Abstract: A method (100) of aneurysm analysis (110) and virtual stent simulation (120) for endovascular treatment of sidewall intracranial aneurysms.

Abstract: A method (100) for positioning and operating components (18, 22) of an X-ray C-arm system (10) during repeated angiographic medical procedures.

Abstract: A method for generating precedence-preserving crossover and mutations operations for genetic algorithms is provided. The method is based on the determination of activities' Forward Free Float (FFF) and Backward Free Float (BFF) values, utilizing these float values in randomly selected forward and backward paths, respectively. The method may be applied to the finance-based scheduling domain using large scale projects, with the chromosomes of the genetic algorithm encoding activities' start times in a resource-constrained scheduling problem.

Abstract: A method for providing a tool for analyzing an abnormality affixed to a human organ. The method includes: obtaining an image of the organ with the abnormality; separating the image of the abnormality from the image of the organ with the abnormality; mapping a surface of the separated image of the abnormality onto a homeomorphic equivalent template, such template being topologically equivalent to the surface. In one embodiment, the mapping is a continuous, bijective, mapping having a continuous inverse mapping characteristic.

Abstract: A vane for a turbine assembly of a turbocharger includes a first airfoil that includes a length between a leading edge and a trailing edge, a second airfoil that includes a length between a leading edge and a trailing edge where the length of the first airfoil optionally differs from the length of the second airfoil, and one or more intra-vane throats defined at least in part by the first airfoil and the second airfoil. Various other examples of devices, assemblies, systems, methods, etc., are also disclosed.

Abstract: A vane for a turbine assembly of a turbocharger includes an airfoil that has a pair of flow surfaces disposed between a hub end and a shroud end and a leading edge and a trailing edge where the airfoil further includes a non-zero sweep angle, a non-zero lean angle, a non-zero twist angle or any two or more combinations thereof. Various other examples of devices, assemblies, systems, methods, etc., are also disclosed.

Abstract: A vane for a turbine assembly of a turbocharger includes a first airfoil that includes a length between a leading edge and a trailing edge, a second airfoil that includes a length between a leading edge and a trailing edge where the length of the first airfoil optionally differs from the length of the second airfoil, and one or more intra-vane throats defined at least in part by the first airfoil and the second airfoil. Various other examples of devices, assemblies, systems, methods, etc., are also disclosed.

Abstract: A method for guiding stent deployment during an endovascular procedure includes providing a virtual stent model of a real stent that specifies a length, diameter, shape, and placement of the real stent. The method further includes projecting the virtual stent model onto a 2-dimensional (2D) DSA image of a target lesion, manipulating a stent deployment mechanism to navigate the stent to the target lesion while simultaneously acquiring real-time 2D fluoroscopic images of the stent navigation, and overlaying each fluoroscopic image on the 2D DSA image having the projected virtual stent model image, where the 2D fluoroscopic images are acquired from a C-arm mounted X-ray apparatus, and updating the projection of the virtual stent model onto the fluoroscopic images whenever a new fluoroscopic image is acquired or whenever the C-arm is moved, where the stent is aligned with the virtual stent model by aligning stent end markers with virtual end markers.

Abstract: The present invention relates to a method and apparatus for pretreatment planning endovascular coil placement, comprising steps of: a) analyzing three-dimensional data enabling visualization of a volume of interest containing at least a part of a blood vessel with an aneurysm; b) determining the centerline of the vessel; c) determining the aneurysm diameter; d) determining the aneurysm dome height; e) creating a three-dimensional surface model of the aneurysm in the vessel, using the results from the previous steps; f) estimating the volume expansion of one or more coils with the aid of said surface model; and g) visual simulating at least one according to the estimated virtual coil being to place inside the aneurysm.

Abstract: A method of assessing rupture risk of an aneurysm from time-resolved images includes injecting a contrast enhancing agent into a patient with an aneurysm, using an electrocardiogram (ECG) signal to trigger an image acquisition run, wherein a sequence of 2D X-ray fluoroscopic images is acquired along with a corresponding ECG signal value, rotating a C-arm attaching the X-ray fluoroscopic imaging apparatus during said image acquisition run, wherein the images in said X-ray fluoroscopic image sequence are acquired from a rotating viewpoint, sorting the images in said X-ray fluoroscopic image sequence into time windows of the cardiac cycle based on the ECG signal, and constructing one or more 3-dimensional (3D) angiography image volumes of said aneurysm from said 2D fluoroscopic image sequence.

