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Erschienen in:

2011 | OriginalPaper | Buchkapitel

2. Chemical Functionalization of Cellulose Derived from Nonconventional Sources

verfasst von : V. K. Varshney, Sanjay Naithani

Erschienen in: Cellulose Fibers: Bio- and Nano-Polymer Composites

Verlag: Springer Berlin Heidelberg

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Abstract

Chemical functionalization of cellulose aims to adjust the properties of macromolecule for different purposes, particularly, as a chemical feedstock for production of cellulose derivatives for a variety of applications. The conventional sources of cellulose include cotton linters and wood pulp which now-a-days are discouraged on account of the cost of the former and environment conservative regulations associated with the latter. Further, renewable raw materials are gaining considerable importance because of the limited existing quantities of fossil supplies. In this regard, cellulose-rich biomass derived from the nonconventional sources such as weeds, fibers, bamboos, and wastes from agriculture and forests, etc. acquires enormous significance, as alternative chemical feedstock, since it consists of cellulose, hemicellulose, and lignin, which contain many functional groups suitable to chemical functionalization. Etherification of cellulose through methylation, carboxymethylation, cynaoethylation, hydroxypropylation, single or mixed, is one of the most important routes of cellulose functionalization. Chemical composition and rheological characteristics make possible the selection of the modified cellulose to serve special applications. Prompted by above facts, possibility for chemical functionalization of cellulose rich biomass derived from bamboo, Dendrocalamus strictus (DCS), and noxious weeds – Lantana camara (LC) and Parthenium hysterophorus (PH) for their utilization was examined and results are reported. Proximate analysis of these materials was conducted and processes were standardized for production of α-cellulose on 1 kg batch scale. The percent yield, Av. DP, and the percentage of α-cellulose content of the obtained celluloses were found in the range of 35–40, 400–825, >90 (Brightness 80% ISO), respectively. Processes were optimized for production of water-soluble carboxymethyl cellulose (DCS, LC, and PH), cyanoethyl cellulose (DCS) and water-soluble hydroxypropyl cellulose (DCS and PH). The optimized products were characterized by IR spectra. Rheological studies of 1% and 2% aqueous solutions of the optimized carboxymethyl celluloses and hydroxypropyl celluloses showed their non-Newtonian pseudoplastic behavior. Thus, abundantly available biomass from Dendrocalamus strictus bamboo and the weeds – Lantana camara and Parthenium hysterophorus seem to be a potential feedstock for production of α-cellulose and its subsequent functionalization into cellulose derivatives for variety of applications. This was also demonstrated that these noxious weeds could also be managed by their utilization into products of commercial importance.

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Vorheriges Kapitel Natural Fibres: Structure, Properties and Applications

Nächstes Kapitel Production of Flax Fibers for Biocomposites

Akaranta O, Osugi LC (1997) Carboxymethylation of orange mesocarp cellulose and its utilization in drilling mud formulation. Cellulose Chem Technol 31:195–198

Arthur JC Jr (1986) In: Allen G, Bevington JC (eds) Comprehensive polymer science, Vol 6. Pergamon, Oxford

Atchison JE (1996) Twenty-five years of global progress in nonwood plant fiber repulping. TAPPI J 79(10):87–95

Balser K, Hoppe L, Eicher T, Wandel M, Astheimer HJ, Steinmeier H, Allen JM (1986) Cellulose esters. In: Gerhartz W, Stephen YY, Thomas CF, Pfefferkorn R, James F (eds) Ullmann’s encyclopedia of industrial chemistry. Wiley, New York

Bansal A (2005) Structural investigation of Cassia tora Linn. seed polysaccharides. Ph. D. thesis, Forest Research Institute, Deemed University, Dehradun, India

Barai BK, Singhal RS, Kulkarni PR (1997) Optimization of a process for preparing carboxymethyl cellulose from water hyacinth (Eichornia crassipes). Carbohydr Polym 32:229–231CrossRef

Barkalow DG, Young RA (1985) Cellulose derivatives derived from pulp and paper mill sludge. J Wood Chem Technol 5:293–312CrossRef

