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The Ox-Imager CS™ is intended for use by healthcare professionals as a noninvasive tissue oxygenation measurement system that maps value of: oxygen saturation, oxy-hemoglobin, and deoxy-hemoglobin into 2D/3D visual presentations.

SyMRI is a post-processing software medical device intended for use in visualization of the brain. SyMRI analyzes input data from MR imaging systems. SyMRI utilizes data from a multi-delay, multi-echo acquisition (MDME) to generate parametric maps of R1, R2 relaxation rates, and proton density (PD). SyMRI can generate multiple image contrasts from the parametric maps. SyMRI enables post-acquisition image contrast adjustment. SyMRI is indicated for head imaging. SyMRI is also intended for automatic labeling, visualization and volumetric quantification of segmentable brain tissues from a set of MR images. Brain tissue volumes are determined based on modeling of parametric maps from MDME images. When interpreted by a trained physician, SyMRI images can provide information useful in determining diagnosis. SyMRI should always be used in combination with at least one other, conventional MR acquisition (e.g. T2-FLAIR).

SyMRI is a post-processing software medical device intended for use in visualization of the brain. SyMRI analyzes input data from MR imaging systems. SyMRI utilizes data from a multi-delay, multi-echo acquisition (MDME) to generate parametric maps of R1, R2 relaxation rates, and proton density (PD). SyMRI can generate multiple image contrasts from the parametric maps. SyMRI enables post-acquisition image contrast adjustment. SyMRI is indicated for head imaging. When interpreted by a trained physician, SyMRI images can provide information useful in determining diagnosis. SyMRI should always be used in combination with at least one other, conventional MR acquisition (e.g. T2-FLAIR).

SyMRI is a post-processing software medical device intended for use in visualization of soft tissue. SyMRI analyzes input data from MR imaging systems. SyMRI utilizes data from supported MR sequences to generate parametric maps of R1, R2 relaxation rates, and proton density (PD). SyMRI is intended for automatic labeling, visualization and volumetric quantification of segmentable brain tissues from a set of MR images. Brain tissue volumes are determined based on modeling of parametric maps from SyMRI. SyMRI can also generate multiple image contrasts from the parametric maps. SyMRI enables post-acquisition image contrast adjustment. SyMRI is indicated for head imaging. When interpreted by a trained physician, output from SyMRI can provide information useful in determining diagnosis. SyMRI 2D is intended to be used in combination with at least one other, conventional MR acquisition (e.g. T2-FLAIR). T1W and T2W images from SyMRI 3D may replace conventional MR images in a clinical setting when interpreting together with a conventional 3D T2W FLAIR image.

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

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.