Best Medical 3D Visualization Software for Nonprofit - Page 2

ExacTrac Dynamic brings together advanced tracking technologies to enhance both power and precision in medical treatments. It ensures high-precision care across a variety of patient positioning and monitoring tasks, particularly in areas such as cranial and prostate treatments. The system features groundbreaking thermal-surface camera technology that operates alongside real-time X-Ray tracking to provide exceptional accuracy. By utilizing a 4D Thermal Camera, it generates a reliable hybrid thermal surface by mapping the patient's heat signature to their reconstructed 3D structural data. This process involves the collection of 300,000 distinct 3D surface points, which are then aligned with the thermal camera's heat signals, adding a new dimension to the tracking of patient positioning. Such innovations are set to transform the landscape of precision medicine, offering even better outcomes for patients undergoing treatment.

The FDA-cleared D2P® software, in combination with 3D Systems printers, empowers surgeons, radiologists, lab technicians, and device designers to efficiently generate high-quality diagnostic digital 3D models and tangible 3D prints. By importing DICOM images into the D2P standalone modular software, all necessary steps for 3D model segmentation and preparation are streamlined into a single workstation. Designed as a medical device, D2P facilitates pre-operative surgical planning and the creation of 3D-printed anatomical models for diagnostic use. Its distinctive image segmentation toolkit, paired with sophisticated virtual reality (VR) visualization, significantly reduces the time and effort required for clinicians and point-of-care (POC) personnel to produce customized anatomical models for their patients. Furthermore, the digital models generated by D2P can be utilized across various platforms, including 3D printers, VR systems, surgical planning applications, and CAD software, enhancing the overall flexibility and effectiveness of medical practices. This innovative approach not only improves surgical preparation but also fosters collaboration among healthcare professionals by providing them with precise and accessible anatomical representations.

LarkXR is a cutting-edge enterprise-level solution for real-time 3D XR cloud streaming and rendering, transforming the hosting and delivery of immersive 3D experiences. Its standout features include exceptional streaming and rendering capabilities, the ability to pool multi-GPU resources, and ultra-low latency of under 30 milliseconds. Users can enjoy high-fidelity, high-precision 3D/XR content with resolutions ranging from 2K to 8K and frame rates between 60 to 120 FPS. The platform is designed with developers in mind, offering rich APIs and SDKs suitable for a variety of industries, along with robust second development capabilities. Deployment is quick and easy with no-code options and smooth integration into existing systems. Compatibility is extensive, supporting all major terminals and engines such as Unreal Engine, Unity, CryEngine, Unigine, and OSG, as well as XR and spatial devices including VR, AR, MR headsets, holographic displays, mobile devices, and PCs. Additionally, it accommodates web-based XR applications with WebXR and WebGL streaming support, functioning seamlessly across multiple operating systems like Windows, Linux, MacOS, Android, and iOS. The platform is built for scalability and stability, capable of supporting over 20,000 concurrent users and more than 50 million minutes of streaming, all while offering a zero-cost testing phase to users, making it an outstanding choice for enterprises looking to enhance their digital experiences. This comprehensive approach ensures that LarkXR remains at the forefront of the immersive technology landscape.

The Galileo system, created by Fourier Intelligence, is an innovative platform for research and training focused on biomechanics, rehabilitation, and sports science. It combines an array of state-of-the-art technologies, including a six-axis motion platform, force plate, LED curved screen, adaptive dual-belt treadmill, dynamic weight support, motion capture system, rehabilitation robots for both upper and lower limbs, exercise equipment, and human-computer interaction software. This comprehensive setup facilitates a versatile environment for clinical assessments and rehabilitation training, leveraging the benefits of virtual reality and robotics for both clinical and research applications. The system is effective for evaluating and treating a wide range of functional impairments in both adults and children, addressing issues such as neurological and musculoskeletal injuries, amputations, limb disabilities, cardiorespiratory dysfunction, and degenerative diseases. Additionally, its integration of advanced technology enhances the effectiveness of rehabilitation methods, making it a valuable tool in modern therapeutic practices.

