AKIMed-c12 is a groundbreaking polymer revolutionising the world of soft tissue engineering. Available in the form of 1 - 3 mm granulates, this innovative solution is designed to be seamlessly integrated into bioprinters or direct extrusion 3D printers, offering unrivalled versatility and compatibility.

Our non-toxic, degradable, and biocompatible polymer provides a remarkable breakthrough in soft tissue engineering. Its pliable nature allows for intricate and precise printing, enabling the creation of complex tissue structures with ease.

We take pride in offering our own meticulously synthesized polymer, AKIMed-c12, in the form of high-quality filaments. These filaments are precisely extruded in our state-of-the-art lab, ensuring a research-grade product that meets the highest standards of excellence.

With our AKIMed-c12 filament, researchers have the opportunity to fabricate customized scaffolds using the fused filament fabrication (FFF) technique. This innovative material bears resemblance to poly (ɛ-caprolactone), PCL, yet exhibits a more accelerated degradation behavior, opening new doors for rapid tissue regeneration.

We’re offering soft, pliable, and highly porous 3D printed scaffolds that cater to both in vitro cell culture and in vivo testing. Our scaffolds are meticulously fabricated using AKIMed-c12, a high molecular weight linear semicrystalline poly(ether ester) renowned for its exceptional properties.

Designed for longevity, our scaffolds exhibit an estimated degradation time of 9-10 months under hydrolytic conditions at 37°C. This ensures a stable yet controlled degradation rate, allowing for optimal tissue regeneration processes.

We understand the importance of compatibility with standard cell culture well-plates. Simply inform us of the brand and number of wells in your plates, and we will customize our scaffold designs to seamlessly fit your specific requirements.

We offer a range of customization options to meet your research needs. Choose from linear, hexagonal, gradient, or staggered designs, allowing you to tailor the mechanical properties of the scaffold to your desired specifications.

With our expertise in scaffold design and simulation tools, we possess the know-how to precisely tailor the scaffold properties to your research questions. By assessing mechanical properties and fluid flow through your design before you begin, you gain valuable insights into your system's behavior, enabling more informed decisions during cell culture experiments.