Use of waste mushroom beds for the production of value-added biodegradable fiber sheet

Walaiporn Suksai; Chaniga Chuensangjun; Jittimon Wongsa; Vilai Rungsardthong; Savitri Vatanyoopaisarn; Benjawan Thumthanaruk; Rungsima Yeetsorn; Buddhi P. Lamsal

doi:10.1051/e3sconf/202130202016

All issues

Volume 302 (2021)

E3S Web Conf., 302 (2021) 02016

References

Open Access

Issue		E3S Web Conf. Volume 302, 2021 2021 Research, Invention, and Innovation Congress (RI²C 2021)


Article Number		02016
Number of page(s)		10
Section		Environmental Science and Engineering
DOI		https://doi.org/10.1051/e3sconf/202130202016
Published online		10 September 2021

P. Kalac, Mineral composition and radioactivity of edible mushrooms (Elsevier Inc., London, 2019) [Google Scholar]
M.C. Tseng, J.H. Luong, Mushroom cultivation – technology for chemical production, Fermentation Processes, 7 (1984): 45–79 [Google Scholar]
P. Karpilanondh, Mushroom technology (Textbook Publishing Center KMUTNB, 2018) [Google Scholar]
S. Ritnuch, Straw mushroom cultivation in a plastic bag (Offset Creation, 2009) [Google Scholar]
Z. Lou, Y. Sun, X. Zhou, S.A. Baig, B. Hu, X. Xu, Composition variability of spent mushroom substrates during continuous cultivation, composting process and their effects on mineral nitrogen transformation in soil, Geoderma Regional, 307, 19 (2017): 30–37 [Google Scholar]
S. Wu, Y. Lan, Z. Wu, Y. Peng, S. Chen, Z. Huang, L. Xu, I. Gelbic, X. Guan, L. Zhang, S. Zou, Pretreatment of spent mushroom substrate for enhancing the conversion of fermentable sugar, Bioresource Technology, 148 (2013): 596–600 [PubMed] [Google Scholar]
Z. Run-Hua, D. Zeng-Qiang, L. Zhi-Guo, Use of spent mushroom substrate as growing media for tomato and cucumber seedlings, Pedosphere, 22, 3 (2012): 333–342 [Google Scholar]
H.N. lin, Y.T. Wang, M.J. Zhu, Evaluation of spent mushroom compost as a lignocellulosic substrate for hydrogen production by Clostridium thermocellum, International Journal of Hydrogen Energy, 42 (2017): 26687–26694 [Google Scholar]
W. Anapanurak, B. Puangsin, Paper mulberry pulp properties by various alkaline processes, The research project for higher utilization of forestry and agricultural plant materials in Thailand (HUFA), (n.d.): 117–125 [Google Scholar]
W. ChaiChan, W. ChaiChan, A. Sawain, Plant pots from co-production of spent coffee grounds, shell lime and rubber wood sawdust (Rajamangala University of Technology Srivijaya, 2017) [Google Scholar]
Y.S. Cheng, P. Mutrakulcharoen, S. Chuetor, K. Cheenkachorn, P. Tantayotai, E.J. Panakkal, M. Sriariyanun, Recent situation and progress in biorefining process of lignocellulosic biomass: toward green economy, Applied Science and Engineering Progress, 13, 4 (2020): 299–311 [Google Scholar]
B.D.S. Deeraj, K. Joseph, J.S. Jayan, A. Saritha, Dynamic mechanical performance of natural fiber reinforced composites: a brief review (Applied Science and Engineering Progress, 2021) [Google Scholar]
T. Matsumura, T. Kinumoto, M. Matsuoka, T. Tsumura, M. Toyoda, Preparation of carbonaceous fiber sheets derived from bamboo and application to gas diffusion layer of proton exchange membrane fuel cells (Oita University, 2015) [Google Scholar]
P. Kuntadong, M. Peekoh, O. Sindanjark, Biocomposite films based on cassava starch reinforced with durian rind cellulose fibers, RMUTP Research Journal, 13, 1 (2019): 39–50 [Google Scholar]
