N-(carboxymethylidene)chitosans and N-(carboxymethyl)chitosans: Novel chelating polyampholytes obtained from chitosan glyoxylate

Glyoxylic acid, added to aqueous suspensions of chitosan, causes immediate dissolution of chitosan and gel formation within 3–4 h if the pH is 4.5–5.5. Solutions at lower pH values gel after 2 min of warming at 60–80°. Chitosan glyoxylate solutions brought to alkaline pH with sodium hydroxide do not precipitate chitosan. Evidence is given that a Schiff base, namely N-(carboxymethylidene)chitosan, is formed. N-(Carboxymethylidene)chitosans are reduced by sodium cyanoborohydride at room temperature to give N-(carboxymethyl)chitosans, obtained as white, free-flowing powders, soluble in water at all pH values. A series of N-(carboxymethyl)chitosans having various degrees of acetylation and N-carboxymethylation was obtained, and characterized by viscometry, elemental analysis, and i.r. spectrometry. For the fully substituted N-(carboxymethyl)chitosans, the pK′ is 2.3, the pK″ is 6.6, and the isoelectric point is 4.1. The addition of N-(carboxymethyl)chitosan to solutions (0.2–0.5mm) of transition-metal ions produces immediate insolubilization of N-(carboxymethyl)chitosan-metal ion chelates.     

Physicochemical characterization of chitin and chitosan from crab shells

Crab chitosan was prepared by alkaline N-deacetylation of crab chitin for 60, 90 and 120 min and the yields were 30.0-32.2% with that of chitosan C120 being the highest. The degree of N-deacetylation of chitosans (83.3–93.3%) increased but the average molecular weight (483–526 kDa) decreased with the prolonged reaction time. Crab chitosans showed lower lightness and WI values than purified chitin, chitosans CC and CS but higher than crude chitin. With the prolonged reaction time, the nitrogen (8.9–9.5%), carbon (42.2–45.2%) and hydrogen contents (7.9–8.6%) in chitosans prepared consistently increased whereas N/C ratios remained the same (0.21). Crab chitosans prepared showed a melting endothermic peak at 152.3–159.2 °C. Three chitosans showed similar microfibrillar crystalline structure and two crystalline reflections at 2θ = 8.8–9.0° and 18.9–19.1°. Overall, the characteristics of three crab chitosans were unique and differed from those of chitosan CC and CS as evidenced by the element analysis, differential scanning calorimetry, scanning electron microscopy and X-ray diffraction patterns.     

Preparation and characterization of cellulose/chitosan blend films

Cellulose and chitosan were mixed in N-methylmorpholine-N-oxide (NMMO) and heated to 100 °C, and then were processed under a pressure of 70 kg/cm² exerted by a compression molding machine at 100 °C for 8 min. As a result, transparent orange viscose films were obtained. After rinsing with deionized water and drying transparent yellowish blend films were obtained. Scanning electron microscope (SEM) indicated that when the chitosan content in the blend increased up to 3% the surface structure became smoother, but the film containing 5% (w/w) chitosan, became coarse again probably due to phase separation. Tensile strength test results were consistant with this. Antibacterial assessment proved that addition of chitosan to the films results in slight antibacterial properties. The halo zone test confirmed that the blend films made in this research have non-diffusible antibacterial properties.     

Quaternization of N-aryl chitosan derivatives: synthesis, characterization, and antibacterial activity

Chemical modification of chitosan by introducing quaternary ammonium moieties into the polymer backbone renders excellent antimicrobial activity to the adducts. In the present study, we have synthesized 17 derivatives of chitosan consisting of a variety of N-aryl substituents bearing either electron-donating or electron-withdrawing groups. Selective N-arylation of chitosan was performed via Schiff bases formed by the reaction between the 2-amino groups of the glucosamine residue of chitosan with aromatic aldehydes under acidic conditions, followed by reduction of the Schiff base intermediates with sodium cyanoborohydride. Each of the derivatives was further quaternized using N-(3-chloro-2-hydroxypropyl)trimethylammonium chloride (Quat-188) as the quaternizing agent that reacted with either the primary amino or hydroxyl groups of the glucosamine residue of chitosan. The resulting quaternized materials were water soluble at neutral pH. Minimum inhibitory concentration (MIC) antimicrobial studies of these materials were carried out on Escherichia coli (Gram-negative) and Staphylococcus aureus (Gram-positive) bacteria in order to explore the impact of the extent of N-substitution (ES) on their biological activities. At ES less than 10%, the presence of the hydrophobic substituent, such as benzyl and thiophenylmethyl, yielded derivatives with lower MIC values than chitosan Quat-188. Derivatives with higher ES exhibited reduced antibacterial activity due to low quaternary ammonium moiety content. At the same degree of quaternization, all quaternized N-aryl chitosan derivatives bearing either electron-donating or electron-withdrawing substituents did not contribute antibacterial activity relative to chitosan Quat-188. Neither the functional group nor its orientation impacted the MIC values significantly.     

