The present invention relates to a method for positioning a patient's body part including a target to be irradiated relative to an irradiation source of a radiation imaging device, that generates a radiation beam directed towards the target, the method being constituted to be executed by a processor of a computer and comprising the following steps: receiving, at the processor, geometry data describing the geometry of at least one structure located in the field of view of the radiation imaging device; receiving, at the processor, tracking data describing the spatial position of the at least one structure within the field of view of the radiation imaging device; determining, with the processor, position data incorporating the geometry data and the tracking data, describing whether a position of the at least one structure lies within a radiation beam trajectory through the target; determining, with the processor, repositioning data describing a position of the at least one structure away from the radiation beam trajectory through the target; outputing, from the processor, the repositioning data allowing for repositioning of the at least one structure. The present invention further relates to a corresponding computer program and system.

The present invention relates to a thermoplastic composition suitable for manufacturing a thermoplastic sheet for producing a medical cast, such as a radiation mask. The composition has a polymeric component comprising a mixture of a styrene acrylonitrile copolymer and polycaprolactone, optionally together with a cross-linker and/or a filler, wherein the polymeric component comprises, 20 to 40 weight % of a styrene acrylonitrile copolymer and 80 to 60 weight % of a polycaprolactone, expressed in weight % of the polymeric component, wherein the thermoplastic composition has a glass transition temperature of 35° C.-80° C. The invention further relates to a thermoplastic sheet and to a medical cast, in particular a radiation mask, obtainable from said composition. In a final aspect, the invention relates to a method for producing said sheet and said radiation mask.

The present invention relates to a thermoplastic composition suitable for manufacturing a thermoplastic sheet for producing a medical cast, such as a radiation mask. The composition has a polymeric component comprising a mixture of a styrene acrylonitrile copolymer and polycaprolactone, optionally together with a cross-linker and/or a filler, wherein the polymeric component comprises, 20 to 40 weight % of a styrene acrylonitrile copolymer and 80 to 60 weight % of a polycaprolactone, expressed in weight % of the polymeric component, wherein the thermoplastic composition has a glass transition temperature of 35° C.-80° C. The invention further relates to a thermoplastic sheet and to a medical cast, in particular a radiation mask, obtainable from said composition. In a final aspect, the invention relates to a method for producing said sheet and said radiation mask.

A frame for fixation of equipment to the head of a patient during neurological diagnosis, therapy or surgery is adapted to enclose the head of the patient. The frame includes a number of mounting slots arranged in the frame. The mounting slots are adapted to receive a number of fixation pins adapted to fixate the frame to a bone in the head. The frame further includes two anterior longitudinal posts and two posterior longitudinal posts, extending along a longitudinal axis A, an anterior portion, adapted to be arranged at the anterior side of the head, the anterior portion interconnecting the two anterior longitudinal posts, and a posterior portion, adapted to be arranged at the posterior side of the head, the posterior portion interconnecting the two posterior longitudinal posts. The anterior longitudinal posts and the posterior longitudinal posts are interconnected with two lateral portions, adapted to extend one on each side of the head, and wherein the lateral portions are axially offset, along the longitudinal axis A, with respect to the anterior and posterior portion. A stereotactic frame system includes such a frame.

A frame for fixation of equipment to the head of a patient during neurological diagnosis, therapy or surgery is adapted to enclose the head of the patient. The frame includes a number of mounting slots arranged in the frame. The mounting slots are adapted to receive a number of fixation pins adapted to fixate the frame to a bone in the head. The frame further includes two anterior longitudinal posts and two posterior longitudinal posts, extending along a longitudinal axis A, an anterior portion, adapted to be arranged at the anterior side of the head, the anterior portion interconnecting the two anterior longitudinal posts, and a posterior portion, adapted to be arranged at the posterior side of the head, the posterior portion interconnecting the two posterior longitudinal posts. The anterior longitudinal posts and the posterior longitudinal posts are interconnected with two lateral portions, adapted to extend one on each side of the head, and wherein the lateral portions are axially offset, along the longitudinal axis A, with respect to the anterior and posterior portion. A stereotactic frame system includes such a frame.

A kit including a medical guide template, and a sterilizable receptacle accommodating the guide template, the kit being configured to allow deformation of the template into an operational medical guide.

A kit including a medical guide template, and a sterilizable receptacle accommodating the guide template, the kit being configured to allow deformation of the template into an operational medical guide.

A medical navigation system is provided for detecting movement of a subject, the system having an optical tracking system including a camera, a display, and a controller electrically coupled with the optical tracking system and the display. The controller has a processor coupled with a memory and is configured to receive a data signal from the optical tracking system and recognize and continuously monitor optical tracking markers on the subject within a field of view of the camera, and provide an alert on the display when movement of the optical tracking markers on the subject falls within predefined parameters.

A medical robot system, including a robot coupled to an end effector element with the robot configured for controlled movement and positioning. The robot system includes a robot base having a display, a robot arm coupled to the robot base, wherein movement of the robot arm is electronically controlled by the robot base. The end-effector is coupled to the robot arm, containing one or more end-effector tracking markers. The system also includes a plurality of dynamic reference bases (DRB) attached to multiple patient fixture instruments, wherein the plurality of dynamic reference bases include one or more tracking markers indicating a position of the patient fixture instrument in a navigational space. The system also includes a first camera system and a second camera system, the first and second camera systems being able to detect a plurality of tracking markers.

A medical robot system, including a robot coupled to an end effector element with the robot configured for controlled movement and positioning. The robot system includes a robot base having a display, a robot arm coupled to the robot base, wherein movement of the robot arm is electronically controlled by the robot base. The end-effector is coupled to the robot arm, containing one or more end-effector tracking markers. The system also includes a plurality of dynamic reference bases (DRB) attached to multiple patient fixture instruments, wherein the plurality of dynamic reference bases include one or more tracking markers indicating a position of the patient fixture instrument in a navigational space. The system also includes a first camera system and a second camera system, the first and second camera systems being able to detect a plurality of tracking markers.