VIS Gallery - Visualization in Medical Applications

	3D piecewise linear patches source: Non-linear Registration of Pre- and Intraoperative Volume Data contact: Christof Rezk-Salama
	Registration of pre- and intraoperative data based on piecewise linear patches source: Non-linear Registration of Pre- and Intraoperative Volume Data contact: Christof Rezk-Salama
	Registration of pre- and intraoperative data based on piecewise linear patches source: Non-linear Registration of Pre- and Intraoperative Volume Data contact: Christof Rezk-Salama
	Registration of pre- and intraoperative data based on piecewise linear patches source: Non-linear Registration of Pre- and Intraoperative Volume Data contact: Christof Rezk-Salama
	Direct Volume Rendering of dural arteriovenous fistula. source: Interactive Direct Volume Rendering of Dural Arteriovenous Fistulae contact: Peter Hastreiter
	Direct Volume Rendering of dural arteriovenous fistula. source: Interactive Direct Volume Rendering of Dural Arteriovenous Fistulae contact: Peter Hastreiter
	Direct Volume Rendering of dural arteriovenous fistula. source: Interactive Direct Volume Rendering of Dural Arteriovenous Fistulae contact: Peter Hastreiter
	Direct Volume Rendering of dural arteriovenous fistula. source: Interactive Direct Volume Rendering of Dural Arteriovenous Fistulae contact: Peter Hastreiter
	Polygonal models and direct volume rendering of the temporal bone and the inner ear source: Interactive Direct Volume Rendering of the Inner Ear for the Planning of Neurosurgery contact: Peter Hastreiter
	Fusion of pre--operative and intraoperative MR data showing the brain shift. source: Analysis and Visualization of the Brain Shift Phenomenon in Neurosurgery contact: Peter Hastreiter
	Fusion of pre--operative and intraoperative MR data showing the brain shift. source: Analysis and Visualization of the Brain Shift Phenomenon in Neurosurgery contact: Peter Hastreiter
	Fusion of a brain in pre--operative and intraoperative MR data showing the brain shift. source: Analysis and Visualization of the Brain Shift Phenomenon in Neurosurgery contact: Peter Hastreiter
	Direct volume rendering of the inner ear with CT. source: Interactive and Intuitive Visualization of Small and Complex Vascular Structures in MR and CT contact: Peter Hastreiter
	Interactive box clipping with arbitrary geometry. source: Interactive and Intuitive Visualization of Small and Complex Vascular Structures in MR and CT contact: Peter Hastreiter
	Direct Volume Rendering of MRA showing intracranial aneurysm. source: Interactive and Intuitive Visualization of Small and Complex Vascular Structures in MR and CT contact: Peter Hastreiter
	Spinal dural arteriovenous malformation (dAVM): (a-d) DSA and (e,f) direct volume rendering of a ``tagged'' MR 3D-CISS data set after segmentation of the marrow and the tissue containing the vessel information (arrows indicate corresponding landmarks). source: Interactive and Intuitive Visualization of Small and Complex Vascular Structures in MR and CT contact: Peter Hastreiter
	Stereo-scopic spherical projection of brain showing both hemispheres (left) - unrolled spherical projection of front and back including manually inserted markers used for the identification of specific convolutions (right). source: Efficient Representation of Cortical Convolutions for the Analysis of Brain Surface Topology contact: Peter Hastreiter
	Interactive direct volume rendering of CTA based on 3D texture mapping: aneurysm of middle cerebral artery bifurcation and related vessels. source: Fast Analysis of Intracranial Aneurysms based on Iteractive Direct Volume Rendering and CT--Angiography contact: Peter Hastreiter
	Interactive direct volume rendering of CTA based on 3D texture mapping: aneurysm of middle cerebral artery bifurcation and related vessels. source: Fast Analysis of Intracranial Aneurysms based on Iteractive Direct Volume Rendering and CT--Angiography contact: Peter Hastreiter
	Interactive direct volume rendering of CTA based on 3D texture mapping: aneurysm of middle cerebral artery bifurcation and related vessels. source: Fast Analysis of Intracranial Aneurysms based on Iteractive Direct Volume Rendering and CT--Angiography contact: Peter Hastreiter
