WebPAX® is intended for use in the communication and storage of medical images. WebPAX® is alsointended for use as a comprehensive solution to view, optimize, and post-process diagnostic medicalimages as an aid to physicians and other healthcare professionals in the evaluation of digital imagingexaminations.

Sonocubic 3D Ultrasound Software is a software intended to acquire, retrieve, analyze and store ultrasound images for computerized three-dimensional image processing, from raw 2D ultrasound series.

Sonocubic 3D Ultrasound Software is a software intended to acquire, retrieve, analyze and store ultrasound images for computerized three-dimensional image processing, from raw 2D ultrasound series.

A picture archiving and communication system software that retrieves, archives, distributes, and displays images and data from all common modalities.

A picture archiving and communication system software that retrieves, archives, distributes, and displays images and data from all common modalities.

A picture archiving and communication system software that retrieves, archives, distributes, and displays images and data from all common modalities.

A picture archiving and communication system software that retrieves, archives, distributes, and displays images and data from all common modalities.

A picture archiving and communication system software that retrieves, archives, distributes, and displays images and data from all common modalities.

A picture archiving and communication system software that retrieves, archives, distributes, and displays images and data from all common modalities.

A picture archiving and communication system software that retrieves, archives, distributes, and displays images and data from all common modalities.

A picture archiving and communication system software that retrieves, archives, distributes, and displays images and data from all common modalities.

A picture archiving and communication system software that retrieves, archives, distributes, and displays images and data from all common modalities.

OpenSight is the combination of augmented reality glasses and Novarad's medical imaging software to create three-dimensional holograms of scanned images from different modalities including CR, DX, CT, MR, and PT.

OpenSight is the combination of augmented reality glasses and Novarad's medical imaging software to create three-dimensional holograms of scanned images from different modalities including CR, DX, CT, MR, and PT.

OpenSight is the combination of augmented reality glasses and Novarad's medical imaging software to create three-dimensional holograms of scanned images from different modalities including CR, DX, CT, MR, and PT.

A self-standing software program that adds specific image processing and/or analysis capabilities to radiological DICOM image data.

The CT Sim+, 3-Arm, Red Laser is used in the simulation stage of radiation therapy to prepare a patient for treatment. The lasers can be moved to a point that defines the radiation treatment isocenter or can be used to define the center of the CT imager. The Gammex CT Sim+ is intended to read laser positioning coordinates in a DICOM or Gammex specified software format. Typically the coordinates are calculated by a Radiation Therapy Treatment Planning System (RTPS) or CT Virtual Simulation System.

The CT Sim+, 3-Arm, Green Laser is used in the simulation stage of radiation therapy to prepare a patient for treatment. The lasers can be moved to a point that defines the radiation treatment isocenter or can be used to define the center of the CT imager. The Gammex CT Sim+ is intended to read laser positioning coordinates in a DICOM or Gammex specified software format. Typically the coordinates are calculated by a Radiation Therapy Treatment Planning System (RTPS) or CT Virtual Simulation System.

The CT Sim+, 1-Arm, Red Laser is used in the simulation stage of radiation therapy to prepare a patient for treatment. The lasers can be moved to a point that defines the radiation treatment isocenter or can be used to define the center of the CT imager. The Gammex CT Sim+ is intended to read laser positioning coordinates in a DICOM or Gammex specified software format. Typically the coordinates are calculated by a Radiation Therapy Treatment Planning System (RTPS) or CT Virtual Simulation System.

The CT Sim+, 1-Arm, Green Laser is used in the simulation stage of radiation therapy to prepare a patient for treatment. The lasers can be moved to a point that defines the radiation treatment isocenter or can be used to define the center of the CT imager. The Gammex CT Sim+ is intended to read laser positioning coordinates in a DICOM or Gammex specified software format. Typically the coordinates are calculated by a Radiation Therapy Treatment Planning System (RTPS) or CT Virtual Simulation System.

The CT Sim+, 1-Arm, Blue Laser is used in the simulation stage of radiation therapy to prepare a patient for treatment. The lasers can be moved to a point that defines the radiation treatment isocenter or can be used to define the center of the CT imager. The Gammex CT Sim+ is intended to read laser positioning coordinates in a DICOM or Gammex specified software format. Typically the coordinates are calculated by a Radiation Therapy Treatment Planning System (RTPS) or CT Virtual Simulation System.

The CT Sim+, 3-Arm, Blue Laser is used in the simulation stage of radiation therapy to prepare a patient for treatment. The lasers can be moved to a point that defines the radiation treatment isocenter or can be used to define the center of the CT imager. The Gammex CT Sim+ is intended to read laser positioning coordinates in a DICOM or Gammex specified software format. Typically the coordinates are calculated by a Radiation Therapy Treatment Planning System (RTPS) or CT Virtual Simulation System.

