UniSyn is a software application for image registration and fusion display of scanned image data from CT, PET, SPECT, MR and other medical scanners. It is to be used by qualified radiology and nuclear medicine professionals. UniSyn creates multi-planar reformat and maximum intensity projection displays of the data and provides measurements such as area, volume and Standard Uptake Values for user defined regions on the image.

UniSyn is a software application for image registration and fusion display of scanned image data from CT, PET, SPECT, MR and other medical scanners. It is to be used by qualified radiology and nuclear medicine professionals. UniSyn creates multi-planar reformat and maximum intensity projection displays of the data and provides measurements such as area, volume and Standard Uptake Values for user defined regions on the image.

UniSyn is a software application for image registration and fusion display of scanned image data from CT, PET, SPECT, MR and other medical scanners. It is to be used by qualified radiology and nuclear medicine professionals. UniSyn creates multi-planar reformat and maximum intensity projection displays of the data and provides measurements such as area, volume and Standard Uptake Values for user defined regions on the image.

The I-Q View is a software package to be used with FDA cleared solid-state imaging receptors. It functions as a diagnostic x-ray image acquisition platform and allows these images to be transferred to hard copy, softcopy, and archive devices via DICOM protocol.

icobrain mr is intended for automatic labeling, visualization and volumetric quantification of segmentable brain structures from a set of MR images. This software is intended to automate the current manual process of identifying, labeling and quantifying the volume of segmentable brain structures identified on MR images.icobrain mr consists of two distinct image processing pipelines: icobrain mr cross and icobrain mr long.icobrain mr cross is intended to provide volumes from images acquired at a single timepointicobrain mr long is intended to provide changes in volumes between two images that were acquired on the same scanner, with the same image acquisition protocol and with same contrast at two different timepointsThe results of icobrain mr cross cannot be compared with the results of icobrain mr long.

icobrain mr is intended for automatic labeling, visualization and volumetric quantification of segmentable brain structures from a set of MR images. This software is intended to automate the current manual process of identifying, labeling and quantifying the volume of segmentable brain structures identified on MR images.icobrain mr consists of two distinct image processing pipelines: icobrain mr cross and icobrain mr long.icobrain mr cross is intended to provide volumes from images acquired at a single timepointicobrain mr long is intended to provide changes in volumes between two images that were acquired on the same scanner, with the same image acquisition protocol and with same contrast at two different timepointsThe results of icobrain mr cross cannot be compared with the results of icobrain mr long.

icobrain mr is intended for automatic labeling, visualization and volumetric quantification of segmentable brain structures from a set of MR images. This software is intended to automate the current manual process of identifying, labeling and quantifying the volume of segmentable brain structures identified on MR images.icobrain mr consists of two distinct image processing pipelines: icobrain mr cross and icobrain mr long.icobrain mr cross is intended to provide volumes from images acquired at a single timepointicobrain mr long is intended to provide changes in volumes between two images that were acquired on the same scanner, with the same image acquisition protocol and with same contrast at two different timepointsThe results of icobrain mr cross cannot be compared with the results of icobrain mr long.

icobrain mr is intended for automatic labeling, visualization and volumetric quantification of segmentable brain structures from a set of MR images. This software is intended to automate the current manual process of identifying, labeling and quantifying the volume of segmentable brain structures identified on MR images.icobrain mr consists of two distinct image processing pipelines: icobrain mr cross and icobrain mr long.icobrain mr cross is intended to provide volumes from images acquired at a single timepointicobrain mr long is intended to provide changes in volumes between two images that were acquired on the same scanner, with the same image acquisition protocol and with same contrast at two different timepointsThe results of icobrain mr cross cannot be compared with the results of icobrain mr long.

iQ-SYSTEM PACS is a software for network or web-based medical image viewing and manipulation. It is adapted for storing, processing, routing and reporting.

