Apparatus and methods for providing three-dimensional printed oral stents are provided for head and neck radiotherapy. Movement of the jaw of the patient is simulated via a computer processor. Simulating movement of the jaw of the patient comprises rotating and translating a mandible of the jaw. A digital negative impression is transformed into a digital oral stent by adding support structures to the digital negative impression. The support structures facilitate three-dimensional (3D) printing of the patient-specific oral stent.

Controlling unit for a radiation source includes a mains-driven power supply terminal connectable to a mains-driven power supply, a battery-driven power supply terminal connectable to a battery-driven power supply, a failsafe power supply terminal, a processor unit to control the radiation source, and a patient-in-place sensor unit to provide a respective signal to the processor unit. The failsafe power supply terminal is connected to the mains-driven power supply terminal via a first diode and to the battery-driven power supply terminal via a second diode and he processor unit is connected to the failsafe power supply terminal to receive power from the higher voltage power supply terminal of the mains-driven power supply terminal and the battery-driven power supply terminal, respectively. The processor unit is adapted to shut down the radiation source in case a patient-not-in-place signal is provided.

Controlling unit for a radiation source includes a mains-driven power supply terminal connectable to a mains-driven power supply, a battery-driven power supply terminal connectable to a battery-driven power supply, a failsafe power supply terminal, a processor unit to control the radiation source, and a patient-in-place sensor unit to provide a respective signal to the processor unit. The failsafe power supply terminal is connected to the mains-driven power supply terminal via a first diode and to the battery-driven power supply terminal via a second diode and he processor unit is connected to the failsafe power supply terminal to receive power from the higher voltage power supply terminal of the mains-driven power supply terminal and the battery-driven power supply terminal, respectively. The processor unit is adapted to shut down the radiation source in case a patient-not-in-place signal is provided.

An instrument for accessing and visualizing hollow organs is provided. The instrument includes a mouthpiece having a perforated mask and a sleeve having a generally cylindrical or ovoid shape extending from the perforated mask substantially perpendicularly thereto and defining a channel. The instrument further includes sucking means having a suction chamber or closed volume that is restrained to the mask on the side where the sleeve is formed. The suction chamber has a plurality of through openings adapted to allow fluid communication with a surrounding environment, an intake opening communicating with the suction chamber formed on the mask, wherein the through openings are formed on the skirt of a dome-shaped member which delimits the suction chamber.

A plate to be used by being fixed to a stent to be mounted on a row of teeth of a patient includes a plurality of CT markers, a detachable part that is configured to connect a reference frame, provided with a plurality of infrared markers whose relative positional relationship with the respective CT markers when the reference frame is connected to the plate is known, and a recessed part that is configured to be used in measuring registration accuracy between position coordinates of the CT markers in a three-dimensional reconstructed CT image including the plate as an object and position coordinates of the CT markers in real space in which the plate exists, the position coordinates being calculated on the basis of the position coordinates of the infrared markers.

A device for attaching a localization marker to the lower jaw of an individual. The marker includes an inner face provided with two attachment lugs including an intra-oral portion having a general U-shape adapted for coming into contact with the outer face of the teeth of the lower jaw, an extra-oral portion including an attachment element for the marker, a connecting portion connecting the intra-oral portion and the extra-oral portion. The attachment element includes two recesses each adapted for receiving a respective lug of the marker, the recesses being separated by a tab adapted for being elastically deformed when one of the lugs is engaged in a respective recess so as to exert a pressure force on the lug.

An adjustable head coil system and methods for enhancing and/or optimizing magnetic resonance imaging, involving a housing, the housing having at least one portion, the at least one portion having a lower portion, an upper portion, and opposing side portions, each at least one portion optionally in movable relation to any other portion for facilitating adjustability, each at least one portion configured to accommodate at least one radio-frequency coil, and the upper and lower portions each optionally configured to overlap and engage the opposing side portions for facilitating decoupling the at least one radio-frequency coil, and a tongue portion optionally in movable relation to any other portion for facilitating adjustability, engageable with the lower portion, and fixably couple-able with a transporter.

This document describes devices for reducing risks to healthcare staff from infectious agents. For example, this document describes a bite block with a shield element or a mask that can reduce risk of infectious or noxious agents exposure to healthcare staff.

This document describes devices for reducing risks to healthcare staff from infectious agents. For example, this document describes a bite block with a shield element or a mask that can reduce risk of infectious or noxious agents exposure to healthcare staff.

Example radiographic dental jigs include a generally vertical post traversed by a generally horizontal beam to create a cross that can be used for marking a dental patient's midline (vertical line centered between the eyes), incisal edge plane, and forward lip position. The jig is radiographically scanned along with multiple fiducial markers on the patient's jaw to generate a first scan result. In some examples, physical models of the patient's jaws are also scanned to generate upper and lower jaw images. The upper and lower jaw images are shifted to coincide with the first scan result. Portions of the first scan result, including an image of the dental jig, are superimposed onto the properly shifted upper and lower jaw images to create a composite image. The composite image shows the dental jig in proper relation to the patient's upper and lower jaws, thereby rendering a conventional stick bite virtually obsolete.