Barndt L (1986) Cellulose ethers. In: Gerhartz W, Stephen YY, Thomas CF, Pfefferkorn R, James F (eds) Ullmann’s encyclopedia of industrial chemistry. Wiley, New York

Bhatt A (2004) Chemical investigation of Kydia calysina Rox. bark. Ph. D. thesis, Forest Research Institute, Deemed University, Dehradun, India

Clasen C, Kulicke W-M (2001) Determination of viscoelastic and rheo-optical material functions of water soluble cellulose derivatives. Prog Polym Sci 26:1839–1919CrossRef

Coffey DG, Bell DA, Henderson A (1995) Food polysaccharides and their application. Marcel Dekker, New York

Cross CF, Bevan EJ (1907) Researches on cellulose. Longmann Green, London

Cruz RA, Mendoza AM, Vieira MC, Heinze Th (1999) Studies on grafting of cellulosic materials isolated from Agave lechuguilla and A. fourcroydes. Angew Makromol Chem 273:86–90CrossRef

Daiyong Ye (2005) Preparation of methylcellulose from annual plants. Ph.D. Dissertation Graduate School of Rovira i Virgili University

Davidson RL (1980) Handbook of water soluble gums and resins. McGraw-Hill, New York

Edali M, Esmail MN, Vatistas GH (2001) Rheological properties of high concentrations of carboxymethyl cellulose solutions. J Appl Polym Sci 79:1787–1801CrossRef

Evans HC (1997) The potential of fungal pathogen as classical biological control agents for management of Parthenium hysterophorus L. In: Mahadevappa M and Patil VC (eds) First international conference on Partheniuum management. Dharwad University of Agricultural Sciences, Dharwad, Karnataka, India

Fink HP, Hofmann D, Philipp B (1995) Some aspects of lateral chain order in cellulosics from X-ray scattering. Cellulose 2:51–70

Ghannam MT, Esmail MN (1997) Rheological properties of carboxymethyl cellulose. J Appl Polym Sci 64:289–301CrossRef

Ghosh P, Ganguly PK (1994) Polyacrylonitrile (PAN)-grafted jute fibers: some physical and chemical properties and morphology. J Appl Polym Sci 52:77–84CrossRef

Goyal P (2008) Chemical modification of tamarind kernel powder. Ph. D. thesis, Forest Research Institute, Deemed University, Dehradun, India

Green JW (1963) Carboxymethyl cellulose. In: Whistler RL (ed) Methods in carbohydrate chemistry, vol III. Academic, New York

Gupta S (2005) Chemical modification of Cassia occidentalis. Ph. D. thesis, Forest Research Institute, Deemed University, Dehradun, India

Han JS (1998) Properties of nonwood fibers. In: 1998 Proceedings of the Korean society of wood science and technology annual meeting 3–12

Han JS, Rowell JS (1996) Chemical composition of fibers. In: Rowell RM, Young RA, Rowell J (eds) Paper and composites from agrobased resources. CRC, London

Hebeish A, Guthrei JT (1981) The chemistry and technology of cellulosic copolymers. Springer, Berlin

Hebeish A, Abou-Zied NY, Waly A, Higazy A (1984) Chemical modification of flax cellulose via etherification, esterification, and crosslinking reactions. Cellulose Chem Technol 22:591–605

Heinze T, Liebert T (2001) Unconventional methods in cellulose fictionalization. Prog Polym Sci 26:1689–1762CrossRef

Heinze Th, Erler U, Nehls I, Klemm D (1994) Determination of the substitution pattern of heterogeneously and homogenously synthesized carboxymethyl cellulose by using high-performance liquid chromatography. Angew Makromol Chem 215:93–106CrossRef

Hon DNS (1996a) Cellulose and its derivatives. In: Dumitriu S (ed) Polysaccharides in medicinal applications. Marcel Dekker, New York

Hon DNS (1996b) Chemical modification of lignocellulosic material. Marcel Dekker, New York

