Dar Sami Ullah, Wu Zizhao, Zhang Linyi, Yu Peirong, Qin Yiheng, Shen Yezi, Zou Yunfan, Poh Leslie, Eichen Yoav, Achmon Yigal
Biotechnology and Food Engineering, Guangdong Technion-Israel Institute of Technology, Shantou, China.
Guangdong Technion Department of Chemistry-Israel Institute of Technology, Shantou, China.
Front Bioeng Biotechnol. 2022 Aug 8;10:922974. doi: 10.3389/fbioe.2022.922974. eCollection 2022.
Plasticulture, the practice of using plastic materials in agricultural applications, consumes about 6.7 million tons of plastics every year, which is about 2% of the overall global annual plastics production. For different reasons, plastic material used for agriculture is difficult to recycle. Therefore, most of it is either buried in fertile soils, thereby significantly causing deterioration of their properties, or, at best case, end in landfills where its half-life is measured in decades and even centuries. Hence, developing biodegradable plastic materials that are suitable for agricultural applications is a vital and inevitable need for the global human society. In our labs, two types of potentially biodegradable plastic polymer films were prepared and characterized imidazolium in terms of their bio-degradability. In the first approach, polymers made of ionic liquid monomers were prepared using photo radical induced polymerization. The second approach relies on formation of polyethylene-like n-alkane disulfide polymers from 1,ω-di-thiols through thermally activated air oxidation. These two families of materials were tested for their biodegradability in soils by using a simulation system that combines a controlled environment chamber equipped with a respirometer and a proton-transfer-reaction time of flight mass spectrometer (PTR-TOF-MS) system. This system provides a time-dependent and comprehensive fingerprint of volatiles emitted in the degradation process. The results obtained thus far indicate that whereas the ionic-liquid based polymer does not show significant bio-degradability under the test conditions, the building block monomer, 1,10-n-decane dithiol, as well as its disulfide-based polymer, are bio-degradable. The latter reaching, under basic soil conditions and in room temperature, ∼20% degradation within three months. These results suggest that by introduction of disulfide groups into the polyethylene backbone one may be able to render it biodegradable, thus considerably shortening its half-life in soils. Principal component analysis, PCA, of the data about the total volatiles produced during the degradation in soil indicates a distinctive volatile "fingerprint" of the disulfide-based bio-degradable products which comes from the volatile organic compounds portfolio as recorded by the PTR-TOF-MS. The biodegradation volatile fingerprint of this kind of film was different from the "fingerprint" of the soil background which served as a control. These results can help us to better understand and design biodegradable films for agricultural mulching practices.
塑料栽培,即在农业应用中使用塑料材料的做法,每年消耗约670万吨塑料,约占全球塑料年产量的2%。由于各种原因,用于农业的塑料材料难以回收。因此,大部分塑料要么被埋在肥沃的土壤中,从而显著导致土壤性质恶化,要么在最佳情况下最终进入垃圾填埋场,其半衰期以数十年甚至数百年计。因此,开发适用于农业应用的可生物降解塑料材料是全球人类社会至关重要且不可避免的需求。在我们的实验室中,制备了两种类型的潜在可生物降解塑料聚合物薄膜,并对其咪唑鎓的生物降解性进行了表征。在第一种方法中,使用光自由基引发聚合制备由离子液体单体制成的聚合物。第二种方法依赖于通过热活化空气氧化由1,ω-二硫醇形成类似聚乙烯的正烷二硫化物聚合物。通过使用一个模拟系统对这两类材料在土壤中的生物降解性进行了测试,该模拟系统结合了配备呼吸计的可控环境室和质子转移反应飞行时间质谱仪(PTR-TOF-MS)系统。该系统提供了降解过程中释放的挥发性物质随时间变化的全面指纹图谱。迄今为止获得的结果表明,基于离子液体的聚合物在测试条件下未表现出显著的生物降解性,而构建单体1,10-正癸二硫醇及其基于二硫化物的聚合物是可生物降解的。在碱性土壤条件和室温下,后者在三个月内降解约20%。这些结果表明,通过将二硫基团引入聚乙烯主链,有可能使其具有生物降解性,从而大大缩短其在土壤中的半衰期。对土壤降解过程中产生的总挥发性物质数据进行主成分分析(PCA)表明,基于二硫化物的可生物降解产物具有独特的挥发性“指纹图谱”,这来自PTR-TOF-MS记录的挥发性有机化合物组合。这种薄膜的生物降解挥发性指纹图谱与作为对照的土壤背景“指纹图谱”不同。这些结果有助于我们更好地理解和设计用于农业覆盖实践的可生物降解薄膜。
