Prog. Polym. Sci. 31 (2006) 603–632 Chitin and chitosan: Properties and applications Marguerite Rinaudo CERMAV-CNRS, affiliated with Joseph Fourier University, BP53, 38041 Grenoble Cedex 9, France Received 26 January 2006; received in revised form 13 June 2006; accepted 20 June 2006 Abstract Chitin is the second most important natural polymer in the world. The main sources exploited are two marine crustaceans, shrimp and crabs. Our objective is to appraise the state of the art concerning this polysaccharide: its morphology in the native solid state, methods of identification and characterization and chemical modifications, as well as the difficulties in utilizing and processing it for selected applications. We note the important work of P. Austin, S. Tokura and S. Hirano, who have contributed to the applications development of chitin, especially in fiber form. Then, we discuss chitosan, the most important derivative of chitin, outlining the best techniques to characterize it and the main problems encountered in its utilization. Chitosan, which is soluble in acidic aqueous media, is used in many applications (food, cosmetics, biomedical and pharmaceutical applications). We briefly describe the chemical modifications of chitosan—an area in which a variety of syntheses have been proposed tentatively, but are not yet developed on an industrial scale. This review emphasizes recent papers on the high value-added applications of these materials in medicine and cosmetics. r 2006 Elsevier Ltd. All rights reserved. Keywords: Chitin structure; Chitosan structure; Chitosan derivatives; Biomaterials; Chitosan-based materials; Cosmetics Contents 1. Introduction ..................................................................... 604 2. Chitin .......................................................................... 604 2.1. Chitin structure in the solid state .................................................. 604 2.1.1. Crystallography of chitin ................................................... 605 2.1.2. Reversible and irreversible intra-crystalline swelling of chitin ......................... 606 2.1.3. Infrared spectroscopy of chitin............................................... 607 2.1.4. 13 C CP-MAS solid state spectroscopy .......................................... 608 2.2. Solubility of chitin and chain characterization ......................................... 609 2.3. Chitin derivatives ............................................................. 610 2.4. Applications of chitin .......................................................... 611 3. Chitosan ........................................................................ 611 3.1. Chitosan structure and characterization ............................................. 612 3.1.1. Solubility of chitosan ..................................................... 612 3.1.2. Degree of acetylation of chitosan and distribution of acetyl groups ..................... 612 www.elsevier.com/locate/ppolysci ARTICLE IN PRESS 0079-6700/$ - see front matter r 2006 Elsevier Ltd. All rights reserved. doi:10.1016/j.progpolymsci.2006.06.001 Tel.: +33 476037627; fax: +33 476547203. E-mail address: [email protected].
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Prog. Polym. Sci. 31 (2006) 603–632
www.elsevier.com/locate/ppolysci
Chitin and chitosan: Properties and applications
Marguerite Rinaudo�
CERMAV-CNRS, affiliated with Joseph Fourier University, BP53, 38041 Grenoble Cedex 9, France
Received 26 January 2006; received in revised form 13 June 2006; accepted 20 June 2006
Abstract
Chitin is the second most important natural polymer in the world. The main sources exploited are two marine
crustaceans, shrimp and crabs. Our objective is to appraise the state of the art concerning this polysaccharide: its
morphology in the native solid state, methods of identification and characterization and chemical modifications, as well as
the difficulties in utilizing and processing it for selected applications. We note the important work of P. Austin, S. Tokura
and S. Hirano, who have contributed to the applications development of chitin, especially in fiber form. Then, we discuss
chitosan, the most important derivative of chitin, outlining the best techniques to characterize it and the main problems
encountered in its utilization. Chitosan, which is soluble in acidic aqueous media, is used in many applications (food,
cosmetics, biomedical and pharmaceutical applications). We briefly describe the chemical modifications of chitosan—an
area in which a variety of syntheses have been proposed tentatively, but are not yet developed on an industrial scale. This
review emphasizes recent papers on the high value-added applications of these materials in medicine and cosmetics.
Chitin, poly (b-(1-4)-N-acetyl-D-glucosamine),is a natural polysaccharide of major importance,first identified in 1884 (Fig. 1). This biopolymer issynthesized by an enormous number of livingorganisms; and considering the amount of chitinproduced annually in the world, it is the mostabundant polymer after cellulose. Chitin occurs innature as ordered crystalline microfibrils formingstructural components in the exoskeleton of arthro-pods or in the cell walls of fungi and yeast. It is alsoproduced by a number of other living organisms inthe lower plant and animal kingdoms, serving inmany functions where reinforcement and strengthare required.
ical structure (a) of chitin poly( N-acetyl-b-D-and (b) of chitosan (poly(D-glucosamine) repeat
cture of partially acetylated chitosan, a copolymer
by its average degree of acetylation DA.
Despite the widespread occurrence of chitin, up tonow the main commercial sources of chitin have beencrab and shrimp shells. In industrial processing,chitin is extracted from crustaceans by acid treatmentto dissolve calcium carbonate followed by alkalineextraction to solubilize proteins. In addition adecolorization step is often added to remove leftoverpigments and obtain a colorless product. Thesetreatments must be adapted to each chitin source,owing to differences in the ultrastructure of the initialmaterials (the extraction and pre-treatment of chitinare not described in this paper). The resulting chitinneeds to be graded in terms of purity and color sinceresidual protein and pigment can cause problems forfurther utilization, especially for biomedical pro-ducts. By partial deacetylation under alkaline condi-tions, one obtains chitosan, which is the mostimportant chitin derivative in terms of applications.
This review aims to present state-of-the-artknowledge of the morphology of chitin and chitosanand to indicate the best methods for characteriza-tion in solution or solid state. The last decade ofdevelopment will be discussed, as well as recentchemical modifications solution the uses of chitin tobe expanded.
2. Chitin
2.1. Chitin structure in the solid state
Depending on its source, chitin occurs as twoallomorphs, namely the a and b forms [1,2], whichcan be differentiated by infrared and solid-stateNMR spectroscopy together with X-ray diffraction.A third allomorph g-chitin has also been described[1,3], but from a detailed analysis, it seems that it is
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Fig. 3. Electron diffraction patterns of highly crystalline chitin:
(a) b*c* projection of a-chitin recorded from a fragment of
grasping spine of the arrow worm Sagitta; (b) b*c* projection of
dried b-chitin recorded from a microfibril from the tube of the
vestimentiferan worm Tevnia jerichonana.
M. Rinaudo / Prog. Polym. Sci. 31 (2006) 603–632 605
just a variant of the a family [4]. a-Chitin is by farthe most abundant; it occurs in fungal and yeast cellwalls, in krill, in lobster and crab tendons and shells,and in shrimp shells, as well as in insect cuticle. It isalso found in or produced by various marine livingorganisms. In this respect, one can cite the harpoonsof cone snails [5], the oral grasping spine of Sagitta
[6–8] and the filaments ejected by the seaweedPhaeocystis [9], etc. These exotic a-chitins haveproved particularly interesting for structural studiessince, in comparison with the abundant arthropodchitin, some of them present remarkably highcrystallinity [10] together with high purity (theyare synthesized in the absence of pigment, protein,or calcite). In addition to the native chitin, a-chitinsystematically results from recrystallization fromsolution [11,12], in vitro biosynthesis [13,14] orenzymatic polymerization [15].
The rarer b-chitin is found in association withproteins in squid pens [1,3] and in the tubessynthesized by pogonophoran and vestimetiferanworms [16,17]. It occurs also in aphrodite chaetae[18] as well as in the lorica built by some seaweedsor protozoa [19,20]. A particularly pure form ofb-chitin is found in the monocrystalline spinesexcreted by the diatom Thalassiosira fluviatilis
[20–22]. As of today, it has not been possible toobtain b-chitin either from solution or by in vitrobiosynthesis.
2.1.1. Crystallography of chitin
The crystallography of chitin has been investi-gated for a long time [23–26]. Examples of diffrac-tion diagrams are shown in Figs. 2 and 3. At firstglance the powder X-ray diagrams of chitins fromshrimp shell (a-chitin) and anhydrous squid pen (b-chitin) appear nearly the same, but in a refinedanalysis, they can be differentiated in two ways: (i) a
Fig. 2. X-ray powder diffraction diagrams (a) of a-chitin from
purified shrimp cuticle and (b) of b-chitin from dried purified
squid pen.
strong diffraction ring, often quoted as the a-chitinsignature is found at 0.338 nm (Fig. 2a) whereas asimilar ring occurs at 0.324 nm in b-chitin; (ii) aninner ring at 0.918 nm in b-chitin is sensitive tohydration, moving to 1.16 nm in the presence ofliquid water, whereas a similar strong inner ring at0.943 nm in a-chitin is insensitive to hydration.
Further information on the crystalline structureof a- and b-chitin is obtained by analysis of electrondiffraction patterns of highly crystalline samples.Examples are shown in Fig. 3, where 3a is taken ona fragment of a Sagitta grasping spine and 3b on amicrofibril extracted from a tube synthesized by avestimentiferan worm Tevnia jerichonana. Thesetwo patterns, corresponding to b*c* projections,indicate clearly that along the b* direction, thecell parameter of a-chitin is close to twice that ofb-chitin, whereas the c* parameter is the same inboth patterns. In addition the a*c* projections (notshown) of a- and b-chitin are nearly identical inboth allomorphs. These observations are consistentwith the currently accepted crystalline parametersand symmetry elements of a- chitin and anhydrousb-chitin (Table 1). The crystallographic parametersof a and b-chitin reveal that there are twoantiparallel molecules per unit cell in a-chitin,whereas only one is present in b-chitin, whichconsists therefore of a parallel arrangement. Despitethis difference, it appears that the N-acetyl glycosylmoiety is the independent crystallographic unit inboth allomorphs.