Inada A, Nakanishi T, Tokuda H, Sharma OP (1997) Antitumor activities of lantadenes on mouse skin tumors and mouse hepatic tumors. Planta Med 63:476–478CrossRef

Jayakumar R, Mahadevappa M, Joshi S, Prasad TG (1989) Dormancy studies in Cassia sericea seeds. Seed Res 17(2):118–121

Jayanth KP (1987) Introduction and establishment of Zygogramma bicolorata on P. hysterophorus at Bangalore, India. Curr Sci 56(7):310–311

Jhonson DP (1969) Spectrophotometric determination of the hydroxypropyl group in starch ethers. Anal Chem 41:859–860CrossRef

Khalil EMA, El-Wakil NA (2000) Infrared absorption spectra of cyanoethylated cellulose fibers. Cellulose Chem Technol 34:473–479

Khullar R, Varshney VK, Naithani S, Heinze T, Vieira-Nagel GPK, Naithani S, Soni PL (2007) Carboxymethylation of cellulose isolated from bamboo (Dendrocalamus Strictus) and its rheology. Cellulose Chem Technol 40(7):545–552

Khullar R, Varshney VK, Naithani S, Soni PL (2008) Study of the influence of reaction conditions for production of cyanoethylcellulose from cellulosic material from bamboo (Dendrocalamus strictus). J Nat Fibers 5(2):138–147CrossRef

Klemm D, Phillip B, Heinze T, Heinze U, Wagenknetch W (1998) Comprehensive cellulose chemistry, vol 2. Wiley, WeinheimCrossRef

Kulicke WM, Kull AH, Kull W, Thielking H, Engelhart J, Pannek JB (1996) Characterization of aqueous carboxymethylcellulose solutions in terms of their molecular structure and its influence on rheological behavior. Polymer 37(13):2723–2731CrossRef

Kulicke WM, Reinhardt Fuller UGG, Arendt O (1999) Characterization of the flow properties of sodium carboxymethylcellulose via mechanical and optical techniques. Rheol Acta 38:26–33CrossRef

Kulshreshtha AK, Dweltz NE (1973) Para crystalline lattice disorder in cellulose – 1. Reappraisal of the application of the two-phase hypothesis to the analysis of powder x-ray diffractograms of native and hydrolyzed cellulosic materials. J Polym Sci 11:487–497

Mathur NK, Mathur V (2001) Chemical Weekly, July Edition, 155

McDougall GJ, Morrison IM, Stewart D, Weyers JDB, Hillman JR (1993) Plant fibres: botany, chemistry and processing. J Sci Food Agric 62:1–20CrossRef

Menachem L (2006) Handbook of fiber chemistry. CRC, USA

Nevell TP, Zeronian SH (1985) Cellulose chemistry and its applications. Ellis Horwood, Chichester York

Nicholson MD, Meritt FM (1985) Cellulose ethers. In: Nevell TP, Zeronian SH (eds) Cellulose chemistry and its applications. Ellis Horwood, Chichester

Oggiano N, Angelini LG, Cappelletto P (1997) Pulping and paper properties of some fibre crops. Ind Crops Prod 7(1):59–67CrossRef

Osullivan AC (1997) Cellulose: the structure slowly unravels. Cellulose 4:173–207CrossRef

Pandey N (2008) Chemical modification of alpha cellulose from Lantana camara. Ph. D. thesis, Forest Research Institute, Deemed University, Dehradun, India

Pass MA (1991) Poisoning of livestock by Lantana plants. In: Keeler R, Tu AT (eds) Handbook of natural toxins, vol 6. Marcel Dekker, New York

Patnaik S, Sarangi S, Mohanty AK, Singh BC (1989) Graft copolymerization of acrylonitrile onto jute fibers (Studies on Ce (IV)- hippuric acid redox system). J Appl Polym Sci 37:2099–2107CrossRef

Patra CM, Singh BC (1994) Influence of N-acetylglycine on the kinetics of ceric ion-initiated graft-copolymerization of acrylonitrile and methyl-methacrylate onto jute fibers. J Appl Polym Sci 52:1557–1568CrossRef