Ikshana is a software device to display medical images. It includes functions for image review, image manipulation, measurements, and 3D visualization. Medical images may only be interpreted using an FDA-cleared display monitor that meets technical specifications that are reviewed and accepted by the FDA. Ikshana is intended to be used as an adjunct to the interpretation of images performed using diagnostic imaging systems and is not intended for primary diagnosis. Display monitors used for reading medical images for diagnostic purposes must be FDA-approved radiology monitors.Ikshana software is indicated for use by qualified healthcare professionals, including, but not restricted to, radiologists, non-radiology specialists, physicians, and technologists.When accessing the Ikshana software from a wireless stereoscopic head-mounted display (HMD) or mobile device, the images viewed are for informational purposes only and are not intended for diagnostic use.

ImmersiveTouch is a stand-alone modular software package that allows users to import, visualize, and segment medical images to create accurate 3D representations.

Rapid System Update

Rapid System Update

Rapid System Update

Rapid System Update

Rapid System Update

The Pre-Sure patient modeling system is a method for the creation of patient models. Importantly, and unlike other 3D modeling systems, in the Pre-Sure process the design and production of patient models is performed by Lazarus 3D or its affiliates (with physician input), and not by the End User.The Pre-Sure software process is FDA cleared for the analysis of patient radiological data to create a digital patient design, referred to as a “Digital Twin”. Digital Twins can be used by End Users, when viewed in an appropriately cleared viewing program, for a variety of uses including training, education, and surgical planning.Patient specific Digital Twins may be further used as an input to a 3D printing-based production process performed by Lazarus 3D. This process creates physical patient models, referred to as Pre-Sure models. Each individual patient’s model can be created rapidly from the patient’s radiological data. The resulting physical models of patient anatomy are primarily composed of silicone materials that can be cut, can be sutured, and in some cases can even bleed, and of hard plastic materials that can be sawed, drilled, and can accept screws.End Users of the Preoperative Surgical Rehearsal (Pre-Sure) device receive digital and/or physical patient anatomical models from Lazarus 3D. Digital models may be viewed by End Users using any program cleared for their intended use. The physical models are intended for adjunctive use along with other diagnostic tools and expert clinical judgment for diagnosis, patient management, and/or treatment selection for genitourinary, cardiovascular, craniofacial, gastrointestinal, neurological, musculoskeletal, respiratory, and pediatric applications.

End Users of the PRE-SURE device receive digital and/or physical patient anatomical models from Lazarus 3D. The physical models are intended for adjunctive use along with other diagnostic tools and expert clinical judgement for diagnosis, patient management, and/or treatment selection of genitourinary applications. Digital models may be viewed by End Users using any program cleared for their intended use. The PRE-SURE patient modeling system is a method for the creation of patient models. This system will be used exclusively by Lazarus 3D, with some physician input and feedback, to produce models for End Users. Importantly, and unlike other 3D modeling systems, in the PRE-SURE process the design and production of patient models is performed by Lazarus 3D and not by the End User or a third party. The internal process within Lazarus 3D used for creating PRE-SURE patient models includes use of an FDA cleared stand-alone software package. As a part of the PRE-SURE production process, this software is intended for internal use within Lazarus 3D to create digital anatomical models from patient radiological data that can be used by End Users for a variety of uses such as training, education, and pre-operative surgical planning. The patient specific digital anatomical models may be further used as an input to a 3D printing-based production process performed by Lazarus 3D to create physical patient models. Each individual patient’s model can be created rapidly from the patient’s radiological data using Lazarus 3D’s patented rapid prototyping technology. The resulting physical models of patient anatomy are primarily composed of silicone materials that can be cut, can be sutured, and in some cases can even bleed.