The CT Sim+, 1-Arm, Red Laser is used in the simulation stage of radiation therapy to prepare a patient for treatment. The lasers can be moved to a point that defines the radiation treatment isocenter or can be used to define the center of the CT imager. The Gammex CT Sim+ is intended to read laser positioning coordinates in a DICOM or Gammex specified software format. Typically the coordinates are calculated by a Radiation Therapy Treatment Planning System (RTPS) or CT Virtual Simulation System.

The CT Sim+, 1-Arm, Green Laser is used in the simulation stage of radiation therapy to prepare a patient for treatment. The lasers can be moved to a point that defines the radiation treatment isocenter or can be used to define the center of the CT imager. The Gammex CT Sim+ is intended to read laser positioning coordinates in a DICOM or Gammex specified software format. Typically the coordinates are calculated by a Radiation Therapy Treatment Planning System (RTPS) or CT Virtual Simulation System.

The CT Sim+, 1-Arm, Blue Laser is used in the simulation stage of radiation therapy to prepare a patient for treatment. The lasers can be moved to a point that defines the radiation treatment isocenter or can be used to define the center of the CT imager. The Gammex CT Sim+ is intended to read laser positioning coordinates in a DICOM or Gammex specified software format. Typically the coordinates are calculated by a Radiation Therapy Treatment Planning System (RTPS) or CT Virtual Simulation System.

NeuroQ™ has been developed to aid in the assessment of human brain scans through quantification of mean pixel values lying within standardized regions of interest, and to provide quantified comparisons with brain scans derived from FDG-PET studies of defined groups having no identified neuropsychiatric disease or symptoms, i.e., asymptomatic controls (AC). The Program provides automated analysis of brain PET scans, with output that includes quantification of relative activity in 240 different brain regions, as well as measures of the magnitude and statistical significance with which activity in each region differs from mean activity values of brain regions in the AC database. The program can be used to compare activity in brain regions of individual scans between two studies from the same patient, between symmetric regions of interest within the brain PET study, and to perform an image fusion of the patients PET and CT data. The program can also be used to for assisting in the assessment of prognosis in patients undergoing dementia evaluation with respect to the likelihood of progression of symptomatic disease, to provide analysis of amyloid uptake levels in the brain, and to evaluate and to provide a quantitative analysis of uptake levels in basal ganglia structures of the brain. The program processes the studies automatically, however, user verification of output is required and manual processing capability is provided.

NeuroQ™ has been developed to aid in the assessment of human brain scans through quantification of mean pixel values lying within standardized regions of interest, and to provide quantified comparisons with brain scans derived from FDG-PET studies of defined groups having no identified neuropsychiatric disease or symptoms, i.e., asymptomatic controls (AC). The Program provides automated analysis of brain PET scans, with output that includes quantification of relative activity in 240 different brain regions, as well as measures of the magnitude and statistical significance with which activity in each region differs from mean activity values of brain regions in the AC database. The program can be used to compare activity in brain regions of individual scans between two studies from the same patient, between symmetric regions of interest within the brain PET study, and to perform an image fusion of the patients PET and CT data. The program can also be used to for assisting in the assessment of prognosis in patients undergoing dementia evaluation with respect to the likelihood of progression of symptomatic disease, to provide analysis of amyloid uptake levels in the brain, and to evaluate and to provide a quantitative analysis of uptake levels in basal ganglia structures of the brain. The program processes the studies automatically, however, user verification of output is required and manual processing capability is provided.

NeuroQ™ has been developed to aid in the assessment of human brain scans through quantification of mean pixel values lying within standardized regions of interest, and to provide quantified comparisons with brain scans derived from FDG-PET studies of defined groups having no identified neuropsychiatric disease or symptoms, i.e., asymptomatic controls (AC). The Program provides automated analysis of brain PET scans, with output that includes quantification of relative activity in 240 different brain regions, as well as measures of the magnitude and statistical significance with which activity in each region differs from mean activity values of brain regions in the AC database. The program can be used to compare activity in brain regions of individual scans between two studies from the same patient, between symmetric regions of interest within the brain PET study, and to perform an image fusion of the patients PET and CT data. The program can also be used to for assisting in the assessment of prognosis in patients undergoing dementia evaluation with respect to the likelihood of progression of symptomatic disease, to provide analysis of amyloid uptake levels in the brain, and to evaluate and to provide a quantitative analysis of uptake levels in basal ganglia structures of the brain. The program processes the studies automatically, however, user verification of output is required and manual processing capability is provided.