H. Kargarzadeh, M. Loelovich, I. Ahmad, S. Thomas, A. Dufresne, Nanocellulose and cellulose nanocomposites (Wiley-VCH Verlag GmbH & Co. KGaA Weinheim, Germany, 2017) [Google Scholar]
C. Doree, The methods of cellulose chemistry including methods for the investigation of substances associated with cellulose in plant tissues (Chapman and Hall, London, 1947) [Google Scholar]
P. Teerapronchaisit, Polymers and biomolecules in organic compounds, (Department of Chemistry, Faculty of Applied Science, Khon Kaen University, 2010) [Google Scholar]
Y. Habibi, Key advances in the chemical modification of nanocelluloses, Chemical Society Reviews, 43 (2014): 151–1542 [Google Scholar]
R.A. SHANKS, Natural fiber, composites materials, processes and applications, Woodhead Publishing Limited, (2014): 66-83 [Google Scholar]
B. Boontima, A. Noomhorm, C. Puttanlek, D. Uttapap, V. Rungsardthong, Mechanical properties of sugarcane bagasse fiber-reinforced soy based biocomposites, Polymers and the Environment, 23, 1 (2014): 97–106 [Google Scholar]
P. Saenghirunwattana, A. Noomhorm, V. Rungsardthong, Mechanical properties of soy protein based “green” composites reinforced with surface modified cornhusk fiber, Industrial Crops and Products, 60 (2014): 144–150 [Google Scholar]
M.P. Arrieta, E. Fortunati, N. Burgos, M.A. Peltzer, J. López, L. Peponi, Nanocellulose-based polymeric blends for food packaging applications, multifunctional polymeric nanocomposites based on cellulosic reinforcements (Elsevier Inc., London, 2016) [Google Scholar]
R. Pawongrat, Pretreatment processes for enhancing the efficiency of ethanol production from lignocellulosic-agricultural wastes, Veridian EJournal, 2, 1 (2015): 143-157 [Google Scholar]
S. Sriwongchai, Biodiesel production from agricultural wastes by using biotechnological process (Burapha University, 2017) [Google Scholar]
T. Piyang, W. Chaichan, K. Sagulsawasdipan, Environment-friendly plant pot production from palm oil sludge and mushroom cultured waste, RMUTSV Research Journal, 10, 3 (2018): 497-511 [Google Scholar]
TAPPI’s (Technical Association of the Pulp and Paper Industry) International Nanotechnology Division, Roadmap for the Development of International Standards for Nanocellulose, (2011) [Google Scholar]
N. Kongklom, C. Chuensangjun, Y. Chisti, S. Sirisansaneeyakul, Improved keeping quality of Dendrobium “Bom” orchids using nutrients entrapped in a biodegradable hydrogel, Scientia Horticulturae, 234 (2018): 184–192 [Google Scholar]
A. Atiqah, M. Jawaid, M.R. Ishak, S.M. Sapuan, Moisture absorption and thickness swelling behaviour of sugar palm fiber reinforced thermoplastic polyurethane, Procedia Engineering, 184 (2017): 581–586 [Google Scholar]
P. Seephueak, C. Preecha, W. Seephueak, The study diversity of fungi and bacteria occurring on spent mushroom compost and utilization, Agricultural Technology, 13, 5 (2017) [Google Scholar]
S.H. Lim, Y.H. Lee, H.W. Kang, Efficient recovery of lignocellulolytic enzymes of spent mushroom compost from oyster mushroom, Pleurotus spp., and potential use in dye decolorization, Mycobiology, 41, 4 (2013): 214–220 [Google Scholar]
J. Kumla, N. Suwannarach, K. Sujarit, W. Penkhrue, P. Kakumyan, K. Jatuwong, S. Vadthanarat, S. Lumyong, Cultivation of mushroom and their lignocellulolytic enzyme production through the utilization of agro-industrial waste, Molecules, 25, 12 (2020) [Google Scholar]