Surgical Science stands out as a premier provider of medical simulation training and software solutions, with a commitment to improving patient safety and healthcare results through personalized, validated simulations. By offering high-fidelity simulations, they allow healthcare professionals to refine their skills—ranging from fundamental techniques to the management of intricate cases—safely, without exposing patients to risk. Renowned by surgeons, clinicians, and healthcare teams globally, Surgical Science's evidence-based simulations contribute to enhanced patient care on a daily basis. With over 8,000 simulators in operation, spanning more than 150 medical procedures and backed by over 400 validated studies, their influence is considerable. Their ready-to-use simulators, combined with evidence-based customizable curricula, empower healthcare professionals and teams to advance their expertise, foster professional development, and ultimately enhance the quality of patient care and safety. Furthermore, the integration of these advanced simulation tools into training programs has revolutionized the way medical professionals prepare for real-world challenges, ensuring they are equipped to provide the best possible care in critical situations.

Materialise Mimics is an all-encompassing software solution aimed at transforming medical imaging data into precise 3D models, serving a variety of purposes such as custom device development and detailed anatomical studies. This platform includes a diverse array of tools that streamline the planning, designing, and 3D printing processes for models and surgical guides tailored to different levels of complexity, enabling immediate use in clinical settings. Central to the platform is Mimics Core, a sophisticated software designed for 3D medical image segmentation that efficiently transitions from image capture to the creation of 3D models. This functionality aids in virtual procedure planning and is essential to the overall effectiveness of the platform. Additionally, the Mimics Innovation Suite expands the platform's capabilities by offering advanced resources for engineers and researchers. By simplifying the engagement with 3D medical imaging data, it becomes a valuable asset for improving patient outcomes through innovative technological applications. Ultimately, this software provides a crucial bridge between advanced imaging techniques and practical medical solutions.

MiNNOVAA is a company specializing in medical information technology, particularly in the realms of medical imaging software and the exchange of medical images. With the guiding principle of "medical imaging innovation," we stand out for our nimbleness and the state-of-the-art technology we utilize in crafting our solutions. Our main areas of concentration are the development of medical image viewers, enhancement of radiology workflows, and the incorporation of artificial intelligence in diagnostic reporting. Our energetic team comprises around 20 skilled programmers and product managers, alongside professionals in marketing, sales, technical support, call center operations, and administration, all dedicated to driving a meaningful transformation in the field of medical imaging and enhancing individual healthcare experiences. We offer a comprehensive clinical imaging IT solution tailored for mid-sized hospitals and imaging clinics, featuring a wide array of functionalities such as on-premise core PACS software, a DICOM web viewer, multi-platform imaging workstation software, seamless integration with EHR/EMR/HIS systems, and an efficient workflow engine/RIS. Ultimately, our commitment to innovation and comprehensive solutions aims to redefine how medical imaging is approached and utilized within healthcare settings.

Altris AI is an innovative clinical decision support system powered by artificial intelligence and hosted in the cloud, aimed at helping eye care professionals with the interpretation of OCT scans and clinical decision-making. This platform streamlines the identification of pathological OCT scans while being capable of recognizing over 70 different retina pathologies and biomarkers, some of which are uncommon. Among its features are the ability to assess severity, analyze retina layer thickness, segment layers, detect pathologies, and perform both automatic and manual measurements. Altris AI seamlessly works with all OCT devices and accommodates various formats such as DICOM, JPEG, and PNG. The system holds FDA clearance, CE certification, and adheres to GDPR and HIPAA regulations, ensuring robust data security and patient confidentiality. By incorporating Altris AI into their workflow, eye care practitioners can enhance patient triage, improve diagnostic precision, and more effectively track the progression of diseases, ultimately leading to better patient outcomes. Additionally, this advanced technology empowers eye care professionals to make more informed decisions, fostering an environment of improved patient care and treatment strategies.