	Interactive direct volume rendering of CTA based on 3D texture mapping: aneurysm of anterior communicating artery. source: Fast Analysis of Intracranial Aneurysms based on Iteractive Direct Volume Rendering and CT--Angiography contact: Peter Hastreiter
	Interactive direct volume rendering of CTA based on 3D texture mapping: aneurysm of anterior communicating artery. source: Fast Analysis of Intracranial Aneurysms based on Iteractive Direct Volume Rendering and CT--Angiography contact: Peter Hastreiter
	Interactive direct volume rendering of CTA based on 3D texture mapping: closer view of basilar bifurcation aneurysm showing connected vessels. source: Fast Analysis of Intracranial Aneurysms based on Iteractive Direct Volume Rendering and CT--Angiography contact: Peter Hastreiter
	Interactive direct volume rendering of CTA based on 3D texture mapping: basilar bifurcation aneurysm. source: Fast Analysis of Intracranial Aneurysms based on Iteractive Direct Volume Rendering and CT--Angiography contact: Peter Hastreiter
	3D texture mapping and OpenInventor: visualization of polygonal and voxel data. source: Intuitive and Interactive Manipulation of 3D Data Sets by Integrating Texture Mapping Based Volume Rendering into the OpenInventor Class Hierarchy contact: Peter Hastreiter
	3D texture mapping and OpenInventor: visualization of polygonal and voxel data. source: Intuitive and Interactive Manipulation of 3D Data Sets by Integrating Texture Mapping Based Volume Rendering into the OpenInventor Class Hierarchy contact: Peter Hastreiter
	3D texture mapping and OpenInventor: visualization of fMR data using tagged volumes. source: Intuitive and Interactive Manipulation of 3D Data Sets by Integrating Texture Mapping Based Volume Rendering into the OpenInventor Class Hierarchy contact: Peter Hastreiter
	3D texture mapping and OpenInventor: visualization of fMR data using tagged volumes. source: Intuitive and Interactive Manipulation of 3D Data Sets by Integrating Texture Mapping Based Volume Rendering into the OpenInventor Class Hierarchy contact: Peter Hastreiter
	3D texture mapping and OpenInventor: visualization of multiple volumes. source: Intuitive and Interactive Manipulation of 3D Data Sets by Integrating Texture Mapping Based Volume Rendering into the OpenInventor Class Hierarchy contact: Peter Hastreiter
	3D texture mapping and OpenInventor: visulization of segmented data using tags. source: Intuitive and Interactive Manipulation of 3D Data Sets by Integrating Texture Mapping Based Volume Rendering into the OpenInventor Class Hierarchy contact: Peter Hastreiter
	3D texture mapping and OpenInventor: visulization of segmented data using tags. source: Intuitive and Interactive Manipulation of 3D Data Sets by Integrating Texture Mapping Based Volume Rendering into the OpenInventor Class Hierarchy contact: Peter Hastreiter
	3D texture mapping and OpenInventor: view interior structures using of clip planes. source: Intuitive and Interactive Manipulation of 3D Data Sets by Integrating Texture Mapping Based Volume Rendering into the OpenInventor Class Hierarchy contact: Peter Hastreiter
	3D texture mapping and OpenInventor: view interior structures using of clip planes. source: Intuitive and Interactive Manipulation of 3D Data Sets by Integrating Texture Mapping Based Volume Rendering into the OpenInventor Class Hierarchy contact: Peter Hastreiter
	Fusion of DSA and an interpolated slice image of the MRA. source: Retrospective Registration of MRA and DSA based on Mutual Information contact: Peter Hastreiter
	Fusion of DSA and maximum intensity projection of MRA. source: Retrospective Registration of MRA and DSA based on Mutual Information contact: Peter Hastreiter
	Starting from the camera coordinate system the model shows the maximum intensity projection (MIP) of a MRA data set onto the DSA plain including the focal distance f and the optical shift ox and oy. source: Retrospective Registration of MRA and DSA based on Mutual Information contact: Peter Hastreiter
