- Scientifically Accurate Molecular Structure
Based on the Watson-Crick DNA model (B-form double helix), with options for A-form or Z-form configurations.
Includes precisely positioned sugar-phosphate backbones and correctly paired nitrogenous bases (adenine-thymine, cytosine-guanine) with hydrogen bond detailing.
Optional histone proteins and nucleosome units for chromatin or eukaryotic DNA modeling.
- Source Options
High-resolution 3D scan of laboratory-grade physical models (if scanned from a reference).
Procedurally generated digital model (parametric design allowing for base pair adjustments, helix pitch, and strand length modifications).
- Optimized for 3D Printing & Rendering
Watertight, manifold mesh (no holes or non-printable geometry errors).
Variable LOD (Level of Detail) – Simplified for FDM printing or highly detailed for resin/SLA printing.
Pre-supported versions available for trouble-free resin 3D printing.
Scalable dimensions (from nanoscale simulation to macroscopic educational models).
- File Formats & Compatibility
Available in multiple formats for broad software compatibility:
OBJ, STL, FBX (universal 3D printing/rendering).
Blender, Maya, 3ds Max, Cinema 4D (native project files upon request).
STEP/IGES (for CAD-based scientific applications).
- Applications
Education – Classroom models, interactive biology exhibits.
Research – Molecular visualization, computational biology.
Medical & Forensics – DNA structure analysis, instructional aids.
Sci-Fi & Game Design – High-tech props, futuristic holograms.
Preview Renders
Sample images rendered in KeyShot for photorealistic accuracy.
Customization Options
Adjustable helix twist, base pair count, and supercoiling.
Optional UV unwrapping & PBR textures for realistic rendering.
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