Advances in Polyhydroxyalkanoate (PHA) Production

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crude glycerol; polyhydroxyalkanoate; ε-polylysine; Bacillus licheniformis; fermentation; PHA; monomer evolution; mixed culture; modeling; polymer composition; biopolymer; cyanobacteria; polyhydroxyalkanoates; CO2 mitigation; flue gas utilization; photobioreactor; 4-hydroxybutyrate; biopolymers; Burkholderia sacchari; copolyester; poly(3-hydroxybutyrate-co-4-hydroxybutyrate); polyhydroxyalkanoate (PHA); saccharose; sucrose; sugarcane; polyhydroxyalkanoates; poly(3-hydroxybutyrate-co-3-hydroxyhexanoate); poly(ε-caprolactone); polymers blend; tissue engineering; scaffolds; additive manufacturing; computer-aided wet-spinning; archaea; halophiles; sugarcane bagasse; polyhydroxyalkanoates; Halogeometricum borinquense strain E3; Soxhlet extractor; bioprospecting; biopolymer; environmental diversity; polyhydroxyalkanoates; detoxification; lignite; Burkholderia; biopolymer; municipal sewage plant; PHA; primary sludge; VFA; polyhydroxyalkanoates; biopolymers; renewable feedstock; mixed microbial consortia; enrichment strategy; pure cultures; synthetic biology; downstream processing; Pseudomonas putida; flow cytometry; polyhydroxyalkanoate; PHA mobilization; PHA depolymerization; starvation; carbon limitation; BODIPY 493/503; biopolymer; seawater; waste glycerol; deep sea; polyhydroxyalkanoate; PHA; copolymer; soybean wastewater; polyhydroxyalkanoates; PHAs; non-oxidized PE wax; N-PEW; Cupriavidus necator H16; bacteria; copolyester; feedstocks; fermentation; haloarchaea; metabolism; mixed microbial cultures; polyhydroxyalkanoate; strain selection; process engineering; processing; pure culture; sustainability; waste streams