A dispenser of barrier envelopes is formed of a pair of selectively interlocking open-top box-like structures. When interlocked, the pair of structures forms an interior chamber that is configured to store and protect one or more barrier envelopes inside from external contaminants such as viruses, bacteria and/or fungi. The dispenser of barrier envelopes includes a through opening for the purpose of dispensing the one or more envelopes to a user, and a spring in its interior chamber for directing the one or more envelopes toward the through opening.

A device and methods for performing a simulated CT biopsy on a region of interest on a patient. The device comprises a gantry (22) configured to mount an x-ray emitter (24) and CT detector (26) on opposing sides of the gantry, a motor (28) rotatably coupled to the gantry such that the gantry rotates horizontally about the region of interest, and a high resolution x-ray detector (172) positioned adjacent the CT detector in between the CT detector and the x-ray emitter.

A sterile drape can be used to cover a C-arm imaging machine used during a medical procedure. In some configurations, the drape includes a detector body cover, a C-arm body cover, and an elastic banding. The detector body cover can be positioned around a detector of the imaging machine. The C-arm body cover can include a tunnel portion that is positioned to surround a portion of the C-arm extending away from the detector. The elastic banding can extend about a perimeter of a junction between the detector body cover and the C-arm body cover. The elastic banding can provide a biasing force that draws the junction between the detector body cover and the C-arm body cover closed.

A dental x-ray sensor holder 1 and sheath 4 for affixing a sensor to a backing plate 2 of the holder 1. The dental x-ray sensor holder 1 and sheath 4 generally includes a sensor holder 1 with a backing plate 2, having one or more spring arms 3, and affixed to or formed contiguously with a proximal end of a bite block 9 of the holder 1. It also includes a sensor sheath adapted to secure a sensor to the backing plate for X-ray acquisition.

Sterile barriers or sterile drapes that can be used with medical devices, including hand-held or self-supported X-ray equipment, are described in this application. In particular, this application describes sterile drapes that can be used with a medical device, the drape comprising a closed end portion, a middle portion with a size sufficient to enclose a part of the medical device being used near a patient, and an open end portion, the end portion configured to be closed by a user once the middle portion encloses the part of the medical device being used near a patient, wherein the sterile drape creates a sterile barrier around substantially the entire medical device once the open end is closed. Using the sterile drape allows the medical device, such as a hand-held or self-supported X-ray device, to be used in a medical procedure that requires a sterile field near the patient without disrupting that sterile field. Other embodiments are described.

A device and methods for performing a simulated CT biopsy on a region of interest on a patient. The device comprises a gantry (22) configured to mount an x-ray emitter (24) and CT detector (26) on opposing sides of the gantry, a motor (28) rotatably coupled to the gantry such that the gantry rotates horizontally about the region of interest, and a rotation of source high resolution x-ray detector (172) positioned adjacent the CT detector in between the CT detector and the x-ray emitter.

A radiation protection device attaches to the C-arm of a fluoroscope and shields and collimates the X-ray beam between the X-ray source and the patient and between the patient and the image intensifier. One embodiment has a radiation shield of X-ray opaque material that surrounds the C-arm of the fluoroscopy system, the X-ray source and the image intensifier. A padded slot fits around the patient's body. Another embodiment has conical or cylindrical radiation shields that extend between the X-ray source and the patient and between the patient and the image intensifier. The radiation shields have length adjustments and padded ends to fit the device to the patient. The radiation protection device may be motorized to advance and withdraw the radiation shields. A blanket-like radiation shield covers the patient in the area surrounding where the X-ray beam enters the body.

Various systems are provided for collision avoidance in an x-ray imaging system. In one example, an x-ray system includes a moveable arm comprising an x-ray source arranged at a first end and an x-ray detector arranged at a second end, an ultrasonic sensor positioned on the movable arm, the x-ray source, or the x-ray detector, and a sterile drape configured to be positioned over at least a portion of the movable arm, the x-ray source, and/or the x-ray detector, the sterile drape including an adhesive pad configured to contact a front face of the ultrasonic sensor.

A disinfecting medical imaging system including medical imaging equipment and a UV light source for disinfecting the medical imaging equipment. The UV light source can include a composite ultraviolet (UV) for performing viral and bacterial disinfection. The disinfection system may be built into the medical imaging equipment or external thereto such as conveyed on a robotic arm.

A radiation protection device attaches to the C-arm of a fluoroscope and shields and collimates the X-ray beam between the X-ray source and the patient and between the patient and the image intensifier. One embodiment has a radiation shield of X-ray opaque material that surrounds the C-arm of the fluoroscopy system, the X-ray source and the image intensifier. A padded slot fits around the patient's body. Another embodiment has conical or cylindrical radiation shields that extend between the X-ray source and the patient and between the patient and the image intensifier. The radiation shields have length adjustments and padded ends to fit the device to the patient. The radiation protection device may be motorized to advance and withdraw the radiation shields. A blanket-like radiation shield covers the patient in the area surrounding where the X-ray beam enters the body.