Advanced Visualization

The basic features of the Autobone Xpress software are introduced. Autobone Xpress is a CT image post processing application dedicated to the automatic segmentation of bones from CT Angiography Data.

One Click and Two Clicks Advanced Vessel Analysis for CT and the linked views.

Stenosis measurements and summary table.

Review Settings & Set Symmetry Steps of the CT Perfusion 4D Software focusing on the CT Brain Stroke Protocol.

Functional Maps of the CT Perfusion 4D Software focusing on the CT Brain Stroke Protocol.

Basic Review, Lesion & Liver segmentation features of Hepatic VCAR, a CT post-processing software dedicated to advanced analysis of liver pathology and morphology.

Virtual Scalpel segment separation feature of Hepatic VCAR.

Portal Vein Segment Separation and VR Compare features of Hepatic VCAR.

Baseline set up of the OncoQuant Software.

OncoQuant Part I and focuses on a liver follow-up examination.

Stroke VCAR is a CT image SW dedicated to the analysis of Brain Hematoma and Aneurysms. Brain Hematoma segmentation and clinical report workflows.

Stroke VCAR is a CT image SW dedicated to the analysis of Brain Hematoma and Aneurysms. Aneurysm segmentation and clinical report workflows.

Basic Review and Parenchyma Analysis feature of the Thoracic VCAR Software.

Lobe Segmentation feature of the Thoracic VCAR Software.

Overview of the Volume Viewer protocols page and how to configure it.

Basic functions in the GEN-IQ application are used to do a pharmacokinetic analysis of a dynamic contrast enhanced brain image series. It also shows how save the calculate parameter maps, and how to generate image fusion between a calculated parameter map and an anatomic image.

Basic functions in the GEN-IQ application is used to do a pharmacokinetic analysis of a dynamic contrast enhanced prostate image series. It also shows how to save the calculated parameter maps, and how to generate image fusion between a calculated parameter map and an anatomic image.

Demonstration on using the predefined protocol 3D SynchroView to display and review multiple image series simultaneously. Some of the features of the 3D VolumeViewer are also demonstrated.

How to do a multi oblique reformation of an 3D anatomic image volume. It also shows how to save the results using Batch.

How to generate volume rendering using segment to demonstrate the vascular tree after a 3D TOF -Time-Of-Flight scan. It also shows how to save the results using Batch.

Basic functions in the ReadyView application, MR Standard, are shown. It is used to perform perfusion calculation in anatomies outside of the brain, and in this video it is applied to the prostate. It also shows how to save the calculate parameter maps, and how to generate image fusion between a calculated parameter map and an anatomic image.

How to post process a diffusion tensor image series. ReadyView is used to generate parametric maps (e.g. FA-Fractional Anisotropy, Average DC, Isotropic, Trace…) and to do Fibertrak/tractography. It also shows how save the calculate parameter maps, and how to generate screen capture of generated fiber tracks.

Perform ADC calculation and perfusion calculation in the same workflow is demonstrated. Also shows how to save the calculated parameter maps and generate image fusion between a calculated parameter map and an anatomic image.

Calculation of ADC maps is described. It also shows how save the calculate parameter maps, and how to generate image fusion between a calculated parameter map and an anatomic image.

Simultaneously post process several types of different functional image volumes. ReadyView is used to perform ADC/diffusion, Arterial Spin Labeling (ASL)-perfusion and Gd / contrast media based perfusion.

Calculation of T2* perfusion parameter maps is described. It also shows how save the calculate parameter maps, and how to generate image fusion between a calculated parameter map and an anatomic image.

Calculation of T2* / R2* relaxation, nickname StarMap, is described. It also shows how save the calculate parameter maps.

Basic functions in the SER application is used to calculate perfusion maps following using a dynamic contrast enhanced T1w image series. It also shows how save the calculated parameter maps.

How to create a MIP- Maximum Intensity Projection from a 3D TOF-time of flight image volume. It also shows how to save the results using Batch.

Multiphase image series generated with the TRICKS application is reviewed using the predefined protocol - 3D SynchroView. It also shows how to save selected phases as MIPs using Batch mode.

Auto-select Segmentation Tools which are part of the Volume Viewer software.

