The production of polyhydroxyalkanoates using volatile fatty acids derived from the acidogenic biohydrogen effluents: An overview

被引:9
作者
Sekoai, Patrick [1 ]
Ezeokoli, Obinna [2 ]
Yoro, Kelvin [3 ]
Eterigho-Ikelegbe, Orevaoghene [4 ]
Habimana, Olivier [5 ]
Iwarere, Samuel [6 ]
Daramola, Michael [6 ]
Ojumu, Tunde [1 ]
机构
[1] Cape Peninsula Univ Technol, Dept Chem Engn, ZA-7535 Cape Town, South Africa
[2] North West Univ, Unit Environm Sci & Management, ZA-2520 Potchefstroom, South Africa
[3] Lawrence Berkeley Natl Lab, Energy Technol Area, 1 Cyclotron Rd, Berkeley, CA 94720 USA
[4] Univ Witwatersrand, Fac Engn & Built Environm, Sch Chem & Met Engn, DSI NRF SARChI Clean Coal Technol Res Grp, ZA-2050 Johannesburg, South Africa
[5] Univ Hong Kong, Sch Biol Sci, Pokfulam, Hong Kong, Peoples R China
[6] Univ Pretoria, Fac Engn, Dept Chem Engn, Built Environm & Informat Technol, ZA-0028 Hatfield, South Africa
来源
BIORESOURCE TECHNOLOGY REPORTS | 2022年 / 18卷
关键词
Acidogenic fermentation; Polyhydroxyalkanoates; Volatile fatty acids; CHAIN-LENGTH POLYHYDROXYALKANOATES; MIXED CULTURES; PHA PRODUCTION; CUPRIAVIDUS-NECATOR; WASTE-WATER; MICROBIAL COMMUNITY; RETENTION TIME; SCALING-UP; FOOD WASTE; POLY(3-HYDROXYBUTYRATE);
D O I
10.1016/j.biteb.2022.101111
中图分类号
Q81 [生物工程学(生物技术)]; Q93 [微生物学];
学科分类号
071005 ; 0836 ; 090102 ; 100705 ;
摘要
Biohydrogen production is regarded as the cleanest process of producing H2 due to its non-polluting features and its ability to valorize wastes. However, its industrialization remains stagnant due to the process barriers facing this technology. Research is now geared towards the beneficiation of acidogenic-derived metabolites to improve its competitiveness. The acidogenic effluents consist of chemical precursors known as volatile fatty acids (VFAs), which can serve as cheap substrates for polyhydroxyalkanoates (PHAs). PHAs are emerging as a potential replacement for petroleum-based plastics due to their environmental friendliness, biodegradability, and costeffectiveness. This overview discusses the synthesis of PHAs using acidogenic-derived VFAs as a carbon source. It examines the setpoint parameters that affect the recovery of PHAs using VFAs that are obtained from acidogenic effluents. Furthermore, the challenges that hinder the industrialization of PHAs are elucidated. The paper concludes by providing suggestions that could fast-track the development of PHAs using waste effluents.
引用
收藏
页数:12
相关论文
共 50 条
[31]   Production of polyhydroxyalkanoates from propylene oxide saponification wastewater residual sludge using volatile fatty acids and bacterial community succession [J].
Meng, Dong ;
Gong, Chunjie ;
Sukumaran, Rajeev Kumar ;
Dionysiou, Dionysios D. ;
Huang, Zhaosong ;
Li, Ruirui ;
Liu, Yuling ;
Ji, Yan ;
Gu, Pengfei ;
Fan, Xiangyu ;
Li, Qiang .
BIORESOURCE TECHNOLOGY, 2021, 329
[32]   Effects of different temperatures and pH values on volatile fatty acids production during codigestion of food waste and thermal-hydrolysed sewage sludge and subsequent volatile fatty acids for polyhydroxyalkanoates production [J].
Gong, Xiaoqiang ;
Wu, Menghan ;
Jiang, Yong ;
Wang, Hui .
BIORESOURCE TECHNOLOGY, 2021, 333
[33]   Production of biomethane, biohydrogen, and volatile fatty acids from Nordic phytoplankton biomass grown in blended wastewater [J].
Wicker, Rebecca J. ;
Daneshvar, Ehsan ;
Patel, Alok ;
Dhar, Bipro Ranjan ;
Bhatnagar, Amit .
CHEMICAL ENGINEERING JOURNAL, 2024, 479
[34]   Acidogenic Fermentation of Cassava Wastewater: Effect of the Substrate-to-Microorganism Ratio and Temperature on Volatile Fatty Acids Production [J].
Sanchez-Ledesma, Lina Marcela ;
Rodriguez-Victoria, Jenny Alexandra ;
Ramirez-Malule, Howard .
WATER, 2024, 16 (23)
[35]   Recovery and concentration of thermally hydrolysed waste activated sludge derived volatile fatty acids and nutrients by microfiltration, electrodialysis and struvite precipitation for polyhydroxyalkanoates production [J].
Tao, Bing ;
Passanha, Pearl ;
Kumi, Philemon ;
Wilson, Victoria ;
Jones, Dean ;
Esteves, Sandra .
CHEMICAL ENGINEERING JOURNAL, 2016, 295 :11-19
[36]   Effects of volatile fatty acids in biohydrogen effluent on biohythane production from palm oil mill effluent under thermophilic condition [J].
Mamimin, Chonticha ;
Prasertsan, Poonsuk ;
Kongjan, Prawit ;
O-Thong, Sompong .
ELECTRONIC JOURNAL OF BIOTECHNOLOGY, 2017, 29 :78-85
[37]   Structural optimization of biohydrogen production: Impact of pretreatments on volatile fatty acids and biogas parameters [J].
Mahmoodi-Eshkaftaki, Mahmood ;
Mockaitis, Gustavo .
INTERNATIONAL JOURNAL OF HYDROGEN ENERGY, 2022, 47 (11) :7072-7081
[38]   Enhanced volatile fatty acids production from solid-state acidogenic fermentation of food waste by optimization of substrate to inoculum ratio [J].
Esfandiar, Razieh ;
Najafpour-Darzi, Ghasem ;
Mohammadi, Maedeh .
BIOMASS CONVERSION AND BIOREFINERY, 2025, 15 (12) :18421-18436
[39]   Targeted Acidogenic Fermentation of Waste Streams for the Selective Production of Volatile Fatty Acids as Bioplastic Precursors [J].
Hidalgo, Dolores ;
Garrote, Lidia ;
Infante, Francisco ;
Martin-Marroquin, Jesus M. ;
Perez-Zapatero, Enrique ;
Corona, Francisco .
APPLIED SCIENCES-BASEL, 2025, 15 (11)
[40]   An Overview of Recent Advancements in Microbial Polyhydroxyalkanoates (PHA) Production from Dark Fermentation Acidogenic Effluents: A Path to an Integrated Bio-Refinery [J].
Saratale, Rijuta Ganesh ;
Cho, Si-Kyung ;
Saratale, Ganesh Dattatraya ;
Kumar, Manu ;
Bharagava, Ram Naresh ;
Varjani, Sunita ;
Kadam, Avinash A. ;
Ghodake, Gajanan S. ;
Palem, Ramasubba Reddy ;
Mulla, Sikandar I. ;
Kim, Dong-Su ;
Shin, Han-Seung .
POLYMERS, 2021, 13 (24)
12345