The proposed crystal structures of a- and b-chitinare represented in Figs. 4 and 5. In both structures,the chitin chains are organized in sheets where theyare tightly held by a number of intra-sheet hydrogenbonds. This tight network, dominated by the ratherstrong C–O?NH hydrogen bonds, maintains the
Fig. 4. Structure of a-chitin: (a) ac projection; (b) bc projection;
(c) ab projection. The structure contains a statistical mixture of 2
conformations of the –CH2OH groups [26].Fig. 5. Structure of anhydrous b-chitin: (a) ac projection; (b) bc
projection; (c) ab projection. The set of coordinates defined in
Ref. [25] could not be used due to an error in the definition of the
N-acetyl moiety. Instead coordinates provided by Y. Noishiki, Y.
Nishiyama and M. Wada in a private communication were used
to draw the molecular structure of b-chitin.
M. Rinaudo / Prog. Polym. Sci. 31 (2006) 603–632606
chains at a distance of about 0.47 nm (Figs. 4a, 4c,5a and 5c) along the a parameter of the unit cell. Ina-chitin, there are also some inter-sheet hydrogenbonds along the b parameter of the unit cell,involving association of the hydroxymethyl groupsof adjacent chains. Such a feature is not found in thestructure of b-chitin, which is therefore moresusceptible than a-chitin to intra-crystalline swel-ling. The current model for the crystalline structureof a-chitin indicates that the inter-sheet hydrogenbonds are distributed in two sets (Fig. 4b) with halfoccupancy in each set [26]. It is not clear whetherthis feature is general for all a-chitin samples orspecific to lobster tendon chitin, which was used inthe structure determination. In this respect, theobservation of diffraction patterns of variousa-chitin samples indicates some discrepancy in theirdiffraction patterns. In particular the X-ray patternof lobster tendon chitin presents a marked 001diffraction spot [26], which is absent in the morecrystalline Sagitta chitin [7,8,10]. Therefore, it
appears that more work is required to resolve theseambiguities about the crystal structure of a-chitin.In contrast, the structure of anhydrous b-chitinappears to be well established. However, the crystalstructure of the b-chitin hydrate remains to berefined, as some uncertainty exists, even as to itsunit cell parameters [17,27].
2.1.2. Reversible and irreversible intra-crystalline
swelling of chitin
As mentioned above, no inter-sheet hydrogenbond is found in the crystal structure of b-chitin,whereas the sheets themselves are tightly bound by anumber of intra-sheet hydrogen bonds. This re-markable feature explains why a number of polarguest molecules, ranging from water to alcohol andamines, can readily penetrate the crystal lattice ofb-chitin without disturbing the sheet organization
and the crystallinity of the samples. This swelling isquite rapid: it was found that the highly crystallinechitin from pogonophore tubes could be swollen inwater in about a minute [28]. Once a guest haspenetrated the crystalline lattice of b-chitin, it canbe displaced by another one of a different chemicalfamily to produce a wide distribution of crystallineb-chitin complexes. Essentially, during swelling theb parameters of the b-chitin unit cell expandlaterally whereas a and c remain constant. Theincorporation of the swelling agent within thecrystalline lattice is thus indicated by the positionof the 010 diffraction spot. Table 2 lists thevariation of the position of this spot with respectto a selection of representative guests. This intra-crystalline swelling is reversible, as in all these casesremoval of the guest molecule allows the structureto revert to its original state of anhydrous b-chitin,though with some loss of crystallinity.
The inter-sheet swelling of a-chitin crystals ismore specific. Whereas water and alcohols cannotpenetrate the crystalline lattice of a-chitin, strongerswelling agents such as aliphatic diamines have beenshown to intercalate into the crystalline lattice toform highly crystalline complexes [32]. As inb-chitin, the guest molecules are incorporatedbetween the chitin sheets of a-chitin and accord-ingly, the b cell parameter expands, whereas the a
and c parameters remain essentially constant. Theinter-sheet parameter expansion, which is about thesame in both a- and b-chitin, increases linearly with
Table 2
Variation of the 010 diffraction spot of b-chitin with incorpora-
tion of various guest molecules
Guest Position of the 010
diffraction spot
Ref.
(nm)
No guest 0.917 [25]
Water 1.16a [25]
Methanol 1.30 [29]
n-butanol 1.55 [29]
n-octanol 1.97 [29]
n-hexylamine 1.81 [30]
Ethylenediamine
(type I)
1.18 [30]
Ethylenediamine
(type II)
1.45 [30]
Acrylamide 1.33 [31]
p-aminobenzoic acid 1.31 [31]
D-glucose 1.27 [31]
aThis value corresponds to b-chitin dihydrate. Under reduced
hydration conditions the b-chitin monohydrate is obtained, for
which the 010 diffraction spot is at 1.04 nm [31].
the number of carbon atoms in a diamine guest: anexpansion of 0.7 nm being observed, for instance, inthe case of the C7 diamine [32].
Whereas the intra-crystalline swelling of b-chitinin water, alcohols or amines is reversible, its swellingin relatively strong acid media, namely concentratednitric acid or 6–8M HCl, leads irreversibly a-chitin[18,33]. During this swelling, not only the inter-sheet, but also the intra-sheet hydrogen bonds arebroken [34] and the crystalline state appears to becompletely lost [35]. Nevertheless the crystallinity isrestored, as a-form crystals, upon removal of theacid. In the case of oriented material, such as squidpen chitin, the b-a conversion is also marked by asubstantial shrinkage of the structure [33]. Toaccount for this shrinkage and the solid-state b-aconversion, a chain folding mechanism has tenta-tively been proposed [33]. Other possibilities invol-ving the interdigitation of b-chitin microfibrils ofopposite polarities can also be envisaged. At theultrastructural level, it was found that substantialhydrolysis followed by partial dissolution occurredduring the acid treatment. When a subsequentwashing step was applied, the shortest hydrolyzedchains were found to recrystallize by epitaxy on theunderlying unhydrolyzed chitin chains, leading to ashish-kebab morphology [35]. Thus, the conversiondid not occur at a single crystal level, but some or allb-chitin crystals were destroyed during the acidswelling and new crystals of a-chitin were producedduring recrystallization. The irreversibility of theb-a conversion indicates that a-chitin is thermo-dynamically more stable than b-chitin. This stabilityis confirmed by the fact that a-chitin is alwaysobtained in recrystallization from solution.
2.1.3. Infrared spectroscopy of chitin
A number of studies have dealt with the descrip-tion and interpretation of the infrared spectra ofchitin [36–41]. Spectra of a- and b-chitin samplesshown in Fig. 6 are typical of polysaccharides;because of the high crystallinity of the samples, theydisplay a series of very sharp absorption bands. TheCQO stretching region of the amide moiety,between 1600 and 1500 cm�1, is quite interestingas it yields different signatures for a-chitin andb-chitin. For a-chitin, the amide I band is split at1656 and 1621 cm�1, whereas it is unique, at1626 cm�1 for b-chitin. In contrast, the amide IIband is unique in both chitin allomorphs: at1556 cm�1 for a-chitin and 1560 cm�1 for b-chitin.The occurrence of two amide I bands for a-chitin
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Fig. 6. FTIR spectra of chitin: (a) for single crystals of a-chitin;(b) for deproteinized dried b-chitin from the tube of Tevnia
jerichonana.
Fig. 7. 13C CP/MAS solid state spectra of (a) a-chitin from
deproteinized lobster tendon; (b) b-chitin from dried deprotei-
nized tube of Tevnia jerichonana. Reprinted with permission from
Macromolecules 1990; 23: 3576–3583. Copyright 2006, American
Chemical Society.
M. Rinaudo / Prog. Polym. Sci. 31 (2006) 603–632608
has been the subject of debate. The band at1656 cm�1, which occurs at similar wavelengths inpolyamides and proteins, is commonly assigned tostretching of the CQO group hydrogen bonded toN–H of the neighboring intra-sheet chain. Regard-ing the 1621 cm�1 band , which is not present inpolyamides and proteins, its occurrence may in-dicate a specific hydrogen bond of CQO with thehydroxymethyl group of the next chitin residue ofthe same chain [41]. This hypothesis is reinforced bythe presence of only one band in this region for N-acetyl D-glucosamine [37,42]. Also, in a-chitin, theband at 1621 cm�1 is modified in deuterated water,whereas the band at 1656 cm�1 remains nearlyunaffected [40]. Other possibilities may also beconsidered, as the band at 1621 cm�1 could be eithera combination band or due to an enol form of theamide moiety [37]. The lack of a more precisedefinition of the molecular structure of a-chitin and
its inter-sheet hydrogen bonding does not allow usto give a definitive explanation for this band.
2.1.4. 13C CP-MAS solid state spectroscopy
A number of 13C solid-state NMR spectra ofa- and b-chitin have been published [40,43–45], themost crystalline samples yielding the best resolvedspectra. Examples of such spectra are shown inFig. 7, and a list of their corresponding chemicalshifts is presented in Table 3. When recorded at7.05 T, each spectrum consists of 6 single-linesignals and 2 doublets at C-2 and CQO, but thesedoublets are in fact singlets that are split by theeffect of the 14N quadrupole coupling [44]. Thesplitting disappears if the spectra are acquired athigher field strength and, on the other hand,becomes broader at lower field strength. In account-ing for this phenomenon, there are therefore only 8signals for the 8 carbon atoms of a- and b-chitins.Thus, in both allomorphs, the N-acetyl D-glucosa-mine moiety can be considered as the magneticindependent residue, in full agreement with thecrystal structure of a- and b-chitin where thisresidue is also the crystallographic independentunit. In looking at the data in Table 3, we see thatthe spectra of a- and b-chitin are nearly the same,and it is not easy to differentiate them by solid-state13C NMR. Nevertheless, the relaxation time of C-6
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Table 3
Chemical shifts of solid chitin [44]
Anhydrous b-chitinfrom diatom spines
(ppm)
a-chitin from lobster
tendon (ppm)
C1 105.4 104.6
C2a 55.3 55.6
73.l
C3 73.1 73.7
C4 84.5
C5 75.5 83.6
C6 59.9 61.1
CQOa 175.6 173.0
176.4
CH3 22.8 23.1
Reprinted with permission from Macromolecules 1990; 23:
3576–3583. Copyright 2006, American Chemical Society.aThe splitting for C-2 and CQO is due to the 14N quadrupole
Reprinted with permission from J Chem Educ 1990; 67: 938–942.
