Expanding the Horizon of eco-friendly Poly(glycolic acid) to the packaging industry: Synthesis and modification

IF 5.5 2区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

Sustainable Chemistry and Pharmacy Pub Date : 2025-04-25 DOI:10.1016/j.scp.2025.102023

Hojun Shin, Jongchul Seo

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引用次数: 0

Abstract

The increase in packaging waste and resulting environmental pollution have emerged as global problems, and the development and practical use of bioplastics have been suggested as key solutions. Consequently, numerous efforts have been made to introduce bioplastics as packaging materials. Important factors include securing sufficient physical properties and industrial production processes to replace petroleum-based plastics. However, bioplastics generally exhibit inadequate thermal stability, mechanical strength, and barrier properties compared to engineering plastics, limiting their application as packaging materials. Polyglycolic acid (PGA) is a notable material because it is bio-based, rapidly biodegradable, biocompatible, and exhibits high mechanical strength and exceptional barrier properties owing to its dense chemical structure. However, the PGA production process—including its synthesis and manufacturing conditions—and PGA's properties have not yet been fully examined owing to its inherent characteristics such as hydrophilicity, narrow melting windows, and insolubility in many organic solvents. Consequently, practical attempts are needed to develop PGA-based packaging materials. In this paper, we summarize the PGA synthesis and modification methods in the sustainable packaging industry before discussing the applicability and future strategies for using PGA as a packaging material.

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拓展环保聚乙二醇酸在包装工业中的应用：合成与改性

包装废弃物的增加和由此造成的环境污染已成为全球性问题，而生物塑料的开发和实际使用被认为是关键的解决方案。因此，人们为将生物塑料用作包装材料做出了许多努力。其中的重要因素包括确保生物塑料具有足够的物理特性和工业生产工艺，以取代石油基塑料。然而，与工程塑料相比，生物塑料的热稳定性、机械强度和阻隔性能普遍不足，限制了其作为包装材料的应用。聚乙二醇酸（PGA）是一种值得注意的材料，因为它以生物为基础，可快速生物降解，具有生物相容性，并且由于其致密的化学结构而具有较高的机械强度和优异的阻隔性能。然而，由于 PGA 本身具有亲水性、熔化窗口窄、不溶于多种有机溶剂等特性，人们尚未对 PGA 的生产工艺（包括合成和制造条件）以及 PGA 的特性进行充分研究。因此，需要进行实际尝试来开发基于 PGA 的包装材料。在本文中，我们总结了可持续包装行业中的 PGA 合成和改性方法，然后讨论了将 PGA 用作包装材料的适用性和未来策略。

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来源期刊

Sustainable Chemistry and Pharmacy Environmental Science-Pollution

CiteScore

8.20

自引率

6.70%

发文量

274

审稿时长

37 days

期刊介绍： Sustainable Chemistry and Pharmacy publishes research that is related to chemistry, pharmacy and sustainability science in a forward oriented manner. It provides a unique forum for the publication of innovative research on the intersection and overlap of chemistry and pharmacy on the one hand and sustainability on the other hand. This includes contributions related to increasing sustainability of chemistry and pharmaceutical science and industries itself as well as their products in relation to the contribution of these to sustainability itself. As an interdisciplinary and transdisciplinary journal it addresses all sustainability related issues along the life cycle of chemical and pharmaceutical products form resource related topics until the end of life of products. This includes not only natural science based approaches and issues but also from humanities, social science and economics as far as they are dealing with sustainability related to chemistry and pharmacy. Sustainable Chemistry and Pharmacy aims at bridging between disciplines as well as developing and developed countries.