Richard A. Gross scite author profile

Biodegradable polymers are designed to degrade upon disposal by the action of living organisms. Extraordinary progress has been made in the development of practical processes and products from polymers such as starch, cellulose, and lactic acid. The need to create alternative biodegradable water-soluble polymers for down-the-drain products such as detergents and cosmetics has taken on increasing importance. Consumers have, however, thus far attached little or no added value to the property of biodegradability, forcing industry to compete head-to-head on a cost-performance basis with existing familiar products. In addition, no suitable infrastructure for the disposal of biodegradable materials exists as yet.

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Cutinase-Catalyzed Hydrolysis of Poly(ethylene terephthalate)

Ronkvist¹,

Xie²,

Lu³

et al. 2009

Macromolecules

537

512

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A detailed study and comparison was made on the catalytic activities of cutinases from Humilica insolens (HiC), Pseudomonas mendocina (PmC), and Fusarium solani (FsC) using low-crystallinity (lc) and biaxially oriented (bo) poly(ethylene terephthalate) (PET) films as model substrates. Cutinase activity for PET hydrolysis was assayed using a pH-stat to measure NaOH consumption versus time, where initial activity was expressed as units of micromoles of NaOH added per hour and per milliliter of reaction volume. HiC was found to have good thermostability with maximum initial activity from 70 to 80 °C, whereas PmC and FsC performed best at 50 °C. Assays by pH-stat showed that the cutinases had about 10-fold higher activity for the lcPET (7% crystallinity) than for the boPET (35% crystallinity). Under optimal reaction conditions, initial activities of cutinases were successfully fit by a heterogeneous kinetic model. The hydrolysis rate constant k 2 was 7-fold higher for HiC at 70 °C (0.62 μmol/cm2/h) relative to PmC and FsC at 50 and 40 °C, respectively. With respect to PET affinity, PmC had the highest affinity, while FsC had the lowest value. In a 96 h degradation study using lcPET films, incubation with PmC and FsC both resulted in a 5% film weight loss at 50 and 40 °C, respectively. In contrast, HiC-catalyzed lcPET film hydrolysis at 70 °C resulted in a 97 ± 3% weight loss in 96 h, corresponding to a loss in film thickness of 30 μm per day. As degradation of lcPET progressed, crystallinity of the remaining film increased to 27% due to preferential degradation of amorphous regions. Furthermore, for all three cutinases, analysis of aqueous soluble degradation products showed that they consist exclusively of terephthalic acid and ethylene glycol.

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Polymer Synthesis by In Vitro Enzyme Catalysis

Gross¹,

Kumar²,

Kalra³

2001

Chem. Rev.

678

515

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Polylactide stereochemistry: effect on enzymic degradability

Reeve¹,

McCarthy²,

Downey³

et al. 1994

Macromolecules

417

325

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Richard A. Gross

Biodegradable Polymers for the Environment

Cutinase-Catalyzed Hydrolysis of Poly(ethylene terephthalate)

Polymer Synthesis by In Vitro Enzyme Catalysis

Polylactide stereochemistry: effect on enzymic degradability

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