Used with permission from the Journal of Chemical Education,
vol. 6, No. 11, 1990, pp. 938–942; copyright r 1990, Division of
Chemical Education, inc.
M. Rinaudo / Prog. Polym. Sci. 31 (2006) 603–632 609
in crab shell a-chitin is found to be much shorterthan that of the other carbons of this chitin and alsoshorter than for C-6 of anhydrous b-chitin [44].A possible explanation may be related to thespecificity of the split hydrogen bonds linking thehydroxymethyl groups of the a-chitin moleculesfrom adjacent sheets. A refinement of the crystallineand molecular structure of a-chitin should help inunderstanding not only this hydrogen bondingsituation but should also give a clue for the shortrelaxation time of C-6. It also remains to be seenwhether this fast relaxation is specific for crab shellchitin or is general for all crystalline a-chitins.
2.2. Solubility of chitin and chain characterization
Chitin occurs naturally partially deacetylated(with a low content of glucosamine units), depend-ing on the source (Table 4) [46]; nevertheless, botha and b forms are insoluble in all the usual solvents,despite natural variations in crystallinity. Theinsolubility is a major problem that confronts thedevelopment of processing and uses of chitin. Animportant mechanism previously mentioned is thata solid-state transformation of b-chitin into a-chitinoccurs by treatment with strong aqueous HCl (over7M) and washing with water [35]. In addition,b-chitin is more reactive than the a form, animportant property in regard to enzymatic andchemical transformations of chitin [47].
Because of the solubility problem, only limitedinformation is available on the physical propertiesof chitin in solution. The first well-developed study
was by Austin [48], who introduced the solubilityparameters for chitin in various solvents. Heobtained a complex between chitin and LiCl (whichis coordinated with the acetyl carbonyl group). Thecomplex is soluble in dimethylacetamide and inN-methyl-2-pyrrolidone. We recall that the samesolvents and, especially, LiCl/DMAc mixtures, arealso solvents for cellulose, another b(1-4) glucan[49]. In addition, Austin also used formic, dichlor-oacetic and trichloroacetic acids for dissolution ofchitin chains.
Experimental values of parameters K and a
relating intrinsic viscosity [Z] and molecular weightM for chitin in several solvents according to thewell-known Mark–Houwink equation
½Z� ¼ KMa (1)
are given in Table 5. Molecular weights weredetermined by light scattering using the dn/dc
values mentioned in the table.For a long time the most widely used solvent for
chitin was a DMAc/LiCl mixture, though CaCl2 �2H2O-saturated methanol was also employed, aswell as hexafluoroisopropyl alcohol and hexafluor-acetone sesquihydrate [50]. Vincendon [53] dissolvedchitin in concentrated phosphoric acid at roomtemperature. In this solvent, decreases of theviscosity and of the molar mass were observed withtime with no change in the degree of acetylation.The same author also dissolved chitin in a freshsaturated solution of lithium thiocyanate and gotthe NMR spectra at 90 1C [54]. A few papers discusspreparation of alkali chitin by dissolution of chitinat low temperature in NaOH solution. The chitin isfirst dispersed in concentrated NaOH and allowed
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Table 5
Mark–Houwink parameters of chitin
Solvent K (mL/g) a T (1C) dn/dc Ref.
2.77M NaOH 0.1 0.68 20 0.145 [51a]
DMAc/LiCl 5% 7.6� 10�3 0.95 30 0.091 [51b]
DMAc/LiCl 5% 2.4� 10�1 0.69 25 0.1 [52]
M. Rinaudo / Prog. Polym. Sci. 31 (2006) 603–632610
to stand at 25 1C for 3h or more; the alkali chitinobtained is dissolved in crushed ice around 0 1C. Thisprocedure allowed the authors to cast transparentchitin film with good mechanical properties[51a,55,56]. The resulting chitin is amorphous and,under some conditions, it can be dissolved in water,while chitosan with a lower degree of acetylation (DA)and ordinary chitin are insoluble. The authorsinterpreted this phenomenon as related both to thedecrease of molecular weight under alkaline conditionsand to some deacetylation; they confirmed that to getwater solubility, the DA has to be around 50% and,probably, that the acetyl groups must be regularlydispersed along the chain to prevent packing of chainsresulting from the disruption of the secondarystructure in the strong alkaline medium [56,57].
Recently, an interesting study, utilizing techniquessuch as rheology, turbidimetry and fluorescence,demonstrated that alkali chitin solubilized in cold(�0 1C) aqueous NaOH (16% w/w) according withthe protocol of Sannan et al. [55,56] forms an LCSTsolution with a critical temperature around 30 1C [58].A chitin gel, obtained from the solution by washing toextract NaOH, was found to be temperature andpH-sensitive [59]. These authors demonstrated avolume phase transition at �21 1C as the result ofthe influence of temperature on polymer–polymer andpolymer–water interactions such as hydrogen bondingand hydrophobic interactions. This transition isobserved only within a narrow range of pH (7.3–7.6)and modifies the mechanical shear modulus as afunction of oscillating variation in temperature.
The rheology of chitin in solution is that of asemi-rigid polysaccharide for which the conforma-tional analysis has been developed in comparisonwith chitosan; this point will be taken up later in thediscussion of the role of the DA on the intrinsicpersistence length of the polymer.
2.3. Chitin derivatives
The most important derivative of chitin ischitosan (Fig. 1), obtained by (partial) deacetylation
of chitin in the solid state under alkaline conditions(concentrated NaOH) or by enzymatic hydrolysis inthe presence of a chitin deacetylase. Because of thesemicrystalline morphology of chitin, chitosansobtained by a solid-state reaction have a hetero-geneous distribution of acetyl groups along thechains. In addition, it has been demonstrated thatb-chitin exhibits much higher reactivity in deacety-lation than a-chitin [47]. The influence of thisdistribution was examined by Aiba [60], whoshowed that the distribution, random or blockwise,is very important in controlling solution properties.Reacetylation, up to 51%, of a highly deacetylatedchitin in the presence of acetic anhydride gives awater soluble derivative, whereas a heterogeneousproduct obtained by partial deacetylation of chitinis soluble only under acidic conditions, or eveninsoluble. It was demonstrated from NMR mea-surements that the distribution of acetyl groupsmust be random to achieve the higher watersolubility around 50% acetylation.
Homogeneously deacetylated samples were ob-tained recently by alkaline treatment of chitin underdissolved conditions [61]. On the other hand, thereacetylation of a highly deacetylated chitin wasdone by Maghami and Roberts [62], incidentallyproviding homogeneous samples for our SECanalysis discussed below. Toffey et al. transformedchitosan films cast from aqueous acetic acid intochitin by heat treatment [63,64]. After chitosan, themost studied derivative of chitin is carboxymethyl-chitin (CM-chitin), a water-soluble anionic polymer.The carboxymethylation of chitin is done similarlyto that of cellulose; chitin is treated with mono-chloracetic acid in the presence of concentratedsodium hydroxide. The same method can be usedfor carboxymethylation of chitosan [65]. Themethod for cellulose derivatization is also used toprepare hydroxypropylchitin, a water-soluble deri-vative used for artificial lachrymal drops [66,67].
Other derivatives such as fluorinated chitin [68], N-and O-sulfated chitin [65,69,70], (diethylamino)ethyl-chitin [71], phosphoryl chitin [72], mercaptochitin [73]
and chitin carbamates [74] have been described in theliterature. Modification of chitin is also often effectedvia water soluble derivatives of chitin (mainly CM-chitin). The same type of chemical modifications(etherification and esterification) as for cellulose canbe performed on the available C-6 and C-3 –OHgroups of chitin [75].
Chitin can be used in blends with natural orsynthetic polymers; it can be crosslinked by theagents used for cellulose (epichlorhydrin, glutaral-dehyde, etc.) or grafted in the presence of ceric salt[76] or after selective modification [77].
Chitin is partially degraded by acid to obtainseries of oligochitins [47,78]. These oligomers, aswell as those derived from chitosan, are recognizedfor their bioactivity: including anti-tumor, bacter-icidal and fungicidal activity, eliciting chitinase andregulating plant growth. They are used in testing forlysozyme activity. They are also used as activestarting blocks to be grafted on protein and lipids toobtain analogs of glycoproteins and glycolipids.
2.4. Applications of chitin
Chitin has low toxicity and is inert in thegastrointestinal tract of mammals; it is biodegrad-able, owing to the presence of chitinases widelydistributed in nature and found in bacteria, fungiand plants, and in the digestive systems of manyanimals. Chitinases are involved in host defenseagainst bacterial invasion. Lysozymes from eggwhite, and from fig and papaya plants, degradechitin and bacterial cell walls. Sashiva et al. [79]showed that a certain degree of deacetylation isnecessary to allow hydrolysis of chitin [79].
Chitin has been used to prepare affinity chroma-tography column to isolate lectins and determinetheir structure [80]. Chitin and 6-O-carboxymethyl-chitin activate peritoneal macrophages in vivo,suppress the growth of tumor cells in mice, andstimulate nonspecific host resistance against Escher-
ichia Coli infection. Chitin also accelerates wound-healing [65b].