K.O. Reddy, C.U. Maheswari, M. Shukla, E. Muzenda, Preparation, chemical composition, characterization, and properties of Napier grass paper sheets, Separation Science and Technology, 49 (2014): 1527–1534 [Google Scholar]
S. Butrat, Steam explosion for chemi-thermo mechanical pulping of physic nut (Jatropha curcas Linn.) for paper packaging applications, (Master of Science (Packaging Technology), (Department of Packaging and Materials Technology, Kasetsart University (n.d.)) [Google Scholar]
Y. Fahmy, T.A. Fahmy, F. Mobarak, M.E. Sakhawy, M. Fadl, Agricultural residues (wastes) for manufacture of paper, board, and miscellaneous products: background overview and future prospects, ChemTech Research, Sphinx Knowledge House, 10, 2 (2017): 424–448 [Google Scholar]
A. Guadie, A. Mulat, A. Kokeb, N. Gabbiye, Synthesis and characterization of Eucalyptus pulp by kraft process for paper sheet formation, Environmental Science and Technology, 1, 2 (2015): 20–26 [Google Scholar]
V. Rana, G. Joshi, S.P. Singh, P.K. Gupta, Eucalypts in pulp and paper industry (Eucalypts, India, 2016) [Google Scholar]
M. Chaisupakitsin, W. Wongsirojanakul, A. Ruengkul, O. Siriwan, Acoustical panel from coconut coir / EPS hybrid composites, Science and Technology, 15, 2 (2007): 54–60 [Google Scholar]
C. Homkhiew, S. Rawangwong, W. Boonchouytan, W. Thongruang, Mechanical and physical properties of thermoplastic natural rubber composites reinforced with rubberwood sawdust, SWU Engineering Journal, 13, 1 (2018): 107–122 [Google Scholar]
C. Ngaowthong, V. Rungsardthong, S. Siengchin, Polypropylene/hemp woody core fiber composites: Morphology, mechanical, thermal properties, and water absorption behaviors, Mechanical Engineering, 8, 3 (2016): 1–10 [Google Scholar]
V. Dogra, C. Kishore, A. Verma, A.K. Rana, A. Gaur, Fabrication and experimental testing of hybrid composite material having biodegradable bagasse fiber in a modified epoxy resin: evaluation of mechanical and morphological behavior (Applied Science and Engineering Progress, 2021) [Google Scholar]
J. Brander, Surface Application of paper chemicals (Chapman & Hall, London, 1997) [Google Scholar]
I. Spiridon, C.A. Teaca, R. Bodirlau, M. Bercea, Behavior of cellulose reinforced cross-linked starch composite films made with tartaric acid modified starch microparticles, Polymers and the Environment, 21 (2013): 431–440 [Google Scholar]
B. Nasri-Nasrabadi, M. Mehrasa, M. Rafienia, S. Bonakdar, T. Behzad, S. Gavanji, Porous starch/cellulose nanofibers composite prepared by salt leaching technique for tissue engineering, Carbohydrate Polymers, 108 (2014): 232–238 [PubMed] [Google Scholar]
B. Deepa, E. Abraham, B.M. Cherian, A. Bismarck, J.J. Blaker, L.A. Pothan, A.L. Leao, S.F. Souza, M. Kottaisamy, Structure, morphology and thermal characteristics of banana nano fibers obtained by steam explosion, Bioresource Technology, 102 (2011): 1988–1997 [PubMed] [Google Scholar]
N. Konno, M. Kimura, R. Okuzawa, Y. Nakamura, M. Ike, N. Hayashi, A. Obara, Y. Sakamoto, N. Habu, Preparation of cellulose nanofibers from waste mushroom bed of shiitak (Lentinus edodes) by TEMPO-mediated oxidation, Mokuzal Hozon (Wood Protection), 42 (2016): 157–164 [Google Scholar]

