Bioplastics
Plant-based or biodegradable polymers for sustainable applications.
A biodegradable, plant-based thermoplastic and the most popular 3D printing filament.
A standard grade of polylactic acid designed for general-purpose applications, offering good processability and biodegradability.
A modified PLA grade offering improved heat resistance for applications requiring higher service temperatures than standard PLA.
An amorphous and fast-crystallizing grade of PDLLA, used in medical applications requiring controlled degradation.
A stereocomplex grade of PDLA, offering enhanced thermal and mechanical properties through interaction with PLLA.
A flexible grade of PHA offering good toughness and biodegradability in various environmental conditions.
A rigid and brittle grade of PHB, characterized by its high crystallinity and rapid degradation.
A copolymer of PHB and PHV providing a balance of flexibility, toughness, and biodegradability.
A bio-based PBS grade offering excellent processability and biodegradability for film and packaging applications.
A biodegradable copolyester offering enhanced flexibility and toughness compared to standard PBS.
A biodegradable copolyester with excellent flexibility, toughness, and good processability, ideal for film applications.
A blend of starch and plasticizers, offering biodegradability and compostability with tunable properties.
A clear, rigid bioplastic derived from cellulose, with good dimensional stability and photographic properties.
A cellulose derivative with improved toughness and weatherability for injection molding applications.
A highly transparent, biodegradable film derived from purified cellulose, known for its gas barrier properties.
A high-density polyethylene produced from renewable sugarcane, chemically identical to conventional HDPE.
A bio-based version of PET, produced from plant-derived ethylene glycol, offering identical performance to conventional PET.
High-performance bio-based polyamide derived from castor oil, offering excellent chemical resistance and flexibility.
A bio-based polyamide with low moisture absorption and good flexibility, derived from renewable resources.
A 100% bio-based polyester with superior barrier properties to PET, suitable for packaging.
A bio-derived aromatic polymer extracted from wood, used as a filler or building block for biocomposites.
A biopolymer derived from chitin, known for its biodegradability, biocompatibility, and antimicrobial properties.
A protein-based bioplastic derived from milk, offering biodegradability and film-forming properties.
A sustainable material grown from fungal mycelium on agricultural waste, used for packaging and insulation.
An amorphous PDLLA grade with high molecular weight, offering increased strength and slower degradation for medical applications.
A standard injection molding grade of PLA optimized for cycle times and part quality in mass production.
A toughened PHA copolymer offering improved impact resistance and flexibility for durable applications.
A bio-based PET grade optimized for film extrusion, offering excellent clarity and printability.
A modified PBS grade offering enhanced tensile strength and rigidity for structural applications.
A PBAT grade with improved heat resistance for applications requiring higher service temperatures.
A softer, more flexible grade of bio-based PA11 for applications requiring high resilience and impact absorption.
Crosslinked chitosan for improved water resistance and mechanical stability in humid environments.
A higher stiffness grade of bio-PA610 for applications requiring good mechanical integrity and low moisture uptake.
Regenerated cellulose film with a barrier coating for enhanced protection.
PLLA component for creating stereocomplex PLA, offering superior thermal and mechanical properties when blended with PDLA.
A PHA grade meeting biocompatibility standards for medical and healthcare applications.
A highly flexible and extensible PBSA grade designed for films requiring superior drape and toughness.
A low-density polyethylene made from sugarcane, offering the flexibility and toughness of conventional LDPE.