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Includes 2 VersaTek Cuffs, 1 VersaTek 2-Port Hub, Power Supply and AC Cord, CONFORMat Clinical Software CD with CONFORMat and CONFORMat Dual Maps, Help File and PDF of System Manual, (2) 5330E Sensors, 10 ft. USB Cable, (2) 25 ft. Cuff Cables, System Carrying Case, Sensor Carrying Tube, Quick Start Guide, and 1 Training Session (USA Only)

MR Diffusion Perfusion Mismatch V1.0 is an automatic calculation tool indicated for use in radiology. The device is an image processing software allowing computation of parametric maps from (1) MR Diffusion-weighted imaging (DWI) and (2) MR Perfusion-weighted imaging (PWI) and extraction of volumes of interest based on numerical thresholds applied to the aforementioned maps. Computation of mismatch between extracted volumes is automatically provided. The device is intended to assist trained radiologists and surgeons in the imaging assessment workflow by extraction and communication of metrics from MR Diffusion-weighted imaging (DWI) and MR Perfusion-weighted imaging (PWI). The results of MR Diffusion Perfusion Mismatch V1.0 are intended to be used in conjunction with other patient information and, based on professional judgment, to assist the clinician in the medical imaging assessment. MR Diffusion Perfusion Mismatch V1.0 can be integrated and deployed through technical platforms.

CT Perfusion V1.0 is an automatic calculation tool indicated for use in radiology. The device is an image processing software allowing computation of parametric maps from CT Perfusion data and extraction of volumes of interest based on numerical thresholds applied to the aforementioned maps. Computation of mismatch between extracted volumes is automatically provided. The device is intended to be used by trained professionals with medical imaging education including but not limited to, physicians and medical technicians in the imaging assessment workflow by extraction and communication of metrics from CT Perfusion dataset. The results of CT Perfusion V1.0 are intended to be used in conjunction with other patient information and, based on professional judgment, to assist the clinician in the medical imaging assessment. Trained professionals are responsible for viewing the full set of native images per the standard of care. CT Perfusion V1.0 can be integrated and deployed through technical platforms.

Provides software applications used to process, display, analyze and manage nuclear medicine and other medical imaging data transferred from other workstation or acquisition stations. The Lung Lobe Quantification module in Hybrid3D introduces an efficient and automated workflow solution to compute 3D lobar anatomy from CT (with or without contrast). Functional images (SPECT V/Q, SUV SPECT, CT iodine maps, hyperpolarized xenon MRI, etc.) can also be include in the analysis to relate lobar anatomy to function.

Provides software applications used to process, display, analyze and manage nuclear medicine and other medical imaging data transferred from other workstation or acquisition stations. The Lung Lobe Quantification module in Hybrid3D introduces an efficient and automated workflow solution to compute 3D lobar anatomy from CT (with or without contrast). Functional images (SPECT V/Q, SUV SPECT, CT iodine maps, hyperpolarized xenon MRI, etc.) can also be include in the analysis to relate lobar anatomy to function. UDI = 00859873006073 applies to Hybrid 3D version 2.x and 3.x.

TumorSight Viz is an image processing system designed to assist in the visualization and analysis, of breast DCE-MRI studies. TumorSight Viz reads DICOM magnetic resonance images. TumorSight Viz processes and displays the results on the TumorSight Viz web application. Available features support: 1) Visualization (standard image viewing tools, MIPs, and reformats) 2) Analysis (registration, subtractions, kinetic curves, parametric image maps, segmentation and 3D volume rendering) 3) Communication and storage (DICOM import, retrieval, and study storage) The TumorSight Viz system consists of proprietary software developed by SimBioSys, Inc. hosted on a cloud-based platform and accessed on an off-the-shelf computer

Includes 2 VersaTek Cuffs, 1 VersaTek Wireless Unit with Battery Pack Holder and Belt, Power Supply and AC Cord, Line Filter, CONFORMat Clinical Software CD with CONFORMat and CONFORMat Dual Maps, Help File, PDF of System Manual and Wireless software features, Pre-configured wireless router, (2) 5330E Sensors, Li-Ion Battery Pack, Battery Pack Charger and Battery Pack Charger Power Supply, 6.5 ft. Mini USB Cable, (2) 4 ft. Cuff Cables, Elastic Take-Up Belt, Elastic Belt Extension, 2 Arm/Leg Straps, 2 Velcro Cable Ties, 2 Velcro Wrist/Ankle Bands, Sensor Carrying Tube, System Carrying Case, Quick Start Guide, and 1 Training Session (USA Only)

