Integrated Biorefinery Design with Techno‐Economic and Life Cycle Assessment Tools in Polyhydroxyalkanoates Processing
Copyright policy )Integrated Biorefinery Design with Techno‐Economic and Life Cycle Assessment Tools in Polyhydroxyalkanoates Processing
AbstractTo support and move toward a sustainable bioeconomy, the production of polyhydroxyalkanoates (PHAs) using renewable biomass has acquired more attention. However, expensive biomass pretreatment and low yield of PHAs pose significant disadvantages in its large‐scale production. To overcome such limitations, the most recent advances in metabolic engineering strategies used to develop high‐performance strains that are leading to a new manufacturing concept converting biomass to PHAs with co‐products such as amino acids, proteins, biohydrogen, biosurfactants, and various fine chemicals are critically summarized. This review article presents a comprehensive roadmap that highlights the integrated biorefinery strategies, lifecycle analysis, and techno‐economic assessment for sustainable and economic PHAs production. Finally, current and future challenges that must be addressed to transfer this technology to real‐world applications are reviewed.
- Universiti Malaysia Terengganu Malaysia
- Universiti Malaysia Terengganu Malaysia
- Saveetha University India
- Saveetha University India
- Chandigarh University India
Biomass (ecology), Renewable energy, techno‐economic analysis, Economics, Macroeconomics, Organic chemistry, Engineering, Production (economics), Materials of engineering and construction. Mechanics of materials, Polyhydroxyalkanoates, Chemical Engineering, Engineering (General). Civil engineering (General), Bioplastic, Chemistry, Physical Sciences, TA401-492, TA1-2040, Biohydrogen, Biodegradable Polymers as Biomaterials and Packaging, Biotechnology, Life-cycle assessment, Materials Science, Biomedical Engineering, Carbon Dioxide Utilization for Chemical Synthesis, FOS: Medical engineering, Biomaterials, life cycle assessment, Biofuel, Genetics, Waste management, Biology, FOS: Chemical engineering, Bacteria, Process Chemistry and Technology, polyhydroxyalkanoates, integrated biorefinery, Agronomy, Biorefinery, Manufacturing engineering, Biochemical engineering, Catalytic Conversion of Biomass to Fuels and Chemicals, Electrical engineering, FOS: Biological sciences, Hydrogen production, Hydrogen
Biomass (ecology), Renewable energy, techno‐economic analysis, Economics, Macroeconomics, Organic chemistry, Engineering, Production (economics), Materials of engineering and construction. Mechanics of materials, Polyhydroxyalkanoates, Chemical Engineering, Engineering (General). Civil engineering (General), Bioplastic, Chemistry, Physical Sciences, TA401-492, TA1-2040, Biohydrogen, Biodegradable Polymers as Biomaterials and Packaging, Biotechnology, Life-cycle assessment, Materials Science, Biomedical Engineering, Carbon Dioxide Utilization for Chemical Synthesis, FOS: Medical engineering, Biomaterials, life cycle assessment, Biofuel, Genetics, Waste management, Biology, FOS: Chemical engineering, Bacteria, Process Chemistry and Technology, polyhydroxyalkanoates, integrated biorefinery, Agronomy, Biorefinery, Manufacturing engineering, Biochemical engineering, Catalytic Conversion of Biomass to Fuels and Chemicals, Electrical engineering, FOS: Biological sciences, Hydrogen production, Hydrogen