N-carboxyacyl-N-acylchitosan gels as novel media for gel chromatography

Three partially substituted N-carboxyacyl and six N-carboxyacyl-N-acyl derivatives of chitosan were prepared and their practical use as media for gel chromatography was examined. N-(3′-Carboxy-2′-propenoyl)-N-stearoyl-chitosan gel was a relatively good medium for gel chromatography (solvent, water), and had a wide fractionation range (MW = 2 × 10⁴?6 × 10⁵). Its chromatographic properties were compared with those of N-methylene-chitosan gel (solvent, 0·5 m NaCl).     

Preparation of NG-monoethyl-l-arginine

N^G-Monoethyl-l-arginine, a putative in vivo product after administration of the potent hepatocarcinogen l-ethionine to rats, has been chemically synthesized by coupling N-ethyl, S-methylthiopseudouronium iodide with α-amino-blocked l-ornithine. The structure of the compound as N^G-monoethyl-l-arginine was confirmed by ¹³C NMR. Its elution time on an automatic amino acid analyzer, R_f values using thin-layer chromatography, and isoelectric point have been compared with those of N^G-monomethyl-l-arginine.     

Novel complex hydrogels based on N-carboxyethyl chitosan and quaternized chitosan and their controlled in vitro protein release property

A novel pH-responsive hydrogel (CHC) composed of N-carboxyethyl chitosan (CEC) and N-[(2-hydroxy-3-trimethylammonium) propyl] chitosan chloride (HTCC) was synthesized by the redox polymerization technique. Turbidimetric titrations were used to determine the stoichiometric ratio of these two chitosan derivatives. The hydrogel was characterized by FT-IR, thermal gravimetric analysis (TGA), X-ray diffractometry (XRD), and scanning electron microscopy (SEM). The dynamic transport of water showed that the hydrogel reached equilibrium within 48 h. The swelling ratio of CHC hydrogel depended significantly on the pH of the buffer solution. The performance of the CHC as a matrix for the controlled release of BSA was investigated. It was found that the release behavior was determined by pH value of the medium as well as the intermolecular interaction between BSA and the hydrogels.     

N-Alkylation of tripodal iron(III) imidazolate complexes: Reactivity and structure

The N-alkylation of iron(III) complexes of the tripodal imidazolate complexes derived from the Schiff base condensation of tris(2-aminoethyl)amine (tren) with three molar equivalents of 2-imidazolecarboxaldehyde (2ImH), 4-imidazolecarboxaldehyde (4ImH) or 4-methyl-5-imidazolecarboxaldehyde (5-Me4ImH) was investigated. While each complex possesses three nucleophilic imidazolate nitrogen atoms, only the complex derived from 2-imidazolecarboxaldehyde, Fetren(2Im)₃, was completely alkylated under the ambient conditions used in this work. Using methyl iodide as the alkylating agent, a correlation between spin state of the product and degree of methylation was observed. Low spin iron complexes were more nucleophilic than high spin systems. The structure reactivity relationship was exploited in the reaction of Fetren(2Im)₃ with methyl iodide and allyl iodide to give [Fetren(N-Me2Im)₃]²⁺ and [Fetren(N-allyl2Im)₃]²⁺. The products are iron(II) due to reduction of the iron(III) by iodide ion which builds up in the reaction mixture as the alkylation reaction proceeds. These complexes were characterized by a number of methods including EA, IR, ES-MS, Mössbauer spectroscopy, magnetic susceptibility and X-ray diffraction.     

