Integrating chemical and biological technologies in upcycling plastic waste to medium-chain α,ω-Diacid

被引:1
|
作者
Yeo, In-Seok [1 ]
Go, Kang-Seok [2 ,3 ]
Jeon, Woo-Young [1 ]
Jang, Min-Jeong [1 ]
Lee, Hye-Jeong [1 ]
Seo, Sung-Hwa [1 ]
Kim, Young Su [1 ]
Park, Hyuna [1 ]
Min, Byung-wook [4 ]
Park, Kyungmoon [5 ]
Yang, Yung-Hun [6 ]
Choi, Kwon-Young [7 ,8 ]
Lee, Hong-Weon [1 ,9 ]
Jeon, Sang-Goo [2 ,10 ]
Ahn, Jung -Oh [1 ,9 ]
机构
[1] KRIBB, Biotechnol Proc Engn Ctr, 30 Yeongudanji Ro, Cheongju 28116, Chungcheongbuk, South Korea
[2] Korea Inst Energy Res KIER, Bioenergy & Energy Resources Upcycling Res Lab, Daejeon 34129, South Korea
[3] Univ Sci & Technol, Energy Engn Dept, 217 Gajeong-ro, Daejeon 34113, South Korea
[4] Sehan Recycle Inc, 14 Gasan Digital 2-ro, Seoul 08592, South Korea
[5] Hongik Univ, Dept Biol & Chem Engn, Sejong 30016, South Korea
[6] Konkuk Univ, Coll Engn, Dept Biol Engn, Seoul 05029, South Korea
[7] Ajou Univ, Coll Adv Bioconvergence, Bioadv Mat Major, Suwon 16499, South Korea
[8] Ajou Univ, Energy Syst Res, Suwon 16499, South Korea
[9] Univ Sci & Technol, Bioproc Dept, 217 Gajeong ro, Daejeon 34113, South Korea
[10] Korea Inst Energy Res, Biomass & Waste Energy Lab, 152 Gajeong Ro, Daejeon 34129, South Korea
来源
JOURNAL OF CLEANER PRODUCTION | 2024年 / 451卷
基金
新加坡国家研究基金会;
关键词
Sustainability; Pyrolysis oil; Microbial biotransformation; alpha; omega-diacids; Plastic waste upcycling; Candida tropicalis; FATTY-ACIDS; PYROLYSIS; CONVERSION; RECOVERY; MODEL; BTEX; PET;
D O I
10.1016/j.jclepro.2024.141890
中图分类号
X [环境科学、安全科学];
学科分类号
08 ; 0830 ;
摘要
The growing accumulation of plastic waste poses a pressing environmental challenge. Traditional disposal methods, such as incineration and landfilling, carry considerable health and ecological risks. In response, our study presents an innovative method to repurpose mixed plastic waste into valuable alpha, omega-diacids utilizing chemobiological processes. We extracted pyrolysis oil, rich in hydrocarbons spanning a broad range of chain lengths (C 7 to C 32 ), from household plastic waste and employed a genetically engineered beta-oxidation-blocked Candida tropicalis strain to convert this oil into alpha, omega-diacids of various chain lengths. Simple distillation at 200 degrees C enabled the extraction of medium-chain hydrocarbons from the pyrolysis oil. However, an increased ratio of medium-chain alkenes posed a toxicity challenge to the cells. Through hydrogenation, these medium-chain alkenes were fully converted to alkanes. Remarkably, cell growth was maintained even with an 8% concentration of hydrogenates. The subsequent biotransformation yielded medium-chain diacids, with 94.3% of the produced alpha, omega-diacids being of medium-chain length (C 7 to C 14 ). These results offer a novel and scalable solution for converting everyday plastic waste into valuable chemicals, thus significantly contributing to the circular economy and the advancement of sustainability goals.
