A robotic surgery system includes: (1) a positioning stage and (2) at least one manipulator arm mounted to the positioning stage, wherein the manipulator arm includes a track and a tool carriage moveably mounted to the track, and the tool carriage includes a base and a pair of light emitting devices mounted to the base.

A method for visualizing and targeting anatomical structures inside a patient utilizing a handheld screen device may include grasping the handheld screen device and manipulating a position of the handheld screen device relative to the patient. The handheld screen device may include a camera and a display. The method may also include orienting the camera on the handheld screen device relative to an anatomical feature of the patient by manipulating the position of the handheld screen device relative to the patient, capturing first image data of light reflecting from a surface of the anatomical feature with the camera on the handheld screen device, and comparing the first image data with a pre-operative 3-D image of the patient to determine a location of an anatomical structure located inside the patient and positioned relative to the anatomical feature of the patient.

A method for visualizing and targeting anatomical structures inside a patient utilizing a handheld screen device may include grasping the handheld screen device and manipulating a position of the handheld screen device relative to the patient. The handheld screen device may include a camera and a display. The method may also include orienting the camera on the handheld screen device relative to an anatomical feature of the patient by manipulating the position of the handheld screen device relative to the patient, capturing first image data of light reflecting from a surface of the anatomical feature with the camera on the handheld screen device, and comparing the first image data with a pre-operative 3-D image of the patient to determine a location of an anatomical structure located inside the patient and positioned relative to the anatomical feature of the patient.

The invention relates to a method for displaying an injection point for a medical instrument. The method comprises the following steps: Providing at least one marker on a surface of an object, with such marker exhibiting the property that it can be recorded both tomographically, in particular fluoroscopically, and also optically; Generating tomographic image data that can be used to reconstruct a fluoroscopic image of the at least one marker, located on the surface of the object, together with the object; Determining the insertion point for the medical instrument on the surface of the object relative to the at least one marker in the coordinate system of the tomographic image data; Generating visual image data that can be used to reconstruct a visual image of the at least one marker, located on the surface of the object, together with the object; Transforming the coordinate of the insertion point in the coordinate system of the tomographic image data into the coordinate system of the visual image data using the relative position of the insertion point to the at least one marker; and Displaying the insertion point for the medical instrument in real time in a view of the object.

Provided is a laser projection apparatus, a control method thereof, and a laser guidance system including the laser projection apparatus. The laser projection apparatus for projecting planned operation information of an insertion location and an insertion angle on a C-arm image photographed using a C-arm fluoroscopy device directly onto an affected part includes a line laser module configured to generate a line laser and to form a plane by rotating around an origin, a matching unit configured to calculate a coordinate representing the insertion location in a C-arm coordinate system based on C-arm fluoroscopy, calculate an insertional vector according to the coordinate representing the insertion location and the insertion angle, and calculate a vector perpendicular to the plane formed by the line laser in the C-arm coordinate system according to the insertional vector, and a control unit configured to control the line laser module based on the vector perpendicular to the plane.

Provided is a laser surgical guidance system including a C-arm fluoroscopy (hereinafter, C-arm) to identify a patient's condition and support a surgical plan and a laser targeting projector to project a line of the surgical plan directly onto an affected part through a line projection module which generates a laser. The laser surgical guidance system may generate a particular laser pattern from the line projection module, transmit the particular laser pattern outputted from the line projection module through a calibration tool including a collimator having a particular orientation, calculate an extrinsic parameter of the calibration tool in a projection image having passed through the calibration tool, and convert coordinates of the C-arm image into the line projection module coordinates using the extrinsic parameter.

Even when an insertion object is inserted to a deep position of a subject or even when the insertion object is inserted into the subject at an angle close to a right angle, it is possible to confirm the position of the insertion object in a photoacoustic image. The insertion object is, for example, a hollow puncture needle 15 that includes an opening at a tip thereof. The puncture needle 15 includes a light guide member 152 that guides light emitted from a first light source to the vicinity of the opening, and a light emitting portion 153 that is provided in the vicinity of the opening and emits the light. First photoacoustic waves, which are caused by the light emitted from the light emitting portion 153, are generated in the puncture needle 15. A first photoacoustic image is generated on the basis of the first photoacoustic waves.

Even when an insertion object is inserted to a deep position of a subject or even when the insertion object is inserted into the subject at an angle close to a right angle, it is possible to confirm the position of the insertion object in a photoacoustic image. The insertion object is, for example, a hollow puncture needle 15 that includes an opening at a tip thereof. The puncture needle 15 includes a light guide member 152 that guides light emitted from a first light source to the vicinity of the opening, and a light emitting portion 153 that is provided in the vicinity of the opening and emits the light. First photoacoustic waves, which are caused by the light emitted from the light emitting portion 153, are generated in the puncture needle 15. A first photoacoustic image is generated on the basis of the first photoacoustic waves.

A method of spectrometric analysis comprises obtaining one or more sample spectra for an aerosol, smoke or vapour sample. The one or more sample spectra are subjected to pre-processing and then multivariate and/or library based analysis so as to classify the aerosol, smoke or vapour sample. The results of the analysis are used for various surgical or non-surgical applications.

A method of spectrometric analysis comprises obtaining one or more sample spectra for an aerosol, smoke or vapour sample. The one or more sample spectra are subjected to pre-processing and then multivariate and/or library based analysis so as to classify the aerosol, smoke or vapour sample. The results of the analysis are used for various surgical or non-surgical applications.