Reactions of chitosan: 5. The reaction of chitosan with 2,4-dinitrofluorobenzene and determination of the extent of the reaction

The reaction between chitosan and 2,4-dinitrofluorobenzene has been studied and suitable conditions established for hydrolysis of the product prior to determination of the extent of reaction by u.v./visible spectroscopy. The chromophore system in $\text{N-(2,4-}\text{dinitrophenyl}\text{)-2-}\text{amino}\text{-2-}\text{deoxy-}\text{d}\text{-glucose}$, the final product from the acid hydrolysis of N-(2,4-dinitrophenyl)chitosan, is unstable to heating in solution in either water or aqueous acid. The temperature of hydrolysis should therefore not exceed 50°C and at this temperature the u.v./visible absorption spectrum of $\text{N-(2,4-}\text{dinitrophenyl}\text{)-2-}\text{amino}\text{-2-}\text{deoxy-}\text{d}\text{-glucose}$ is constant for up to 50 h. Complete reaction of the amine groups is not achieved under heterogeneous or homogeneous conditions, only approximately 50% of the available amine groups undergoing reaction under homogeneous conditions. This restricted reactivity results from the bulky N-(2,4-dinitrophenyl) residues shielding adjacent unreacted amine groups on the same chain, thereby preventing their reaction with 2,4-dinitrofluorobenzene. Such intramolecular steric hindrance would be expected to increase with increase in the free amine group content of the sample, due to the increase in the fraction of amine groups occurring in sequence length of two or more, and an inverse relationship between the total initial free amine group content and the percentage of these that react with 2,4-dinitrofluorobenzene has been found     

Asymmetric synthesis of duloxetine intermediate (S)-(-)-3-N-methylamino-1-(2-thienyl)-1-propanol using immobilized Saccharomyces cerevisiae in liquid-core sodium alginate/chitosan/sodium alginate microcapsules

Duloxetine intermediate (S)-(-)-3-N-methylamino-1-(2-thienyl)-1-propanol was synthesized using ACA liquid-core immobilized Saccharomyces cerevisiae CGMCC No. 2230. The optimum culture time for ACA liquid-core immobilized cells was found to be 28 h. The optimum ACA liquid-core capsule formation conditions were found to be 90 % chitosan deacetylation, 30,000–50,000 chitosan molecular weight, 5.0 g/L chitosan, and pH 6.0 citrate buffer solution. The highest activity was found when reduction conditions were pH 6.0, 30 °C and 180 rpm. The ACA-immobilized cells can be reused nine times and only 40 % of the activity is retained after nine cycles. Product inhibition of reduction was observed in batch reduction. Continuous reduction in the membrane reactor was found to remove the product inhibition on reduction and improve production capacity. Conversion reached 100 % and enantiometric excess of (S)-(-)-3-N-methylamino-1-(2-thienyl)-1-propanol exceeded 99.0 % in continuous reduction of 5 g/L 3-N-methylamino-1-(2-thienyl)-1-propanone in the membrane reactor.     

N-hexanoyl chitosan stabilized magnetic nanoparticles: Implication for cellular labeling and magnetic resonance imaging

This project involved the synthesis of N-hexanoyl chitosan or simply modified chitosan (MC) stabilized iron oxide nanoparticles (MC-IOPs) and the biological evaluation of MC-IOPs. IOPs containing MC were prepared using conventional methods, and the extent of cell uptake was evaluated using mouse macrophages cell line (RAW cells). MC-IOPs were found to rapidly associate with the RAW cells, and saturation was typically reached within the 24 h of incubation at 37°C. Nearly 8.53 ± 0.31 pg iron/cell were bound or internalized at saturation. From these results, we conclude that MC-IOPs effectively deliver into RAW cells in vitro and we also hope MC-IOPs can be used for MRI enhancing agents in biomedical fields.     

Sulfated N-(carboxymethyl)chitosans: Novel blood anticoagulants

N-(Carboxymethyl)chitosan was subjected to sulfation in a mixture of concentrated sulfuric acid (oleum) and N,N-dimethylformamide, under anhydrous conditions. The resulting product contained 11% of sulfur and degree of substitution: N-acetyl, 42%; N-carboxymethyl, 58%; and sulfate, 100%. Sonication of the sulfated N-(carboxymethyl)chitosan gave two main fractions whose molecular weights were 39,000 and 80,000. In human blood, complexes of sulfated N-(carboxymethyl) chitosan and antithrombin inhibited both thrombin and factor Xa, and produced neither hemolysis nor alterations in erythrocytes and lymphocytes. Sulfated N-(carboxymethyl)chitosan is therefore proposed as a blood anticoagulant.     

