Abstract: A patient support system to be used in conjunction with a standard linear accelerator, and other sources, is described that allows access of the treatment beam to the breast from up to 360 degrees. This support system places the patient in a prone position with the breast going through an aperture. The prone position increases the separation of the breast from the chest wall and other critical organs and reduces motion of the target tissue due to breathing. This invention offers up to 36-degree radiation beam access to the breast. This helps in skin sparing, better dose conformity, and allows one to use modern treatment techniques such as IMRT and IGRT. It also includes a provision for an imaging system. This invention can also be used with CT and MR imaging modalities.

Abstract: A patient support system to be used in conjunction with a standard linear accelerator, and other sources, is described that allows access of the treatment beam to the breast from up to 360 degrees. This support system places the patient in a prone position with the breast going through an aperture. The prone position increases the separation of the breast from the chest wall and other critical organs and reduces motion of the target tissue due to breathing. This invention offers up to 360 degree radiation beam access to the breast. This helps in skin sparing, better dose conformity, and allows one to use modern treatment techniques such as IMRT and IGRT. It also includes a provision for an imaging system. This invention can also be used with CT and MR imaging modalities.

Abstract: A shielding system which can be applied to a radiation therapy system and/or diagnostic system includes a scatter shield configured to absorb scattered radiation from a patient, a source shield to absorb unwanted radiation from the radiation source, and an anti-reflective beam dump configured to absorb radiation that is transmitted through a patient. The radiation therapy and/or diagnostic system includes a radiation source positioned in the source shield, and a patient support positioned in the scatter shield.

Abstract: A shielding system which can be applied to a radiation therapy system and/or diagnostic system includes a scatter shield configured to absorb scattered radiation from a patient, a source shield to absorb unwanted radiation from the radiation source, and an anti-reflective beam dump configured to absorb radiation that is transmitted through a patient. The radiation therapy and/or diagnostic system includes a radiation source positioned in the source shield, and a patient support positioned in the scatter shield.

Abstract: A patient support system to be used in conjunction with a standard linear accelerator, and other sources, is described that allows access of the treatment beam to the breast from up to 360 degrees. This support system places the patient in a prone position with the breast going through an aperture. The prone position increases the separation of the breast from the chest wall and other critical organs and reduces motion of the target tissue due to breathing. This invention offers up to 360 degree radiation beam access to the breast. This helps in skin sparing, better dose conformity, and allows one to use modern treatment techniques such as IMRT and IGRT. It also includes a provision for an imaging system. This invention can also be used with CT and MR imaging modalities.

Abstract: A radiation applicator system is structured to be mounted to a radiation source for providing a predefined dose of radiation for treating a localized area or volume, such as the tissue surrounding the site of an excised tumor. The applicator system includes an applicator and an adapter. The adapter is formed for fixedly securing the applicator to a radiation source, such as a radiosurgery system which produces a predefined radiation dose profile with respect to a predefined location along the radiation producing probe. The applicator includes a shank and an applicator head, wherein the head is located at a distal end of the applicator shank. A proximate end of the applicator shank couples to the adapter. A distal end of the shank includes the applicator head, which is adapted for engaging and/or supporting the area or volume to be treated with a predefined does of radiation.

Abstract: A radiation applicator system is structured to be mounted to a radiation source for producing a predefined dose of radiation for treating a localized volume of tissue, such as the tissue surrounding the site of an excised tumor. The applicator system includes an applicator and, in some embodiments, an adapter. The adapter is formed for fixedly securing the applicator to a radiation source, such as the x-ray source of a radiosurgery system which produces a predefined radiation dose profile with respect to a predefined location along its radiation producing probe. The applicator includes a shank and an applicator head, wherein the head is located at a distal end of the applicator shank. A proximate end of the applicator shank couples to the adapter. A distal end of the shank includes the applicator head, which defines a concave treatment surface for engaging and, preferably, supporting the area to be treated with a predefined does of radiation.