Diagnostic web DICOM viewer

Diagnostic web DICOM viewer

Diagnostic web DICOM viewer

Diagnostic web DICOM viewer

Olea S.I.A. Neurovascular V1.0 is an optional user interface for use on the Olea Medical technical integration platform Olea S.I.A. V1.0 and is designed to be used by trained professionals with medical imaging education including, but not limited to, physicians and medical technicians.Olea S.I.A. Neurovascular V1.0 is intended to:• display MR and CT series and outputs provided by compatible docker applications processing, through the technical integration platform,• allow the user to edit and modify parameters that are optional inputs of aforementioned applications. These modified parameters are provided through the technical integration platform as inputs to the docker application to reprocess outputs. When available, Olea S.I.A. Neurovascular V1.0 display can be updated with the reprocessed outputs.The information displayed is intended to be used in conjunction with other patient information and based on professional judgment, to assist the clinician in the medical imaging assessment. It is not intended to be used in lieu of the standard care imaging.Trained professionals are responsible for viewing the full set of native images per the standard of care.

MR DWI/FLAIR Measurement V1.0 is an image processing application indicated for use in the analysis of:(1) MR Diffusion-weighted imaging (DWI)(2) MR FLAIR images.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:• computation of the map relative to the water diffusion, i.e., ADC map;• extraction and communication of metrics derived from the above map, i.e., hypointense area on ADC, and FLAIR series as well as ratios with contralateral information on FLAIR images.The results of MR DWI/FLAIR Measurement 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. MR DWI/FLAIR Measurement 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.

MRCP+ v2 is a standalone software medical device. The purpose of the MRCP+ v2 device is to assist a trained operator with the quantitative evaluation of biliary system structures acquired from magnetic resonance (MR) images from a single time-point (a patient visit). A Perspectum-trained operator loads previously acquired magnetic resonance cholangiopancreatography (MRCP) data as input into the MRCP+ v2 device. A structured summary report is generated as output by the device, which includes quantitative analysis results and geometric characteristics of the biliary system and pancreatic ducts. The MRCP+ v2 report is intended to facilitate reporting by a radiologist for subsequent interpretation and to aid diagnosis by a physician as part of a panel of testing, including conventional radiological tools.

RamSoft Gateway

OmegaAI Image Viewer is designed to access, process, manipulate medical images or videos created from diagnostic imaging systems such as X-ray, Nuclear medicine, MRI, Ultrasound, laboratory systems, and images from other sources such as handheld devices and cameras, endoscopy or other sources of images and videos. It can perform various image manipulation activities and store the modifications as presentation state along with the original study for future reference. The OmegaAI Image Viewer allows users to perform image manipulations using the Adjustment Tools, including window level, rotate, flip, pan, stack roll, and magnify. Notably, users have access to Markup Tools such as annotate, angle, cobb angle, probe, Mark ROI, and measurement. The OmegaAI Image Viewer is also capable of organizing all the captured images for a patient and presenting them in a web user interface, allowing the user to view images in their preferred layout and enabling them to compare current images with prior images of the respective patient. Available on popular mobile and desktop platforms with keyboard, mouse, and touch inputs, the OmegaAI Image Viewer provides access to medical images in a convenient way for health care professionals to use as a diagnostic viewer and for review purposes. OmegaAI Image Viewer supports major desktop and mobile browsers such as Microsoft Edge, Chrome, Safari, Apple iOS, Android.

OmegaAI Image Viewer is designed to view and manipulate medical images or videos created from diagnostic imaging systems such as X-ray, Computed tomography, Nuclear medicine, MRI, Ultrasound, laboratory systems, and images from other sources such as handheld devices and cameras, endoscopy or other sources of images and videos. It can perform various image manipulation activities and store the modifications as presentation state along with the original study for future reference. OmegaAI Image Viewer allows users to perform image manipulations using the Adjustment Tools, including window level, rotate, flip, pan, stack scroll, and magnify. Notably, users have access to Markup Tools such as annotate, angle, cobb angle, probe, Mark ROI, and measurement. OmegaAI Image Viewer is also capable of organizing all the captured images for a patient and presenting them in a zero-footprint, web user interface, allowing the users to view images in their preferred layout and enabling them to compare current images with prior images of the respective patient.