Chitin is widely used to immobilize enzymes andwhole cells; enzyme immobilization has applicationsin the food industry, such as clarification of fruitjuices and processing of milk when a- andb-amylases or invertase are grafted on chitin [81].On account of its biodegradability, nontoxicity,physiological inertness, antibacterial properties,hydrophilicity, gel-forming properties and affinity
for proteins, chitin has found applications in manyareas other than food such as in biosensors [81].
Chitin-based materials are also used for thetreatment of industrial pollutants and adsorbs silverthiosulfate complexes [82a] and actinides [82b].
Chitin can be processed in the form of films andfibers: fibers were first developed by Austin [83] andthen by Hirano [84]. The chitin fibers, obtained bywet-spinning of chitin dissolved in a 14% NaOHsolution, can also result of blending with cellulose[85] or silk [86]. They are nonallergic, deodorizing,antibacterial and moisture controlling [73]. Regen-erated chitin derivative fibers are used as bindersin the paper making process; addition of 10%n-isobutylchitin fiber improves the breakingstrength of paper [87].
However, the main development of chitin filmand fiber is in medical and pharmaceutical applica-tions as wound-dressing material [88,89] and con-trolled drug release [90,91]. Chitin is also used as anexcipient and drug carrier in film, gel or powderform for applications involving mucoadhesivity.Another interesting application is in a hydroxyapa-tite–chitin–chitosan composite bone-filling material,which forms a self-hardening paste for guided tissueregeneration in treatment of periodontal bonydefects [92].
Chitin was also O-acetylated to prepare gelswhich are still hydrolyzed by enzyme such as hen-egg white lysozyme [93]. CM-chitin was selectivelymodified to obtain antitumor drug conjugates [94].For example, 5-fluorouracil which has markedantitumor activity and the D-glucose analog ofmuramyl-L-alanyl-isoglutamine, responsible for im-muno-adjuvant activity were grafted on CM-chitinusing a specific spacer and an ester bond.
Chitin oligomers have been claimed as anticancerdrugs, and the oligomer with DP ¼ 5 is active incontrolling the photosynthesis of maize and soy-beans [95].
3. Chitosan
When the degree of deacetylation of chitinreaches about 50% (depending on the origin ofthe polymer), it becomes soluble in aqueous acidicmedia and is called chitosan. The solubilizationoccurs by protonation of the –NH2 function on theC-2 position of the D-glucosamine repeat unit,whereby the polysaccharide is converted to apolyelectrolyte in acidic media. Chitosan is the onlypseudonatural cationic polymer and thus, it finds
many applications that follow from its uniquecharacter (flocculants for protein recovery, depollu-tion, etc.). Being soluble in aqueous solutions, it islargely used in different applications as solutions,gels, or films and fibers. The first step in character-izing chitosan is to purify the sample: it is dissolvedin excess acid and filtered on porous membranes(with different pore diameters down to 0.45 mm).Adjusting the pH of the solution to ca. 7.5 byadding NaOH or NH4OH causes flocculation dueto deprotonation and the insolubility of the polymerat neutral pH. The polymer is then washed withwater and dried.
3.1. Chitosan structure and characterization
In the solid state, chitosan is a semicrystallinepolymer. Its morphology has been investigated, andmany polymorphs are mentioned in the literature.Single crystals of chitosan were obtained using fullydeacetylated chitin of low molecular weight [96].The electron diffraction diagram can be indexed inan orthorhombic unit cell (P212121) witha ¼ 0:807 nm, b ¼ 0:844 nm, c ¼ 1:034 nm; the unitcell contains two antiparallel chitosan chains, butno water molecules. The influence of experimentalconditions on the crystallinity has also beendescribed [97,98].
The main investigations of chitosan concern itspreparation with varied molecular weights and DAfrom chitin, the dependence of its solution proper-ties on the DA, the preparation of derivatives andapplications. Sponges, powders and fibers can beobtained by regeneration of chitosan or its deriva-tives from solutions. These points will be developedin the following discussion.
3.1.1. Solubility of chitosan
A highly deacetylated polymer has been used toexplore methods of characterization [99]. Thesolution properties of a chitosan depend not onlyon its average DA but also on the distribution of theacetyl groups along the main chain in addition ofthe molecular weight [57,60,100]. The deacetylation,usually done in the solid state, gives an irregularstructure due the semicrystalline character of theinitial polymer. Examination of the role of theprotonation of chitosan in the presence of aceticacid [101] and hydrochloric acid on solubility[102]showed that the degree of ionization depends on thepH and the pK of the acid. Solubilization ofchitosan with a low DA occurs for an average
degree of ionization a of chitosan around 0.5; inHCl, a ¼ 0:5 corresponds to a pH of 4.5–5.Solubility also depends on the ionic concentration,and a salting-out effect was observed in excess ofHCl (1M HCl), making it possible to prepare thechlorhydrate form of chitosan. When the chlorhy-drate and acetate forms of chitosan are isolated,they are directly soluble in water giving an acidicsolution with pK0 ¼ 670.1 [102], in agreement withprevious data [103] and corresponding to theextrapolation of pK for a degree of protonationa ¼ 0. Thus, chitosan is soluble at pH below 6.
The solubility of chitosan is usually tested inacetic acid by dissolving it in 1% or 0.1M aceticacid. We demonstrated that the amount of acidneeded depends on the quantity of chitosan to bedissolved [101]. The concentration of protonsneeded is at least equal to the concentration of�NH2 units involved.
In fact, the solubility is a very difficult parameterto control: it is related to the DA, the ionicconcentration, the pH, the nature of the acid usedfor protonation, and the distribution of acetylgroups along the chain, as well as the conditionsof isolation and drying of the polysaccharide. It isimportant also to consider the intra-chain H bondsinvolving the hydroxyl groups as shown below. Therole of the microstructure of the polymer is clearlyshown when a fully deacetylated chitin is reacety-lated in solution; the critical value of chitosan DAto achieve insolubility in acidic media is then greaterthan 60%. In addition, solubility at neutral pH hasalso been claimed for chitosan with DA around50% [60].
Recently, a water-soluble form of chitosan atneutral pH was obtained in the presence of glycerol2-phosphate [104–107]. Stable solutions were ob-tained at pH 7–7.1 and room temperature, but a gelformed on heating to about 40 1C. The sol–geltransition was partially reversible and the gelationtemperature depended slightly upon experimentalconditions (Figs. 8 and 9).
3.1.2. Degree of acetylation of chitosan and
distribution of acetyl groups
The characterization of a chitosan sample re-quires the determination of its average DA. Varioustechniques, in addition to potentiometric titration[108], have been proposed, such as IR [42,109–111],elemental analysis, an enzymatic reaction [112], UV[113], 1H liquid-state NMR [114] and solid-state 13CNMR [115–117]. The fraction of –NH2 in the
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0.01000 0.1000 1.000 10.00
frequency (Hz)
0.1000
1.000
10.00
100.0
1000
G'(P
a)
0.1000
1.000
10.00
100.0
1000
G''
(Pa)
Fig. 9. Dynamic rheological moduli for chitosan-glycerol 2-phosphate at pH ¼ 7.19 at two different temperatures. Polymer concentration
Fig. 8. Dynamic rheology giving the moduli G0 and G00 at 1Hz frequency as a function of temperature for a chitosan-glycerol-phosphate
solution: evidence of thermogelation at pH ¼ 7.19. Polymer concentration 15 g/L. Heating curves: storage modulus G0 (&), loss modulus
G00 (’). Cooling curves: G0, (,), G00 (.).
M. Rinaudo / Prog. Polym. Sci. 31 (2006) 603–632 613
polymer (which determines the DA) can be obtainedby dissolution of neutral chitosan in the presence ofa small excess of HCl on the basis of stoichiometryfollowed by neutralization of the protonated –NH2
groups by NaOH using pH or conductivity mea-surements. These techniques and the analysis of thedata obtained have been previously described [108].
Presently, we consider that 1H NMR is the mostconvenient technique for measuring the acetylcontent of soluble samples. Fig. 10 gives the 1Hspectrum obtained for chitosan dissolved in D2Ocontaining DCl (pD ca. 4).The signal at 1.95 ppmallows determination of the acetyl content by
reference to the H-1 signal at 4.79 ppm for theD-glucosamine residue and at 4. 50 ppm for the H-1of the N-acetyl-D-glucosamine unit at 85 1C. 13C and15N solid state NMR were also tried and discussedrecently; these techniques were used over the wholerange of acetyl content from 0% to 100%. As anexample, the chemical shifts for carbon atoms on 4samples are given in Table 6: A is an a-chitin, B is ahomogeneous reacetylated chitosan and C, D arecommercial samples [117]. 15N NMR gives only twosignals related to the amino group and to theN-acetylated group (Fig. 11); this technique can beused in the solid state, whatever the DA. 13C was
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Fig. 10. 1H NMR spectrum of chitosan in D2O, pH�4,
T ¼ 85 1C, conc. 5 g/L: (1) H-1 of glucosamine units, (2) H-1 of
N-acetyl-glucosamine, (3) H-2, (4) protons of the acetyl group of
N-acetyl-glucosamine.
Table 6
Chemical shifts of chitin and chitosan obtained by 13CP-MAS.
(A) a-chitin, (B) chitosan obtained by partial reacetylation, (C
and D) commercial chitosans [117]
Samples A B C D
CQO 173.8 173.7 173.6 nd
C1 104.1 103.5 104.7 104.7
C4 83.0 82.4 82.4 85.7–81.0
C5 75.7 74.7 75.0 74.1
C3 73.3 74.7 75.0 74.1
C6 60.8 60.3 60.1 60.7–59.6
C2 55.2 56.6 57.6 56.8
�CH3 22.8 23.1 23.2 nd
Reprinted with permission from Biomacromolecules
2000;1:746–751. Copyright 2006, American Chemical Society.