引用
收藏
页数:11
相关论文
共 50 条
  • [21] Chemical Upcycling of Polylactic Acid Plastic Waste into Alanine over Ru/CeO2 with Decoration of Indium
    Wang, Shaoshuai
    Hu, Jiaxue
    Zhao, Qiang
    Liu, Guojun
    Gui, Zhenzheng
    Liu, Xiaojing
    Huang, Yong
    Zhang, Peng
    Chen, Yuhui
    Wang, Fenfen
    ACS SUSTAINABLE CHEMISTRY & ENGINEERING, 2024, 12 (31): : 11754 - 11766
  • [22] Chemical upcycling of waste polyolefinic plastics to low-carbon synthetic naphtha for closing the plastic use loop
    Dai, Leilei
    Zhou, Nan
    Lv, Yuancai
    Cheng, Yanling
    Wang, Yunpu
    Liu, Yuhuan
    Cobb, Kirk
    Chen, Paul
    Lei, Hanwu
    Ruan, Roger
    SCIENCE OF THE TOTAL ENVIRONMENT, 2021, 782
  • [23] Upcycling plastic waste into syngas by staged chemical looping gasification with modified Fe-based oxygen carriers
    Wu, Shijie
    Ren, Zongqiang
    Hu, Qiang
    Yao, Dingding
    Yang, Haiping
    APPLIED ENERGY, 2024, 353
  • [24] Chemical upcycling of waste polyolefinic plastics to low-carbon synthetic naphtha for closing the plastic use loop
    Dai, Leilei
    Zhou, Nan
    Lv, Yuancai
    Cheng, Yanling
    Wang, Yunpu
    Liu, Yuhuan
    Cobb, Kirk
    Chen, Paul
    Lei, Hanwu
    Ruan, Roger
    Science of the Total Environment, 2021, 782
  • [25] In-situ production of lactate driving the biotransformation of waste activated sludge to medium-chain fatty acid
    Wu, Shu-Lin
    Wei, Wei
    Ngo, Huu Hao
    Guo, Wenshan
    Wang, Chen
    Wang, Yun
    Ni, Bing-Jie
    JOURNAL OF ENVIRONMENTAL MANAGEMENT, 2023, 345
  • [26] From Plastic Waste to Treasure: Selective Upcycling through Catalytic Technologies (Adv. Energy Mater. 41/2023)
    Yue, Shuai
    Wang, Pengfei
    Yu, Bingnan
    Zhang, Tao
    Zhao, Zhiyong
    Li, Yi
    Zhan, Sihui
    ADVANCED ENERGY MATERIALS, 2023, 13 (41)
  • [27] Medium-chain triglycerides and conjugated linolenic acids in functional yogurts: impact of GIT and potential biological activities
    Machado, Manuela
    Sousa, Sergio
    Morais, Pilar
    Miranda, Armenio
    Rodriguez-Alcala, Luis M.
    Gomes, Ana Maria
    Pintado, Manuela
    FOOD & FUNCTION, 2022, 13 (21) : 10937 - 10946
  • [28] Beyond biodegradation: Chemical upcycling of poly(lactic acid) plastic waste to methyl lactate catalyzed by quaternary ammonium fluoride
    Xie, Shaoqu
    Sun, Zengran
    Liu, Tuan
    Zhang, Jinwen
    Li, Tianjin
    Ouyang, Xinping
    Qiu, Xueqing
    Luo, Song
    Fan, Wei
    Lin, Hongfei
    JOURNAL OF CATALYSIS, 2021, 402 (402) : 61 - 71
  • [29] Improving microbial medium-chain fatty acid production using GPCR-based chemical sensors
    Sarria, Stephen
    Bhattacharyya, Souryadeep
    Peralta-Yahya, Pamela
    PROTEIN SCIENCE, 2015, 24 : 2 - 2
  • [30] Acidogenic fermentation of food waste to generate electron acceptors and donors towards medium-chain carboxylic acids production
    Arhin, Samuel Gyebi
    Cesaro, Alessandra
    Di Capua, Francesco
    Esposito, Giovanni
    JOURNAL OF ENVIRONMENTAL MANAGEMENT, 2023, 348
12345