TEMPO-mediated oxidation of chitin, regenerated chitin and N-acetylated chitosan

A commercial chitin, regenerated chitin prepared from chitin solutions in 6.8% NaOH and N-acetylated chitosans with degrees of N-acetylation (DNAc) of 77–93% were subjected to oxidization in water with NaClO and catalytic amounts of 2,2,6,6-tetramethylpiperidinyloxy radical (TEMPO) and NaBr. When regenerated chitin with DNAc of 87% and N-acetylated chitosan with DNAc of 93% were used as starting materials, water-soluble β-1,4-linked poly-N-acetylglucosaminuronic acid (chitouronic acid) Na salts with degrees of polymerization of ca. 300 were obtained quantitatively within 70 min. On the other hand, the original chitin and N-acetylated chitosan with DNAc of 77% did not give water-soluble products, owing to incomplete oxidation. The high crystallinity of the original chitin brought about low reactivity, and the high C2-amino group content of the N-acetylated chitosan with DNAc of 77% led to degradations rather than the selective oxidation at the C6 hydroxyls. The obtained chitouronic acid had low viscosities in water, and clear biodegradability by soil microorganisms.     

Determination of the degree of deacetylation of chitin and chitosan by X-ray powder diffraction

A new method to determine the degree of deacetylation (DD) of alpha-chitin and chitosan in the range of 17-94% DD using X-ray powder diffraction (XRD) is proposed. The results were calibrated using (1)H NMR spectroscopy for chitosan and FTIR for chitin, in comparison with the potentiometric titration method. The results showed a good linear correlation between the CrI020 from XRD and the calibrated DD value. This method is found to be simple, rapid and nondestructive to the sample.     

Influence of some reactional parameters on the substitution degree of biopolymeric Schiff bases prepared from chitosan and salicylaldehyde

Some reactional parameters as mol ratio (salicylaldehyde:free amino groups), reaction time and temperature were investigated in order to improve the substitution degree (DS) in the preparation of biopolymeric Schiff bases from chitosan. In this case, the reaction of chitosan and salicylaldehyde was used as a probe system in order to produce the Schiff base. The use of 50% (mol/mol) salicylaldehyde excess, reaction time of 18 h and temperature of 55 °C permitted to obtain a DS of 60% without evidences of hydrolysis of the biopolymeric matrix or changes in its acetylation degree.     

Determination of the degree of N-acetylation (DA) of chitin and chitosan in the presence of water by first derivative ATR FTIR spectroscopy

A new method for the determination of the degree of N-acetylation (DA) of chitin and chitosan is described using first derivative diamond ATR FTIR spectroscopy. Applying the derivative values of the amide III band at 1327 cm⁻¹ and the CH deformation band of the N-acetyl group at 1383 cm⁻¹ as measure of the N-acetyl content of the sample in relation to the derivative value of the bridge oxygen vibration at 1163 cm⁻¹ as internal standard, a linear correlation to the results of first derivative UV spectroscopy was obtained and confirmed by elemental analysis and Raman spectroscopy. The described method allows the determination of the degree of N-acetylation of chitosan and chitin in the presence of water thus making drying procedures unnecessary.     

Structure analysis and degree of substitution of chitin, chitosan and dibutyrylchitin by FT-IR spectroscopy and solid state C NMR

Chitin, an important constituent of the exoskeleton of many organisms such as crustacea and insects, and its derivates promote the ordered healing of tissues and are therefore very suitable for use in wound dressings. The degree of substitution (DS) is an important parameter when assessing the conversion of chitin into one of its derivates. The degree of acetylation of chitin and chitosan and the degree of butyrylation of dibutyrylchitin was evaluated. It is found that FT-IR spectroscopy is a relatively easy but indirect way of determining the DS. FT-IR spectroscopy proved to be very useful for comparing the degrees of conversion and -substitution, as well as for differentiating between different chitin types. Absolute DS determinations by FT-IR however are only reliable when a calibration, using a direct technique such as ¹³C-NMR, is made.     

Immobilization of a protease on modified chitosan beads for the depolymerization of chitosan

Neutral protease was immobilized on chitosan (CS), carboxymethyl chitosan (CMCS), and N-succinyl chitosan (NSCS) hydrogel beads. And the biocatalysts obtained were used to prepare low molecular weight chitosan (LMWC) and chitooligomers. Weight-average molecular weight of LMWC produced by neutral protease immobilized on CS, CMCS and NSCS hydrogel beads were 3.4 kDa, 3.2 kDa and 1.9 kDa, respectively. The effects of immobilization support and substrate on enzymatic reaction were analyzed by measuring classical Michaelis-Menten kinetic parameters. The FT-IR, XRD and potentiometric determination results indicated decrease of molecular weight led to transformation of crystal structure, but the degree of N-deacetylation and chemical structures of residues were not changed compared to initial chitosan. The degree of polymerization of chitooligomers was mainly from 2 to 7. We observed a strong dependence of the immobilized enzyme properties on the chemical nature of the supports, which leads to different microenvironment of neutral protease and changes the hydrolyzing process.     

