Optimizing Acrylonitrile Grafting onto Rayon Fibers to Enhance Its Application Characteristics

Q3 Materials Science

Macromolecular Symposia Pub Date : 2025-04-14 DOI:10.1002/masy.202400204

Abhinav Kumar, Vaibhav Kataria, Prachi Singhal, Aditi Sangal, Sunita Rattan

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引用次数: 0

Abstract

Rayon is a regenerated cellulosic fiber, extensively being used in biomedical applications in the form of fabrics and surgical dressings. As a surgical dressing material, rayon exhibits advantages including light in weight, swelling ability, retaining absorbency on storage, does not shed fibers on the surface of the wound while cleaning the wound etc. However, conventional rayon-based dressing materials exhibit restricted swelling capacity that need to be enhanced for better absorption of wound exudates and rapid wound healing. Further, the mechanical properties and anti-bacterial properties must be worked upon as moisture absorption hampers these properties. To overcome these challenges, the structure of rayon fibers can be tailored through functionalization to increase its swelling capacity and to widen their application such as for full thickness skin wound applications. In the present study, rayon fibers are grafted with acrylonitrile (AN) to provide Ry─g─AN (Rayon─grafted─acrylonitrile). The grafting is carried out under microwave radiation catalyzed by cerium ions. The structure and morphology of the prepared fibers are characterized by SEM, FTIR, and XRD. The grafting conditions are systematically studied, optimizing factors, including concentrations of initiator and AN, temperature, solvent etc. with respect to the variations in grafting percentage. Maximum grafting obtained is 178% with 4 ml of monomer concentration, 0.5 ml initiator concentration, 30 ml of solvent, and 3 min. of microwave radiation exposure. Acrylonitrile is one of the versatile monomers that can impart mechanical strength, antimicrobial properties, along with reactive nitrile groups that could assist in further chemical treatment and drug loading to the dressing material.

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优化丙烯腈在人造丝上的接枝以增强其应用特性

人造丝是一种再生纤维素纤维，以织物和手术敷料的形式广泛应用于生物医学领域。作为手术敷料，人造丝具有重量轻、膨胀能力强、储存时保持吸水性、清洁伤口时不会在伤口表面脱落纤维等优点。然而，传统的人造丝敷料的膨胀能力有限，需要加强膨胀能力才能更好地吸收伤口渗出物，使伤口快速愈合。此外，机械性能和抗菌性能也必须加以改进，因为吸湿会影响这些性能。为了克服这些挑战，可以通过功能化来调整人造丝纤维的结构，以提高其膨胀能力，并扩大其应用范围，如用于全厚皮肤伤口。在本研究中，人造丝纤维与丙烯腈（AN）接枝，形成 Ry─g─AN（Rayon─grafted─acrylonitrile）。接枝是在铈离子催化的微波辐射下进行的。制备的纤维的结构和形态由扫描电镜、傅立叶变换红外光谱和 X 射线衍射仪进行表征。对接枝条件进行了系统研究，优化了与接枝率变化有关的因素，包括引发剂和 AN 的浓度、温度、溶剂等。在单体浓度为 4 毫升、引发剂浓度为 0.5 毫升、溶剂浓度为 30 毫升、微波辐射时间为 3 分钟的条件下，接枝率最高可达 178%。丙烯腈是一种用途广泛的单体，可赋予敷料机械强度、抗菌特性以及活性腈基，从而有助于对敷料进行进一步的化学处理和药物添加。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Macromolecular Symposia Materials Science-Polymers and Plastics

CiteScore

1.50

自引率

0.00%

发文量

226

期刊介绍： Macromolecular Symposia presents state-of-the-art research articles in the field of macromolecular chemistry and physics. All submitted contributions are peer-reviewed to ensure a high quality of published manuscripts. Accepted articles will be typeset and published as a hardcover edition together with online publication at Wiley InterScience, thereby guaranteeing an immediate international dissemination.