Includes 2 VersaTek Cuffs, 1 VersaTek Wireless/Datalogger Unit with Battery Pack Holder and Belt, Power Supply and AC Cord, Line Filter, CONFORMat Clinical Software CD with CONFORMat and CONFORMat Dual Maps, Help File, PDF of System Manual, Pre-configured wireless router, (2) 5330E Sensors, Formatted Memory Stick, Li-Ion Battery Pack, Battery Pack Charger and Battery Pack Charger Power Supply, 6.5 ft. Mini USB Cable, Trigger Switch, (2) 4 ft. Cuff Cables, Elastic Take-Up Belt, Elastic Belt Extension, 2 Arm/Leg Straps, 2 Velcro Cable Ties, 2 Velcro Wrist/Ankle Bands, Sensor Carrying Tube, System Carrying Case, Quick Start Guide, and 1 Training Session (USA Only)

Includes 2 VersaTek Cuffs, 1 VersaTek Datalogger Unit with Battery Pack Holder and Belt, Power Supply and AC Cord, Line Filter, CONFORMat Clinical Software CD with CONFORMat and CONFORMat Dual Maps, Help File, PDF of System Manual and Datalogger software features, (2) 5330E Sensors, Formatted Memory Stick, Li-Ion Battery Pack, Battery Pack Charger and Battery Pack Charger Power Supply, 6.5 ft. Mini USB Cable, Trigger Switch, (2) 4 ft. Cuff Cables, Elastic Take-Up Belt, Elastic Belt Extension, 2 Arm/Leg Straps, 2 Velcro Cable Ties, 2 Velcro Wrist/Ankle Bands, Sensor Carrying Tube, System Carrying Case, Quick Start Guide, and 1 Training Session (USA Only)

STAGE is a MR post-processing software medical device intended for use in the visualization of the brain. STAGE analyzes input data from MR imaging systems. STAGE runs within a VM environment on hardware that meets the minimum requirements. STAGE utilizes magnitude and phase data acquired with specific parameters to generate enhanced T1 weighted images, SWI images, susceptibility enhanced images, pseudo-susceptibility maps, true SWI images, MR angiography (MRA) images, simulated T2 images, simulated T2 FLAIR images, simulated dual inversion recovery (DIR) images, and maps of T1, R2*, and proton density (PD). CROWN, introduced in STAGE, reduces noise some of these outputs, enhancing SNR and/or reducing imaging time. STAGE is indicated for brain imaging. Maximum and minimum intensity projections of some of these outputs will also be provided. The STAGE outputs can be configured to match the conventional acquisition series in MR protocols (i.e. routine brain w/) in terms of contrast, orientation and resolution. STAGE should always be used in combination with at least one other conventional MR acquisition technique (e.g. T2 FLAIR). STAGE input data can be acquired within a range of collection parameters, within shorter echo acquisitions allowing for less susceptibility affects and higher anatomic signal at the air tissue interface or with longer echo times for higher susceptibility effects around blood products and iron sources.

The P200TE is a non-contact scanning laser ophthalmoscope and optical coherence tomographer intended for in-vivo viewing and digital imaging of posterior ocular structures, including the retina, retinal nerve fiber layer and optic disc. The P200TE is a non-contact scanning laser ophthalmoscope and optical coherence tomographer. It is intended for in-vivo viewing, digital imaging, and analysis of posterior ocular structures, including the retina, retinal nerve fiber layer, ganglion cell complex (GCC) and optic disc, under mydriatic and non-mydriatic conditions. It is indicated for producing high resolution, ultra-widefield, en face reflectance images, autofluorescence images, axial cross-sectional images, three-dimensional images, retinal layer boundary analysis, optic nerve head analysis and thickness maps. The P200TE is indicated for use as a device to aid in the detection, diagnosis, documentation and management of retinal health and diseases that manifest in the retina.

