371x 🔖
Enter the , cataloged under Art. No. 371X by leading laboratory suppliers like Carl ROTH . This isn't just another resin; it’s a specialized solution designed to push the boundaries of what 3D printers can achieve at the nano and micro scales. What is SOLID INX© X100?
The challenge in bioprinting has always been the "Goldilocks" problem: finding a material that is hard enough to hold a shape but "soft" enough to be biologically relevant. The 371X material fills this gap by offering a stable, solid-phase result that remains compatible with highly innovative bioprinting technologies .
By utilizing these standardized bioinks, researchers can ensure their results are reproducible—a vital step in moving from laboratory experiments to clinical applications. Enter the , cataloged under Art
The series refers to a specific formulation of bioink optimized for high-precision printing technologies. While its counterpart, GEL-MA INX© X100 (371L), focuses on gelatin-based biocompatibility, the SOLID INX© X100 (371X) is engineered for structural excellence. Key Features of the 371X Series:
In the rapidly evolving world of tissue engineering and regenerative medicine, the search for the "perfect" bioink is relentless. Scientists are constantly balancing the need for high-resolution structural integrity with the delicate requirements of biological cell environments. This isn't just another resin; it’s a specialized
Whether you are working on medical image reconstruction optimizations or building the next generation of functional tissue, the offers the precision and biological functionality required for today’s most innovative technologies. Bioprinting | Carl ROTH - France
Designed for use with advanced systems like the Nanoscribe Quantum X Bio and Upnano NanoOneBio , this material allows for the creation of intricate organ structures with extreme accuracy. The 371X material fills this gap by offering
Time is of the essence in the lab. This formulation is tailored to balance high-speed printing without sacrificing the resolution required for cellular scaffolds. Why It Matters for Research