De-Oiled Rice Bran as a Source of Bioethanol

Beliya, Esmil; Tiwari, Sakshi; Jadhav, S. K.; Tiwari, K. L.

doi:10.1260/0144-5987.31.5.771

Cited by 14 publications

(8 citation statements)

References 23 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Banerjee et al (2009) studied effect of temperature on bioethanol production from rice husk and found maximum production at 30°C. Beliya et al (2013) found 25°C was optimum temperature for bioethanol production from deoiled rice bran.…”

Section: Effect Of Temperature Variations On Bioethanol Productionmentioning

confidence: 91%

See 1 more Smart Citation

Bioethanol production from rice bran with optimization of parameters by Bacillus cereus strain McR-3

Tiwari

Jadhav

Tiwari

2015

Int. J. Environ. Sci. Technol.

View full text Add to dashboard Cite

The potential environmental benefits that can be obtained from replacing petroleum fuels with biofuels derived from renewable biomass sources are the main driving forces for promoting the production and use of biofuels. Due to depletion of fossil fuels, ethanol, which can be obtained via the bioconversion of renewable feedstock, is widely regarded as an efficient alternative for gasoline as transportation fuel. Biomass energy can play an important role in reducing greenhouse gas emissions. Rice bran is a by-product of milling process of rice, and due to its carbohydrate contents, it may serve as good source for bioethanol production. The present study deals with bioethanol production from rice bran and screening of bioethanol-producing bacteria from rice bran. In the screening process, three fermentative bacteria were obtained; they were studied on the basis of morphology, biochemical characteristics and maximum bioethanol production. The maximum bioethanol-producing bacteria was identified by sequencing method. The bacteria thus identified as Bacillus cereus strain McR-3 is a novel bacteria reported in bioethanol production from rice bran substrate. Different parameters like temperature and pH also affects the production of bioethanol. It was observed that optimum temperature and pH for maximum bioethanol production was 37°C and 5, respectively.

show abstract

Section: Effect Of Temperature Variations On Bioethanol Productionmentioning

confidence: 91%

“…Pandey et al (2013) used azolla as a source of bioethanol. Beliya et al (2013) used deoiled rice bran for bioethanol production. Tiwari et al (2014) produced fuel ethanol from waste fruits.…”

Section: Introductionmentioning

confidence: 99%

Bioethanol production from rice bran with optimization of parameters by Bacillus cereus strain McR-3

Tiwari

Jadhav

Tiwari

2015

Int. J. Environ. Sci. Technol.

View full text Add to dashboard Cite

show abstract

“…The bioethanol yield had a value of 0.42 g/g and productivity of 0.173 g/L/h. Biological pretreatment with the fungus Aspergillus niger increased the ethanol production by P. kudriavzevii RCEF4907 in the study of Beliya et al [58]. Under optimum conditions of temperature (25 • C), pH (6.5) and nutrients (addition of 1% Urea), the strain was able to produce 11.4% ethanol.…”

Section: Production Of Bioethanolmentioning

confidence: 97%

Valorising Agro-industrial Wastes within the Circular Bioeconomy Concept: the Case of Defatted Rice Bran with Emphasis on Bioconversion Strategies

et al. 2020

View full text Add to dashboard Cite

The numerous environmental problems caused by the extensive use of fossil resources have led to the formation of the circular bioeconomy concept. Renewable resources will constitute the cornerstone of this new, sustainable model, with biomass presenting a huge potential for the production of fuels and chemicals. In this context, waste and by-product streams from the food industry will be treated not as “wastes” but as resources. Rice production generates various by-product streams which currently are highly unexploited, leading to environmental problems especially in the countries that are the main producers. The main by-product streams include the straw, the husks, and the rice bran. Among these streams, rice bran finds applications in the food industry and cosmetics, mainly due to its high oil content. The high demand for rice bran oil generates huge amounts of defatted rice bran (DRB), the main by-product of the oil extraction process. The sustainable utilisation of this by-product has been a topic of research, either as a food additive or via its bioconversion into value-added products and chemicals. This review describes all the processes involved in the efficient bioconversion of DRB into biotechnological products. The detailed description of the production process, yields and productivities, as well as strains used for the production of bioethanol, lactic acid and biobutanol, among others, are discussed.

show abstract

“…% from the sugar beet pulp (Rezic et al, 2013). De-oiled rice bran was reported to yield 10.5e11.4 % ethanol (Beliya et al, 2013). Switch grass germplasms yielded 0.082 g ethanol/g of raw biomass (Yang et al, 2009).…”

Section: Fermentation Of Hydrolyzate E Ethanol Productionmentioning

confidence: 99%

Assessment of holocellulose for the production of bioethanol by conserving Pinus radiata cones as renewable feedstock

Victor

Pulidindi

Gedanken

2015

Journal of Environmental Management

View full text Add to dashboard Cite

De-Oiled Rice Bran as a Source of Bioethanol

Cited by 14 publications

References 23 publications

Bioethanol production from rice bran with optimization of parameters by Bacillus cereus strain McR-3

Bioethanol production from rice bran with optimization of parameters by Bacillus cereus strain McR-3

Valorising Agro-industrial Wastes within the Circular Bioeconomy Concept: the Case of Defatted Rice Bran with Emphasis on Bioconversion Strategies

Assessment of holocellulose for the production of bioethanol by conserving Pinus radiata cones as renewable feedstock

Contact Info

Product

Resources

About