Current usage metrics show cumulative count of Article Views (full-text article views including HTML views, PDF and ePub downloads, according to the available data) and Abstracts Views on Vision4Press platform.

Data correspond to usage on the plateform after 2015. The current usage metrics is available 48-96 hours after online publication and is updated daily on week days.

Initial download of the metrics may take a while.

[1] P. Kalac, Mineral composition and radioactivity of edible mushrooms (Elsevier Inc., London, 2019) [Google Scholar]

[2] M.C. Tseng, J.H. Luong, Mushroom cultivation – technology for chemical production, Fermentation Processes, 7 (1984): 45–79 [Google Scholar]

[3] P. Karpilanondh, Mushroom technology (Textbook Publishing Center KMUTNB, 2018) [Google Scholar]

[4] S. Ritnuch, Straw mushroom cultivation in a plastic bag (Offset Creation, 2009) [Google Scholar]

[5] Z. Lou, Y. Sun, X. Zhou, S.A. Baig, B. Hu, X. Xu, Composition variability of spent mushroom substrates during continuous cultivation, composting process and their effects on mineral nitrogen transformation in soil, Geoderma Regional, 307, 19 (2017): 30–37 [Google Scholar]

[6] S. Wu, Y. Lan, Z. Wu, Y. Peng, S. Chen, Z. Huang, L. Xu, I. Gelbic, X. Guan, L. Zhang, S. Zou, Pretreatment of spent mushroom substrate for enhancing the conversion of fermentable sugar, Bioresource Technology, 148 (2013): 596–600 [PubMed] [Google Scholar]

[7] Z. Run-Hua, D. Zeng-Qiang, L. Zhi-Guo, Use of spent mushroom substrate as growing media for tomato and cucumber seedlings, Pedosphere, 22, 3 (2012): 333–342 [Google Scholar]

[8] H.N. lin, Y.T. Wang, M.J. Zhu, Evaluation of spent mushroom compost as a lignocellulosic substrate for hydrogen production by Clostridium thermocellum, International Journal of Hydrogen Energy, 42 (2017): 26687–26694 [Google Scholar]

[9] W. Anapanurak, B. Puangsin, Paper mulberry pulp properties by various alkaline processes, The research project for higher utilization of forestry and agricultural plant materials in Thailand (HUFA), (n.d.): 117–125 [Google Scholar]

[10] W. ChaiChan, W. ChaiChan, A. Sawain, Plant pots from co-production of spent coffee grounds, shell lime and rubber wood sawdust (Rajamangala University of Technology Srivijaya, 2017) [Google Scholar]

[11] Y.S. Cheng, P. Mutrakulcharoen, S. Chuetor, K. Cheenkachorn, P. Tantayotai, E.J. Panakkal, M. Sriariyanun, Recent situation and progress in biorefining process of lignocellulosic biomass: toward green economy, Applied Science and Engineering Progress, 13, 4 (2020): 299–311 [Google Scholar]

[12] B.D.S. Deeraj, K. Joseph, J.S. Jayan, A. Saritha, Dynamic mechanical performance of natural fiber reinforced composites: a brief review (Applied Science and Engineering Progress, 2021) [Google Scholar]

[13] T. Matsumura, T. Kinumoto, M. Matsuoka, T. Tsumura, M. Toyoda, Preparation of carbonaceous fiber sheets derived from bamboo and application to gas diffusion layer of proton exchange membrane fuel cells (Oita University, 2015) [Google Scholar]

[14] P. Kuntadong, M. Peekoh, O. Sindanjark, Biocomposite films based on cassava starch reinforced with durian rind cellulose fibers, RMUTP Research Journal, 13, 1 (2019): 39–50 [Google Scholar]

[15] H. Kargarzadeh, M. Loelovich, I. Ahmad, S. Thomas, A. Dufresne, Nanocellulose and cellulose nanocomposites (Wiley-VCH Verlag GmbH & Co. KGaA Weinheim, Germany, 2017) [Google Scholar]

