Entrapping Immobilisation of Lipase on Biocomposite Hydrogels toward for Biodiesel Production from Waste Frying Acid Oil

Entrapping Immobilisation of Lipase on Biocomposite Hydrogels toward for Biodiesel Production from Waste Frying Acid Oil

A new application of biocomposite hydrogels named gelatin-alginate (GA) and pectin alginate (PA) enables the use of the hydrogels as carriers for lipase entrapment during biodiesel production. Waste frying acid oil (WFAO), a raw material, was converted to biodiesel via an esterification reaction cat...

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Main Authors: Papasanee Muanruksa, Praepilas Dujjanutat, Pakawadee Kaewkannetra
Format: Article
Language:English
Published: MDPI AG 2020-07-01
Series:Catalysts
Subjects:
biocomposite hydrogel
waste frying acid oil
esterification reaction
immobilised lipase
biodiesel
Online Access:https://www.mdpi.com/2073-4344/10/8/834
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spelling doaj-9e108d1833524ecbadf1a12e599b32ef2020-11-25T03:29:25ZengMDPI AGCatalysts2073-43442020-07-011083483410.3390/catal10080834Entrapping Immobilisation of Lipase on Biocomposite Hydrogels toward for Biodiesel Production from Waste Frying Acid OilPapasanee Muanruksa0Praepilas Dujjanutat1Pakawadee Kaewkannetra2Graduate School of Khon Kaen University, Khon Kaen 40002, ThailandPostdoctoral Training of Department of Biotechnology, Khon Kaen University, Khon Kaen 40002, ThailandCentre for Alternative Energy Research and Development (AERD), Faculty of Engineering, Khon Kaen University, Khon Kaen 40002, ThailandA new application of biocomposite hydrogels named gelatin-alginate (GA) and pectin alginate (PA) enables the use of the hydrogels as carriers for lipase entrapment during biodiesel production. Waste frying acid oil (WFAO), a raw material, was converted to biodiesel via an esterification reaction catalysed by two different immobilised biocatalysts: gelatin-alginate lipase (GAL) and pectin-alginate lipase (PAL). The highest immobilisation yield of GAL and PAL beads was achieved at 97.61% and 98.30%, respectively. Both of them gave biodiesel yields in the range of 75–78.33%. Furthermore, capability and reusability of biocatalysts were improved such that they could be reused up to 7 cycles. Moreover, the predicted biodiesel properties met the European biodiesel standard (EN14214). Interestingly, entrapped lipase on composite hydrogels can be used as an alternative catalyst choice for replacing the chemical catalyst during the biodiesel production.https://www.mdpi.com/2073-4344/10/8/834biocomposite hydrogelwaste frying acid oilesterification reactionimmobilised lipasebiodiesel
collection DOAJ
language English
format Article
sources DOAJ
author Papasanee Muanruksa
Praepilas Dujjanutat
Pakawadee Kaewkannetra
spellingShingle Papasanee Muanruksa
Praepilas Dujjanutat
Pakawadee Kaewkannetra
Entrapping Immobilisation of Lipase on Biocomposite Hydrogels toward for Biodiesel Production from Waste Frying Acid Oil
Catalysts
biocomposite hydrogel
waste frying acid oil
esterification reaction
immobilised lipase
biodiesel
author_facet Papasanee Muanruksa
Praepilas Dujjanutat
Pakawadee Kaewkannetra
author_sort Papasanee Muanruksa
title Entrapping Immobilisation of Lipase on Biocomposite Hydrogels toward for Biodiesel Production from Waste Frying Acid Oil
title_short Entrapping Immobilisation of Lipase on Biocomposite Hydrogels toward for Biodiesel Production from Waste Frying Acid Oil
title_full Entrapping Immobilisation of Lipase on Biocomposite Hydrogels toward for Biodiesel Production from Waste Frying Acid Oil
title_fullStr Entrapping Immobilisation of Lipase on Biocomposite Hydrogels toward for Biodiesel Production from Waste Frying Acid Oil
title_full_unstemmed Entrapping Immobilisation of Lipase on Biocomposite Hydrogels toward for Biodiesel Production from Waste Frying Acid Oil
title_sort entrapping immobilisation of lipase on biocomposite hydrogels toward for biodiesel production from waste frying acid oil
publisher MDPI AG
series Catalysts
issn 2073-4344
publishDate 2020-07-01
description A new application of biocomposite hydrogels named gelatin-alginate (GA) and pectin alginate (PA) enables the use of the hydrogels as carriers for lipase entrapment during biodiesel production. Waste frying acid oil (WFAO), a raw material, was converted to biodiesel via an esterification reaction catalysed by two different immobilised biocatalysts: gelatin-alginate lipase (GAL) and pectin-alginate lipase (PAL). The highest immobilisation yield of GAL and PAL beads was achieved at 97.61% and 98.30%, respectively. Both of them gave biodiesel yields in the range of 75–78.33%. Furthermore, capability and reusability of biocatalysts were improved such that they could be reused up to 7 cycles. Moreover, the predicted biodiesel properties met the European biodiesel standard (EN14214). Interestingly, entrapped lipase on composite hydrogels can be used as an alternative catalyst choice for replacing the chemical catalyst during the biodiesel production.
topic biocomposite hydrogel
waste frying acid oil
esterification reaction
immobilised lipase
biodiesel
url https://www.mdpi.com/2073-4344/10/8/834
work_keys_str_mv AT papasaneemuanruksa entrappingimmobilisationoflipaseonbiocompositehydrogelstowardforbiodieselproductionfromwastefryingacidoil
AT praepilasdujjanutat entrappingimmobilisationoflipaseonbiocompositehydrogelstowardforbiodieselproductionfromwastefryingacidoil
AT pakawadeekaewkannetra entrappingimmobilisationoflipaseonbiocompositehydrogelstowardforbiodieselproductionfromwastefryingacidoil
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