Abstract: The present disclosure describes ultrasound imaging systems and methods, which may enable the automatic identification of an image plane in a pre-operative volume corresponding to a real-time image of a moving region of interest. An example method includes receiving real-time ultrasound image data from a probe associated with a position-tracking sensor, generating real-time images based on the real-time ultrasound data and deriving a motion model from the real-time ultrasound image data. The method may further include automatically identifying an image plane in a pre-operative data set to correspond to the real-time ultrasound image by correcting for motion-induced misalignment between the real-time data and the pre-operative data.

Abstract: The present invention relates to a medical imaging apparatus. The apparatus comprises an ultrasound acquisition unit including an ultrasound probe for acquiring ultrasound image data of a patient. An image data interface is provided for receiving 3D medical image data of the patient and a position determining unit for determining a position of the ultrasound probe. A calibration unit determines a transfer function between the ultrasound image data and the 3D medical image data at a plurality of positions (C) of the ultrasound probe and provides a corresponding plurality of calibrated transfer functions and calibration positions. A computation unit synchronizes the ultrasound image data and the 3D medical image data on the basis of a position of the ultrasound probe and the plurality of calibrated transfer functions, said computation unit is further adapted to weight the calibrated transfer functions on the basis of a position of the ultrasound probe.

Abstract: A medical imaging apparatus (10) for inspecting a volume of a subject (12) is disclosed. The medical imaging apparatus comprises an ultrasound acquisition unit (14) including an ultrasound probe for acquiring ultrasound image data of the subject, an image interface (20) for receiving medical image data of the subject, a position determining unit (30) for determining a position of the ultrasound probe. An alignment unit is provided for aligning the ultrasound image data and the medical image data based on anatomical features (32) of the subject and the detected position of the ultrasound probe and for adapting the alignment of the ultrasound image data and the medical image data based on a motion model. An image processing unit (18) is provided for processing the ultrasound image data and the medical image data to fuse the ultrasound image data and the medical image data based on the alignment to combined image data.

Abstract: A medical imaging apparatus (10) for evaluating medical image data is disclosed. The medical imaging apparatus comprises an ultrasound acquisition unit including an ultrasound probe (14) for acquiring ultrasound image data of a patient (12) and an ultrasound segmentation unit (24) for segmenting anatomical features of the patient in the ultrasound image data and for providing ultrasound segmentation data (46). The apparatus comprises an image data interface (18) for receiving 3D medical image data of the patient and a medical image segmentation unit (26) for segmenting the 3D medical image data and for providing medical image segmentation data (48).

Abstract: An ultrasound imaging apparatus (16) is disclosed for providing two-dimensional ultrasound images of a patient. The ultrasound imaging apparatus comprises an input interface (18) for receiving three-dimensional ultrasound data of a volume of the patient from an ultrasound acquisition unit as a continuous data stream and a motion detection unit (22) for determining a motion of an object in the three-dimensional ultrasound data and a direction of the motion in the three-dimensional ultrasound data. An image processing unit (20) determines a spatial rotation angle (46) of an image plane (32, 34) within the volume on the basis of the determined direction of the motion and determines two-dimensional ultrasound image data on the basis of the three-dimensional ultrasound data in the image plane within the volume. The two-dimensional image data is provided via an output interface to a display unit (26).

Abstract: The present invention relates to an ultrasound imaging system (10) for inspecting an object (33) in a volume (32). The ultra-sound imaging system comprises an ultrasound image acquisition probe (14) for acquiring three-dimensional ultrasound images and providing three-dimensional ultrasound image data, comprising a tracking device (25, 27) for tracking a position of the ultrasound image acquisition probe (14) and providing a viewpoint position (128, 130) of the three-dimensional ultrasound images. By this, an improved initialization and improved co-registration and co-segmentation is enabled by providing a plurality of three-dimensional ultrasound images and their respective viewpoint positions (128, 130), and to conduct a segmentation (80) of the object (33) simultaneously out of the plurality of three-dimensional ultrasound images and taking into account the viewpoint positions (128, 130).

Abstract: The invention relates to a suspension of red corpuscles encapsulating asparaginase as a medicament for treating pancreatic cancer. It in particular concerns a therapeutic composition or medicament intended for the treatment of pancreatic cancer, containing an effective quantity of such a suspension of red corpuscles.

Abstract: An encoding method applied to an input video sequence corresponding to successive scenes subdivided into successive video object planes (VOPs) is provided that generates, for coding all the video objects of said scenes, a coded bit stream the content of which is described in terms of separate channels and constituted of encoded video data in which each data item is described by a bitstream syntax that allows the recognition and decoding of all the elements of the content. The syntax comprises an additional syntactic information provided for describing independently the type of temporal prediction of the various channels. The additional information is a syntactic element placed at the slice level or the macroblock level in the coded bitstream, and its meaning is either specific for each present channel or shared by all existing channels.

Abstract: The invention relates to a suspension of red corpuscles encapsulating asparaginase as a medicament for treating pancreatic cancer. It in particular concerns a therapeutic composition or medicament intended for the treatment of pancreatic cancer, containing an effective quantity of such a suspension of red corpuscles.

Abstract: A global motion estimation method between an incoming frame F(n) of a sequence of frames and a large static image M(n−1), which is constructed from previous frames F(1), F(2), . . . , F(n−1) of the video sequence, uses a motion model based on a two-dimensional perspective transform that contains eight motion parameters. The eight motion parameters are the coordinates of the four vertices of the incoming frame. The motion estimation method enables any displacement of the four corners of the original rectangular image to fit the next one by optimizing a cost function. Useful applications include those related to MPEG-4 and, more especially, to MPEG-7 standard, such as sprite generation or mosaicing.

Abstract: The invention relates to a new method of reconstruction of tridimensional scenes. While conventional methods are often limited to the 3D reconstruction of the bounding volume of the concerned objects, the proposed method of recovery of a 3D geometric model from 2D views taken by one single camera, giving an information even about the parts which are hidden in each view, is implemented according to a first depth labeling step, implemented in a sub-system (11) and including initialization and projection sub-steps followed by a refinement process, and to a second reconstruction step, implemented in a sub-system (12). By means of a close cooperation of the 3D depth maps thus obtained for two views of a scene, a 3D model is identified and extracted.

Abstract: A video encoder and decoder are provided for processing a sequence of animated pictures in such a way that an interactive game, such as a puzzle for instance, may be played. Each picture of a movie sequence is divided into a predetermined number of pieces that are then randomly coded (according to the MPEG-4 standard), transmitted and/or stored, decoded and displayed. It is then possible to play with the pieces to reorder them while they are in motion (with possible associated audio), according to predefined rules and ends of scenarios. The left and right buttons of a mouse, or a similar control device, are used to displace either one piece, or a group of attached pieces respectively, in order to verify if the proposed location for a piece is free and possible (no contradiction with any other surrounding piece) and then to drop said piece on the new spot, or, on the contrary, if some contradiction is detected, send back the piece (or, respectively, the group of attached pieces) to its previous location.

Abstract: The invention relates to a new method of reconstruction of tridimensional scenes. While conventional methods are often limited to the 3D reconstruction of the bounding volume of the concerned objects, the proposed method of recovery of a 3D geometric model from 2D views taken by one single camera, giving an information even about the parts which are hidden in each view, is implemented according to a first depth labeling step, implemented in a sub-system (11) and including initialization and projection sub-steps followed by a refinement process, and to a second reconstruction step, implemented in a sub-system (12). By means of a close cooperation of the 3D depth maps thus obtained for two views of a scene, a 3D model is identified and extracted.