[16] C. Doree, The methods of cellulose chemistry including methods for the investigation of substances associated with cellulose in plant tissues (Chapman and Hall, London, 1947) [Google Scholar]

[17] P. Teerapronchaisit, Polymers and biomolecules in organic compounds, (Department of Chemistry, Faculty of Applied Science, Khon Kaen University, 2010) [Google Scholar]

[18] Y. Habibi, Key advances in the chemical modification of nanocelluloses, Chemical Society Reviews, 43 (2014): 151–1542 [Google Scholar]

[19] R.A. SHANKS, Natural fiber, composites materials, processes and applications, Woodhead Publishing Limited, (2014): 66-83 [Google Scholar]

[20] B. Boontima, A. Noomhorm, C. Puttanlek, D. Uttapap, V. Rungsardthong, Mechanical properties of sugarcane bagasse fiber-reinforced soy based biocomposites, Polymers and the Environment, 23, 1 (2014): 97–106 [Google Scholar]

[21] P. Saenghirunwattana, A. Noomhorm, V. Rungsardthong, Mechanical properties of soy protein based “green” composites reinforced with surface modified cornhusk fiber, Industrial Crops and Products, 60 (2014): 144–150 [Google Scholar]

[22] M.P. Arrieta, E. Fortunati, N. Burgos, M.A. Peltzer, J. López, L. Peponi, Nanocellulose-based polymeric blends for food packaging applications, multifunctional polymeric nanocomposites based on cellulosic reinforcements (Elsevier Inc., London, 2016) [Google Scholar]

[23] R. Pawongrat, Pretreatment processes for enhancing the efficiency of ethanol production from lignocellulosic-agricultural wastes, Veridian EJournal, 2, 1 (2015): 143-157 [Google Scholar]

[24] S. Sriwongchai, Biodiesel production from agricultural wastes by using biotechnological process (Burapha University, 2017) [Google Scholar]

[25] T. Piyang, W. Chaichan, K. Sagulsawasdipan, Environment-friendly plant pot production from palm oil sludge and mushroom cultured waste, RMUTSV Research Journal, 10, 3 (2018): 497-511 [Google Scholar]

[26] TAPPI’s (Technical Association of the Pulp and Paper Industry) International Nanotechnology Division, Roadmap for the Development of International Standards for Nanocellulose, (2011) [Google Scholar]

[27] N. Kongklom, C. Chuensangjun, Y. Chisti, S. Sirisansaneeyakul, Improved keeping quality of Dendrobium “Bom” orchids using nutrients entrapped in a biodegradable hydrogel, Scientia Horticulturae, 234 (2018): 184–192 [Google Scholar]

[28] A. Atiqah, M. Jawaid, M.R. Ishak, S.M. Sapuan, Moisture absorption and thickness swelling behaviour of sugar palm fiber reinforced thermoplastic polyurethane, Procedia Engineering, 184 (2017): 581–586 [Google Scholar]

[29] P. Seephueak, C. Preecha, W. Seephueak, The study diversity of fungi and bacteria occurring on spent mushroom compost and utilization, Agricultural Technology, 13, 5 (2017) [Google Scholar]

[30] S.H. Lim, Y.H. Lee, H.W. Kang, Efficient recovery of lignocellulolytic enzymes of spent mushroom compost from oyster mushroom, Pleurotus spp., and potential use in dye decolorization, Mycobiology, 41, 4 (2013): 214–220 [Google Scholar]

[31] J. Kumla, N. Suwannarach, K. Sujarit, W. Penkhrue, P. Kakumyan, K. Jatuwong, S. Vadthanarat, S. Lumyong, Cultivation of mushroom and their lignocellulolytic enzyme production through the utilization of agro-industrial waste, Molecules, 25, 12 (2020) [Google Scholar]

