Our Technology
Grounded in MEW technology and validated by research, VivoTex scaffolds provide reproducible, human-relevant models that accelerate discovery and improve outcomes.
Why Choose VivoTex
Precision Microfiber Scaffolds
Engineered with micron-level accuracy to deliver highly reproducible architectures for advanced in-vitro models.
Accelerate Your Research
Improve optimization time with ready-to-use scaffolds designed to deliver consistent biological performance from day one.
Synthetic ECM That Behaves Like Native Tissue
Our geometry-driven MEW and electrospun scaffolds mimic native tissue microenvironments, enabling more physiologically relevant results.
Scale Without Compromise
From prototype to high-volume production, we deliver consistent quality at every scale.
Tunable to Your Applications
Get tailored fiber architectures, materials, and formats—without the burden of in-house fabrication.
Direct Access to the Inventors of MEW
Work closely with our decades-experienced team to solve technical challenges, refine applications, and accelerate project success.
Precisely controlled MEW micro-architecture facilitates cell–cell interactions that are critical for tissue organization & function.
Scaffold geometry, including fiber diameter, spacing, and orientation can be precisely tuned to guide cell migration & infiltration.
MEW scaffolds are fabricated with defined geometry, delivered sterile & ready to use, with a team ready to support your success.
High-precision fabrication delivers uniform fiber placement & scaffold geometry, enabling consistent experimental outcomes.
Our scaffolds provide mechanical integrity & stability, improving handling during seeding, culture, & downstream analysis.
Inside the Technology
Fully Customizable Fiber Diameters
VivoTex’s melt electrowriting (MEW) technology provides micron-level control over fiber placement, spacing, and orientation—far beyond the precision of traditional FDM printing. This allows researchers to design scaffolds that closely replicate native ECM architectures, supporting highly reproducible and physiologically relevant models for advanced tissue research.
Minimum 100 µm Pore Spacing
Engineered for accuracy, VivoTex scaffolds achieve consistent pore sizes down to 100 µm—ideal for promoting nutrient diffusion, cell attachment, and organized growth. This precision enables tunable microenvironments for diverse applications, including tissue engineering, regenerative medicine, and oncology research.
Customizable Scaffold Designs
Every study is different. VivoTex scaffolds can be tailored to replicate specific tissue microenvironments through adjustments in porosity, fiber diameter, and mechanical properties. This flexibility empowers researchers to model skin, bone, vascular, and cancer tissues with high structural fidelity and reproducibility.
Precise Manufacturing at Scale
VivoTex combines the precision of laboratory-grade fabrication with scalable production. Each scaffold maintains consistent architecture and performance, ensuring research reliability from pilot studies to large-scale applications—without compromising micro-level accuracy or structural integrity.
Ready to Use, Sterile Delivery
All VivoTex scaffolds arrive pre-sterilized and ready for use, saving researchers valuable preparation time. Designed to integrate seamlessly into existing workflows, they support cell alignment, differentiation, and function from the first use—bridging the gap between 2D and physiologically relevant 3D cultures.
PCL Fibers Precisely Arranged to Create Micro-Architectures
Using medical-grade poly(ε-caprolactone) (PCL), VivoTex constructs highly uniform micro-architectures that mimic the organization of native ECM. These stable, bioresorbable structures enhance mechanical strength while maintaining the porosity and biocompatibility needed for long-term cell culture and regenerative applications.
Our Research Applications
Regenerative Medicine
Empowering researchers to regenerate complex tissue structures with unparalleled accuracy.
Cancer Research
Enabling groundbreaking studies into tumor growth, metastasis, and targeted treatments.
Drug Discovery
Revolutionizing how drugs are tested and screened using realistic in-vitro models.