Fujifilm's Synapse 3D represents a cutting-edge visualization solution that has been crafted in conjunction with a variety of medical professionals, including radiologists, cardiologists, and surgeons, providing more than 50 applications designed to improve both the accuracy and efficiency of diagnoses. This platform features advanced server-side technology that accommodates both cloud and on-premise hosting, enabling sophisticated image analyses that aid in interpretation, reporting, and treatment planning while promoting effective clinical collaboration throughout the organization. It addresses specialty fields such as cardiology, pulmonology, oncology, urology, neurology, and gastroenterology, showcasing its versatility. The architecture of Synapse 3D is scalable, allowing for unlimited expansion, and its reliable workflows boost overall productivity while catering to extensive visualization requirements through specialized applications. The platform also includes native cardiology features that enhance cardiac care, and its AI-driven detection capabilities significantly enhance the accuracy and efficiency of interpretations. Additionally, Synapse 3D offers seamless integration with Fujifilm's Synapse Enterprise PACS, making it an invaluable resource for healthcare providers seeking to optimize patient outcomes. With these comprehensive features, it stands to revolutionize the way medical imaging is approached in clinical settings.

AnalyzeDirect is a medical technology firm focused on research, known for its global distribution and support of Analyze, a premier software for advanced biomedical imaging that excels in visualization, manipulation, and measurement. The latest version, Analyze 15.0, provides an accessible and user-friendly interface for image visualization and analysis in medical research, incorporating advanced segmentation tools that enable quick and accurate definition of regions, comprehensive statistical analysis supported by strong measurement capabilities, and effective registration techniques for image fusion across different modalities. Additionally, it comes equipped with a wide range of display tools for reviewing and visualizing images, as well as filtering options for enhancing and optimizing image quality. This software is compatible with more than 45 file formats, including DICOM alongside various standard radiological and neurological formats, making it a preferred choice for a diverse group of users, such as physicians, researchers, educators, and graduate students affiliated with leading medical institutions, universities, pharmaceutical firms, biotech enterprises, medical device manufacturers, and contract research organizations across the globe. The extensive usability of Analyze ensures that it remains a vital resource in advancing medical imaging technologies and methodologies.

Caas MR 4D Flow is expertly crafted to efficiently extract pertinent data from 3D phase-contrast MR images with minimal effort. Utilizing these advanced images, it provides two innovative 4D Flow modules that facilitate comprehensive flow analysis, which is instrumental in the assessment and interpretation of cardiovascular MR images, as well as in strategizing the timing and nature of interventions. One of these modules focuses on evaluating blood vessels, ranging from major arteries like the aorta to smaller vessels such as those found in the kidneys, while the other specializes in assessing heart valves concerning regurgitation fraction. Among the significant outputs are the visualization of aortic blood flow presented as streamlines, pathlines, and color-coded vectors; detailed mapping of wall shear stress alongside localized wall shear stress values; measurement of pressure differences across specific segments; and the visualization and quantification of regurgitant fractions for all four heart valves, in addition to conducting 2D flow phase-contrast analyses. This comprehensive approach not only enhances understanding but also significantly aids clinicians in making informed decisions regarding patient care.

EchoPixel's True3D software platform generates a holographic digital replica of a patient's heart, which allows surgical teams to analyze and strategize using a virtual model prior to making any incisions. This innovative technology addresses the constraints of traditional 2D imaging by offering a 4D interactive holographic environment that provides real-time insights on the positioning of catheters and implantable devices in complex anatomical settings. True3D finds its application in various clinical scenarios, including congenital heart anomalies such as MAPCA, PA reconstruction, DORV, ASD, VSD, and CAVC, as well as in structural heart interventions like LAAO, transseptal cross, TMVR, and TAVR. Leading medical institutions around the globe, including Miyazaki University Hospital in Japan, have embraced this platform, which has also achieved medical device registration in Japan. By utilizing True3D, healthcare professionals can deepen their comprehension of three-dimensional anatomical relationships, which may lead to shorter procedure durations. Furthermore, the ability to visualize a patient's heart in such detail can significantly enhance preoperative planning and ultimately improve patient outcomes.

Brainlab's Elements Cranial Stereotactic Radiosurgery (SRS) represents a cutting-edge software tool aimed at simplifying the intricate planning involved in cranial surgeries, including procedures for arteriovenous malformations, pituitary adenomas, and vestibular schwannomas. This workflow incorporates automation throughout each phase, encompassing image fusion, distortion correction, object outlining, and segmentation, which collectively ensure remarkable accuracy and reliability at a submillimeter level. A standout feature is the patented 4Pi arc setup optimization, which, when paired with a volumetric modulated arc therapy algorithm tailored for radiosurgery, results in superior plan quality by delivering precisely targeted doses while sparing vital surrounding structures. The software further provides distinctive 3D visualizations and reliable dosimetric outputs, significantly improving the precision and efficiency of treatment planning. Moreover, Elements SmartBrush facilitates swift and straightforward 3D target outlining, enabling users to define volumes efficiently using only two slices, thus enhancing overall workflow productivity. This innovative approach not only streamlines the planning process but also enhances the accuracy of treatment delivery in complex cases.

