The necessary detector configuration and mathematical algorithms to implement a lateral (side-viewing) field of view in a gamma detection probe designed for laparoscopic use is disclosed. For this application, the diameter of the probe is limited to 12 mm. A hybrid collimation design, using a combination of both electronic collimation and metallic shielding, allows the probe to detect gamma emissions form 15 KeV-1.0 MeV. In the lower energy range, the 1.52 mm tungsten shielding is sufficient to collimate the primary detector. Two additional detectors are used to provide electronic collimation and depth detection. The upper energy limit of 1.0 MeV is imposed to exclude the possibility of electron-positron pair production which occurs at energies of 1.022 MeV and greater.

Disclosed herein is an apparatus comprising: an insertion tube configured to be inserted into a human; an image sensor inside the insertion tube; wherein the image sensor is configured to move to a plurality of positions with respect to the insertion tube.

A system having an X-ray imaging device for capturing an X-ray image on an imaging film, and a device for reading out the imaging film. The imaging film includes a data carrier, and the X-ray imaging device and/or readout device comprises includes a data device that has a write/read device for writing, on the data carrier, imaging parameters relating to the X-ray image capture and for reading information that is stored on the data carrier, the write/read device being configured to transmit the read information to the readout device such that the imaging parameters in force when capturing the X-ray image are available to the readout device for an imaging film readout. A method for providing information for a readout device is also provided.

The present invention relates to an in vivo radiation amount measuring instrument. An in vivo radiation amount measuring instrument according to the present invention comprises: a main body elongated along an in vivo inserting direction and capable of supplying a fluid; an expanding part having at least a portion thereof fixed or connected to the main body and capable of being expanded and contracted by means of the outflow/inflow of the fluid; and a radiation measuring part disposed on the expanding part and measuring the amount of surface radiation distribution on in vivo tissue which the expanding part contacts by expanding.

A holding device for use with a patient during an X-ray procedure includes an elongated arm having a proximal end and a distal end, a handle at the proximal end, and a retainer mounted on the distal end of the elongated arm for retaining something that is to be used adjacent to the patient during the X-ray procedure. An X-ray shield may be mounted on the arm between the retainer and the handle. There may be hinged joints between the retainer and the handle.

A holding device for use with a patient during an X-ray procedure includes an elongated arm having a proximal end and a distal end, a handle at the proximal end, and a retainer mounted on the distal end of the elongated arm for retaining something that is to be used adjacent to the patient during the X-ray procedure. An X-ray shield may be mounted on the arm between the retainer and the handle. There may be hinged joints between the retainer and the handle.

A medical device includes a host structure that has an interior area and one or more propulsion systems linked to the host structure. The host structure and the propulsion systems are configurable into a peripheral boundary of a size adapted to fit in a lumen or cavity of a living organism such as a human being or animal. The medical device includes one or more power supplies in communication with the propulsion systems. The medical device includes a control unit in communication with the propulsion systems and the power supplies. The control unit has a computer process controller configured to control the propulsion systems to move the host structure and the propulsion systems in the lumen so that the host structure and the propulsion systems are self-maneuverable within the lumen.

A wireless intraoral dental x-ray imaging sensor and method of use. The sensor optionally has a rechargeable battery located away from the edge of a PCB/ceramic substrate to enable encapsulation. The sensor has a compact microcontroller unit with several blocks including a radiolink, processing capacity, and a low power management system. Bit truncation and image compression take place on a readout substrate and/or on the MCU. External memory blocks allow for at least partial image storage for safety and as a backup.

Disclosed herein is an apparatus comprising an insertion tube; an image sensor inside the insertion tube; wherein the image sensor comprises an array of pixels; wherein the image sensor is configured to count numbers of particles of radiation incident on the pixels, within a period of time. Also disclosed herein is a method of using this apparatus.

A sensor licensing system for an intraoral sensor includes an on/off mechanism, a driver, and a sensor. The on/off mechanism is coupled to the intraoral sensor and has an encrypted licensing code so that the on/off mechanism turns on and off the intraoral sensor. The driver processes the encrypted license code stored in the sensor memory and determines if license code is expired based on the computer clock, exposure counter or other desired limits. The sensor periodically checks an online server for an updated encrypted license code and stores new license code in sensor memory. The updated license code is created and stored on the server when a new periodic subscription payment is made. The sensor periodically checks and downloads any updated license code. Failure to make a payment will result in no encrypted license code update being created and eventual expiration of the old encrypted license code.