NeuroQ™ has been developed to aid in the assessment of human brain scans through quantification of mean pixel values lying within standardized regions of interest, and to provide quantified comparisons with brain scans derived from FDG-PET studies of defined groups having no identified neuropsychiatric disease or symptoms, i.e., asymptomatic controls (AC). The Program provides automated analysis of brain PET scans, with output that includes quantification of relative activity in 240 different brain regions, as well as measures of the magnitude and statistical significance with which activity in each region differs from mean activity values of brain regions in the AC database. The program can be used to compare activity in brain regions of individual scans between two studies from the same patient, between symmetric regions of interest within the brain PET study, and to perform an image fusion of the patients PET and CT data. The program can also be used to for assisting in the assessment of prognosis in patients undergoing dementia evaluation with respect to the likelihood of progression of symptomatic disease, to provide analysis of amyloid uptake levels in the brain, and to evaluate and to provide a quantitative analysis of uptake levels in basal ganglia structures of the brain. The program processes the studies automatically, however, user verification of output is required and manual processing capability is provided.

NeuroQ™ has been developed to aid in the assessment of human brain scans through quantification of mean pixel values lying within standardized regions of interest, and to provide quantified comparisons with brain scans derived from FDG-PET studies of defined groups having no identified neuropsychiatric disease or symptoms, i.e., asymptomatic controls (AC). The Program provides automated analysis of brain PET scans, with output that includes quantification of relative activity in 240 different brain regions, as well as measures of the magnitude and statistical significance with which activity in each region differs from mean activity values of brain regions in the AC database. The program can be used to compare activity in brain regions of individual scans between two studies from the same patient, between symmetric regions of interest within the brain PET study, and to perform an image fusion of the patients PET and CT data. The program can also be used to for assisting in the assessment of prognosis in patients undergoing dementia evaluation with respect to the likelihood of progression of symptomatic disease, to provide analysis of amyloid uptake levels in the brain, and to evaluate and to provide a quantitative analysis of uptake levels in basal ganglia structures of the brain. The program processes the studies automatically, however, user verification of output is required and manual processing capability is provided.

The Emory Cardiac Toolbox™ 4.0 is used to display gated wall motion and for quantifying parameters of left-ventricular perfusion and function from gated SPECT & PET myocardial perfusion studies and for the evaluation of dynamic PET studies. These parameters are: perfusion, ejection fraction, end-diastolic volume, end-systolic volume, myocardial mass, transient ischemic dilatation (TID), analysis of coronary blood flow and coronary flow reserve, and assessment of cardiac mechanic dyssynchrony. In addition, the program offers the capability of providing the following diagnostic information: computer assisted visual scoring, prognostic information, and expert system image interpretation. The program can also be used for the 3D alignment of coronary artery models from CT coronary angiography onto the left ventricular 3D epicardial surface and for generation of the short axis, vertical, and horizontal long axis tomograms from the SPECT raw data using either filtered backprojection (FBP) or iterative reconstruction (MLEM/OSEM). The Emory Cardiac Toolbox can be used with any of the following Myocardial SPECT Protocols: Same Day and Two Day Sestamibi, Dual-Isotope (Tc-99m/Tl-201), Tetrofosmin, and Thallium, Rubidium-82, Rubidium-82 with CT-based attenuation correction, N-13-ammonia, FDG protocols, and user defined normal databases. This program was developed to run in the .NET operating system environment which can be executed on any PC, any nuclear medicine computer system, or through a web browser. In addition, the program can be used for the decision support in interpretation and automatic structured reporting of the study. The program processes the studies automatically, however, user verification of output is required and manual processing capability is provided.

The Emory Cardiac Toolbox™ 4.0 is used to display gated wall motion and for quantifying parameters of left-ventricular perfusion and function from gated SPECT & PET myocardial perfusion studies and for the evaluation of dynamic PET studies. These parameters are: perfusion, ejection fraction, end-diastolic volume, end-systolic volume, myocardial mass, transient ischemic dilatation (TID), analysis of coronary blood flow and coronary flow reserve, and assessment of cardiac mechanic dyssynchrony. In addition, the program offers the capability of providing the following diagnostic information: computer assisted visual scoring, prognostic information, and expert system image interpretation. The program can also be used for the 3D alignment of coronary artery models from CT coronary angiography onto the left ventricular 3D epicardial surface and for generation of the short axis, vertical, and horizontal long axis tomograms from the SPECT raw data using either filtered backprojection (FBP) or iterative reconstruction (MLEM/OSEM). The Emory Cardiac Toolbox can be used with any of the following Myocardial SPECT Protocols: Same Day and Two Day Sestamibi, Dual-Isotope (Tc-99m/Tl-201), Tetrofosmin, and Thallium, Rubidium-82, Rubidium-82 with CT-based attenuation correction, N-13-ammonia, FDG protocols, and user defined normal databases. This program was developed to run in the .NET operating system environment which can be executed on any PC, any nuclear medicine computer system, or through a web browser. In addition, the program can be used for the decision support in interpretation and automatic structured reporting of the study. The program processes the studies automatically, however, user verification of output is required and manual processing capability is provided.

