Key Features

• Methacrylated gelatin base for bioinks and hydrogels in 3D bioprinting
• Pharmaceutical-grade raw material: porcine gelatin (300° Bloom) from a certified Polish source
• Enables tunable material properties through formulation and process parameter control
• Compatible with standard UV/Vis photocuring protocols in the presence of photoinitiators (e.g., LAP)

Applications

• 3D soft tissue models and cell-laden constructs for in vitro research
• Photocuring in layer-by-layer fabrication techniques (DLP / SLA) and photopatterning workflows
• Base component for blends with other methacrylate-functionalized materials in R&D formulation development

Key Features

• Variant optimized for improved shape stability and geometric fidelity
• Pharmaceutical-grade raw material: porcine gelatin (300° Bloom) from a certified Polish supplier
• Compatible with UV/Vis photocuring protocols in the presence of photoinitiators (e.g., LAP)
• Suitable as a base for methacrylate-based blends designed to produce structurally stable constructs

Applications

• 3D constructs with high geometric precision requirements (fine details, thin walls, channel structures)
• Scaffolds and hydrogels for projects where construct stability is a critical performance parameter
• R&D projects focused on developing materials with enhanced load-bearing capacity for soft tissue engineering

Key Features

• Methacrylated alginate serving as a polysaccharide component for 3D bioinks and hydrogels
• Viscosity-tailored variants enabling selection according to process and solution preparation requirements
• Designed for multicomponent formulations where alginate modulates mixture performance
• UV/Vis photocuring compatibility in the presence of photoinitiators (e.g., LAP), depending on the complete formulation

Applications

• Multicomponent bioink formulations where viscosity control and process behavior are critical parameters
• 3D hydrogels for tissue reconstruction within composite biomaterial systems
• Formulations requiring a polysaccharide component with controlled viscosity

Key Features

• Methacrylated hyaluronic acid component for ECM-mimicking hydrogel systems
• Availability of multiple molecular weight variants to match process and application requirements
• Controlled batch parameters ensuring consistency and reproducibility
• Designed for UV/Vis photocuring protocols in the presence of photoinitiators (e.g., LAP)

Applications

• 3D hydrogels and bioinks where hyaluronan presence is essential for microenvironment design
• Multicomponent material blends where molecular weight serves as a tool for tuning solution and hydrogel properties
• Soft tissue models and photopatterning systems (formulation-dependent)

Key Features

• Methacrylated chitosan component for bioink and 3D hydrogel formulations
• Variants with different degrees of substitution enabling tuning of process behavior and material properties
• Controlled batch specifications ensuring consistency and reproducibility in R&D workflows
• Designed for multicomponent systems where chitosan acts as a functional performance-modulating ingredient

Applications

• Multicomponent hydrogel and bioink formulations where chitosan contributes to material performance tuning
• Projects requiring degree of substitution as a key formulation design parameter
• 3D constructs and in vitro models where incorporation of chitosan into the microenvironment is desired

Key Features

• Gelatin-based methacrylate platform enabling customizable hydrogel network architecture
• Availability of multiple variants to support process-specific and construct-specific requirements
• Compatible with UV/Vis photocuring protocols in the presence of photoinitiators (e.g., LAP)
• Well suited for formulations requiring precise control of hydrogel microarchitecture

Applications

• 3D constructs where efficient mass transport and diffusion within hydrogels are critical
• Thick tissue models sensitive to diffusion limitations
• R&D projects where comparison of material variants supports formulation optimization