Brainlab's Elements Multiple Brain Metastases SRS represents a cutting-edge software solution aimed at optimizing the planning and execution of treatment for patients suffering from multiple brain metastases. This innovative workflow allows healthcare providers to target several metastases at once without subjecting the entire brain to radiation, thus significantly shortening the duration of treatment delivery. The procedure starts with pre-planning steps that are supported by automation, which includes tasks like image fusion, distortion correction, object outlining, and segmentation; all of which enhance both the speed and precision of the planning process. The software utilizes inverse-optimized dynamic conformal arc techniques, focusing on a single isocenter to achieve highly conformal dose distributions with sharp gradients, ensuring accurate target coverage while protecting surrounding healthy tissue. This method facilitates the rapid generation of consistent, high-quality radiosurgery plans within minutes, ultimately benefiting clinicians and patients alike by reducing treatment durations and enhancing overall outcomes. Moreover, the efficiency and effectiveness of this software can lead to improved patient satisfaction and a more streamlined clinical workflow.

Brainlab's Elements Spine Stereotactic Radiosurgery (SRS) represents a cutting-edge software solution aimed at refining the management of spinal metastases. This innovative workflow features automation at each phase, encompassing anatomical mapping, curvature adjustments, and target identification, which guarantees precision and uniformity down to submillimetric levels. A distinctive algorithm addresses variations in spinal curvature, thereby improving the accuracy of image fusion. The software employs automatic segmentation of spinal anatomy through a patented synthetic tissue model that effectively identifies and labels different spine levels for accurate dose calculations. Tools for outlining spinal tumors are included for Gross Tumor Volume (GTV) contouring, along with automatic suggestions for the Clinical Target Volume (CTV) and a cropped spinal canal object in alignment with International Spine Consortium Guidelines. Furthermore, the integration of AI-driven contouring solutions allows for the swift and dependable delineation of over 200 structures, including lymph nodes. This advancement not only streamlines the treatment process but also enhances overall patient outcomes in spinal cancer management.

EMSE is a comprehensive suite of sophisticated and user-friendly software tools designed for measuring, describing, and visualizing the dynamics of the human brain, utilized globally in fields such as neuroscience, neurotechnology, and clinical neurophysiology. Our expertise lies in advanced multimodal source estimation techniques, which empower researchers to integrate EEG and MRI datasets, thus providing clearer insights into both the spatial and temporal aspects of brain activity. Traditional neuroimaging methods, like magnetic resonance imaging (MRI), excel in locating brain activity but fall short in determining the timing of events. In contrast, electroencephalography (EEG) and its related technique, Event-Related Potentials (ERPs), can pinpoint when neural events occur with remarkable precision, but they struggle with spatial localization. By merging MRI and EEG data, EMSE uniquely addresses both the "where" and "when" questions of brain activity, offering a level of detail that neither technique can achieve on its own. This innovative approach is referred to as multimodal dynamic functional brain imaging or source estimation, allowing for a deeper understanding of the brain's intricate workings. By leveraging this technology, researchers can uncover new insights into brain dynamics that were previously unattainable.

Fovia Ai's F.A.S.T. aiCockpit serves as an AI viewer that enhances navigation, visualization, and interaction with AI-generated results from various vendors and algorithms through a unified user experience that minimizes the number of clicks needed. This platform facilitates the visualization and interaction of all algorithm outcomes within a single, user-friendly interface, significantly improving the workflow for radiologists and clinical professionals. By providing physician-validated insights to AI orchestrators, PACS, and reporting systems, it adheres to the most up-to-date interoperability standards. The system is compatible with multiple AI formats, such as DICOM Structured Reports, DICOM Key Images, DICOM GSPS, and DICOM segmentation objects. Furthermore, F.A.S.T. aiCockpit boasts a cloud-ready architecture, enabling access to AI-assisted radiology results from anywhere at any time via any web-enabled browser. With just one straightforward integration, users can seamlessly complete their AI capabilities without the need to switch between various viewers, thus streamlining their overall workflow even further. This innovative approach not only enhances efficiency but also empowers healthcare professionals to make more informed decisions quickly.

