Abstract: The disclosure relates to devices, systems, and methods for controlling acquisition parameters when carrying out a medical x-ray examination, wherein the device includes a lever.

Abstract: The disclosure relates to a system for tracking the position of a target object. A marker arranged on the target object and an additional control marker are tracked by a tracking device secured to the robot arm. The control marker is arranged in a known specified three-dimensional positional relationship with the tracking device. During the tracking of the position of the target object, the specified three-dimensional positional relationship between the tracking device and the control marker is measured. In the event of a difference between the measured and the real specified three-dimensional positional relationship, a corresponding signal is generated depending on the difference.

Abstract: A method is provided for running a collision protection system for a medical operating device, which has a patient bed for a patient to be operated on, an image recording device having at least one movable image recording component for recording image data of the patient during the operation, and an assistance robot having a movable assistance component which during the operation is situated at least temporarily inside the patient and/or is coupled in terms of movement to an instrument situated inside the patient. In the method, an item of criticality information is determined which describes the criticality of possible collisions of components of the operating device and/or movements of the patient with regard to the interaction of the assistance robot with the patient. Depending upon the criticality information, when a criticality criterion indicating a raised criticality, (e.g.

Abstract: A method for recording image data of a moving, (e.g., cyclically moving), region of interest of a patient by a medical imaging system with an X-ray source and an X-ray detector, wherein a robotic device with a kinematic chain of moving components has a tactile connection with the patient, and wherein, the tactile connection is maintained at least for a prespecified period. The method includes acquiring measured values by sensors of the robotic device, evaluating the measured values and forwarding to the medical imaging system, wherein the evaluated measured values include information on the movement and/or position of the region of interest, and irradiation of the region of interest by the radiation source and recording of image data of the irradiated region of interest by the X-ray detector, and wherein the evaluated measured values are used to actuate the imaging system.

Abstract: In an embodiment, a method includes acquiring a first image data set of the patient, via an X-ray apparatus, at a first time point during the operative intervention, the first image data set including the reference structure, the anatomical structure and the reference system between the reference structure and the anatomical structure; acquiring a second image data set of the patient at a second time point, the second image data set including at least the reference structure; registering the second image data set to the first image data set. As a result of the registering of the second image data set to the first image data set, a registered second image data set is determined. Finally, an embodiment of the method includes determining the validity of the reference system by a comparison of the registered second image data set with the first image data set.

Abstract: A method of constructing a tower is provided, the method including the steps of providing an elevation mechanism including a dynamic engaging mechanism realized to engage with a tower surface, arranging a 3D printing device on the elevation means, actuating the dynamic engaging mechanism to effect a vertical elevation of the elevation mechanism, actuating the 3D printing device to deposit an essentially horizontal material layer including at least a tower body region, and repeating the steps to obtain a tower structure. A tower constructed using such a method, and a 3D tower printing apparatus, is also provided.

Abstract: A method is for controlling a system including an imaging modality. The method includes receiving an image and/or a series of images of a portion of a patient from the imaging modality, the field of view of the image and/or of the series of images covering at least a part of an instrument; determining whether the part of the instrument is located within a defined portion of the field of view and/or in a given state selected from a plurality of first states and/or the part of the instrument executes a given movement selected from a plurality of movements; and generating a control command for performing an action depending on whether the part of the instrument is located within the defined portion of the field of view and/or the part of the instrument is in the given state and/or the part of the instrument executes the given movement.

Abstract: A method for determining an item of patient information that alludes to a position and/or a movement of a patient during an examination and/or treatment process with a medical engineering apparatus is provided. The patient information is determined from sensor data of a mobile telephone sensor of a mobile telephone, such as a smartphone, coupled motionally to the patient, at least in one direction of movement.

Abstract: A method is provided for controlling a robotic device, of which the end effector arranged on a kinematic chain interacts with an object, and including an ultrasound apparatus registered to the robotic device for movement capture of the object. Ultrasound image data of the object is captured. The relative movement of the object is determined on the basis of the ultrasound image data using a mathematical method. The absolute movement is determined through registration to a planning data set. Movements of the object are compensated for in the context of the interaction of the end effector of the robotic device with the object. Future movements of the object and a positioning of the end effector of the robotic device adapted thereto are predicted and the robotic device is controlled accordingly. In the calculation of the adapted positioning of the end effector of the robotic device, a temporal delay relative to the movement of the object is included.

Abstract: A method for calibrating a medical imaging device in terms of an image acquisition geometry, a method for performing a two-dimensional-three-dimensional registration based on corresponding calibration data, and a corresponding system are provided. Multiple images of a phantom are acquired using the imaging device in different positions of the phantom. A corresponding motion of the phantom from one position to a respective next position is tracked by a tracking device to keep continuous track of a spatial relation between the phantom and the imaging device. The medical imaging device is then calibrated based on the acquired images, corresponding recorded poses of the imaging device, and the tracked motion of the phantom.

Abstract: The disclosure relates to devices, systems, and methods for controlling acquisition parameters when carrying out a medical x-ray examination, wherein the device includes a lever.