[32] K.O. Reddy, C.U. Maheswari, M. Shukla, E. Muzenda, Preparation, chemical composition, characterization, and properties of Napier grass paper sheets, Separation Science and Technology, 49 (2014): 1527–1534 [Google Scholar]

[33] S. Butrat, Steam explosion for chemi-thermo mechanical pulping of physic nut (Jatropha curcas Linn.) for paper packaging applications, (Master of Science (Packaging Technology), (Department of Packaging and Materials Technology, Kasetsart University (n.d.)) [Google Scholar]

[34] Y. Fahmy, T.A. Fahmy, F. Mobarak, M.E. Sakhawy, M. Fadl, Agricultural residues (wastes) for manufacture of paper, board, and miscellaneous products: background overview and future prospects, ChemTech Research, Sphinx Knowledge House, 10, 2 (2017): 424–448 [Google Scholar]

[35] A. Guadie, A. Mulat, A. Kokeb, N. Gabbiye, Synthesis and characterization of Eucalyptus pulp by kraft process for paper sheet formation, Environmental Science and Technology, 1, 2 (2015): 20–26 [Google Scholar]

[36] V. Rana, G. Joshi, S.P. Singh, P.K. Gupta, Eucalypts in pulp and paper industry (Eucalypts, India, 2016) [Google Scholar]

[37] M. Chaisupakitsin, W. Wongsirojanakul, A. Ruengkul, O. Siriwan, Acoustical panel from coconut coir / EPS hybrid composites, Science and Technology, 15, 2 (2007): 54–60 [Google Scholar]

[38] C. Homkhiew, S. Rawangwong, W. Boonchouytan, W. Thongruang, Mechanical and physical properties of thermoplastic natural rubber composites reinforced with rubberwood sawdust, SWU Engineering Journal, 13, 1 (2018): 107–122 [Google Scholar]

[39] C. Ngaowthong, V. Rungsardthong, S. Siengchin, Polypropylene/hemp woody core fiber composites: Morphology, mechanical, thermal properties, and water absorption behaviors, Mechanical Engineering, 8, 3 (2016): 1–10 [Google Scholar]

[40] V. Dogra, C. Kishore, A. Verma, A.K. Rana, A. Gaur, Fabrication and experimental testing of hybrid composite material having biodegradable bagasse fiber in a modified epoxy resin: evaluation of mechanical and morphological behavior (Applied Science and Engineering Progress, 2021) [Google Scholar]

[41] J. Brander, Surface Application of paper chemicals (Chapman & Hall, London, 1997) [Google Scholar]

[42] I. Spiridon, C.A. Teaca, R. Bodirlau, M. Bercea, Behavior of cellulose reinforced cross-linked starch composite films made with tartaric acid modified starch microparticles, Polymers and the Environment, 21 (2013): 431–440 [Google Scholar]

[43] B. Nasri-Nasrabadi, M. Mehrasa, M. Rafienia, S. Bonakdar, T. Behzad, S. Gavanji, Porous starch/cellulose nanofibers composite prepared by salt leaching technique for tissue engineering, Carbohydrate Polymers, 108 (2014): 232–238 [PubMed] [Google Scholar]

[44] B. Deepa, E. Abraham, B.M. Cherian, A. Bismarck, J.J. Blaker, L.A. Pothan, A.L. Leao, S.F. Souza, M. Kottaisamy, Structure, morphology and thermal characteristics of banana nano fibers obtained by steam explosion, Bioresource Technology, 102 (2011): 1988–1997 [PubMed] [Google Scholar]

[45] N. Konno, M. Kimura, R. Okuzawa, Y. Nakamura, M. Ike, N. Hayashi, A. Obara, Y. Sakamoto, N. Habu, Preparation of cellulose nanofibers from waste mushroom bed of shiitak (Lentinus edodes) by TEMPO-mediated oxidation, Mokuzal Hozon (Wood Protection), 42 (2016): 157–164 [Google Scholar]