Abstract: A support system for a radiation treatment system includes a rotatable extension arm extending from a vertical shaft and a rotatable counterbalance extending diametrically opposed to the extension arm from the vertical shaft. The vertical shaft is rotatably supported by a support base. The support base may include a damping mechanism to damp the rotational motion of the vertical shaft relative to the support base, wherein the damping force is preferably proportional to the velocity of the vertical shaft. The radiation treatment system is suspended from a cable extending from a distal end of the extension arm. The extension arm can be formed from a first arm extending from the vertical shaft and a second arm rotatably coupled to the first arm in order to permit the radiation treatment system to be moved in horizontal direction. The cable supporting the radiation treatment system can be coupled to a vertical counterbalance weight to allow the vertical position of the radiation treatment system to be adjusted.

Abstract: A radiation applicator system is structured to be mounted to a radiation source for producing a beam of radiation for treating a localized volume of tissue, such as growing blood vessels in the eye that can cause macular degeneration. The applicator system includes an applicator and, in some embodiments, an adapter. The adapter is formed for fixedly securing the applicator to a radiation source, such as a radiosurgery system which produces a predefined radiation dose profile with respect to a predefined location along the radiation producing probe. The applicator includes a shank and an applicator head. A proximate end of the applicator shank couples to the adapter. A distal end of the shank includes the applicator head, which is adapted to produce a beam of radiation. The applicator head includes a radiation shield and a beam collimator. The radiation shield selectively blocks the emitted radiation so that the applicator can be held by a surgeon during treatment.

Abstract: A radiation applicator system is structured to be mounted to a radiation source for providing a predefined dose of radiation for treating a localized volume of tissue, such as the tissue surrounding the site of an excised tumor. The applicator system includes an applicator and, in some embodiments, an adapter. The adapter is formed for fixedly securing the applicator to a radiation source, such as a radiosurgery system which produces a predefined radiation dose profile with respect to a predefined location along its radiation producing probe. The applicator includes a shank and an end cap, wherein the end cap includes a substantially flat or convex treatment surface and is located at a distal end of the applicator shank. A proximate end of the applicator shank couples to the adapter. A distal end of the shank includes the end cap, which is adapted for engaging and preferably supporting the area to be treated with a predefined does of radiation.

Abstract: A phantom apparatus for measuring the radiation dose distribution produced by a brachytherapy device used to treat a localized area with radiation. The brachytherapy device includes an insertable probe capable of producing predefined radiation dose geometries about a predefined point. The phantom apparatus includes a tank containing a medium having a radiological equivalent characteristic of the localized area to be treated. The phantom apparatus also includes a radiation sensor for measuring the radiation dose and a positioning system for moving the probe with respect to the radiation sensor. The radiation sensor is also coupled to a positioning system to orient the sensor for optimal dose measurements. The phantom apparatus includes a control system that coordinates the movements of the probe and the radiation sensor to avoid a collision. The control system moves the probe along a predefined path around radiation sensor and records the dose at predefined points along the path.

Abstract: A system is disclosed for producing images representing radiation dose distributions in order to verify the radiation dose applied to a target area. The system uses a phantom assembly constructed of material that is the radiological equivalent of live tissue. The phantom assembly has slits where radiation sensitive film can be inserted and can include a channel for an insertable radiation generating device. The treatment dose is then applied to the phantom and the radiation sensitive film records the dose. A CCD camera microdensitometer is then used to read the exposed radiation sensitive film. The CCD camera microdensitometer includes a computer system which processes the image to remove artifacts and generates isodose contours for the radiation treatment applied. In addition, several pieces of radiation sensitive film in different planes can be exposed and processed in order to produce images representing the radiation dose distribution in three dimensions.

Abstract: The present invention is directed to an x-ray source for irradiating a surface defining a body cavity in accordance with a predetermined dose distribution. The source comprises a housing, an elongated tubular probe, a target assembly, and an inflatable balloon. The housing encloses an electron beam source and includes elements for generating an electron beam along a beam path. The tubular probe extends along a central axis from the housing about the beam path. The target assembly extends along the central axis and is coupled to the end of the probe distal from the housing. The target assembly includes a target element is positioned in the beam path. The target element is adapted to emit x-rays in response to electrons incident thereon from the beam. The probe tip assembly and associated control electronics include elements for positioning the target element in the beam path, and is substantially x-ray transparent.

