Production of biodiesel by enzymatic transesterification of non-edible Salvadora persica (Pilu) oil and crude coconut oil in a solvent-free system

Azeem Abdul Aziz Budhwani; Ayesha Maqbool; Tanveer Hussain; Muhammad Noman Syed

doi:10.1186/s40643-019-0275-3

Bioresources and Bioprocessing ›› 2019, Vol. 6 ›› Issue (1) : 41 DOI: 10.1186/s40643-019-0275-3

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Production of biodiesel by enzymatic transesterification of non-edible Salvadora persica (Pilu) oil and crude coconut oil in a solvent-free system

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Abstract

Background

It is becoming imperative to develop renewable fuels such as biodiesel which are sustainable and environmentally friendly. Exploiting non-edible oils is more necessary to reduce dependency of edible oils for biodiesel production. The current study investigated biodiesel production from non-edible Salvadora persica seed oil (SPSO) and crude coconut oil (CCO) by Burkholderia cepacia lipase acting as a biocatalyst in a solvent-free system. The biodiesel yield produced from these feedstocks was compared and the effect of ethanol (acyl acceptor) vs. SPSO and CCO in various ratios on biodiesel production was determined.

Results

The presence of medium-chain fatty acids in majority was confirmed for SPSO and CCO while the average molecular weight was calculated as 749.53 g/mol and 664.57 g/mol, respectively. Thin Layer Chromatography indicated ethyl esters in the produced Salvadora and coconut biodiesel samples. Maximum biodiesel yield (around 70%) was obtained at 1:4 oil-to-ethanol molar ratio from both oils followed by a decline at higher ratios. The gas chromatographic analysis of Salvadora biodiesel at 1:4 molar ratio showed that the yield of individual esters was mostly of medium- and long-chain fatty acids. The analysis of coconut biodiesel at 1:4 molar ratio revealed that it consists mainly of the esters of medium-chain fatty acids. A comparison of estimated properties of biodiesel from both the parent oils with the international standard showed that it meets most of the requirements.

Conclusion

The study paves the way for a green route for biodiesel production and would promote the use of non-edible vegetable oils over edible ones to produce biodiesel. Further, it is a right step to use lipases in biodiesel production as compared to chemical catalysts. Ethanol, which can also be produced from biomass fermentation, can be used as acyl acceptor to produce biodiesel and this makes the process eco-friendly. Moreover, Burkholderia cepacia lipase is a good choice among lipases to get high biodiesel yields successfully from SPSO and CCO at low oil-to-ethanol molar ratios.

Keywords

Salvadora persica seed oil / Crude coconut oil / Biodiesel / Thin layer chromatography / Gas chromatography

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Azeem Abdul Aziz Budhwani, Ayesha Maqbool, Tanveer Hussain, Muhammad Noman Syed. Production of biodiesel by enzymatic transesterification of non-edible Salvadora persica (Pilu) oil and crude coconut oil in a solvent-free system. Bioresources and Bioprocessing, 2019, 6(1): 41 DOI:10.1186/s40643-019-0275-3

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Abdulla R, Ravindra P. Immobilized Burkholderia cepacia lipase for biodiesel production from crude Jatropha curcas L. oil. Biomass Bioenergy, 2013, 56: 8-13.

[2]	Al-Zuhair S. Production of biodiesel: possibilities and challenges. Biofuel Bioprod Biorefin, 2007, 1: 57-66.

[3]	Atabani AE, Silitonga AS, Badruddin IA, Mahlia TMI, Masjuki HH, Mekhilef S. A comprehensive review on biodiesel as an alternative energy resource and its characteristics. Renew Sust Energy Rev, 2012, 16: 2070-2093.

[4]	Babajide O, Petrik L, Musyoka N, Amigun B, Ameer F. Use of coal fly ash as a catalyst in the production of biodiesel. Pet Coal, 2010, 52: 261-272.

[5]	Barabás I, Todoruţ IA. Montero G. Biodiesel quality, standards and properties. Biodiesel: quality, emissions and by-products, 2011, Rijeka: InTech.

[6]	Bommarius AS, Riebel-Bommarius BR. Biocatalysis: fundamentals and applications, 2004, Weinheim: Wiley-VCH

[7]	Bureau C. The CRB commodity yearbook 2006 with CD-ROM, 2007, Hoboken: Wiley.

[8]	Carvalho AK, da Conceição LR, Silva JP, Perez VH, de Castro HF. Biodiesel production from Mucor circinelloides using ethanol and heteropolyacid in one and two-step transesterification. Fuel, 2017, 202: 503-511.

[9]	Chen YH, Chen JH, Luo YM. Complementary biodiesel combination from tung and medium-chain fatty acid oils. Renew Energ, 2012, 44: 305-310.

[10]	Dossat V, Combes D, Marty A. Lipase-catalysed transesterification of high oleic sunflower oil. Enzyme Microb Technol, 2002, 30: 90-94.

[11]	Fontana JD, Zagonel G, Vechiatto WW, Costa BJ, Laurindo JC, Fontana R, Pelisson L, Jorge BH, Lanças FM. Simple TLC-screening of acylglycerol levels in biodiesel as an alternative to GC determination. J Chromatogr Sci, 2009, 47: 844-846.

[12]	Guldhe A, Singh P, Kumari S, Rawat I, Permaul K, Bux F. Biodiesel synthesis from microalgae using immobilized Aspergillus niger whole cell lipase biocatalyst. Renew Energy, 2016, 85: 1002-1010.

