are associated with the handheld surgical tool and configured to display a target trajectory of the handheld surgical tool for the surgical procedure.

Techniques and technologies for guiding medical instruments during medical procedures using real-time imaging technologies are disclosed. A representative apparatus includes a medical instrument, an imaging system, a stage assembly, and a control system. The medical instrument includes an elongated portion configured to be inserted into a body portion and having an optical fiber that includes a tip portion that is extendable beyond a distal end of the elongated portion. The imaging system provides a sampling energy that is emitted from the tip portion. The stage assembly actuates the tip portion to perform scanning of one or more tissues with the sampling energy. The imaging system receives a reflected energy, providing a plurality of one-dimensional arrays of intensity values of the reflected energy. The control system analyzes the plurality of one-dimensional arrays of intensity values to determine a shape and a location of the target tissue, and displays information for guiding the medical instrument into engagement with the target tissue.