Reversible acetalization of cellulose: A platform for bio-based materials with adjustable properties and biodegradation

Bio-based and biodegradable polymers are essential for a sustainable society. Cellulose is the most abundant biopolymer on earth; however, derivatization is necessary for its processing, which slows down its biodegrad-ability dramatically, e.g. used cigarette filters made from cellulose acetate are barely biodegradable. We developed the first reversible modification of cellulose, which allows processing and guarantees full biodegra-dation even at high degrees of substitution as the linkers, acetals, can be cleaved first during the degradation process releasing native cellulose that biodegrades in a second step. Acetalization is a versatile platform approach to bio-based and fully degradable cellulose-derivatives, which are characterized by solubility in common organic solvents (alcohols, aromatic and chlorinated solvents), adjustable glass transition temperatures (-48 degrees C < Tg < 80 degrees C), young's modulus (1.9 MPa < E < 58 MPa) and contact angle (86 degrees< & theta; < 124 degrees). In contrast to previously known cellulose modifications, cellulose acetals remain fully degradable as the acetal bond is reversible and undergoes an acidic cleavage under desired conditions, for instance in compost, followed by enzymatic degra-dation of the remaining cellulose backbone. With climate change and plastic pollution, these new and versatile cellulose acetals provide bio-based and biodegradable alternatives to fossil-based and non-degradable polyolefin plastics, leading to a more sustainable future for our planet.

Automated summary

Bio-based and biodegradable cellulose acetals, with their reversible modification of cellulose, provide a versatile and sustainable alternative to non-degradable polyolefin plastics. These cellulose acetals are characterized by solubility in common organic solvents, adjustable physical properties, and the ability to undergo full degradation in compost and enzymatic processes. With the increasing urgency of climate change and plastic pollution, these cellulose derivatives offer a promising solution for a more sustainable future.