CT CoPilot is intended for use in automating post-acquisition quantitative analysis of CT images of the brain for patients aged 18 or older. CT CoPilot performs automatic reformatting, labeling and quantification of segmentable structures from a set of CT images of the brain. Output of the software provides these values as numerical volumes and images which have been annotated with graphical color overlays, with each color representing a specific brain structure. When CT imaging is performed more than once on a patient, the current data is co-registered to the most recently processed prior exam of the same patient, facilitating comparison between the studies using CT CoPilot. Voxel-by-voxel subtraction maps of the pixel density change in Hounsfield Units (HU) are generated in up to 3 dimensions between the current and most recent processed prior exam of the patient.

cNeuro cPET aids physicians in the evaluation of patient pathologies via assessment and quantification of PET brain scans. The software aids in the assessment of human brain PET scans enabling automated analysis through quantification of tracer uptake and comparison with the corresponding tracer uptake in normal subjects. The resulting quantification is presented using volumes of interest and voxel-based maps of the brain. cNeuro cPET allows the user to generate information regarding relative changes in PET-FDG glucose metabolism. cNeuro cPET additionally allows the user to generate information regarding relative changes in PET brain amyloid load between a subject’s images and a normal database, which may be the result of brain neurodegeneration. PET co-registration and fusion display capabilities with MRI allow PET findings to be related to brain anatomy. cNeuro cPET aids physicians in the image interpretation of PET studies conducted on patients being evaluated for cognitive impairment, or other causes of cognitive decline.

LiverMultiScan (LMSv3) is indicated for use as a magnetic resonance diagnostic device software application for non-invasive liver evaluation that enables the generation, display and review of 2D magnetic resonance medical image data and pixel maps for MR relaxation times. LiverMultiScan (LMSv3) is designed to utilize DICOM 3.0 compliant magnetic resonance image datasets, acquired from compatible MR Systems, to display the internal structure of the abdomen including the liver. Other physical parameters derived from the images may also be produced. LiverMultiScan (LMSv3) provides a number of tools, such as automated liver segmentation and region of interest (ROI) placements, to be used for the assessment of selected regions of an image. Quantitative assessment of selected regions includes the determination of triglyceride fat fraction in the liver (PDFF), T2* and iron-corrected T1 (cT1) measurements. PDFF may optionally be computed using the LMS IDEAL or three-point Dixon methodology. These images and the physical parameters derived from the images, when interpreted by a trained clinician, yield information that may assist in diagnosis.

LiverMultiScan (LMSv3) is indicated for use as a magnetic resonance diagnostic device software application for non-invasive liver evaluation that enables the generation, display and review of 2D magnetic resonance medical image data and pixel maps for MR relaxation times. LiverMultiScan (LMSv3) is designed to utilize DICOM 3.0 compliant magnetic resonance image datasets, acquired from compatible MR Systems, to display the internal structure of the abdomen including the liver. Other physical parameters derived from the images may also be produced. LiverMultiScan (LMSv3) provides a number of tools, such as automated liver segmentation and region of interest (ROI) placements, to be used for the assessment of selected regions of an image. Quantitative assessment of selected regions includes the determination of triglyceride fat fraction in the liver (PDFF), T2* and iron-corrected T1 (cT1) measurements. PDFF may optionally be computed using the LMS IDEAL or three-point Dixon methodology. These images and the physical parameters derived from the images, when interpreted by a trained clinician, yield information that may assist in diagnosis.

LiverMultiScan (LMSv3) is indicated for use as a magnetic resonance diagnostic device software application for non-invasive liver evaluation that enables the generation, display and review of 2D magnetic resonance medical image data and pixel maps for MR relaxation times. LiverMultiScan (LMSv3) is designed to utilize DICOM 3.0 compliant magnetic resonance image datasets, acquired from compatible MR Systems, to display the internal structure of the abdomen including the liver. Other physical parameters derived from the images may also be produced. LiverMultiScan (LMSv3) provides a number of tools, such as automated liver segmentation and region of interest (ROI) placements, to be used for the assessment of selected regions of an image. Quantitative assessment of selected regions includes the determination of triglyceride fat fraction in the liver (PDFF), T2* and iron-corrected T1 (cT1) measurements. PDFF may optionally be computed using the LMS IDEAL or three-point Dixon methodology. These images and the physical parameters derived from the images, when interpreted by a trained clinician, yield information that may assist in diagnosis.

LiverMultiScan (LMSv3) is indicated for use as a magnetic resonance diagnostic device software application for non-invasive liver evaluation that enables the generation, display and review of 2D magnetic resonance medical image data and pixel maps for MR relaxation times. LiverMultiScan (LMSv3) is designed to utilize DICOM 3.0 compliant magnetic resonance image datasets, acquired from compatible MR Systems, to display the internal structure of the abdomen including the liver. Other physical parameters derived from the images may also be produced. LiverMultiScan (LMSv3) provides a number of tools, such as automated liver segmentation and region of interest (ROI) placements, to be used for the assessment of selected regions of an image. Quantitative assessment of selected regions includes the determination of triglyceride fat fraction in the liver (PDFF), T2* and iron-corrected T1 (cT1) measurements. PDFF may optionally be computed using the LMS IDEAL or three-point Dixon methodology. These images and the physical parameters derived from the images, when interpreted by a trained clinician, yield information that may assist in diagnosis.