[13]	Gunstone FD, Harwood JL, Dijkstra AJ. The lipid handbook with CD-ROM, 2007, Boca Raton: CRC Press

[14]	Jegannathan KR, Jun-Yee L, Chan ES, Ravindra P. Production of biodiesel from palm oil using liquid core lipase encapsulated in κ-carrageenan. Fuel, 2010, 89: 2272-2277.

[15]	Khan MA, Qaiser M. Khan MA, Böer B, Kust GS, Barth HJ. Halophytes of Pakistan: characteristics, distribution and potential economic usages. Sabkha ecosystems volume II: West and Central Asia, 2006, Dordrecht: Springer, Netherlands

[16]	Kumar S, Rani C, Mangal M. A Critical review on Salvadora persica: an important medicinal plant of arid zone. Int J Phytomedicine, 2012, 4: 292-303.

[17]	Lara PV, Park EY. Potential application of waste activated bleaching earth on the production of fatty acid alkyl esters using Candida cylindracea lipase in organic solvent system. Enzyme Microb Tech, 2004, 34: 270-277.

[18]	Liu J, Deng L, Wang M, Nie K, Liu L, Tan T, Wang F. Lipase catalyzed synthesis of medium-chain biodiesel from cinnamonum camphora seed oil. Chinese J Chem Eng, 2014, 22: 1215-1219.

[19]	Marina AM, Che Man YB, Amin I. Virgin coconut oil: emerging functional food oil. Trends Food Sci Tech, 2009, 20: 481-487.

[20]	Mariod AA, Matthäus B, Hussein IH. Chemical characterization of the seed and antioxidant activity of various parts of Salvadora persica. J Am Oil Chem Soc, 2009, 86: 857-865.

[21]	Marty A, Dossat V, Condoret JS. Continuous operation of lipase-catalyzed reactions in nonaqueous solvents: influence of the production of hydrophilic compounds. Biotechnol Bioeng, 1997, 56: 232-237.

[22]	Oliveira MVS, Da Rós PCM, Mattedi S, Castro HF, Soares CMF, Lima ÁS. Transesterification of babassu oil catalyzed by Burkholderia cepacia encapsulated in sol-gel matrix employing protic ionic liquid as an additive. Acta Sci Technol, 2014, 36: 445-451.

[23]	Pham LJ. McKeon TA, Hayes DG, Hildebrand DF, Weselake RJ. Coconut (Cocos nucifera). Industrial oil crops, 2016, Urbana: AOCS Press.

[24]	Pleiss J, Fischer M, Schmid RD. Anatomy of lipase binding sites: the scissile fatty acid binding site. Chem Phys Lipids, 1998, 93: 67-80.

[25]	Rahman HIH (2000) The chemistry of coconut oil. Bruneiana: Anthology of Science Articles 1:9–15

[26]	Ramadhas AS, Jayaraj S, Muraleedharan C. Biodiesel production from high FFA rubber seed oil. Fuel, 2005, 84: 335-340.

[27]	Reddy MP, Shah MT, Patolia JS. Salvadora persica, a potential species for industrial oil production in semiarid saline and alkali soils. Ind Crops Prod, 2008, 28: 273-278.

[28]	Rossell JB, King B, Downes MJ. Composition of oil. J Am Oil Chem Soc, 1985, 62: 221-230.

[29]	Saifuddin N, Fazlili AS, Kumaran P, Pei-Jua N, Priathashini P. The production of biodiesel and bio-kerosene from coconut oil using microwave assisted reaction. IOP Conf Ser Earth Environ Sci, 2016, 32: 012039.

[30]	Sánchez DA, Tonetto GM, Ferreira ML. Burkholderia cepacia lipase: a versatile catalyst in synthesis reactions. Biotechnol Bioeng, 2018, 115: 6-24.

[31]	Sebastian J, Muraleedharan C, Santhiagu A. A comparative study between chemical and enzymatic transesterification of high free fatty acid contained rubber seed oil for biodiesel production. Cogent Eng, 2016, 3: 1178370.

[32]	Shahidi F. Nutraceutical and specialty lipids and their co-products, 2006, Boca Raton: CRC Taylor & Francis.

[33]	Sharma A, Kar SK. Energy sustainability through green energy, 2015, India: Springer.

[34]	Shrestha D, Gerpen JV. Singh BP. Biodiesel from oilseed crops. Industrial crops and uses, 2010, Wallingford: CABI.

[35]	Soumanou MM, Bornscheuer UT. Improvement in lipase-catalyzed synthesis of fatty acid methyl esters from sunflower oil. Enzyme Microb Technol, 2003, 33: 97-103.

[36]	Souza LTA, Mendes AA, Castro HFD. Selection of lipases for the synthesis of biodiesel from jatropha oil and the potential of microwave irradiation to enhance the reaction rate. Biomed Res Int, 2016

[37]	Suryanto A, Suprapto S, Mahfud M. The production of biofuels from coconut oil using microwave. Mod Appl Sci, 2015, 9: 93-98.

[38]	Talebi AF, Tabatabaei M, Chisti Y. BiodieselAnalyzer: a user-friendly software for predicting the properties of prospective biodiesel. Biofuel Res J, 2014, 1: 55-57.

[39]	Talebian-Kiakalaieh A, Amin NAS, Mazaheri H. A review on novel processes of biodiesel production from waste cooking oil. Appl Energy, 2013, 104: 683-710.