Fig. 11. 15N CP-MAS NMR spectra of (A) a-chitin, (B)
homogeneous partially reacetylated chitosan, (C and D) hetero-
geneous commercial chitosans. Reprinted with permission from
Biomacromolecules 2000; 1:746–751.Copyright 2006, American
Chemical Society.
Table 7
Degrees of acetylation of chitin and chitosan obtained by liquid
state (1H) and solid state (13C and 15N) NMR on the same
samples as in Table 6 [117]
Samples A B C D
DA from 1H
NMR
(liquid state)
insoluble 0.58 0.21 acetyl
traces
DA from 13C
NMR
(solid state)
0.99 0.61 0.20 0
DA from 15N
NMR
(solid state)
1 0.63 0.20 0
Reprinted with permission from Biomacromolecules 2000; 1:
746–751. Copyright 2006, American Chemical Society.
M. Rinaudo / Prog. Polym. Sci. 31 (2006) 603–632614
also compared with 1H NMR and 15N NMR andgood agreement was found over the entire range ofDA, whatever the state of the sample (Table 7).
The distribution of acetyl groups along the chain(random or blockwise) may influence the solubilityof the polymer and also the inter-chain interactionsdue to H-bonds and the hydrophobic character ofthe acetyl group. This distribution was evaluatedfrom 13C NMR measurements [118,119]; diad andtriad frequencies were determined for homogeneousand heterogeneous chitosan with different valuesof DA.
3.1.3. Molecular weight of chitosan
Another important characteristic to consider forthese polymers is the molecular weight and its
distribution. The first difficulty encountered in thisrespect concerns the solubility of the samples anddissociation of aggregates often present in poly-saccharide solutions [120]. As to choice a solvent forchitosan characterization, various systems havebeen proposed, including an acid at a givenconcentration for protonation together with a saltto screen the electrostatic interaction.
The solvent is important also when molecularweight has to be calculated from intrinsic viscosityusing the Mark–Houwink relation, Eq. (1) above,
with known values of the parameters K and a. Onesolvent first proposed (0.1M AcOH/0.2M NaCl)for molecular weight characterization was shown topromote aggregation and to overestimate the valuesof molecular weights calculated [121]. Some valuesof the Mark–Houwink parameters for chitosansolutions are given in Table 8. It was demonstratedthat the aggregates perturb not only the molecularweight determination by light scattering but also theviscosity determination. To avoid these artifacts, wethen proposed to use 0.3M acetic acid/0.2Msodium acetate (pH ¼ 4.5) as a solvent since wehad no evidence for aggregation in this mixture[123]. Absolute M values were obtained from sizeexclusion chromatography (SEC) with on-lineviscometer and light scattering detectors to allowdetermination of the Mark–Houwink parameters,and also the relation between the molecular radiusof gyration Rg and molecular weight. This analysisalso required determination of the refractive indexincrement dn/dc (where c is the polymer concentra-tion). More recently, we compared dn/dc valuesgiven in the literature with those we determined forsamples with various DA values and showed thatthe DA has a negligible influence on dn/dc in theacetic acid/sodium acetate mixture [124]. We ob-tained a value of 0.190ml/g, which is different fromvalues used by some other authors.
The fractionation by SEC on a preparative scale in0.02M acetate buffer/0.1M NaCl (pH ¼ 4.5) wasdone and discussed by Berth and Dautzenberg [125].It was applied to chitosans of commercial origin withvarious DA’s obtained by reacetylation following theprotocol of Roberts [62,121,126]. On the fractions,static light scattering, using a dn/dc of 0.203mL/g,and viscosity measurements showed that in the rangecovered (0.03oDAo0.53) the DA had no influenceon the properties of the chain. In their paper, theauthors also compared their results with all the datapreviously published in the literature. From this
Table 8
Mark–Houwink parameters for chitosan in various solvents
Solvent K (mL/g)
0.1M AcOH/0.2M NaCl 1.81� 10�3
0.1M AcOH/0.02M NaCl 3.04� 10�3
0.2M AcOH/0.1M AcONa/4M urea 8.93� 10�2
0.3M AcOH/0.2M AcONa (DA ¼ 0.02) 8.2� 10�2
0.3M AcOH/0.2M AcONa (0oDAo0.03) 7.9� 10�2
0.02M acetate buffer/0.1M NaCl 8.43� 10�2
comparison, they proposed a set of parameters forthe dependence of the intrinsic viscosity [Z] and therms molecular radius of gyration Rg on molecularweight, valid for all the samples
½Z�ðmL=gÞ ¼ 0:0843M0:92 (2)
and
RgðnmÞ ¼ 0:075M0:55. (3)
These parameters are in good agreement with theprevious results of Rinaudo et al. [123], especially forthe Mark–Houwink parameters with K ¼
0:082mL=g and a ¼ 0:76, respectively, whenDA ¼ 2%.
In a more recent paper [124], we describe acomplete analysis of the molecular weight distribu-tion by SEC using triple detection (viscosity,concentration, molecular weight) on heterogeneouschitosans, obtained from commercial sources aftersolid-state treatment, and on some homogeneouschitosans with different molecular weights obtainedby reacetylation of a highly deacetylated chitosan[121,126]. The DA of these acid-soluble chitosansvaried from 0.02 to 0.61. The data confirm theconclusion that the stiffness of the chain is nearlyindependent of the DA and demonstrate that thevarious parameters depend only slightly on theDA—a point that will be discussed below in relationto the persistence length.
The relation obtained between Rg and themolecular weight is
RgðnmÞ ¼ ð0:064� 0:002ÞM0:55�0:01. (4)
We proposed average values for the Mark–Hou-wink parameters within portions of the total rangeof DA covered, valid for heterogeneous as well ashomogeneous samples (see Table 9) [124]. Therelatively high values for the parameter a are inagreement with the semirigid character of thispolysaccharide; to validate this conclusion, one
investigates chitin and chitosan molecular modeling[127] and compares the predictions with the experi-mental results obtained by SEC. It is important tomention the usual method of preparing chitosanswith various molecular weights using nitrous acid indilute HCl aqueous solution [128,129].
We also investigated the influence of the ionicstrength on the Mark–Houwink parameters K and a
[123,130,131]. The two series of solvents used were0.3M acetic acid/variable Na acetate content and0.02M acetate buffer (pH ¼ 4.5) buffer with var-ious concentrations of NaCl, allowing to determinethe intrinsic viscosity as a function of the saltconcentration; from these experimental values,extrapolation to infinite ionic strength is used toapproach the y-conditions.
3.1.4. Persistence length of chitosan
The dimensions of chitosan chains and theirrelated hydrodynamic volume and viscometric
D
0
20
40
60
80
100
120
140
0 200 400
Per
sist
ence
Len
gth
(A)
Fig. 12. Persistence length as a function of the degree of polymerizatio
25 1C with a dielectric constant D ¼ 80.
Table 9
Mark–Houwink parameters for chitosan with different average
DA in 0.3M AcOH/0.2M AcONa [124]
DA (%) K (mL/g) a
0–3 0.079 0.79
12 0.074 0.80
22–24 0.070 0.81
40 0.063 0.83
56-61 0.057 0.825
contribution depend on the semi-rigid character ofthe polysaccharide chains. Since chitosan in an acidmedium is a polyelectrolyte, these properties areinfluenced by the ion concentration. We havediscussed this point, citing static and dynamic lightscattering experiments in the dilute and semidiluteregimes [132,133]. The actual persistence length Lt
at a given ion concentration contains an intrinsiccontribution Lp and an electrostatic contribution Le
calculated following Odijk’s treatment [134]. Theworm-like model for a semiflexible chain has beendeveloped by several groups and successfullyapplied to polysaccharides [123,124,135].
A conformational analysis of chitins with differ-ent degrees of deacetylation was recently developedin our group [127]. We concluded that chitin andchitosan are semi-rigid polymers characterized by apersistence length (asymptotic value obtained athigh degree of polymerization) that depends mod-erately on the DA of the molecule (Fig. 12). Fromthis analysis, chitosan without acetyl groups has anintrinsic persistence length Lp ¼ 9 nm at 25 1C whenthe electrostatic repulsions are screened. Lp in-creases as DA increases up to Lp ¼ 12:5 nm forDA ¼ 60%, then remains constant up to purechitin. The local stiffness is related to the conforma-tion of the molecule, and especially to theintra-chain H bond network formed as shownin Fig. 13. The decrease of the stiffness of chitosanas temperature increases is shown by 1H NMR [136]and follows the prediction from molecular
P600 800 1000
chitosan
chitin
n for chitin and chitosan obtained from molecular modelling at
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Fig. 13. Molecular modelling: (a) of a chitin chain with two H
bonds (1) between—OH 3 and O 5, (2) between—OH 6 and O of
CQO; and (b) of a chitosan chain with two H bonds (1)
between—OH 3 and O 5, and (2) between—OH 6 and N.
M. Rinaudo / Prog. Polym. Sci. 31 (2006) 603–632 617
modeling. A critical temperature around 40 1C isfound where Lp starts to decrease more rapidly,behavior that is certainly related to the destabiliza-tion of H bonds as temperature increases. Thedifference in Lp values between experiment andprediction is not dramatic for chitosan—and itcannot be directly determined for chitin fromexperiment because of the low solubility of chitin.It was shown from size exclusion chromatographyusing three detectors on-line, that Lp is about 11nm,nearly constant, for 0oDAo25%. Up to 60%acetylation, the stiffness of chitosan is not muchinfluenced by the DA, rising only to 15nm. Theinfluence of the substitution has to be related to thestability of the intra-chain H-bonds, as is shown forchitin and chitosan from molecular modeling (seeFig. 13). The small variation of the persistence lengthwith DA is in direct relation with the evolution of theMark–Houwink parameters in Table 9.