LiverMultiScan v5 (LMSv5) is indicated for use as a magnetic resonance diagnostic device software application for non-invasive liver evaluation that enables the generation, display and review of 2D magnetic resonance medical image data and pixel maps for MR relaxation times. LMSv5 is designed to utilize DICOM 3.0 compliant magnetic resonance image datasets, acquired from compatible MR Systems, to display the internal structure of the abdomen including the liver. Other physical parameters derived from the images may also be produced. LMSv5 provides several tools, such as automated liver segmentation and region of interest (ROI) placements, to be used for the assessment of selected regions of an image. Quantitative assessment of selected regions includes the determination of triglyceride fat fraction in the liver (PDFF), T2*, LIC (Liver Iron Concentration) and iron corrected T1 (cT1) measurements. These images and the physical parameters derived from the images, when interpreted by a trained clinician, yield information that may assist in diagnosis.

LiverMultiScan v5 (LMSv5) is indicated for use as a magnetic resonance diagnostic device software application for non-invasive liver evaluation that enables the generation, display and review of 2D magnetic resonance medical image data and pixel maps for MR relaxation times. LMSv5 is designed to utilize DICOM 3.0 compliant magnetic resonance image datasets, acquired from compatible MR Systems, to display the internal structure of the abdomen including the liver. Other physical parameters derived from the images may also be produced. LMSv5 provides several tools, such as automated liver segmentation and region of interest (ROI) placements, to be used for the assessment of selected regions of an image. Quantitative assessment of selected regions includes the determination of triglyceride fat fraction in the liver (PDFF), T2*, LIC (Liver Iron Concentration) and iron corrected T1 (cT1) measurements. These images and the physical parameters derived from the images, when interpreted by a trained clinician, yield information that may assist in diagnosis.

LiverMultiScan (LMSv4) is indicated for use as a magnetic resonance diagnostic device software application for non-invasive liver evaluation that enables the generation, display and review of 2D magnetic resonance medical image data and pixel maps for MR relaxation times. LiverMultiScan (LMSv4) is designed to utilize DICOM 3.0 compliant magnetic resonance image datasets, acquired from compatible MR Systems, to display the internal structure of the abdomen including the liver. Other physical parameters derived from the images may also be produced. LiverMultiScan (LMSv4) provides a number of tools, such as automated liver segmentation and region of interest (ROI) placements, to be used for the assessment of selected regions of an image. Quantitative assessment of selected regions includes the determination of triglyceride fat fraction in the liver (PDFF), T2* and iron-corrected T1 (cT1) measurements. T2* may optionally be computed using the DIXON or LMS MOST methodologies. These images and the physical parameters derived from the images, when interpreted by a trained clinician, yield information that may assist in diagnosis.

Medis Suite MRCT is software intended to be used for the visualization and analysis of MR and CT images of the heart and blood vessels. Medis Suite MRCT is intended to support the following visualization functionalities: - cine loop and 2D review - double oblique review - 3D review by means of MIP and volume rendering - 3D reformatting - performing caliper measurements Medis Suite MRCT is also intended to support the following analyses: - cardiac function quantification - MR velocity-encoded flow quantification - anatomy and tissue segmentation - signal intensity analysis for the myocardium and infarct sizing - MR parametric maps (such as T1, T2, T2* relaxation) Medis Suite MRCT is also intended to be used for: - quantification of T2* results in MR images that can be used to characterize iron loading in the heart and the liver - MR velocity-encoded flow quantification of cerebral spinal fluid These analyses are based on contours that are either manually drawn by the clinician or trained medical technician who is operating the software, or automatically detected by the software and subsequently presented for review and manual editing. The results obtained are displayed on top of the images and provided in reports. The analysis results obtained with Medis Suite MRCT are intended for use by cardiologists and radiologists to support clinical decisions concerning the heart and vessels.

