Cardio4D Platform
Predictive cardiovascular analysis for clinicians, device innovators, and patients.
For Clinicians & Hospitals
Data-driven insight for complex cardiovascular procedures — improve outcomes, reduce uncertainty, save time.
Explore →For Medical Device Companies
Predictive cardiovascular simulation for device development — reduce cost, shorten time to market, accelerate design cycles.
Explore →For Individuals & Patients
A personal 3D virtual model of the heart — plus 3D-printed keepsakes for patients and loved ones.
Explore →For Clinicians & Hospitals
Data-driven insight for complex cardiovascular procedures
Our mission is to empower clinicians with data-driven insights that improve patient outcomes in complex cardiovascular procedures — including Thoracic Aortic Aneurysm (TAA) rupture risk analysis, Transcatheter Mitral Valve Replacement (TMVR), Transcatheter Aortic Valve Replacement (TAVR), and other structural heart interventions. By combining cutting-edge AI with deep clinical expertise, we make personalized cardiac care accessible and actionable.
Improve Patient Outcomes
Patient-specific 3D anatomy, biomechanical risk metrics, and automated measurements that inform device selection and procedural strategy.
Reduce Uncertainty
Move beyond diameter-only criteria. Quantitative wall stress, virtual implantation, and predicted device–anatomy interaction turn judgment calls into evidence-based decisions.
Reduce Time
From CT upload to interactive 3D analysis in hours, not weeks — automated AI segmentation replaces manual contouring and offline modeling.
Analysis Modules
Purpose-built analysis modules for structural heart care.
AI-Driven 3D Anatomy Reconstruction
Deep-learning segmentation with automated mesh generation for accurate anatomical visualization and measurements across all cardiac phases.
TAA Rupture Risk Analysis
Biomechanical simulation to quantify wall stress and predict rupture risk, supporting decisions on surgical repair versus continued monitoring.
Transcatheter Heart Valve Replacement & Repair
TMVR / TEER / TAVR / TTVR
Virtual implantation and biomechanical simulation for TMVR, TEER, TAVR, and TTVR to assess procedure feasibility, device efficacy, and patient-specific outcomes.
How It Works
Secure Upload
Upload de-identified DICOM or NIfTI datasets to our encrypted server.
Custom Selection
Choose 3D modeling preferences and Cardio4D analysis modules.
AI-Driven Results
Our AI segments the anatomy and generates the report. The completed analysis is available in a private portal as soon as our email notification arrives.
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Building a device? See how we support medical device companies →
For Medical Device Companies
Predictive cardiovascular simulation for device development
Drawing on deep expertise in the cardiovascular device space, we partner with established medical device companies and start-ups alike to optimize devices through high-fidelity computational simulation. Combining medical imaging with computational modeling, we build and test in-silico models that accelerate R&D — exploring a broader design space than bench or animal testing alone — while generating complementary evidence to strengthen regulatory submissions aligned with FDA and other regulatory requirements.
Reduce Cost
Replace a portion of physical prototyping and animal testing with validated simulation — more design candidates at lower cost per iteration.
Shorten Time to Market
In-silico evidence runs in parallel with bench and pre-clinical work, compressing the path from concept to regulatory submission.
Accelerate Design Cycles
Test devices across libraries of real patient anatomies and hemodynamic conditions — find failure modes and sizing gaps before the first prototype is built.
How We Support Device Teams
Support across the full development lifecycle — from first concept to clinical evidence.
Device Sizing & Design Optimization
Match device geometry to target patient anatomies and hemodynamic conditions, and quantify anatomical fit across the intended patient population.
Animal Study Planning
Refine study protocols in-silico first — reduce the number of animals required and improve the likelihood of successful outcomes.
Engineering Analysis
Evaluate device performance, durability, and failure modes under realistic physiological loading — stress, fatigue, migration, and device–tissue interaction.
Regulatory & Clinical Evidence
Generate quantitative in-silico data to support regulatory submissions, pre-clinical studies, and clinical trials, aligned with FDA, CE, ISO, and ASME V&V 40.
For Individuals & Patients
A Heart, made personal
We create a personal 3D virtual model of the heart from a cardiac CT scan — explore the anatomy in an interactive 3D webview, or hold it as a 3D-printed keepsake for patients and loved ones.
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