HeartFlow offers a groundbreaking, non-invasive cardiac test that delivers detailed visualizations of individual coronary arteries, allowing doctors to develop more tailored treatment strategies for their patients. The process begins when a patient has a standard coronary computed tomography scan performed at a medical facility. Following this scan, the CT images are securely sent to our cloud-based system. Utilizing cutting-edge algorithms powered by artificial intelligence, we create a customized digital representation of the patient's coronary arteries. Our skilled analysts then review this model, making necessary adjustments to ensure accuracy. After finalizing the patient-specific model, the HeartFlow pathway employs physiological principles and computational fluid dynamics to analyze blood flow and compute FFRCT values throughout the model. We adhere to strict and well-established protocols throughout this entire process, ensuring uniform processing for every individual patient, which ultimately enhances the quality of care provided. This innovative approach not only improves diagnostic precision but also empowers healthcare providers to make informed decisions for optimal patient outcomes.

Founded in 2016, Infervision stands at the forefront of AI-driven medical technology, dedicated to enhancing multidisciplinary healthcare services and operations through innovative artificial intelligence solutions. Their advanced AI offerings are designed to assist healthcare professionals across a spectrum of tasks, including disease screening, diagnosis, intervention, treatment, patient management, and medical research. Among their array of solutions, InferRead CT Lung specializes in detecting lung nodules from chest CT scans, while InferRead DR Chest focuses on identifying chest abnormalities via X-ray imaging. Moreover, InferRead CT Coronary is tailored for recognizing coronary artery stenosis during coronary CT angiography, and InferRead CT Stroke is adept at triaging hemorrhages from brain CT scans. The company also provides InferRead CT Bone for spotting chest fractures in CT images and InferRead CT Pneumonia for diagnosing and managing pneumonia cases. Beyond these, their offerings extend to InferOperate, which facilitates 3D reconstruction for thoracic, liver, and urological surgical procedures, and InferCare, a tool designed for effective patient management and image follow-up. Additionally, InferScholar acts as an AI-enhanced resource for medical research, further solidifying Infervision's commitment to transforming healthcare through AI technology. This comprehensive suite of solutions positions Infervision as a pivotal player in the evolution of medical practices.

Qure.ai's qLC-Suite is a cutting-edge AI-driven tool aimed at improving the early identification and management of lung nodules, which is crucial for prompt lung cancer intervention. This solution delivers accurate measurements, thorough characterization, and 3D imaging of lung nodules, ensuring that opportunities for early treatment are not overlooked. It is capable of supporting both incidental and targeted screenings by efficiently identifying nodules and calculating their volume with just one click. Moreover, the system monitors volumetric changes over time, providing valuable insights into nodule development. The qLC-Suite is designed to integrate smoothly into current workflows, offering quick analysis and reporting that assist healthcare professionals in their decision-making processes. In addition to its analytical capabilities, it serves as a comprehensive platform for managing lung nodules, facilitating care coordination through intelligent prompts, providing hardware-agnostic image viewing for AI-enhanced chest X-rays and CT scans, enabling seamless sharing of scans across departments, and allowing for tailored notifications for cases of concern. Overall, qLC-Suite represents a significant advancement in lung cancer care, promoting timely interventions that can ultimately save lives.

INFINITY ANALYZE 7 is a user-friendly software solution tailored for camera management, capturing images, and processing them in life science, clinical, and industrial research settings. It accommodates both brightfield and fluorescence imaging modes, guaranteeing results that are reproducible, precise, and of high quality. The software boasts a variety of functions, including image processing, fluorescence acquisition, calibration settings, customizable presets, annotations, and extensive camera controls. Users are able to engage in activities such as focus stacking, image stitching, and executing numerous post-processing techniques on the acquired images. The fluorescence functionality supports both multi-channel and single-channel image acquisition, simplifying the creation of composite images from sequences. Enhanced workflow efficiency is achieved through user-defined button labels and hotkeys, which provide rapid access to presets during microscope objective switches. Additionally, users can incorporate annotations such as lines, arrows, and shapes to emphasize specific areas of interest within their images, further enriching the visual data presentation. This versatility makes INFINITY ANALYZE 7 an invaluable tool for researchers aiming for detailed and organized imaging capabilities.

