Poly(3‐hydroxybutyrate) production by <i>Bacillus cereus</i> SPV using sugarcane molasses as the main carbon source

Akaraonye, Everest; Moreno, Catalina; Knowles, Jonathan C.; Keshavarz, Tajalli; Roy, Ipsita

doi:10.1002/biot.201100122

Cited by 65 publications

(29 citation statements)

References 24 publications

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“…However, quite interestingly, there have been only few reports on the utilization of pure or refined substrates (sugars) for P(3HB) production, [27][28][29][30] while different types of inexpensive carbon sources such as agro-industrial wastes including cane molasses, sugar beet juice, rice straw hydrolysate, grass biomass hydrolysate, plant oils e.g., coconut oil, have been largely investigated. [31][32][33][34][35][36][37][38] Alcaligenes and Bacillus sp. remain the microorganisms of choice for P(3HB) production (Table 1).…”

Section: Batch Fermentationmentioning

confidence: 99%

“…62 Another fed-batch strategy involving substrate feeding at a constant feed rate for P(3HB) production has been described. 31,64 A novel exponential feeding strategy based on alkali-addition monitoring was developed to maintain waste glycerol (substrate) at a constant level inside the bioreactor. 65 It resulted in a significantly high P(3HB) concentration of 65.6 g L -1 , yield of 62.7 % dcw, and productivity of 1.3 g L -1 h -1…”

Section: Fed-batch Fermentationmentioning

confidence: 99%

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Strategies for Large-scale Production of Polyhydroxyalkanoates

Kaur

Roy

2015

Chem.Biochem.Eng.Q.

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Polyhydroxyalkanoates (PHAs) are biodegradable and biocompatible intracellular polyesters that are accumulated as energy and carbon reserves by bacterial species, under nutrient limiting conditions. Successful large-scale production of PHAs is dependent on three crucial factors, which include the cost of substrate, downstream processing cost, and process development. In this respect, design and implementation of bioprocess strategies for efficient PHA bioconversions enable high PHA concentrations, yields and productivities. Additionally, development of PHA fermentation processes using inexpensive substrates, such as agro-industrial wastes, facilitates further cost reduction, thus benefitting large-scale PHA production. Thus, the aim of this review is to highlight various bioprocess strategies for high production of PHAs and their novel copolymers in relatively large quantities. This review also discusses the application of kinetic analysis and mathematical modelling as important tools for process optimization and thus improvement of the overall process economics for large-scale production of PHAs.

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Section: Batch Fermentationmentioning

confidence: 99%

Section: Fed-batch Fermentationmentioning

confidence: 99%

Strategies for Large-scale Production of Polyhydroxyalkanoates

Kaur

Roy

2015

Chem.Biochem.Eng.Q.

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“…Being the unwanted waste from food industry, WCO also demonstrates its value as substrate for PHA production (1.180 USD$/kg PHA). Agreeing with the literature (Akaraonye et al 2012), further analysis has shown that carbon source has dominated the share of raw material cost which contribute at least 66.3 % of the total cost. Internal rate of return (IRR) and total annual cost (TAC) have always been used by the literature (Gurieff and Lant 2007;Van Wegen et al 1998;Choi et al 2010) to evaluate economic performance of PHAs biosynthesis process.…”

Section: Economic Assessment Of Pha Biosynthesismentioning

confidence: 72%

“…For the determination of PHB content, the GC method of Akaraonye et al with slight modification was employed (Akaraonye et al 2012). 2 mL of chloroform and 2 mL of acidified methanol which contained 1 % v/v of sulphuric acid were added to approximately 20-mg dried samples.…”

Section: Biomass Determination and Pha Content Analysismentioning

confidence: 99%

Preliminary integrated economic and environmental analysis of polyhydroxyalkanoates (PHAs) biosynthesis

Leong

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Lin

et al. 2016

Bioresour. Bioprocess.

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Being biodegradable and renewable, polyhydroxyalkanoates (PHAs), a green polymer, attract much attentions as potential alternative for conventional plastics due to increased concern towards environmental issue and resource depletion. However, PHAs not only have suffered some economic disadvantages on the market, and its environmental-friendliness has also been questioned as well. Therefore, there is a growing demand to improve both economic and environmental performances of PHAs production, especially at earlier stage of the process where there are plenty of opportunities and the modification cost is cheap. Therefore, a preliminary integrated assessment is introduced to provide a rapid evaluation for PHAs biosynthesis at R&D stage by coupling material cost analysis together with lifecycle assessment. Using fuzzy approach multi-objective optimization, crude glycerol is the most optimum substrate for biopolymer productions from Cupriavidus necator. The insight from sensitivity analysis has showed that the integrated assessment is sensitive to fluctuation in price and yield of substrate, while maintaining its robustness as similar result is obtained when using different multi-objective optimization tools. Providing some novel insights on PHAs biosynthesis like performance and site selection influencing factor, the integrated assessment can be used to facilitate screening for large-scale production of PHAs.

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“…[326] Sinorhizobium meliloti 41 and Hydrogenophaga pseudoflava DSM 1034 can biosynthesize P(3HB), P(3HB-co-3HV) copolyesters, and P(3HB-co-3HV-co-4HB) terpolyesters from lactose. [329][330][331] Furthermore, PHAs can also be produced directly from molasses (e.g.,s ugarcane, sugar beet,a nd soy molasses), ahigh sucrose content byproduct from the sugar industry,o ro ther sucrose-rich products (e.g.,m aple sap, sugar beet juice, pineapple juice, or oil palm frondj uice) by using C. necator, [332] A. vinelandii, [331] Enterobacter species, [333] Pseudomonas corrugate, [334] A. latus, [335] recombinant E. coli, [336,337] B. subtilis, [337] B. megaterium, [338] Bacillus cereus, [339] or mixed cultures. [327] Sucrose, ad isaccharide composed of ag lucosea nd af ructose unit, is one of the most abundant and relativelyi nexpensive carbon sources extracted from sugar-bearing raw materials, such as sugar beet and sugarcane.…”

Section: Carbohydratesmentioning

confidence: 99%

Biotic and Abiotic Synthesis of Renewable Aliphatic Polyesters from Short Building Blocks Obtained from Biotechnology

2018

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Biobased polymers have seen their attractiveness increase in recent decades thanks to the significant development of biorefineries to allow access to a wide variety of biobased building blocks. Polyesters are one of the best examples of the development of biobased polymers because most of them now have their monomers produced from renewable resources and are biodegradable. Currently, these polyesters are mainly produced by using traditional chemical catalysts and harsh conditions, but recently greener pathways with nontoxic enzymes as biocatalysts and mild conditions have shown great potential. Bacterial polyesters, such as poly(hydroxyalkanoate)s (PHA), are the best example of the biotic production of high molar mass polymers. PHAs display a wide variety of macromolecular architectures, which allow a large range of applications. The present contribution aims to provide an overview of recent progress in studies on biobased polyesters, especially those made from short building blocks, synthesized through step-growth polymerization. In addition, some important technical aspects of their syntheses through biotic or abiotic pathways have been detailed.

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Poly(3‐hydroxybutyrate) production by Bacillus cereus SPV using sugarcane molasses as the main carbon source

Cited by 65 publications

References 24 publications

Strategies for Large-scale Production of Polyhydroxyalkanoates

Strategies for Large-scale Production of Polyhydroxyalkanoates

Preliminary integrated economic and environmental analysis of polyhydroxyalkanoates (PHAs) biosynthesis

Biotic and Abiotic Synthesis of Renewable Aliphatic Polyesters from Short Building Blocks Obtained from Biotechnology

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