The DaTQuant application enables visual evaluation and quantification of 123I-ioflupane (DaTscan) images. DaTQuant Normal Database enables quantification relative to normal population databases of 123I-ioflupane (DaTscan) images. This application may assist in detection of loss of functional dopaminergic neuron terminals in the striatum, which is correlated with Parkinson’s disease

PET VCAR (Volume Computer Assisted Reading) is a PET/CT software package fully integrated within the GE oncology platform, OncoQuant*, to help improve visualization and analytical monitoring of disease progression or response to treatment or therapy using multi-exam comparison. PET VCAR can also be used by the clinician to assist in diagnosis, staging, treatment planning and monitoring treatment response.

PET VCAR (Volume Computer Assisted Reading) is a PET/CT software package fully integrated within the GE oncology platform, OncoQuant*, to help improve visualization and analytical monitoring of disease progression or response to treatment or therapy using multi-exam comparison. PET VCAR can also be used by the clinician to assist in diagnosis, staging, treatment planning and monitoring treatment response.

Q.Check provides the user with a noninvasive systematic method to display, compare and highlight the key aspects of an exam affecting SUV variability and gauge the quality of the studies based on PERCIST or user preferences criteria. The determination of SUV is dependent on identical patient preparation and adequate scan quality that is similar between the baseline and follow-up studies. Absolute and rigorous standardization of the protocol for PET is required to achieve reproducible SUVs. The Q.Check function helps the user to check and validate the acquisition parameters between the baseline and the follow-up studies. Major differences between the studies are highlighted for the user's consideration. Highlights criteria are following PERCIST 1.0 requirements. The Q.Check can be exported as comma-separated values file (CSV) for further analysis on the user's PC using standard office tools such as Microsoft® Excel®.

PET VCAR (Volume Computer Assisted Reading) is a PET/CT software package fully integrated within the GE oncology platform, OncoQuant*, to help improve visualization and analytical monitoring of disease progression or response to treatment or therapy using multi-exam comparison. PET VCAR can also be used by the clinician to assist in diagnosis, staging, treatment planning and monitoring treatment response.

The Q.Brain application features automated analysis through quantification of tracer uptake and comparison with the corresponding tracer uptake in control subjects. The resulting quantification is presented using volume of interest, voxel-based and 3D Stereotactic Surface Projection (3DSSP) maps of the brain. Q.Brain image analysis standardizes individual brain shapes into a standard atlas shape while preserving the functional information measured by SPECT and PET imaging. SPECT/PET co-registration to MR and fusion display capabilities allows functional findings to be related to anatomy, and offers visualization of structural abnormalities.

The DaTQuant application enables visual evaluation and quantification of 123I-ioflupane (DaTscan) images. DaTQuant Normal Database enables quantification relative to normal population databases of 123I-ioflupane (DaTscan) images. This application may assist in detection of loss of functional dopaminergic neuron terminals in the striatum, which is correlated with Parkinson’s disease.

Describes the use of FlightPlan For Liver software to plan a liver embolization procedure. It describes how to use a Cone Beam CT acquisition on the AW to automatically highlights vessels traveling to the tumor's vicinity through an intuitive 3-step workflow.

Describes the use of FlightPlan For Liver software to plan a liver embolization procedure in a specific case with 2 tumor targets.

Describes the use of Vision 2 software to guide a liver embolization procedure. It describes the single-click fusion imaging between the live fluoroscopic image and the vessels highlighted to facilitate catheter selection and guidance in complex vascular anatomies for a higher selectivity in liver embolization procedures.

Describes the use of Trajectory Planning software to plan an osteosynthesis. It describes how to use a Cone Beam CT acquisition on the AW to define optimal needle entry points and pathways directly on oblique CBCT cross sections.

Describes the use of TrackVision 2 software to guide an osteosynthesis. The needle advancement can be visualized down a planned trajectory overlaid with live fluoroscopy.

Describes the use of Stereo 3D software to assess the needle position in case of an osteosynthesis. Stereo 3D reconstructs a needle in 3D from 2 fluoroscopic images.

Describes the use of Stereo 3D software to assess the needle position in case of an osteosynthesis. In this specific case, the needle is not tracked automatically and the workflow to identify the needle manually is described.