Disclosed herein is a method of supporting implant surgery in a server, which includes obtaining a subject's oral CT image scanned with a guide model inserted into an oral cavity of the subject, the guide model being manufactured to a certain standard to group human teeth in any range so that the teeth belong to at least one group and to cover a tooth position of a corresponding group, the guide model including a marker made of a radiopaque or radiation semipermeable material, loading a library as information about the standard of the guide model, identifying the marker in the oral CT image, and generating a library matching CT image by matching the oral CT image with the library based on the marker included in the library and the marker identified in the oral CT image, and planning implant surgery of the subject using the library matching CT image.

A dental treatment system has a light irradiation device (2) and an image display (3). The light irradiation device has a polymerization light source (5a) for emitting blue light and a camera (6) for capturing a series of images. The system is set up for generating a first marker (11) and a second marker (20) superimposed with the images and to display the first marker (11) in a fixed positional relationship to an image pattern recognized in a first and in a second image of the series of images and to display the second marker (20) in a fixed positional relationship to an image area underlying the images.

Herein are described surgical screw guides comprising a radio-translucent portion and a radio-opaque portion. The guides are configured for attachment to tissue of a subject, such as gingiva and provide a method for imaging where to insert miniscrews.

Aspects herein are directed to an anchorable brachytherapy device configured to be permanently implanted in a tumor bed at the time of operative removal of the tumor. In example aspects, the brachytherapy device may comprise a plurality of hollow tubes that form a spherical or ellipsoid shape. Protrusions or grooves may be formed on an outer surface of the tubes to help anchor the brachytherapy device in the tumor bed. Radioactive seeds or strands may be positioned within the tube channels to provide radiation to the tumor bed.

Improved mapping and ablation procedures and corresponding devices are provided. A variety of methods and apparatuses can be used for the treatment of cardiac arrhythmias by identifying the location of an arrhythmia source and ablating that source. The methods and apparatuses can provide an improved means of electrical mapping of the heart to identify the location of the arrhythmia source and advancing an ablation electrode to that location so that it may be ablated.

A scannable dental spatial orientation device can comprise a coupling feature operable to couple with a bite plate for supporting a physical dental record material. The scannable dental spatial orientation device can also comprise a body portion having first, second, and third planar faces oriented orthogonal to one another. In addition, the scannable dental spatial orientation device can comprise at least one joint configured for rotating the bite plate and the body portion relative to one another to align the first, second, and third planar faces parallel to a sagittal midline reference plane, a horizontal plane, and a frontal plane of a patient. A dental record optical scan system and a method for digitally recording a maxillary arch position are also disclosed.

In some embodiments, the instant invention provides a device including: (a) at least one sleeve composed of a material configured to exhibit a sufficient flexibility to reduce tissue damage; (b) a locking mechanism configured to secure the at least one sleeve into a position complementary to a bronchial airway; (c) a plurality of locatable elements; and where the size of the at least one sleeve is sufficient to be introduced into the bronchial airway.

A surgical instrument for treating the tissue of a patient is disclosed. The surgical instrument comprises a housing including a handle, a housing frame comprising a housing connector, and a drive system comprising at least one electric motor. The surgical instrument further comprises a shaft assembly releasably assembled to the housing including a shaft frame comprising a proximal connector and a distal connector, wherein the proximal connector is releasably coupled to the housing connector and a shaft drive system comprising at least one rotatable shaft operably coupled to the electric motor. The surgical instrument further comprises an end effector releasably assembled to the shaft assembly including an end effector frame comprising an end effector connector releasably coupled to the distal connector of the shaft assembly, a plurality of staple cartridges removably stored in the end effector, and a plurality of end effector drivers operably coupled to the rotatable shaft.

A tissue segmentation device, controller, and methods therefore are disclosed. The device has an active electrode, a return electrode, a mechanical force application mechanism, voltage and current sensors, and a controller. The controller has a processing component, configured to assign a circuit status to a circuit comprising the at least one electrode. IF (PF0) and ((Vrms/Irms)T), THEN the circuit status is open. IF (PF0) and ((Vrms/Irms)<T), THEN the circuit status is short. PF is a power factor of power applied to the electrosurgical device. T is a threshold value.

In a method and system for reducing motion artifacts in magnetic resonance image data acquired from a facial region of a patient, the patient is positioned in an imaging region of a magnetic resonance imaging device configured to perform a magnetic resonance measurement of the facial region of the patient, the magnetic resonance measurement is performed to acquire magnetic resonance image data of the facial region of the patient, and a motion correction technique is employed exploiting an accessibility to the facial region of the patient during the magnetic resonance measurement. The motion correction technique advantageously reduces an influence of a patient motion on the magnetic resonance image data.