The persistence length has also been determinedby several other authors: it was given as Lp ¼
4:2 nm for DA ¼ 0.15 [100] from hydrodynamicanalysis and the Yamakawa–Fujii approach [137],8 nm [123] from a combination of SEC experimentsand the Odijk treatment[134], then 35 nm for chitinand 22 nm for chitosan (DAE0.42) [138], indicatingan increase of the chain stiffness as DA increases.A critical ratio of C1 ¼ 9 was given for0oDAo0.15 [130]. C1 ¼ limCx ¼ lim hh2
i=xa2
when the number of sugar units (x) goes to infinite;Cx corresponds to the mean-square end-to-endlength of the chain normalized by the number x ofsugar residues in the chain and a2, a being theaverage length between adjacent glycosidic oxygens.The decrease of the stiffness of chitosan chain whenthe DA decreases has been confirmed and analyzed
in terms of the destabilization of the local con-formation by intra-chain H bonds [139].
The stiffness of the chain plays a large role in therheological behavior of the molecule but also, evenin dilute solution, it affects the existence of inter-chain H-bonds forming multimers that perturb allcharacterization of these polysaccharides. Theaggregation has been discussed recently and itscauses have been analyzed; it seems that H-bonds,as well as hydrophobic attractions, have a role,whatever the DA [120].
3.2. Complex formation
3.2.1. Complex formation with metals
Chitosan is known to have good complexingability; the –NH2 groups on the chain are involvedin specific interactions with metals. Many papers areconcerned with complexation for the recovery ofheavy metals from various waste waters [140].A mechanism for complex formation with copperat pH45, was proposed [103] in agreement withX-ray data on chitosan–copper stretched films [141].Recently, the mechanism of complex formation withcopper in dilute solution was re-examined and twodifferent complexes were proposed, depending onthe pH and copper content [142]. This chelationdepends on the physical state of chitosan (powder,gel, fiber, film). Better chelation is obtained forgreater degrees of deacetylation of chitin. Thuschelation is related to the –NH2 content as well as tothe –NH2 distribution [143]. It is also related to theDP of oligo-chitosans; the complex starts to formwhen DP46 [144]. The two forms proposed are:
½Cu ð2NH2Þ�2þ; 2OH�; H2O and
½Cu ð2NH2Þ2�2þ; 2OH�:
The first complex is formed at pH between 5 and5.8, while the second forms above pH 5.8; themaximum amount of copper fixed is [Cu]/[�NH2] ¼ 0.5mol/mol.
The nature of the cation is very important in themechanism of interaction [144]; the affinity ofchitosan for cations absorbed on film showsselectivity following the order
Cuþ2 � Hgþ24Znþ24Cdþ24Niþ24Coþ2�Caþ2;
Eurþ34Ndþ34Crþ3�Prþ3;
for divalent and trivalent cations (Fig. 14) used astheir chlorides. The effect of the nature of the anion
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Fig. 14. Ionic selectivity of chitosan: amount (moles) of divalent and trivalent cations fixed per g of film. Reprinted with permission from
Eur Polym J. 2002; 38:1523–1530. Copyright 2006, Elsevier.
M. Rinaudo / Prog. Polym. Sci. 31 (2006) 603–632618
was separately demonstrated [145]: e.g. sulfateincreases the fixation on swollen chitosan beads.
In another study chitosan powder was dispersedin silver nitrate solution or used to fill a column toadsorb mercuric ions from a chloride solution [146].It was shown that the conditions for using chitosan(50 mesh particles of chitosan or chemically cross-linked beads of chitosan) also play a large role in theadsorption and on the kinetics of retention[147,148].
The complex of chitosan with Fe3+ was preparedby mixing chitosan powder in 1.5M ferric chloride;the solid formed was washed, dried and investigated[149]; these authors obtained an intramolecularwater soluble chitosan–Fe(III) complex and deter-mined that one Fe3+ is coordinated with twochitosan residues, 3 molecules of water and 1chloride ion. The general fomula given is
½FeðH2OÞ3ðGluÞ2Cl�Cl2 �H2O;
where Glu represents the glucosamine moiety. In thecomplex isolated from an aqueous solution ofpolymer and ferric chloride mixed in stoichiometricproportions, it is concluded that one Fe3+ is linkedwith two –NH2 groups and 4moles of oxygen fromwhich at least one water molecule, the remaining Nand O being part of the two saccharide units ofchitosan (Fe3+ being hexa or penta coordinated)[150]. In an X-ray study of chitosan–transitionmetal complexes, Ogawa et al. [151] used tendonchitosan immersed in solutions of various salts.They found the ratio of glucosamine to copper (II)to be 2:1, and the crystal structure of CuCl2/chitosan was different from that in complexesformed with other salts. Derivatives of chitosanhave been prepared in efforts to enhance complexformation [152–157]. In one study, the same orderof ionic selectivity for divalent cations as given
above [144] was found by calorimetric measure-ments with N-carboxymethylchitosan [157].
3.2.2. Electrostatic complexes
Chitosan, as a polyelectrolyte, is able to formelectrostatic complexes under acidic conditions.Two different types of complexes are consideredhere: electrostatic complexes with an oppositelycharged surfactant (SPEC) and polyelectrolytecomplexes (PEC).
3.2.2.1. Complexes with surfactants. A general be-havior of polyelectrolytes is demonstrated withchitosan and sodium dodecyl sulfate (SDS). Anelectrostatic complex is formed in the presence of alow DA chitosan involving cooperative stacking ofsurfactant alkyl chains. Apparently the associationforms a micellar system that precipitates out, but forvery small amounts of added surfactant, interestinginterfacial properties are observed. A critical ag-gregation concentration (c.a.c.) around 100-foldsmaller than the c.m.c. of the surfactant alone isdetected by surface tension measurements (Fig. 15)[158,159]. The cooperativity of the observed inter-action depends directly on the charge density of thechitosan (in fact, it depends on the distance betweentwo adjacent ionic sites), as is shown for carbox-ymethylchitin in the presence of tetradecyltrimethy-lammonium bromide (TTAB) [160].
In addition, a capsule is formed when a chitosansolution is dropped into a SDS surfactant solution;a chitosan gel layer (characterized by an orderednanostructure) crosslinked by charged surfactantmicelles is formed in the interfacial film [161]. Babaket al. [162] showed that this structure can encapsu-late enzymes.
This type of electrostatic complex has beenexamined by calorimetry. The strong affinity and
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Fig. 15. Electrostatic complex formed between chitosan and an
anionic surfactant. Surface tension at air–solution interface
as a function of the concentration of (1) cationic chitosan (2)
anionic surfactant SDS (3) SDS in chitosan (c ¼ 2:7�10�3 monomol=dm3) /SDS complex in acetate buffer (0.05M).
Reprinted with permission from Colloids and surfaces, A:
Physicochem Eng Aspects. 1999; 147: 139–148. Copyright 2006,
Elsevier.
M. Rinaudo / Prog. Polym. Sci. 31 (2006) 603–632 619
its dependence on the excess of external salt confirmthe electrostatic mechanism [163–165].
This electrostatic interaction has been comparedwith covalent analogs obtained by grafting alkylchains on a chitosan backbone (these derivativeswill be described below). The interfacial propertiesof the chitosan-derived polymer surfactant hasrelatively low surface tension acitivity but interest-ing bulk properties. The role of sulfated N-acylchitosan (S–Cn–Chitosan) in a lipid membrane wascompared with that of SDS to show that SDSdissociates the membrane, whereas the polymerstabilizes the membrane, and even increases itsrigidity, suggesting low toxicity in bioorganisms. Insolution, when the alkyl chain in S–Cn–chitosan islonger than 10 units, the polymers form more stablemicelles than those formed by the same alkyl chainsurfactant alone [166].
Interactions of this kind are relevant to the fieldof food chemistry, involving specific interactions ofchitosans with phospholipids and bile acids [164].
3.2.2.2. Complexes with oppositely charged polymers
(proteins, polyanions, DNA). There are no goodexamples of polymer/polymer complex formationbased on chitosan and neutral polymers, althoughmany electrostatic PEC between chitosan andsynthetic or natural polymers are cited in the
literature: e.g. polyacrylic acid, sodium salt (PAA),carboxymethylcellulose (CMC) [167,168], xanthan,carrageenan, alginate (extracted from brown algae),pectin, heparin, hyaluronan (HA) [108,169], sul-fated cellulose, dextran sulfate, N-acylated chitosan/chondroitin sulfate [170,171]. The electrostaticinteraction has been discussed in relation to thestiffness of the backbone and nature of the ionicgroups involved. Especially with alginate or HA, apH-dependent complex is formed, whose stabilitydepends on the ionic strength. The complex forma-tion was investigated in dilute solution by potentio-metry following changes in pH and conductivity todetermine the fraction of ion pairs (–COO�+NH3–)formed, depending on the experimental conditions[108,172]. The interaction between chitosan andalginate gives an electrostatic complex which so farhas been used mostly for biological applications.The complex between DNA and chitosan oligomers(or polymers) is now under investigation in manylaboratories. In a recently published investigation ofthe mechanism and cooperativity of the complexa-tion with chitosan oligomers [173], it was shownthat a minimum DP (and charge) around 6–9 isnecessary for stability. The stability of this complexis reduced above pH ¼ 7.4, near the physiologicalpH, a finding that seems highly relevant for genedelivery applications and is interpreted as onereason for the observed high transfection activityof the oligomer-based complex.
The main applications of these electrostaticcomplexes are antithrombogenic materials, con-trolled release systems, encapsulation of drugs,immobilization of enzymes and cells, and genecarriers. Some examples will be discussed belowwhere the applications of alginate/chitosan com-plexes are discussed.