N-(o-carboxybenzyl) chitosans: Novel chelating polyampholytes

The imine formed by chitosan with phthalaldehydic acid was reduced with sodium cyanoborohydride and the resulting N-(o-carboxybenzyl) chitosan (NCBC) was insolubilised with ethanol and acetone and obtained as a white, free-flowing powder, soluble in both acidic and alkaline solutions. A sample of NCBC with the following degrees of substitution: acetamido 42%±4%, N-(o-carboxybenzyl) amine 43%±3%, free amine 15%±1% and containing 16%±1% moisture, was characterised by IR and UV-Vis. spectrometry, titration and viscometry. The isoelectric point was 6·8; the pK_a values were 5·7 and 8·0. NCBC could be determined by UV-Vis. spectrophotometry in aqueous solutions at 274 nm; maximum viscosity of the solutions was observed at pH 4. Upon addition of NCBC to transition metal ion solutions (0·1–0·5 mm) chelation and insolubilisation took place immediately. The dependence of the collection percentage on pH, NCBC and metal ion concentrations was studied for nine metal ions.     

New syntheses of N-(guanosin-8-yl)-4-aminobiphenyl and its 5′-monophosphate

N-Acetoxy-4-trifluoroacetylaminobiphenyl (N-acetoxy-TFAABP) reacted readily with Guo and GMP at neutrality in a one-step fashion to yield N-(guanosin-8-yl)4-aminobiphenyl (Guo-ABP) (I) and N(guanosin-8-yl)-4-aminobiphenyl-5′-monophosphate (GMP-ABP) (II), respectively.GMP-ABP could also be formed in much lower yield from the reaction of N-acetoxy-4-formylaminobiphenyl (N-acetoxy-FABP) with GMP (pH 7.0) under more rigorous conditions.Enzymatic hydrolysis of GMP-ABP with alkaline phosphatase in Tris buffer (pH 8.0) at 37°C yielded Guo-ABP.Guo-ABP showed a brilliant blue fluorescence on exposure to 366 nm UV light and its UV absorption spectrum was identical to that of Guo-ABP prepared by Kriek via a different route. Elemental analysis and nuclear magnetic resonance (NMR) data further confirmed the identity of this compound.     

The effects of N-substitution of chitosan and the physical form of the products on the rate of hydrolysis by chitinase from Streptomyces griseus

N-Formyl, N-chloroacetyl, N-glycyl, N-isobutyryl, and N-pentanoyl derivatives of chitosan have been prepared. N-Acetylchitosan was the derivative most susceptible to chitinase from Streptomyces griseus and lysozyme from chicken egg-white, but the susceptibility was not restrictive. The relative rates of hydrolysis by chitinase with respect to R in the RCONH group were CH₃ > CH₃CH₂ > H > CH₃CH₂CH₂ > (CH₃)₂CH > NH₂CH₂ > ClCH₂. Neither enzyme hydrolysed chitosan or its N-methylene, N-benzylidene, N-benzoyl, N-nicotinyl, and N-fatty acyl (C₅C₁₈) derivatives, and lysozyme did not hydrolyse N-butyrylchitosan. N-Acetylhexanoyl-chitosans, which had d.s. ratios of ~0.7: ~0.3 and ~0.3; ~0.7, were hydrolysed at ~0.75 and ~0.04 of the rate of N-acetylchitosan (powder) by chitinase. O-Acylation of N-acylchitosans caused a decrease in the rates of hydrolysis by chitinase. N-Acetylchitosan gels were hydrolysed at 8–13 times the rate for crab-shell chitin. These results indicate that not only N- and O-substituents but also the physical form of the substrates influence the rates of hydrolysis by these enzymes.     

Depolymerization of glycosaminoglycuronans into di- and higher molecular-weight oligo-saccharides: Improved preparation of N-acetyldermosine and oligomeric N-acetylchondrosines

Nonsulfated di- to octadeca-saccharides having 2-acetamido-2-deoxy-d-galactose at the reducing end were prepared, in 81% yield, by treatment of chondroitin 6-sulfate (pyridinium salt) with dimethyl sulfoxide containing 10% of water for 14 h at 90°. N-Acetylchondrosine and N-acetyldermosine were obtained from dermatan sulfate of rooster comb, in 30% and 38% yields, respectively, by solvolysis with dimethyl sulfoxide, containing 10% of water, for 30 h at 105°. Hyaluronic acid was also depolymerized by the same solvent in the presence of an equimolar amount of pyridinium sulfate or chloride per disaccharide unit to give reducing di- and higher molecular weight oligo-saccharides. The results of solvolytic desulfation and depolymerization are compared with those of the conventional methods by acid hydrolysis.     