	Interactive direct Volume Rendering and measurement of intracranial aneurysm. source: VECTA - VIRTUAL ENDOSCOPIC CT-ANGIOGRAPHY contact: Peter Hastreiter
	Endoscopic view within intracranial vessels. source: VECTA - VIRTUAL ENDOSCOPIC CT-ANGIOGRAPHY contact: Peter Hastreiter
	Interactive direct volume rendering based on 3D textures using tags for segmented data. source: Fast and Interactive 3D--Segmentation of Medical Volume Data contact: Peter Hastreiter
	Polygonal rendering of segmented brain in MR. source: Fast and Interactive 3D--Segmentation of Medical Volume Data contact: Peter Hastreiter
	Interactive segmentation based on volume growing and immediate visualization based on 3D texture mapping. source: Fast and Interactive 3D--Segmentation of Medical Volume Data contact: Peter Hastreiter
	Direct volume rendering of brain based on 3D textures including automatically detected cortical convolutions. source: Efficient Representation of Cortical Convolutions for the Analysis of Brain Surface Topology contact: Peter Hastreiter
	Indirect volume rendering of brain including automatically detected cortical convolutions. source: Efficient Representation of Cortical Convolutions for the Analysis of Brain Surface Topology contact: Peter Hastreiter
	Indirect volume rendering of brain including automatically detected cortical convolutions. source: Efficient Representation of Cortical Convolutions for the Analysis of Brain Surface Topology contact: Peter Hastreiter
	Closing of segmented brain with smooth envelop (left) and planar representation of left and right hemisphere. source: Efficient Representation of Cortical Convolutions for the Analysis of Brain Surface Topology contact: Peter Hastreiter
	Fusion of MRA and segmented MR(T1) data based on standard ray-casting. source: Integrated Registration and Visualization of Medical Image Data contact: Peter Hastreiter
	Fusion of MR(T1) and MRA using communicating orthogonal 2D slices and magic lenses. source: Integrated Registration and Visualization of Medical Image Data contact: Peter Hastreiter
	Fusion of MR(T1) and CTA using communicating orthogonal 2D slices and magic lenses. source: Integrated Registration and Visualization of Medical Image Data contact: Peter Hastreiter
	Interactive direct volume visualization of MR(T1) and CTA after registration based on 3D texture mapping. source: Integrated Registration and Visualization of Medical Image Data contact: Peter Hastreiter
	Interactive Visualization of vessels in MRA relative to ventricles in MR(T1). source: Integrated Registration and Visualization of Medical Image Data contact: Peter Hastreiter
	Interactive Visualization of ventricles in MR(T1) relative to the vessel situation in MRA. source: Integrated Registration and Visualization of Medical Image Data contact: Peter Hastreiter
	Interactive Visualization of MR(T1) and MRA after registration. source: Integrated Registration and Visualization of Medical Image Data contact: Peter Hastreiter
	Fusion of MR(T1) and CT after registration. source: Integrated Registration and Visualization of Medical Image Data contact: Peter Hastreiter
	Fusion of MR(T1) and CT before registration. source: Integrated Registration and Visualization of Medical Image Data contact: Peter Hastreiter
	Interactive direct volume visualization of MR(T1) and CTA after registration based on 3D texture mapping. source: Integrated Registration and Visualization of Medical Image Data contact: Peter Hastreiter
	Fusion of MR(T1) and MRA using communicating orthogonal 2D slices and magic lenses. source: Integrated Registration and Visualization of Medical Image Data contact: Peter Hastreiter
	Fusion of MR(T1) and CTA using communicating orthogonal 2D slices and magic lenses. source: Integrated Registration and Visualization of Medical Image Data contact: Peter Hastreiter
	Fusion of MRA and segmented MR(T1) data based on standard ray-casting. source: Integrated Registration and Visualization of Medical Image Data contact: Peter Hastreiter

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