Abstract: The present invention is directed to a kit for delivering x-rays to the interior surface of a body cavity. The kit includes an x-ray source and an x-ray source guidance tube. The guidance tube includes an inflatable inelastic balloon disposed about and affixed at its distal end such that when inflated, the central axis of the balloon is coaxial with and is disposed about the central axis of the tubular element. Inflation and deflation of the balloon is controllable from the proximal end of the tubular element. The x-ray source may include an electron activated target for generating x-rays in response to electrons incident on the target. The x-ray source may also includes means for generating an electron beam and steering the beam so that it is incident on the target. The target end is slidably positionable within an interior channel of the source guidance tube.

Abstract: A system is disclosed for producing images representing radiation dose distributions in order to verify the radiation dose applied to a target area. The system uses a phantom assembly constructed of material that is the radiological equivalent of live tissue. The phantom assembly has slits where radiation sensitive film can be inserted and can include a channel for an insertable radiation generating device. The treatment dose is then applied to the phantom and the radiation sensitive film records the dose. A CCD camera microdensitometer is then used to read the exposed radiation sensitive film. The CCD camera microdensitometer includes a computer system which processes the image to remove artifacts and generates isodose contours for the radiation treatment applied. In addition, several pieces of radiation sensitive film in different planes can be exposed and processed in order to produce images representing the radiation dose distribution in three dimensions.

Abstract: A method of treating brain tumors in a patient, comprising the steps of: identifying and locating a brain tumor in vivo by affixing a stereotactic frame to the head of the patient, performing a computer tomographic (CT) scan of the skull of the patient to determine the location, size, and shape of the tumor with respect to the stereotactic frame, performing a biopsy by inserting an extraction tool along a path measured with respect to the frame to the tumor location, extracting a tissue from the location, removing the needle and the extracted tissue and analyzing the tissue; implanting at least a portion of an adjustable x-ray radiation source in the patient proximate the tumor, the adjustable radiation source including an electron beam source outside the head of the patient, and directing an electron beam produced by the source outside the head of the patient along the path to the location; and controlling the source to generate an x-ray radiation pattern characterized by a spatial and temporal distribution,

Abstract: The present invention is directed to an x-ray source for irradiating a volume in accordance with a predetermined dose distribution. The source comprises a housing, an elongated tubular probe, and a target assembly. The housing encloses an electron beam source and includes elements for generating an electron beam along a beam path. The tubular probe extends along a central axis from the housing about the beam path. The target assembly extends along the central axis and is adapted for coupling to the end of the probe distal from the housing. The target assembly includes a target element, a probe tip assembly, and a variable transmission shield. The target element is positioned in the beam path. The target element is adapted to emit x-rays in response to electrons incident thereon from the beam. The probe tip assembly and associated control electronics include elements for positioning the target element in the beam path, and is substantially x-ray transparent.

Abstract: An apparatus for treating a brain tumor in a patient, which includes an x-ray source of preselected or preprogrammed duration and intensity assembled in combination with a reference frame. The reference frame can be, for example, a stereotactic frame. The apparatus allows accurate positioning of the x-ray source within or adjacent to the desired region to be irradiated in the brain of the patient.

Abstract: A low-level, electron beam activated source of preselected or programmable duration and intensity x-rays. The source may be fully or partially implanted into, or surface-mounted onto a desired area to affect a preselected irradiated region. In medical applications, a method of treating malignant cells, such as tumors, in vivo, utilizing the apparatus described above.

Abstract: A capacitance height gage for positioning the reticle of an electron beam lithography apparatus. The gage includes a hybrid circuit substrate carrying four measuring and two reference capacitor circuits. Each has a driven plate, the four measuring plates disposed opposite the object surface to be measured, and the two reference plates disposed on the top of the substrate. Two ground plates are disposed a predetermine distance from the reference driven plates. The object surface comprises the ground plate for the four measuring driven plates. The reference plates calibrate the measuring plates.