Poly(lactide) Upcycling Approach through Transesterification for Stereolithography 3D Printing.

IF 5.5 2区化学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY Biomacromolecules Pub Date : 2024-10-14 Epub Date: 2024-10-02 DOI:10.1021/acs.biomac.4c00840

Silvestr Figalla, Vojtěch Jašek, Jan Fučík, Přemysl Menčík, Radek Přikryl

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Abstract

The legislature determines the recycled and waste contents in fabrication processes to ensure more sustainable production. PLA's mechanical recycling and reuse are limited due to the performance decrease caused by thermal or hydrolytic instability. Our concept introduces an upcycling route involving PLA depolymerization using propylene glycol as a reactant, followed by the methacrylation, assuring the liquid systems' curability provided by radical polymerization. PLA-containing curable systems were studied from a rheological and thermomechanical viewpoint. The viscosity levels varied from 33 to 3911 mPa·s at 30 °C, giving a wide capability potential. The best system reached 2240 MPa storage modulus, 164.1 °C glass-transition temperature, and 145.6 °C heat-resistant index, competitive values to commercial systems. The printability was verified for all of the systems. Eventually, our concept led to SLA resin production containing PLA waste content up to 51 wt %.

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用于立体光刻 3D 打印的聚乳酸酯化升级再循环方法。

立法机构决定制造过程中的回收和废物含量，以确保生产更具可持续性。由于热或水解不稳定性导致性能下降，聚乳酸的机械回收和再利用受到限制。我们的概念引入了一条升级循环路线，涉及使用丙二醇作为反应物对聚乳酸进行解聚，然后进行甲基丙烯酸化，确保液态系统通过自由基聚合实现固化。从流变学和热力学的角度对含聚乳酸的可固化体系进行了研究。在 30 °C 时，粘度水平从 33 到 3911 mPa-s 不等，具有广泛的潜在能力。最佳体系的储存模量为 2240 兆帕，玻璃转化温度为 164.1 °C，耐热指数为 145.6 °C，与商用体系的数值相当。所有系统的可印刷性都得到了验证。最终，我们的理念促成了含有高达 51 wt % 聚乳酸废料的 SLA 树脂的生产。

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来源期刊

Biomacromolecules 化学-高分子科学

CiteScore

10.60

自引率

4.80%

发文量

417

审稿时长

1.6 months

期刊介绍： Biomacromolecules is a leading forum for the dissemination of cutting-edge research at the interface of polymer science and biology. Submissions to Biomacromolecules should contain strong elements of innovation in terms of macromolecular design, synthesis and characterization, or in the application of polymer materials to biology and medicine. Topics covered by Biomacromolecules include, but are not exclusively limited to: sustainable polymers, polymers based on natural and renewable resources, degradable polymers, polymer conjugates, polymeric drugs, polymers in biocatalysis, biomacromolecular assembly, biomimetic polymers, polymer-biomineral hybrids, biomimetic-polymer processing, polymer recycling, bioactive polymer surfaces, original polymer design for biomedical applications such as immunotherapy, drug delivery, gene delivery, antimicrobial applications, diagnostic imaging and biosensing, polymers in tissue engineering and regenerative medicine, polymeric scaffolds and hydrogels for cell culture and delivery.