One aspect of these complexes now in develop-ment is the preparation, layer-by-layer (successively,one layer of polyanion–one layer of polycation), ofpolyelectrolyte capsules or films based on chargedbiocompatible polysaccharides or chitosan/syn-thetic PEC [169,174,175]. In the case of chitosancapsules [174], PAA is used to form the capsules,then the chitosan is crosslinked and the PAA isredissolved. Such chitosan capsules are more stablethan in absence of chemical crosslinking and arepH-sensitive, swelling at low pH and shrinking athigh pH. Porous gels (sponges) can be prepared byformation of a calcium alginate gel stabilized bycomplexation with galactosylated chitosan (a water-soluble derivative) [176]. A complex in the form of
beads was produced by dropwise addition ofNa–alginate to a chitosan–CaCl2 solution. Thesebeads differ from Ca–alginate beads in exhibitingmaximum swelling at pH 9 [177]. Oligo-chitosans,low molecular weight chitosans, were also com-plexed with alginates to form capsules with con-trolled permeability [178,179].
3.3. Chitosan-based materials
Chitosan is used to prepare hydrogels, films,fibers or sponges, as previously mentioned, most ofthe materials are used in the biomedical domain, forwhich biocompatilibity is essential. Many systemsare described in the literature, but we can cite only afew of the most promising. Chitosan is much easierto process than chitin, but the stability of chitosanmaterials is generally lower, owing to their morehydrophilic character and, especially, pH sensitivity.To control both their mechanical and chemicalproperties, various techniques are used, as men-tioned previously for chitin. Often, the methods areadapted from the cellulose world.
First, chitosan may be crosslinked by reagentssuch epichlorohydrin [180], diisocyanate [181] or 1,4-butanediol diglycidyl ether [182]. Specific cross-linking was performed on a blend of starch andchitosan: starch was oxidized to produce a poly-aldehyde that reacts with the –NH2 group ofchitosan in the presence of a reducing agent [183].Many chitosan hydrogels are obtained by treatmentwith multivalent anions: the case of glycerol-phosphate is mentioned above [104], but oxalic acidhas also been used [93b,184] as well as tripolypho-sphate [185,186].
Blends and composites have been preparedespecially by Hirano, in the way mentionedpreviously for chitin [84]. Other systems areproposed in the literature: chitosan/polyamide 6[187], chitosan/cellulose fibers [188], chitosan/cellu-lose using a common solvent [189], chitosan/polyelthylene glycol [190], chitosan/polyvinylpyrro-lidone and chitosan/polyvinyl alcohol [191]. Re-cently, reinforcement of chitosan film with carbonnanotubes was tested; this composite exhibits alarge increase of the tensile modulus with incor-poration of only 0.8% of multiwalled carbonnanotubes [192]. The advantage of chitosan in suchmaterials is not only its biodegradability and itsantibacterial activity, but also the hydrophilicityintroduced by addition of the polar groups able toform secondary interactions (–OH and –NH2
groups involved in H bonds with other polymers).The most promising developments at present are inpharmaceutical and biological areas, and at a lowerlevel in cosmetics. This aspect will be described inthe following.
3.4. Chemical modification of chitosan
3.4.1. Modification reactions
Among the many mentions of chitosan deriva-tives in the literature [65,193,194], one can differ-entiate specific reactions involving the –NH2 groupat the C-2 position or nonspecific reactions of –OHgroups at the C-3 and C-6 positions (especiallyesterification and etherification) [75]. The –NH2 inthe C-2 position is the important point of differencebetween chitosan and cellulose, where three –OHgroups of nearly equal reactivity are available. Themain reaction easily performed involving the C-2position is the quaternization of the amino group ora reaction in which an aldehydic function reactswith –NH2 by reductive amination. This latterreaction can be performed in aqueous solutionunder very mild conditions to obtain randomlydistributed substituents in a controlled amountalong the chitosan chain. This method has beenproposed to introduce different functional groupson chitosan using acryl reagents in an aqueousmedium; introduction of N-cyanoethyl groups issaid to produce some cross-linking through areaction between the nitrile group and the aminegroup [195]. In addition, it is important to note thatmore regular and reproducible derivatives should beobtained from highly deacetylated chitin [99]—assuring control of the quality of the initial materialthat is essential before modification, especially whenbiological applications are to be explored.
3.4.2. Some chitosan derivatives
3.4.2.1. O-and N-Carboxymethlchitosans. Carboxy-methylchitosan (CM-chitosan) is the most fullyexplored derivative of chitosan; it is an amphotericpolymer, whose solubility depends on pH. Undercontrolled reaction conditions (with sodium mono-chloracetate in the presence of NaOH), one gets O-and N-carboxymethylation. The yield of substitu-ents on the three positions was determined by NMR[196]. This reaction extends the range of pH(pH47) in which chitosan is water-soluble, but aphase separation due to the balance betweenpositive and negative charges on the polymer wasobserved at 2.5opHo6.5.
Most interesting is the preparation of N-carbox-ymethylchitosan by reaction with glyoxylic acid inthe presence of a reducing agent [196c]. Thedistribution of monosubstituted (–NH–CH2COOH)and disubstituted (–N (–CH2COOH)2) groups wasestablished by 1H and 13C NMR. Disubstitution iseasily obtained, giving an interesting derivative forion complexation. A specific oxidation of the C-6position hydroxyl group was realized using theTEMPO reactant on chitin to produce a chitin-based hyaluronic acid analog [197]. This derivativeis water soluble in a wide range of pH, but only if itis prepared from a fully acetylated chitin.
3.4.2.2. Chitosan 6-O-sulfate. This derivative is ananticoagulant; it was first prepared as an O- sulfatedderivative [198,199] and more recently as N-sulfatedchitosan [200].
3.4.2.3. N-methylene phosphonic chitosans. Theseinteresting anionic derivatives, with some ampho-teric character were synthesized under variousconditions and proved to have good complexingefficiency for cations such as Ca2+, and those oftransition metals (Cu (II), Cd (II), Zn (II) etc.)[201,202]. The complexation provides corrosionprotection for metal surfaces [203]. These deriva-tives were also modified and grafted with alkylchains to obtain amphiphilic properties that havepotential applications in cosmetics [204].
3.4.2.4. Trimethylchitosan ammonium. This catio-nic derivative, water soluble over all the practicalpH range, is obtained by quaternization of chitosan[205] with methyl iodide in sodium hydroxide undercontrolled conditions, and has been fully character-ized by NMR [196c,206]. A large decrease ofmolecular weight during this reaction is observedunder all conditions tested. These polymers showgood flocculating properties with kaolin dispersions,suggesting applications to paper making [207].Other quaternized derivatives have been preparedare claimed to have antistatic properties [208].
3.4.2.5. Carbohydrate branched chitosans. Carbo-hydrates can be grafted on the chitosan backboneat the C-2 position by reductive alkylation: For thatpurpose, disaccharides (cellobiose, lactose, etc.)having a reducing end group, are introduced, inthe presence of a reductant, on chitosan in the open-chain form [209]. These derivatives are watersoluble. Galactosylated chitosan was mentioned
previously [176]. Carbohydrates can also be intro-duced without ring opening on the C-6 position[210]. These derivatives are important as they arerecognized by the corresponding specific lectins andthus could be used for drug targeting [194].A special case is the grafting of a cyclic oligosac-charide, cyclodextrin, discussed below.
3.4.2.6. Chitosan-grafted copolymers. One of themost explored derivatives is poly(ethylene glycol)-grafted chitosan, which has the advantage of beingwater soluble, depending on the degree of grafting:higher molecular weight PEG at low DS giveshigher solubility than low molecular weight PEG[194]. PEG can be also be introduced by reductiveamination of chitosan using PEG-aldehyde [211].
Polypeptides have been grafted by reaction withN-carboxyanhydrides of amino acids with thepurpose of developing new biomaterials [212], butthe degree of polymerization of the grafted chainscited in this work remains low (DP ¼ 5.9–6.6).
3.4.2.7. Alkylated chitosans. Alkylated chitosansare very important as amphiphilic polymers basedon polysaccharides. The first derivative having thesecharacteristics was a C-10-alkyl glycoside branchedchitosan with a high degree of substitution(DS ¼ 1.5), which gelled when heated over 50 1C[213]. Another approach was used for selectiveN- and O-palmitoylation giving a derivative withtwo or three long alkyl chains per monomeric unit.This reaction involved protection and deprotectionof the C-6 position [214].
By using carboxylic anhydrides with differentchain lengths on CM-chitosan, highly substitutedderivatives with low regularity were obtained. Theywere insoluble in water and their biodegradabilitywas decreased [215].
Using the reductive amination, a series ofamphiphilic derivatives were produced with differ-ent chain lengths (Cn from 3 to 14) and controlledDS (usually lower than 10% to maintain watersolubility in acidic conditions) [216]. This techniquewas also used to introduce n-lauryl chains [217].Alkylated chitosans with good solubility in acidicconditions (pHo6) have a number of very interest-ing properties. First, they exhibit surface activityand they were compared with corresponding lowmolecular weight surfactants [158,159,161]; for thesame amount of alkyl chains with the same length,they have a relatively low effect on the decrease ofthe surface tension but they improve much the
Fig. 16. Rheological behavior (G0 and G00 moduli as a function of
frequency) for (a) chitosan 30 g/L and (b) 50/50 mixture of CD-
chitosan and AD-chitosan at a total polymer concentration
4.43 g/L in 0.3M AcOH/0.03M AcONa. Reprinted with
permission from J Phys Chem B. 2003; 107:8248–8254. Copy-
right 2006, American Chemical Society.