Determination of the degree of acetylation of chitosan by UV spectrophotometry using dual standards

Determination of the degree of acetylation of chitosan by UV spectrophotometry using dual standards is investigated. The UV absorbance of a pure chitosan solution is contributed additively by the N-acetylglucosamine and glucosamine residues; the absorbance divided by the total molar concentration of the residues (A/c(t)) is linearly related to the degree of acetylation (DA). Using acetyl glucosamine and glucosamine hydrochloride as standards in 0.1M hydrochloric acid solution, the equation obtained by linear regression is A/c(t)=3.3615 DA+0.0218, R(2)=0.9958. The DA of the analytical sample (m milligram of chitosan in V liters solution) can be calculated by.     

Mucoadhesive property and biocompatibility of methylated N-aryl chitosan derivatives

The methylated N-aryl chitosan derivatives, methylated N-(4-N,N-dimethylaminocinnamyl) chitosan chloride (MDMCMCh) and methylated N-(4-pyridylmethyl) chitosan chloride (MPyMeCh), were synthesized by two steps, the reductive amination and the methylation. The physicochemical properties of chitosan derivatives were determined by ATR-FTIR, NMR, X-ray diffraction (XRD) and thermogravimetric (TG) techniques. The XRD analysis showed that the crystallinity and thermal stability of methylated chitosan derivatives were lower than those of chitosan. The effects of degree of quaternization (DQ), polymer structure and positive charge location on mucoadhesive property and cytotoxicity were investigated by using a mucin particle method and MTT assay compared to N,N,N-trimethylammonium chitosan chloride (TMChC). It was found that the mucoadhesive property and cytotoxicity increased with increasing DQ. At the DQ of 65%, the mucoadhesive property of the MDMCMCh was twofold lower than that of the TMChC. However, this phenomenon did not affect the mucoadhesive property when the DQ was higher than 65%. Surprisingly, the MPyMeCh showed the lowest toxicity even with the high DQ. These could be due to the resonance effect of the positive charge in the pyridine ring and the molecular weight after methylation. Finally, our result revealed that the mucoadhesive property was dependent on the DQ and polymer structure whereas the cytotoxicity was dependent on the combination of the polymer structure, positive charge location and molecular weight after methylation.     

Determination of deacetylation degree of chitosan: a comparison between conductometric titration and CHN elemental analysis

Chitosan is a polysaccharide used in a broad range of applications. Many of its unique properties come from the presence of amino groups in its structure. A proper quantification of these amino groups is very important, in order to specify if a given chitosan sample can be used in a particular application. In this work, a comparison between the determination of chitosan degree of deacetylation by conductometry and CHN elemental analysis was carried out, using a rigorous error analysis. Accurate expressions relating CHN composition, conductometric titration, and degree of deacetylation, in conjunction with their associated errors, were developed and reported in this note. Error analysis showed conductometric analysis as an inexpensive and secure method for the determination of the degree of deacetylation of chitosan.     

Determination of N-acetyl content in chitosan samples by c.d. measurements

A glucosamine residue, in the ammonium form, does not give a c.d. signal in the 200–250 nm range whereas an N-acetyl glucosamine residue gives an n-π^* transition with a c.d. band located near 211 nm. Thus circular dichroism allows one to deduce the N-acetyl content of chitosans with relatively great accuracy. The c.d. results are compared with three i.r. determinations in the literature.     

Synthesis, characterization, cytotoxicity and antibacterial studies of chitosan, O-carboxymethyl and N,O-carboxymethyl chitosan nanoparticles

Chitosan (CS) is a naturally occurring biopolymer. It has important biological properties such as biocompatibility, antifungal and antibacterial activity, wound healing ability, anticancerous property, anticholesteremic properties, and immunoenhancing effect. Recently, CS nanoparticles have been used for biomedical applications. However, due to the limited solubility of CS in water its water-soluble derivatives are preferred for the above said applications. In this work, the nanoparticles of CS and its water-soluble derivatives such as O-carboxymethyl chitosan (O-CMC) and N,O-carboxymethyl chitosan (N,O-CMC) was synthesized and characterized. In addition, cytotoxicity and antibacterial activity of the prepared nanoparticles was also evaluated for biomedical applications.     

