Progress in the Synthesis and Application of Biodegradable Polymers

Yulin Sun

doi:10.62051/209rhe78

Authors

Yulin Sun

DOI:

https://doi.org/10.62051/209rhe78

Keywords:

Polymer, biodegradable, synthesis, application.

Abstract

With the development of science and technology, biodegradable materials have gradually emerged in people's vision. Biodegradable materials are generally high polymer materials, many of which can be artificially synthesized, and some raw materials are simple and easy to obtain, and the production process is not complicated. This material has many advantages that traditional materials cannot match, and it can be said that the current development prospects of this material are very promising. Its degradability meets the requirements of green chemistry and environmental protection, and the harm to the human body will no longer be as severe as traditional materials. This article introduces several common biodegradable materials such as PLA, PBAT, and some highly recognized synthesis methods, as well as their degradation mechanisms. It also elaborates on their applications in various fields, including biomedical, packaging, and agricultural fields, to illustrate the advantages of biodegradable materials over ordinary traditional materials and their future trends in widespread application in various fields.

Downloads

Download data is not yet available.

References

[1] Xue ZH. A review on biodegradable polymer: shortcomings, developments, and future direction. Rome: Darlington School, 2023.

[2] Gross RA, Kalra B. Biodegradable polymers for the environment. Science (80-). 2002; 297(5582): 803-807.

[3] AP Gupta, V Kumar. New emerging trends in synthetic biodegradable polymers-Polylactide: A critique. Eur Polym J, 2007, 43(10): 4053-4074.

[4] Yu JM, et al. Research progress of green composites based on three degradable plastics. Engineering Plastics Application, 2023, 51(8): 172-177.

[5] Vert M, et al. Something new in the ﬁeld of PLA/GA bioresorbable polymers. J Control Rel, 1998, 53(1): 85-92.

[6] Li DY, Han ZL. Production and application of biodegradable plastics. China Synthetic and Plastics, 2021, 38(5): 83.

[7] Cao J. Study on synthetic technology of total biodegradable PBAT. Coal and Chemical Industry, 2023, 46(8): 124-129.

[8] Diaz A, et al. Synthesis, properties and applications of biodegradable polymers derived from diols and dicarboxylic acids: from polyesters to poly (ester amide) s. International Journal of Molecular Sciences, 2014, 15(5): 7064-7123.

[9] Chen ZY, et al. Research progress in degradation behavior and application of PLGA. China Plastics, 2024, 38(1): 92-99.

[10] Meghana M.C., et al. A road map on synthetic strategies and applications of biodegradable polymers. Polymer Bulletin, 2023, 80: 11507-11556.

[11] Li T. Application of biodegradable polymer synthetic materials in the medical field. Progress and Application, 2023, 35(5): 51-55.

[12] Jiang XY, et al. Self-aggregated pegylated poly (trimethylene carbonate) nanoparticles decorated with c (RGDyK) peptide for targeted paclitaxel delivery to integrin-rich tumors. Biomaterials, 2011, 32 (35): 9457-9469.

[13] Natália D, et al. Tailored biodegradable films via extrusion blow molding using PBS, PBAT, and TPS. Journal of Applied Polymer Science, 2024, 141(3): e54820.

[14] Soňa K, et al. Slow-Release Nitrogen Fertilizers with Biodegradable Poly(3-hydroxybutyrate) Coating: Their Effect on the Growth of Maize and the Dynamics of N Release in Soil. Polymers, 2022, 14(20): 4323.

[15] Trinath Biswal. Biopolymeric conjugation with synthetic fibers and applications. Physical Sciences Reviews, 2023, 0183.