The present invention relates to a head immobilization system for immobilizing a patient's head in a supine position of the patient, the system comprising: a support rail structure adapted to be coupled to a patient rest and extending at least on both lateral sides of the patient's head, a mask frame adapted to be coupled to at least one deformable upper mask sheet, wherein the mask frame is releasably connected to the support rail structure via a first interface section and a second interface section, with at least two pins protruding from the first interface section in a first direction, and at least two pin-receptions provided at the second interface section, wherein each one of the pin-receptions receives one of the pins, and a catch-mechanism for each pin-reception and each corresponding pin, which allows the pin to be pushed further into the pin-reception in the first direction, but which interlocks in case of an attempted withdrawal of the pin from the pin-reception in a second, opposite direction.

Methods and devices are disclosed for treating a patient with an unruptured saccular aneurysm that is not associated with an arteriovenous malformation, wherein ionizing radiation is delivered to the brain of a patient through stereotactic radiosurgery. The radiosurgery may be performed with a Gamma Knife, LINAC device such as CyberKnife, or particle-beam device. The treatment impedes a natural progression of the aneurysm towards rupture and may actually obliterate the aneurysm. The treatment plan may be based in part on measured geometric properties of the aneurysm or on physical aneurysm properties such as permeability, wall thickness, wall motion, the presence of macrophages, shear stress, and flow velocities. The methods may be used in conjunction with endovascular coil embolization.

A head immobilization system for immobilizing a patient's head in a supine position of the patient includes a support rail structure adapted to be coupled to a patient rest. The system can further include a mask frame adapted to be coupled to at least one deformable upper mask sheet. The mask frame is releasably connected to the support rail structure via a first interface section and a second interface section, with at least two pins protruding from the first interface section in a first direction, and at least two pin-receptions provided at the second interface section. Each one of the pin-receptions receives one of the pins. A catch-mechanism for each pin-reception and each corresponding pin allows the pin to be pushed further into the pin-reception in the first direction, but interlocks in case of an attempted withdrawal of the pin from the pin-reception in a second, opposite direction.

The presently described method is directed to determining a way of positioning a patient before execution of a medical procedure involving irradiating the patient with ionizing treatment radiation based on comparing medical images of the patient with a pre-acquired medical image. The planning computed tomography is searched for an image of the reference stricture in order to determine the position of the patient relative to a patient support device. A retroreflective marker device, having a known and advantageously fixed position relative to the base plate, is detected by a navigation system operatively coupled to a motor of the support device. Based on the detected position of the marker device, the motor of the support device is activated to drive the patient into a desired position relative to beam direction along which the treatment radiation is to be issued towards the patient to execute the medical procedure.

A medical navigation system is provided. The medical navigation system includes a computing device having a processor coupled to a memory, a wireless communication component and a display for displaying an image. The medical navigation system further includes a sensor module attached to a medical device. The sensor module includes a housing for housing components of the sensor module and for attaching to the medical device, a processor housed in the housing, a memory coupled to the processor, a wireless communication component coupled to the processor, a battery coupled to the processor, and a sensor coupled to the processor. The sensor generates a signal to be transmitted wirelessly via the sensor module wireless communication component and receivable by the computing device wireless communication component, the signal representing movement of the medical device.

A head stabilization device having the form of a skull clamp includes a first pin assembly and a second pin assembly. The pin assemblies are positioned opposite each other, and the first pin assembly has a first pin while the second pin assembly has a pair of pins. The pins used with the skull clamp are non-uniform. In this respect skull clamp can apply an equal force to a head of a patient from both sides. Additionally, the pressure at each pin location can be the same or substantially the same. This allows each of the pins to have the same or similar bone penetration when in use stabilizing the head of the patient.

Composition in the form of a shaped device, for use as a fiducial marker in tissues in the animal body, in radiotherapy and/or radiosurgery, characterized in that it comprises:a core consisting of a colloidal dispersion of metal nanoparticles and/or oxides or metal salts having X-ray-contrast properties, where said nanoparticles are stabilized with surfactants, polymers or capping agents in a liquid vehicle, anda polymeric casing that encapsulates the core, said device having a minimum size of not less than 500 microns and a maximum size not greater than 3000 microns.

A method is disclosed of making a customized intraoral positioning device to be positioned within a patient's mouth for radiation therapy planning and treatment of a head and/or neck of the patient, the method comprising: receiving a prescribed treatment plan using the customized intraoral positioning device, wherein the treatment plan includes a prescribed incisor separation and/or tongue position of the patient for intended treatment; creating impressions of the patient's upper and lower arches of the patient's mouth; introducing a registration device into the patient's mouth to position the upper and lower arches at the prescribed incisor separation, so as to enable a model of the patient's upper and lower arches to be registered; creating models of the patients upper and lower arches based upon the impressions of the patient's upper and lower arches; digitizing the models of the patient's upper and lower arches; assembling the models of the patient's upper and lower arches on registration device; and digitizing the assembly of the models on the registration device so as to obtain a relationship between the upper and lower arches at the prescribed incisor separation.

A structure for positioning a body part includes a support base, and a shell frame having an inner surface configured to a shape of the body part. The shell frame is further configured to ride upon the support base, or upon a carriage that further rides upon the support base, to enable a pitch and/or a roll of the shell frame to be adjusted relative to the support base.

The presently described method is directed to determining a way of positioning a patient before execution of a medical procedure involving irradiating the patient with ionizing treatment radiation based on comparing medical images of the patient with a pre-acquired medical image. The planning computed tomography is searched for an image of the reference structure in order to determine the position of the patient relative to a patient support device. A retroreflective marker device, having a known and advantageously fixed position relative to the base plate, is detected by a navigation system operatively coupled to a motor of the support device. Based on the detected position of the marker device, the motor of the support device is activated to drive the patient into a desired position relative to beam direction along which the treatment radiation is to be issued towards the patient to execute the medical procedure.