Kinetic study of acid depolymerization of chitosan and effects of low molecular weight chitosan on erythrocyte rouleaux formation

In this study, the depolymerization of chitosan was carried out in an acetic acid aqueous solution and was followed by viscometry for molecular weight determination. It was found that the depolymerization rate increased with elevated temperatures and with high acid concentrations. Based on FTIR analysis, the chitosan was depolymerized randomly along the backbone; no other structural change was observed during the acid depolymerization process. Revealed in the TGA study, the degradation temperature and char yield of LMWCs (low molecular weight chitosan) were molecular weight dependent. The blood compatibility of LMWCs was also investigated: rouleaux formation was observed when erythrocyte contacted with LMWCs, which showed that LMWCs are able to interfere with the negatively charged cell membrane through its polycationic properties. Furthermore, as regards a kinetics investigation, the values of M_n (number-average molecular weight) were obtained from an experimentally determined relationship. The kinetics study showed that the complex salt, formed by amine on chitosan and acetic acid, acted as catalyst. Finally, the activation energy for the hydrolysis of the glycosidic linkage on chitosan was calculated to be 40 kJ/mol; the mechanism of acid depolymerization is proposed. In summary, LMWCs could be easily and numerously generated with acid depolymerization for further biological applications.     

Degradation behavior of chitosan chains in the 'green' synthesis of gold nanoparticles

The degradation behavior of chitosan chains in the synthesis of Au nanoparticles by a 'green' method was investigated in this paper for the first time. UV-vis absorption spectra suggested the formation of Au nanoparticles and TEM images showed that their sizes were between 10 and 50nm. During the process of synthesis, the intrinsic viscosity [eta] of chitosan was observed to decrease gradually, implying that the chitosan chains degraded under the reaction conditions. Further studies showed that the degree of degradation of the chitosan chains was changed with different reaction temperatures, reactant ratios, and the molecular weights of chitosan.     

Fractionation and characterization of chitosan by analytical SEC and H NMR after semi-preparative SEC

Heterogeneity in molecular weight and degree of deacetylation (DDA) of chitosans from different sources and preparation methods were studied by fractionating chitosans, using semi-preparative SEC, and then determining molecular weight profiles of fractions by analytical SEC with multi-angle laser light scattering (SEC–MALLS), and degree of deacetylation (DDA) by ¹H NMR. Fractionation of two high molecular weight chitosans from different manufacturers, produced fractions that spanned a wide range of molecular weight (number-average M_n), from 65 to 400 kDa in one case, that was not evident when unfractionated material was directly analyzed by SEC providing M_n = 188 kDa and PDI = M_w/M_n = 1.73. In a second case, fractions ranged from 20 to 600 kDa with unfractionated M_n = 145 kDa and PDI = 1.83. Fractionation of low molecular weight chitosans also showed a broad range of molecular weight in the original material, however, the fractions obtained with the TSKgel G4000W column in the M_n range of 5–100 kDa were essentially monodisperse with PDIs between 1.0 and 1.4. The DDA of one low molecular weight chitosan (10 kDa) produced by nitrous acid degradation was dependent on the M_n of the fraction. This semi-preparative fractionation procedure revealed important compositional heterogeneities of chitosans not evident in unfractionated material, and permitted the production of monodisperse low molecular weight chitosans with homogeneous properties.     

A new method for the quantification of chitin and chitosan in edible mushrooms

Along with β-glucans, chitin is the dominant component of the fungal cell wall. Chitosan, the deacetylated form of chitin, has found quite a number of biomedical and biotechnological applications recently. Mushroom chitin could be an important source for chitosan production. A direct determination of chitin and chitosan in mushrooms is of expedient interest. In this paper, a new method for the quantification of chitin and chitosan is described. This method is based on the specific reaction between polyiodide anions and chitosan and on measuring the optical density of the insoluble polyiodide–chitosan complex. After deacetylation, chitin can also be quantified. The specificity of the reaction is used to quantify the polymers in the presence of complex matrices. With this new spot assay, the chitin content of mycelia and fruiting bodies from several basidiomycetes and an ascomycete were analysed. The presented method could also be used for the determination in other samples as well. The chitin content of the analysed species varies between 0.4 and 9.8 g chitin per 100 g of dry mass. Chitosan could not be detected in our mushroom samples, indicating that the glucosamine units are mostly acetylated.     

Selective carboxypropionylation of chitosan: synthesis, characterization, blood compatibility, and degradation

Two water-soluble chitosan (WSC) derivatives of N-succinyl-chitosan (NSCS) and N,O-succinyl-chitosan (NOSCS) with a degree of substitution (DS) that ranged form 0.28 to 0.61 were selectively synthesized by varying the molar ration of succinic anhydride and chitosan. The chemical structure and physical properties of the chitosan derivatives were characterized by FT-IR, ¹H NMR, and XRD. XRD analysis showed that the derivatives were amorphous. The lysozyme enzymatic degradation results revealed that the NSCS was of higher susceptibility to lysozyme. The degradation rate and the solubility of the chitosan derivatives were strongly determined by the degree of substitution and the position of the substitution. The results of antithrombotic properties, hemolytic properties and anticoagulant properties of WSCs indicated that the blood compatibility was dramatically improved, and the carboxyl group introduced on the C-6 or C-2 hydroxyl group appeared to impact anticoagulant activity in different ways.     