Ramos LA, Frollini E, Heinze Th (2005) Carboxymethylation of cellulose in the new solvent dimethyl sulphoxide/tetrabutyl ammonium fluoride. Carbohydr Polym 60:259–267CrossRef

Rana V (2006) Chemical investigation of Dalbergia sissoo Rox. laef polysaccharides. Ph. D. thesis, Forest Research Institute, Deemed University, Dehradun, India

Samal RK, Bhuyan BL (1994) Chemical modification of lignocellulosic fibers. 1. Functionality changes and graft polymerization of acrylonitrile onto pineapple leaf fibers – their characterization and behavior. J Appl Polym Sci 52:1675–1685CrossRef

Schweizer E (1857) Das Kupferoxyd-Ammoniak, ein Auflösungsmittel für die Pflanzenfaser. J Prakt Chem 72(1):109–111

Schweizer D, Sorg C (1995) Cellulose ethers for cement extrusion. In: Kennedy JF, Phillips GO, Williams PA, Picullel L (eds) Cellulose and cellulose derivatives: physico-chemical aspects and industrial applications. Woodhead, England

Sharma BR (2003) Chemical modification of polysaccharides for industrial applications. Ph. D. thesis, Forest Research Institute, Deemed University, Dehradun, India

Sharma S (2004) Lantana-whose weed any way! Developing strategic directions for integrated utilization and control. In: Workshop on Lantana camara: Problems and Prospects (Volume of abstracts), organized by IIT, Delhi, HESCO, Dehra Dun and Department of Science & Technology (DST), Govt. of India at Dehra Dun from 10–11 Feb 2004

Sharma R (2007) Studies on chemical modification of cellulose of different DP and their rheology. Ph. D. thesis, Forest Research Institute, Deemed University, Dehradun, India

Sharma OP, Sharma PD (1989) Natural products of lantana plant – the present and prospects. J Sci Ind Res 48:471–478

Sharma OP, Makkar HPS, Dawra RK (1988) A review of the poisonous plants Lantana camara. Toxicon 26:975–985CrossRef

Sharma R, Varshney VK, Naithani S, Chauhan GS, Soni PL (2008) Hydroxypropylation of cellulose (Av. DP 816) isolated from bamboo (Dendrocalamus strictus) with respect to hydroxypropoxyl content and rheological behavior of hydroxypropyl cellulose. J Appl Polym Sci 113(4):2450–2455

Singh SV, Rai AK, Dhawan R (1991) Advances in pulp and paper research in India. ICFRE Publication 15, Dehra Dun

Tewari DN (1995) A monograph on bamboo. International Book Distributors, Dehra Dun

Varshney VK, Gupta PK, Naithani S, Khullar R, Bhatt A, Soni PL (2005) Carboxymethylation of α-cellulose isolated from Lantana camara with respect to degree of substitution and rheological behavior. Carbohydr Polym 63(1):40–45CrossRef

Vieira MC, Heinze Th, Antonio-Cruz R, Mendoza-Martinez AM (2002) Cellulose derivatives from cellulosic material isolated from Agave lechuilla and A. fourcroydes. Cellulose 9:203–212CrossRef

Whistler RL, BeMiller NJ (1973) Industrial gum, polysaccharides and their derivatives. Academic, New York

Yamamoto H, Horii F (1993) CPMAS carbon-13 NMR analysis of the crystal transformation induced for Valonia cellulose by annealing at high temperatures. Macromolecules 26:1313–1317CrossRef

Zugenmaier P (2008) Crystalline cellulose and derivatives: characterization and structures. Springer, BerlinCrossRef

Titel: Chemical Functionalization of Cellulose Derived from Nonconventional Sources
verfasst von: V. K. Varshney
Sanjay Naithani
Verlag: Springer Berlin Heidelberg
Buch: Cellulose Fibers: Bio- and Nano-Polymer Composites
Print ISBN: 978-3-642-17369-1

Electronic ISBN: 978-3-642-17370-7

Copyright-Jahr: 2011
DOI: https://doi.org/10.1007/978-3-642-17370-7_2

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