OmegaAI Image Viewer is designed to access, process, manipulate medical images or videos created from diagnostic imaging systems such as X-ray, Nuclear medicine, MRI, Ultrasound, laboratory systems, and images from other sources such as handheld devices and cameras, endoscopy or other sources of images and videos. It can perform various image manipulation activities and store the modifications as presentation state along with the original study for future reference.The OmegaAI Image Viewer allows users to perform image manipulations using the Adjustment Tools, including window level, rotate, flip, pan, stack roll, and magnify. Notably, users have access to Markup Tools such as annotate, angle, cobb angle, probe, Mark ROI, and measurement.The OmegaAI Image Viewer is also capable of organizing all the captured images for a patient and presenting them in a web user interface, allowing the user to view images in their preferred layout and enabling them to compare current images with prior images of the respective patient.Available on popular mobile and desktop platforms with keyboard, mouse, and touch inputs, the OmegaAI Image Viewer provides access to medical images in a convenient way for health care professionals to use as a diagnostic viewer and for review purposes.OmegaAI Image Viewer supports major desktop and mobile browsers such as Microsoft Edge, Chrome, Safari, Apple iOS, Android.

Gateway is a stand-alone DICOM compliant workstation that views, edits, manipulates, annotates, analyzes, stores, and distributes images and data. Gateway provides the user with the ability to import, transmit, print, display, store, edit, and process medical images and data.

PowerServer is a scalable storage and distribution system for clinical images and data. Images can be stored in lossless or lossy formats. The system is DICOM compliant for image storage, archiving, retrieval, and transmission, and communicates with other DICOM devices. The system also communicates with PowerReader workstations and PowerCache servers. Acquired image data is preserved as captured and changes to display definitions are saved as presentation states so that images may always be reverted back to their initial state. PowerCache is a caching server that communicates with PowerServer and serves PowerReader workstations. A single PowerCache can serve multiple PowerReader workstations, reducing network traffic between PowerReader workstations and PowerServer.PowerReader is a workstation that views, edits, manipulates, annotates, analyzes, stores, and distributes images and data stored on PowerServer and PowerCache. PowerReader can connect directly to PowerServer and can also connect via PowerCache. PowerReader provides the user with the ability to import, transmit, print, display, store, edit, and process medical images and data.Gateway is a stand-alone DICOM compliant workstation that views, edits, manipulates, annotates, analyzes, stores, and distributes images and data. Gateway provides the user with the ability to import, transmit, print, display, store, edit, and process medical images and data

RamSoft PACS is a stand-alone software package that is used on general purpose computing hardware. As long as minimum hardware requirements are met, the user or system integrator is free to choose his/her own hardware platform. The software allows digital image processing, measurement, communication. and storage. RamSoft PACS is tested according to the specifications that are documented in a RamSoft PACS System Test Plan. Testing is an integral part of RamSoft's software development process. The software does not contact the patient, nor does it control any life-sustaining devices. A physician has ample opportunity for competent human intervention while interpreting images and clinical information.

PS RISPACS

A dedicated computerized radiology information system (RIS) designed to electronically receive, collect, store, manage, assist in analysis of, display, output, and distribute data, within or between healthcare facilities, to support the administrative and clinical activities associated with the provision and utilization of radiology services and facilities. It may be used for patient scheduling and generation of work lists for specific radiological systems, and in conjunction with a picture archiving and communication system (PACS). The system consists of dedicated combined hardware (e.g., computers, terminals, network components) and software (typically embedded).

ClearRead CT Console

ClearRead CT Server

ClearRead CT Console

ClearRead CT Server

ClearRead CT Console

ClearRead CT Server

ClearRead CT Console

ClearRead CT Server

ClearRead CT Server

ClearRead CT Server