Characterization and antimicrobial activity of water-soluble N-(4-carboxybutyroyl) chitosans against some plant pathogenic bacteria and fungi

Water-soluble N-(4-carboxybutyroyl) chitosan derivatives with different degrees of substitution (DS) were synthesized to enhance the antimicrobial activity of chitosan molecule against plant pathogens. Chitosan in a solution of 2% aqueous acetic acid-methanol (1:1, v/v) was reacted with 0.1, 0.3, 0.6 and 1 mol of glutaric anhydride to give N-(4-carboxybutyroyl) chitosans at DS of 0.10, 0.25, 0.48 and 0.53, respectively. The chemical structures and DS were characterized by ¹H and ¹³C NMR spectroscopy, which showed that the acylate reaction took place at the N-position of chitosan. The synthesized derivatives were more soluble than the native chitosan in water and in dilute aqueous acetic acid and sodium hydroxide solutions. The antimicrobial activity was in vitro investigated against the most economic plant pathogenic bacteria of Agrobacterium tumefaciens and Erwinia carotovora and fungi of Botrytis cinerea, Pythium debaryanum and Rhizoctonia solani. The antimicrobial activity of N-(4-carboxybutyroyl) chitosans was strengthened than the un-modified chitosan with the increase of the DS. A compound of DS 0.53 was the most active one with minimum inhibitory concentration (MIC) of 725 and 800 mg/L against E. carotovora and A. tumefaciens, respectively and also in mycelial growth inhibiation against B. cinerea (EC₅₀ = 899 mg/L), P. debaryanum (EC₅₀ = 467 mg/L) and R. solani (EC₅₀ = 1413 mg/L).     

N-2′-Acetoxybenzoyl derivatives of chitosan, N-desulphated heparin and 2-amino-2-deoxy-d-glucose

N-2′-Acetoxybenzoyl (aspirin) derivatives (degree of substitution 0·35–1·00) of chitosan, N-desulphated heparin and 2-amino-2-deoxy-d-glucose were prepared by methods that gave yields in the range 65–86%. The salicylate of chitosan was isolated with a 98% yeild. Aspirin or salicylic acid was released much more slowly from N-(2′-acetoxybenzoyl)-chitosan than from the salicylate of chitosan, and much faster at 37°C in 0·1 m NaOH solution than in 2% aqueous acetic acid solution. Salicylic acid was isolated from the dialysate (0·1 m NaOH solution) of N-(2′-acetoxybenzoyl)-chitosan.     

Photo-polymeriable chitosan derivative prepared by Michael reaction of chitosan and polyethylene glycol diacrylate (PEGDA)

N-Alkyled photo-polymeriable chitosan derivative (PEGDA-CS) was synthesized by Michael reaction of chitosan and polyethylene glycol diacrylate (PEGDA) under mild reaction conditions. The chemical structure and physical properties of PEGDA-CS were characterized by FT-IR, ¹H NMR, XRD and TG techniques. The degree of substitution (DS) of PEGDA-CS could be calculated from ¹H NMR. PEGDA-CS exhibited good solubility in distilled water. XRD analysis showed that PEGDA-CS was amorphous. TG results demonstrated that thermal stability of the derivate was lower than that of chitosan. Antimicrobial test showed that PEGDA-CS had the antimicrobial activity on Escherichia coli. It could photopolymerize under ultraviolet light with 2959 as initiator.     

Reactions of chitosan: 2. Preparation and reactivity of N-acyl derivatives of chitosan

A study has been made of the influence of reaction medium on the N-acetylation of chitosan under heterogeneous conditions. The results show that provided a pre-steeping treatment is given a range of reaction media permit rapid N-acetylation. The influence of the nature of the N-acyl group on O-acetylation has also been studied. In general the larger the N-acyl group the greater the ease of O-acetylation, although too bulky a group inhibits reaction through steric hindrance. In all cases the rate of O-acetylation falls to nearly zero when ～ 50% of the hydroxyl groups have reacted, and prolonged reaction times are required if a more highly acetylated product is required.