Abstract: A method (100) of processing clinical 3D imaging of blood vessels in order to enable an analysis of the shape of blood vessels of a person, a statistical analysis of the shape and properties of blood vessels in a group of individuals, and the detection and quantification of blood vessel diseases.

Abstract: A method (100) for positioning and operating components (18, 22) of an X-ray C-arm system (10) during repeated angiographic medical procedures.

Abstract: A method for generating precedence-preserving crossover and mutations operations for genetic algorithms is provided. The method is based on the determination of activities' Forward Free Float (FFF) and Backward Free Float (BFF) values, utilizing these float values in randomly selected forward and backward paths, respectively. The method may be applied to the finance-based scheduling domain using large scale projects, with the chromosomes of the genetic algorithm encoding activities' start times in a resource-constrained scheduling problem.

Abstract: A method for facilitating an image guided medical procedure, utilizing images relating to the procedure, wherein the method includes performing a planning stage, including: obtaining a plurality of pre-procedural images, registering and fusing together the plurality of pre-procedural images, and extracting entities, or data objects, based on the pre-procedural images; performing an intervention stage, including: obtaining intra-procedural images, registering and fusing the pre-procedural and intra-procedural images, registering and fusing the entities with the intra-procedural images, and segmenting selected ones of the entities, based on the intra-procedural images; and performing an assessment stage, including: obtaining post-procedural images, registering and fusing the pre-procedural, the intra-procedural, and the post-procedural images, registering and fusing the entities with the post-procedural images, segmenting selected ones of the entities based on the post-procedural images.

Abstract: The present invention relates to a method and apparatus for pretreatment planning endovascular coil placement, comprising steps of: a) analyzing three-dimensional data enabling visualization of a volume of interest containing at least a part of a blood vessel with an aneurysm; b) determining the centerline of the vessel; c) determining the aneurysm diameter; d) determining the aneurysm dome height; e) creating a three-dimensional surface model of the aneurysm in the vessel, using the results from the previous steps; f) estimating the volume expansion of one or more coils with the aid of said surface model; and g) visual simulating at least one according to the estimated virtual coil being to place inside the aneurysm.

Abstract: A method for providing a tool for analyzing an abnormality affixed to a human organ. The method includes: obtaining an image of the organ with the abnormality; separating the image of the abnormality from the image of the organ with the abnormality; mapping a surface of the separated image of the abnormality onto a homeomorphic equivalent template, such template being topologically equivalent to the surface. In one embodiment, the mapping is a continuous, bijective, mapping having a continuous inverse mapping characteristic.

Abstract: A method for guiding stent deployment during an endovascular procedure includes providing a virtual stent model of a real stent that specifies a length, diameter, shape, and placement of the real stent. The method further includes projecting the virtual stent model onto a 2-dimensional (2D) DSA image of a target lesion, manipulating a stent deployment mechanism to navigate the stent to the target lesion while simultaneously acquiring real-time 2D fluoroscopic images of the stent navigation, and overlaying each fluoroscopic image on the 2D DSA image having the projected virtual stent model image, where the 2D fluoroscopic images are acquired from a C-arm mounted X-ray apparatus, and updating the projection of the virtual stent model onto the fluoroscopic images whenever a new fluoroscopic image is acquired or whenever the C-arm is moved, where the stent is aligned with the virtual stent model by aligning stent end markers with virtual end markers.

Abstract: A method of assessing rupture risk of an aneurysm from time-resolved images includes injecting a contrast enhancing agent into a patient with an aneurysm, using an electrocardiogram (ECG) signal to trigger an image acquisition run, wherein a sequence of 2D X-ray fluoroscopic images is acquired along with a corresponding ECG signal value, rotating a C-arm attaching the X-ray fluoroscopic imaging apparatus during said image acquisition run, wherein the images in said X-ray fluoroscopic image sequence are acquired from a rotating viewpoint, sorting the images in said X-ray fluoroscopic image sequence into time windows of the cardiac cycle based on the ECG signal, and constructing one or more 3-dimensional (3D) angiography image volumes of said aneurysm from said 2D fluoroscopic image sequence.

Abstract: A method for planning a path for an endovascular intervention includes acquiring and displaying 3D angiographic images; selecting a target on the displayed images; extracting a skeleton of a vascular tree from the displayed images; extracting a symbolic vessel path to the target based on the skeleton of the vascular tree; and overlaying and displaying the symbolic vessel path on 2D fluoroscopic images for guiding the endovascular intervention.