Us2.ai is revolutionizing the battle against heart disease by utilizing AI-driven ultrasound software that ensures heart health can be accessible to everyone. This innovative platform provides 45 automated echo parameters, such as strain analysis, and enables real-time interpretation of 2D and Doppler images. It seamlessly integrates with any ultrasound machine, producing zero-click, comprehensive reports that maintain high accuracy and can be easily compared with expert evaluations. The AI echo copilot from Us2.ai autonomously analyzes all heart chambers through both 2D and Doppler perspectives, incorporating global reference guidelines into detailed, real-time reports. Recently, the software obtained FDA clearance for Us2.v2, which also boasts 45 automated echo parameters, including strain analysis, representing a remarkable advancement in healthcare technology. Ultimately, Us2.ai aims to democratize echocardiography, ensuring that ultrasound technology is available to individuals regardless of their location or circumstances, thereby promoting better heart health for all. This commitment to accessibility and innovation positions Us2.ai at the forefront of the medical technology landscape.

Fovia's XStream HDVR SDK Suite delivers an extensive array of tools for sophisticated visualization, allowing for effortless integration across multiple platforms, such as enterprise networks, independent workstations, and cloud-enabled mobile applications. Within this suite, users will find features like F.A.S.T. Interactive Segmentation, which supports dynamic 3D segmentation, F.A.S.T. RapidPrint for efficient volume-to-print processes, and F.A.S.T. Cloud SDK designed for advanced visualization in the cloud. These innovative tools empower the creation of tailored workflows and high-performance imaging applications that enhance user experience. Furthermore, Fovia offers a user-friendly API coupled with custom integration support, ensuring that a wide range of needs in the advanced visualization sector are effectively addressed. This commitment to versatility and user satisfaction solidifies Fovia's position as a leader in the visualization technology market.

Quickly identify the suitable landing zones for the treatment of abdominal aneurysms (EVAR), thoracic aneurysms (TEVAR), or the placement of fenestrated stents (FEVAR). All necessary metrics, including diameter, clock position, volumes, and length, can be acquired through automatically detected centerlines or 3D double oblique imaging. Manufacturer-specific stent order forms are integrated to create PDF files, allowing for straightforward email orders of required stents. Our commitment to enhancing the quality and efficiency of cardiovascular image analysis is focused on improving patient treatment outcomes. We continuously align our product offerings with the latest advancements in cardiovascular technology. This alignment allows us to deliver optimal software solutions to our clients precisely when they need them. Furthermore, we recognize the significance of comprehensive training and support to ensure all users feel confident in their analysis skills. We provide customizable training options designed to meet individual needs and preferences. By fostering a supportive learning environment, we empower our users to excel in their practice.

The BioDigital Human is a dynamic 3D software platform designed for the visualization of anatomy, diseases, and treatment processes. This innovative software transforms health information into a visual format that is not only straightforward but also captivating. Utilizing interactive 3D technology has been shown to enhance understanding and retention in the fields of anatomy, disease, and treatment education. Users can create and manage engaging visualizations to deploy across various digital platforms at significantly lower costs compared to conventional methods. With Human Studio, individuals can craft personalized visualizations, or they may collaborate with our expert services team to represent particular medical conditions and treatments. Additionally, these interactive 3D visualizations can be seamlessly integrated into any Learning Management System (LMS) or digital platform, ensuring a smooth experience for end-users. For the first time, organizations have the opportunity to enrich their health, medical, and life science education through the immersive capabilities offered by BioDigital's software. Tailoring interactive 3D models of human anatomy, physiology, diseases, and treatments for specific educational needs allows for these resources to be embedded directly within curricula or any educational material, enhancing the overall learning experience. This advancement represents a significant leap forward in how educational content can be presented and absorbed.