M. Rinaudo / Prog. Polym. Sci. 31 (2006) 603–632622
stability of the interfacial film [160,218,219]; it wasclearly demonstrated that a simple surfactant andmodified chitosan have completely different beha-vior [161b,166]; secondly, they increase considerablythe viscosity of aqueous solution due to hydro-phobic inter-chain interactions; especially for C-12chain length and a DS�5%, a physical gel isobtained ; the formation of this gel depends onthe pH [220] and on salt concentration [221]. Thesegels result from a balance between electrostaticrepulsions between the positively charged chitosanchains and hydrophobic attraction due to alkylchains mainly in relation with their length [216]. Thehydrophobic domains formed in the systems areimportant to adsorb hydrophobic molecules such aspyrene (a fluorescent probe used to evidence thesedomains in dilute solution); these associations canbe destroyed reversibly by addition of cyclodextrinswhich are known to complex the alkyl chains ofsurfactants [221,222]. It is interesting to mentionthat alkyl chitosans are compatible with neutral andcationic surfactants; it was demonstrated thatcationic surfactant adsorbed on the alkyl chaingrafted on chitosan, promotes its solubilization[158].
3.4.2.8. Cyclodextrin-linked chitosans. The cyclicoligosaccharides, namely a-,b-,g-cyclodextrins(CD), are important because of their ability toencapsulate hydrophobic molecules in their toroidalhydrophobic cavity, whose selectivity dependson the number of glucose units (respectively 6, 7,8 D-glucose units) [222–224]. For various applica-tions, it is interesting to graft the cyclodextrin on apolymeric backbone such as a biocompatible poly-saccharide. A synthesis of a- and b-cyclodextrin-chitosans with relatively high degree of substitutionhas been described [225]. The authors found thatthese new derivatives had the ability to differentiallyrecognize and retain certain guest compounds basedon their molecular shapes and structures. Theyproposed to use these polymers as supports forreverse-phase adsorption or as adsorbents in con-trolled release systems.
A b-cyclodextrin with a specific modification onone of the –OH groups on its small side was graftedto chitosan by reductive amination. At a DS lowerthan 10%, these derivatives are water soluble inacidic conditions with loose inter-chain interactions[226,227]. The grafted cyclodextrin has the sameassociation constant as the free CD with smallhydrophobic molecules such as adamantane [227].
This modified chitosan should be adaptable for drugdelivery. When these CD-chitosans were mixed withchitosan grafted with adamantane (AD), the specificrecognition led to a self-assembled gel (Fig. 16)[228]. This physical gel is stabilized by specific CD/AD linkages in a dynamic mechanism with arelaxation time depending on polymer concentra-tion, temperature, and the presence of excess freeCD or AD [229].
3.5. Applications of chitosan and chitosan derivatives
Table 10 summarizes the main properties ofchitosan and potential biomedical and other appli-cations that they imply. The great current interest inmedical applications of chitosan and some of itsderivatives is readily understood. The cationiccharacter of chitosan is unique: it is the onlypseudo-natural cationic polymer. Its film formingproperties and biological activity invite new appli-cations. Table 11 recalls the main applications ofchitosan. The most important fields where thespecificity of chitosan must be recognized arecosmetics (especially for hair care in relation toelectrostatic interactions) (Table 12) and the phar-maceutical and biomedical applications on whichwe focus, which probably offer the greatest promise[230,231].
Drug delivery applications include oral, nasal,parenteral and transdermal administration, im-plants and gene delivery. The transmucosal admin-istration of drugs has been discussed recently [232].
ARTICLE IN PRESS
Table 10
Principal properties of chitosan in relation to its use in biomedical
applications
Potential Biomedical
applications
Principal characteristics
Surgical sutures Biocompatible
Dental implants Biodegradable
Artificial skin Renewable
Rebuilding of bone Film forming
Corneal contact lenses Hydrating agent
Time release drugs for
animals and humans
Nontoxic, biological
tolerance
Encapsulating material Hydrolyzed by lyzosyme
Wound healing properties
Efficient against bacteria,
viruses, fungi
Table 11
Principal applications for chitosan
Agriculture Defensive mechanism in plants
Stimulation of plant growth
Seed coating, Frost protection
Time release of fertilizers and
nutrients into the soil
Water & waste
treatment
Flocculant to clarify water (drinking
water, pools)
Removal of metal ions
Ecological polymer (eliminate
synthetic polymers)
Reduce odors
Food & beverages Not digestible by human (dietary
fiber)
Bind lipids (reduce cholesterol)
Preservative
Thickener and stabilizer for sauces
Protective, fungistatic, antibacterial
coating for fruit
Cosmetics & toiletries Maintain skin moisture
Treat acne
Improve suppleness of hair
Reduce static electricity in hair
Tone skin
Oral care (toothpaste, chewing gum)
Biopharmaceutics Immunologic, antitumoral
Hemostatic and anticoagulant
Healing, bacteriostatic
M. Rinaudo / Prog. Polym. Sci. 31 (2006) 603–632 623
Mucoadhesivity of chitosan and cationic derivativesis recognized and has been proved to enhance theadsorption of drugs especially at neutral pH;N-trimethyl chitosan chloride interacts with nega-tively charged cell membranes [233,234].
n-Lauryl-carboxymethylchitosan is an amphiphi-lic polymer. It forms micelles that solubilize taxol,making it more effective therapeutically, and it isfound to be safe in terms of membrane toxicity. Thistype of derivative is generally useful as a carrier forhydrophobic cancer drugs [235].
Some recent advances in drug release should bementioned. Films of chitosan incorporating pre-dnisolone, formed by mixing have been tested forthis purpose [242]. Chitosan gels and layer-by-layerpolyelectrolyte capsules are often used for con-trolled release of drugs or proteins, as previouslynoted.
Chitosan and its derivatives have been used forgene transfection: for N-alkylated chitosan, it hasbeen shown that transfection efficiency increasesupon elongating the alkyl side chains and levels offwhen the number of carbons in the side chainexceeds 8 [236]. Quaternized chitosan can be usedfor the same purpose [237].
The physical properties of chitosan recommend it,for use in many types of devices [239]. In addition,proteins and DNA can be assembled with a stimuli-responsive chitosan backbone.
Another point to note is biological activity inregard to agriculture since chitosan exhibits anti-virus and antiphage activities [240]. It inhibits thegrowth of bacteria and bacterial infection, andstimulates the natural defenses in plants. A mechan-ism has been proposed via the ‘‘octadecanoidpathway’’ [241].
Alginate/chitosan systems have found applica-tions as wound dressings and in bone tissueengineering [243,244].
An interesting application concerns a self-settingcalcium phosphate cement: chitosan glyceropho-sphate mixed with calcium phosphate and citric acidforms an injectable self-hardening system for bonerepair or filling [92,238].
4. Conclusion
In this review we aim to present an overview ofthe state of art in the knowledge and technicalapplications of chitin and chitosan. We include anextensive bibliography of recent studies, both basicand applied. Nevertheless, this is an ambitiousproject; and the very large number of paperspublished on a wide range of properties andapplications forces us to make a selection from themost significant results obtained by the manygroups working around the world.
ARTICLE IN PRESS
Table 12
Specific characteristics for applications of chitosan in hair care
Properties Uses
Aqueous solution interacting with negatively charged hair
(electrostatic interaction)
Shampoos
Antistatic effect (due to hydrophilic character), maintains
moisture in low humidity and hair style in high humidity
Hair tonics
Rinses
Permanent wave agents
Hair colorants
Lacquers,
Hair sprays
Time release delivery (chitosan beads, gels or granules)
Removing sebum and oils from hairs (due to hydrophobic
character)
Antibacterial and antifungal activity
Thickening polymer
Role in surfactant stability; stabilize emulsion
Make hair softer, increase mechanical strength
Protect elastic film on hairs, increasing their softness.
M. Rinaudo / Prog. Polym. Sci. 31 (2006) 603–632624
Chitin is a natural polymer for which we try topoint out some unique features and its potential foruseful development. It is important to bear in mindthat its insolubility in ordinary solvents, makeschitin difficult to characterize and to process.
Though much work has been done to elucidatethe morphology of chitin in the solid state,uncertainties still remain in the published record,and better parameters are still needed on a-chitinand hydrated b-chitin.
Chitin can be transformed and used as fiber, film,sponge or powder. The preparation of derivativesthat are soluble, especially in aqueous media, makesit possible to take advantage of the special proper-ties of chitin: this polysaccharide is a film-formingpolymer, biodegradable and renewable; it alsohas antibacterial and fungistatic properties; thesemi-rigid character of chitin is valuable forthickening properties but also promotes theinter-chain interactions that cause difficulties incharacterization. Due to the diversity of sources ofchitin and their state of organization in the solidstate, the quality of commercial chitin available isnot uniform and causes many difficulties duringtransformation and chemical modification. This isone of the factors that hinder the development ofnew uses. In addition, the high cost of extractionand purification of chitin seems to reserve thispolymer to high added-value applications. Forthese reasons, it is assumed that biomedical andpharmaceutical applications are the most promising
domains for development, with cosmetics in secondplace.
Similar conclusions can be drawn for chitosan,which is the most important derivative of chitin,even though the difficulty of controlling thedistribution of the acetyl groups along the backbonemakes it difficult to get reproducible initial poly-mers. Unlike chitin, chitosan is water soluble inacidic media, or under precisely specified conditionsat neutral pH, allowing much development in thedomains of solutions and hydrogels.
The advantage of chitosan over other polysac-charides (cellulose, starch, galactomannans, etc.) isthat its chemical structure allows specific modifica-tions without too many difficulties at the C-2position, as described in this review. Specific groupscan be introduced to design polymers for selectedapplications.
Finally, the natural biological properties of chitinand chitosan are valuable for both plant and animalapplications, and such developments can be con-sidered as valuable extensions of the use of chitinand its derivatives.
Acknowledgments
The author thanks Henri Chanzy (CERMAV-Grenoble) for valuable information regarding thesolid-state structure of chitin and Karim Mazeau(CERMAV-Grenoble) for the molecular modellingof chitin and chitosan.