Medis Suite MRCT is software intended to be used for the visualization and analysis of MR and CT images of the heart and blood vessels. Medis Suite MRCT is intended to support the following visualization functionalities: - cine loop and 2D review - double oblique review - 3D review by means of MIP and volume rendering - 3D reformatting - performing caliper measurements Medis Suite MRCT is also intended to support the following analyses: - cardiac function quantification - MR velocity-encoded flow quantification - anatomy and tissue segmentation - signal intensity analysis for the myocardium and infarct sizing - MR parametric maps (such as T1, T2, T2* relaxation) Medis Suite MRCT is also intended to be used for: - quantification of T2* results in MR images that can be used to characterize iron loading in the heart and the liver - MR velocity-encoded flow quantification of cerebral spinal fluid These analyses are based on contours that are either manually drawn by the clinician or trained medical technician who is operating the software, or automatically detected by the software and subsequently presented for review and manual editing. The results obtained are displayed on top of the images and provided in reports. The analysis results obtained with Medis Suite MRCT are intended for use by cardiologists and radiologists to support clinical decisions concerning the heart and vessels.

The nordicBrainEx Software is a post-processing application for dynamic MRI data developed with focus on ease of use and high performance on a standard Windows workstation. The software provides comprehensive functionality for dynamic image analysis and visualization of MRI data, where signal changes over time are analyzed to determine various modality dependent functional parameters. The following algorithms provide the main functional analyses of the application. - BOLD: BOLD fMRI analysis is used to highlight small magnetic susceptibility changes in the human brain in areas with altered blood-flow resulting from neuronal activity. - DTI: Diffusion analysis is used to visualize local water diffusion properties from the analysis of diffusion-weighted MRI data. Fiber tracking utilizes the directional dependency of the diffusion to display the white matter structure in the brain. - DSC: Calculations of perfusion related parameters that provide information about the blood vessel structure and characteristics. Examples of such maps are blood volume, blood flow, time to peak, mean transit time and leakage. In addition to these specific functional analyses, the application also provides general visualization tools, a database for data handling, and a reporting feature. This is to ensure that the workflow of the application is optimized to ensure efficiency and high throughput in a clinical environment.

RSI-MRI+ is standalone software that is used by radiologists, urologists, and other clinicians to assist with analysis and interpretation of medical images. RSI-MRI+ accepts DICOM images using supported protocols and performs automatic post-acquisition analysis of diffusion-weighted magnetic resonance imaging (DWI) data and optional automated fusion of derived image data with anatomical T2-weighted MR images. Some of the features of RSI-MRI+ include: • Restricted Signal Map: The derived image data produced by RSI-MRI+ includes an enhanced DWI map (the Restricted Signal Map), which demonstrates improved conspicuity of restricted diffusion compared to standard DWI maps. • Color Fusion Series: RSI-MRI+ can be configured to produce a color fusion series which overlays the Restricted Signal Map intensity onto the anatomical T2-weighted image series. • Automated Prostate Segmentation: RSI-MRI+ uses artificial intelligence (AI) powered by a deep learning algorithm to automatically segment the prostate on anatomical T2-weighted images. The segmentation result is provided in the separate Prostate Segmentation Series. • Automated Segmentation Report: RSI-MRI+ generates a report of segmentation volume and images of the segmented prostate as a colored outline on the anatomical image. • Export: RSI-MRI+ outputs are provided in standard DICOM format, which is compatible with most third-party commercial PACS workstation software. NOTE: The RSI-MRI+ supported protocols differ from PI-RADS v2.1 in that they have lower inplane resolution for T2W images and thicker slices for the GE DW

Medis Suite MRCT is software intended to be used for the visualization and analysis of MR and CT images of the heart and blood vessels. This includes: - double oblique review of MR Angiographic images, - 3D review by means of MIP and volume rendering, - 3D reformatting of MR Angiographic images, and - performing caliper measurements. Medis Suite MRCT is intended to support the following visualization functionalities: - cine loop and 2D review - performing caliper measurements Medis Suite MRCT is also intended to support the following analyses: - cardiac function quantification - anatomy and tissue segmentation - signal intensity analysis for the myocardium and infarct sizing - MR parametric maps (such as T1, T2, T2* relaxation) - MR velocity-encoded flow quantification Medis Suite MRCT is also intended to be used for: - quantification of T2* results in MR images that can be used to characterize iron loading in the heart and the liver - MR velocity-encoded flow quantification of cerebral spinal fluid These analyses are based on contours that are either manually drawn by the clinician or trained medical technician who is operating the software, or automatically detected by the software and subsequently presented for review and manual editing. The results obtained are displayed on top of the images and provided in reports. The analysis results obtained with Medis Suite MRCT are intended for use by cardiologists and radiologists: - to support clinical decisions concerning the heart and vessels, and - to support the evaluation of interventions or drug therapy applied for conditions of the heart and vessels.