Kinetics and mechanisms of depolymerization of alginate and chitosan in aqueous solution

The kinetics and mechanisms of depolymerization of aqueous chitosan and alginate solutions at elevated temperatures have been investigated. Chitosan salts of different degree of acetylation (F_A), type of counterions (-glutamate, -chloride) and degree of purity were studied. One commercially available highly purified sodium alginate sample with high content of guluronic acid (G) was also studied. Furthermore, the influence of oxygen, H⁺ and OH⁻ ions on the initial depolymerization rates was investigated. Depolymerization kinetics was followed by measuring the time courses of the apparent viscosity and the intrinsic viscosity. The initial rate constants for depolymerization were determined from the intrinsic viscosity data converted to a quantity proportional to the fraction of bonds broken. The activation energies of the chitosan chloride and chitosan glutamate solutions with pH close to 5 and the same degree of acetylation, F_A = 0.14, were determined from the initial rate constants to be 76 ± 13 kJ/mol and 80 ± 11 kJ/mol, respectively.The results reported herein suggest that the stability of aqueous chitosan and alginate solutions at pH values 5–8 will be influenced by oxidative–reductive depolymerization (ORD) as the primary mechanism as long as transition metal ions are presented in the samples. Acid – and alkaline depolymerization will be the primary mechanisms for highly purified samples.     

Methylated N-aryl chitosan derivative/DNA complex nanoparticles for gene delivery: Synthesis and structure–activity relationships

In this study, three kinds of methylated chitosan containing different aromatic moieties were synthesized by two steps, reductive amination and methylation, respectively. The chemical structures of all methylated derivatives, methylated N-(4-N,N-dimethylaminocinnamyl) chitosan chloride (MDMCMChC), methylated N-(4-N,N-dimethylaminobenzyl) chitosan chloride (MDMBzChC), and methylated N-(4-pyridinylmethyl) chitosan chloride (MPyMeChC) were characterized by ATR–FTIR and ¹H NMR spectroscopy. The complexes between the chitosan derivatives and plasmid DNA at different N/P ratios were characterized by gel electrophoresis, dynamic light scattering, and atomic force microscopic techniques. The smallest particle sizes of these complexes were obtained at N/P ratio of 5 and ranged from 95 to 124 nm while the zeta-potentials were in the range of 18–27 mV. Transfection efficiencies of these complexes were investigated by expression of the plasmid DNA encoding green fluorescence protein (pEGFP-C2) on human hepatoma cells (Huh 7 cells) compared to N,N,N-trimethyl chitosan chloride (TMChC). The rank of transfection efficiency was MPyMeChC > MDMBzChC > TMChC > MDMCMChC, respectively. The cytotoxicity of these complexes was also studied by MTT assay where the MPyMeChC complex exhibited less toxicity than other derivatives even at high N/P ratios. Therefore, MPyMeChC demonstrated potential as its safe and efficient gene carrier.     

Viscoelastic properties of dispersed chitosan/xanthan hydrogels

In this work a gel was formed by complexation of two natural polyelectrolytes, chitosan and xanthan. Changes in the hydrogels rheological properties have been studied in terms of hydrogel concentration (7–10% w/w), chemical media used for the hydrogel dispersion, and ‘test lag time’; i.e., the time between hydrogel dispersion in the chemical media and the start of the rheological test (up to 390 min). The viscoelastic properties of this polysaccharide system were characterized by oscillatory shear measurements under small-deformation conditions and the results show that chitosan/xanthan hydrogels behave like weak gels. The shear modulus increased almost linearly with frequency in the range studied (0.1–65 s⁻¹). The effects of hydrogel concentration and dispersion medium have been related to electrostatic equilibrium and by the presence of counter-ions modifying the internal structure of the hydrogel.     

Study on the synergetic degradation of chitosan with ultraviolet light and hydrogen peroxide

Chitosan was effectively degraded by hydrogen peroxide under irradiation with ultraviolet light. The existence of a synergetic effect on the degradation was demonstrated by means of viscometry. In addition, the optimal conditions of degradation were determined on the basis of orthogonal tests. The structure of the degraded product was characterized by Fourier-transform infrared spectra (FTIR) analysis and diffuse reflectance spectra (DRS) analysis. The mechanism of the degradation of chitosan was correlated with cleavage of the glycosidic bond.