Development of active and intelligent packaging materials from low-value biomass for waste reduction

利用低价值生物质开发活性智能包装材料以减少废物

• 批准号: RGPIN-2019-04498
• 负责人: Wang, Yixiang
• 金额: $ 2.04万
• 依托单位: McGill University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=753533
• 关键词: Development; active; intelligent; packaging; materials

Food waste and plastic pollution are two global issues. In one aspect, hunger and malnutrition are the number one health risks worldwide. In another, about 40% of manufactured food becomes waste each year. Meanwhile, the non-degradable plastic packaging materials have created significant disposal and pollution issues threatening human health and development. Can novel food packaging help address these issues? Active and intelligent packaging made by natural polymers are innovative materials with improved protection and communication at the same time retaining biodegradability. However, the natural resources like forest cannot be over-developed. Therefore, my research program (long-term objective) aims to utilize Canadian low-value biomass (cellulose, starch, protein, and chitin) obtained from waste and by-products to produce biodegradable functional packaging materials for the reduction of food and plastic wastes. These materials will be designed based on the understanding of molecular structures and their interactions to achieve desired mechanical and barrier properties, and will be used to partially replace the non-degradable plastics. By incorporating active compounds, the new packaging materials will also be able to extend the shelf life and/or indicate the food freshness, so as to decrease food waste. The short-term objectives for the next five years are to develop active and intelligent food packaging from cellulosic materials originating from waste textile. More than 15 million tons of waste textile are generated every year in North America, but less than one fifth are recycled. The disposal of waste textile via landfill or incineration causes environmental problem and also represents a waste of useful resources. I intend to use `green' aqueous solvents to dissolve the cellulosic waste textile and convert it into functional films with good mechanical, barrier, and anti-microbial properties (Objective 1). Waste textile is also a potential source of cellulose nanocrystals which will be used to stabilize the hydrophobic sensing compounds in water to develop active visual ink for monitoring food spoilage (Objective 2). Various cellulose derivatives will be obtained from waste textile for the production of electrospun fabrics. These highly porous fabrics will be promising matrices to load sensing compounds for monitoring atmosphere change in package (Objective 3). This proposed research has three anticipated significant outcomes. Firstly, it will generate value-added products (antimicrobial films, active visual ink, and fabric indicator) which have high potential to be applied in commercial products to reduce food and plastic wastes. Secondly, it will further contribute to our fundamental understanding of dissolution of cellulose. Thirdly, it will train a new generation of HQP to address the environmental sustainability issues and technical challenges surrounding the natural polymer based materials.

食物浪费和塑料污染是两个全球性问题。一方面，饥饿和营养不良是全世界的头号健康风险。在另一个国家，每年约有40%的加工食品成为废物。与此同时，不可降解的塑料包装材料产生了严重的处置和污染问题，威胁着人类的健康和发展。新的食品包装能帮助解决这些问题吗？由天然聚合物制成的活性和智能包装是一种创新材料，具有更好的保护和通信功能，同时保持生物降解性。但是，森林等自然资源不能过度开发。因此，我的研究计划（长期目标）旨在利用加拿大从废物和副产品中获得的低价值生物质（纤维素，淀粉，蛋白质和甲壳素）生产可生物降解的功能包装材料，以减少食品和塑料废物。这些材料将基于对分子结构及其相互作用的理解进行设计，以实现所需的机械和阻隔性能，并将用于部分替代不可降解塑料。通过加入活性化合物，新型包装材料还能够延长保质期和/或指示食品新鲜度，从而减少食品浪费。未来五年的短期目标是利用废弃纺织品中的纤维素材料开发活性和智能食品包装。北美每年产生超过1500万吨的废旧纺织品，但只有不到五分之一被回收利用。通过填埋或焚烧处理废纺织品会造成环境问题，也会浪费有用的资源。我打算使用“绿色”水性溶剂溶解纤维素废弃纺织品，并将其转化为具有良好机械、阻隔和抗菌性能的功能性膜（目标1）。废纺织品也是纤维素纳米晶体的潜在来源，其将用于稳定水中的疏水传感化合物，以开发用于监测食品腐败的活性视觉墨水（目标2）。从废纺织品中可以得到各种纤维素衍生物，用于静电纺丝织物的生产。这些高度多孔的织物将是有前途的基质，以负载传感化合物，用于监测包装中的气氛变化（目标3）。这项研究有三个预期的重要成果。首先，它将产生增值产品（抗菌薄膜，活性视觉油墨和织物指示剂），这些产品具有很高的潜力，可用于商业产品，以减少食品和塑料废物。其次，它将进一步有助于我们对纤维素溶解的基本理解。第三，它将培养新一代的HQP，以解决环境可持续性问题和围绕天然聚合物基材料的技术挑战。