Abstract: A method is disclosed for registration on setting an alignment of an instrument relative to an object during a processing or treatment of the object by the instrument. A working image is registered to a planning image. The working image is recorded in a viewing direction that is selected dependent upon relevant degrees of freedom of the instrument such that the relevant degrees of freedom are the degrees of freedom with the greater registration accuracy. In addition, a robot system is provided which is configured for carrying out the method.

Abstract: The disclosure relates to a system for tracking the position of a target object. A marker arranged on the target object and an additional control marker are tracked by a tracking device secured to the robot arm. The control marker is arranged in a known specified three-dimensional positional relationship with the tracking device. During the tracking of the position of the target object, the specified three-dimensional positional relationship between the tracking device and the control marker is measured. In the event of a difference between the measured and the real specified three-dimensional positional relationship, a corresponding signal is generated depending on the difference.

Abstract: A method calculates a calibration parameter for a robot tool. The method is based on the reception of an image dataset from medical imaging of an image volume via a first interface. The image volume contains a part of the robot tool and the robot tool is attached to a robot. A robot dataset is received by a second interface. The robot dataset contains a position of a movable axis of the robot during the recording of the image dataset. The position and/or orientation of a marking in the image dataset are determined by a computing unit. An image-based position and/or orientation of the tool center point of the robot tool are calculated by transforming the position and/or orientation of the marking. The calibration parameter is calculated based on the robot dataset and on the image-based position and/or orientation of the tool center point via the computing unit.

Abstract: A method for assisting navigation of an endoscopic device using a controller with the aid of a digital image data record of an imaging examination modality is provided. The digital image data record describes an image of an object to be examined with the aid of the endoscopic device in a cavity element. A digital two-dimensional or multi-dimensional model of the object to be examined is determined based on the image data record. An operating action that predetermines a relative location of a sensor of the endoscopic device in relation to the object based on the model is received. The model is registered with the endoscopic device and/or a digital endoscopic data record supplied by the endoscopic device. An initial location of the sensor is compared with the predetermined location, and a navigation signal for navigating the endoscopic device is generated taking into account the predetermined relative location.

Abstract: A method for recording image data of a moving, (e.g., cyclically moving), region of interest of a patient by a medical imaging system with an X-ray source and an X-ray detector, wherein a robotic device with a kinematic chain of moving components has a tactile connection with the patient, and wherein, the tactile connection is maintained at least for a prespecified period. The method includes acquiring measured values by sensors of the robotic device, evaluating the measured values and forwarding to the medical imaging system, wherein the evaluated measured values include information on the movement and/or position of the region of interest, and irradiation of the region of interest by the radiation source and recording of image data of the irradiated region of interest by the X-ray detector, and wherein the evaluated measured values are used to actuate the imaging system.

Abstract: A method for calibrating a manipulator of a diagnostic and/or therapeutic manipulator system, wherein the manipulator system includes at least one medical imaging device. The method includes at least: a) moving the manipulator to at least one target pose; b) capturing at least one image of at least a part of the manipulator and/or at least of a part of an end effector of the manipulator with the medical imaging device if the manipulator has moved to the target pose; c) determining the actual pose of the manipulator using the captured image; d) determining the deviation between the target pose and the actual pose of the manipulator; and e) calculating at least one calibration parameter on the basis of the determined deviation, and calibrating the manipulator.

Abstract: In an embodiment, a method includes acquiring a first image data set of the patient, via an X-ray apparatus, at a first time point during the operative intervention, the first image data set including the reference structure, the anatomical structure and the reference system between the reference structure and the anatomical structure; acquiring a second image data set of the patient at a second time point, the second image data set including at least the reference structure; registering the second image data set to the first image data set. As a result of the registering of the second image data set to the first image data set, a registered second image data set is determined. Finally, an embodiment of the method includes determining the validity of the reference system by a comparison of the registered second image data set with the first image data set.

Abstract: The embodiments relate to a method for operating a medical robotic device with an end effector for performing a diagnostic and/or therapeutic measure, involving predetermining at least one position to be reached by the end effector, evaluating at least two movement sequences of the medical robotic device, by which the end effector reaches the respectively predetermined at least one position, using an optimization criterion to select the movement sequence with the best evaluation result as the optimum movement sequence and implementing the optimum movement sequence, so that the respective predetermined position is reached by the end effector, in order to improve the reaching of the predetermined position.

Abstract: A method is provided for running a collision protection system for a medical operating device, which has a patient bed for a patient to be operated on, an image recording device having at least one movable image recording component for recording image data of the patient during the operation, and an assistance robot having a movable assistance component which during the operation is situated at least temporarily inside the patient and/or is coupled in terms of movement to an instrument situated inside the patient. In the method, an item of criticality information is determined which describes the criticality of possible collisions of components of the operating device and/or movements of the patient with regard to the interaction of the assistance robot with the patient. Depending upon the criticality information, when a criticality criterion indicating a raised criticality, (e.g.