The Emory Cardiac Toolbox™ 4.0 is used to display gated wall motion and for quantifying parameters of left-ventricular perfusion and function from gated SPECT & PET myocardial perfusion studies and for the evaluation of dynamic PET studies. These parameters are: perfusion, ejection fraction, end-diastolic volume, end-systolic volume, myocardial mass, transient ischemic dilatation (TID), analysis of coronary blood flow and coronary flow reserve, and assessment of cardiac mechanic dyssynchrony. In addition, the program offers the capability of providing the following diagnostic information: computer assisted visual scoring, prognostic information, and expert system image interpretation. The program can also be used for the 3D alignment of coronary artery models from CT coronary angiography onto the left ventricular 3D epicardial surface and for generation of the short axis, vertical, and horizontal long axis tomograms from the SPECT raw data using either filtered backprojection (FBP) or iterative reconstruction (MLEM/OSEM). The Emory Cardiac Toolbox can be used with any of the following Myocardial SPECT Protocols: Same Day and Two Day Sestamibi, Dual-Isotope (Tc-99m/Tl-201), Tetrofosmin, and Thallium, Rubidium-82, Rubidium-82 with CT-based attenuation correction, N-13-ammonia, FDG protocols, and user defined normal databases. This program was developed to run in the .NET operating system environment which can be executed on any PC, any nuclear medicine computer system, or through a web browser. In addition, the program can be used for the decision support in interpretation and automatic structured reporting of the study. The program processes the studies automatically, however, user verification of output is required and manual processing capability is provided.

The Emory Cardiac Toolbox™ 4.0 is used to display gated wall motion and for quantifying parameters of left-ventricular perfusion and function from gated SPECT & PET myocardial perfusion studies and for the evaluation of dynamic PET studies. These parameters are: perfusion, ejection fraction, end-diastolic volume, end-systolic volume, myocardial mass, transient ischemic dilatation (TID), analysis of coronary blood flow and coronary flow reserve, and assessment of cardiac mechanic dyssynchrony. In addition, the program offers the capability of providing the following diagnostic information: computer assisted visual scoring, prognostic information, and expert system image interpretation. The program can also be used for the 3D alignment of coronary artery models from CT coronary angiography onto the left ventricular 3D epicardial surface and for generation of the short axis, vertical, and horizontal long axis tomograms from the SPECT raw data using either filtered backprojection (FBP) or iterative reconstruction (MLEM/OSEM). The Emory Cardiac Toolbox can be used with any of the following Myocardial SPECT Protocols: Same Day and Two Day Sestamibi, Dual-Isotope (Tc-99m/Tl-201), Tetrofosmin, and Thallium, Rubidium-82, Rubidium-82 with CT-based attenuation correction, N-13-ammonia, FDG protocols, and user defined normal databases. This program was developed to run in the .NET operating system environment which can be executed on any PC, any nuclear medicine computer system, or through a web browser. In addition, the program can be used for the decision support in interpretation and automatic structured reporting of the study. The program processes the studies automatically, however, user verification of output is required and manual processing capability is provided.

The Emory Cardiac Toolbox™ 4.0 is used to display gated wall motion and for quantifying parameters of left-ventricular perfusion and function from gated SPECT & PET myocardial perfusion studies and for the evaluation of dynamic PET studies. These parameters are: perfusion, ejection fraction, end-diastolic volume, end-systolic volume, myocardial mass, transient ischemic dilatation (TID), analysis of coronary blood flow and coronary flow reserve, and assessment of cardiac mechanic dyssynchrony. In addition, the program offers the capability of providing the following diagnostic information: computer assisted visual scoring, prognostic information, and expert system image interpretation. The program can also be used for the 3D alignment of coronary artery models from CT coronary angiography onto the left ventricular 3D epicardial surface and for generation of the short axis, vertical, and horizontal long axis tomograms from the SPECT raw data using either filtered backprojection (FBP) or iterative reconstruction (MLEM/OSEM). The Emory Cardiac Toolbox can be used with any of the following Myocardial SPECT Protocols: Same Day and Two Day Sestamibi, Dual-Isotope (Tc-99m/Tl-201), Tetrofosmin, and Thallium, Rubidium-82, Rubidium-82 with CT-based attenuation correction, N-13-ammonia, FDG protocols, and user defined normal databases. This program was developed to run in the .NET operating system environment which can be executed on any PC, any nuclear medicine computer system, or through a web browser. In addition, the program can be used for the decision support in interpretation and automatic structured reporting of the study. The program processes the studies automatically, however, user verification of output is required and manual processing capability is provided.