Prolyl endopeptidase inhibitory activity of chitosan sulfates with different degree of deacetylation

Three kinds of partially deacetylated chitosan, 90% deacetylated chitosan, 75% deacetylated chitosan and 50% deacetylated chitosan, were prepared from crab chitin by N-deacetylation with 40% (w/w) sodium hydroxide solution for different durations. In order to improve biological activity and solubility, their sulfated derivatives were prepared, and prolyl endopeptidase (PEP) inhibitory activities were investigated. Fifty percent-deacetylated chitosan sulfate (50-CS) exhibited the highest inhibitory activity, and inhibition rate was a dose-dependant. In addition, Dixon plots suggested that 50-CS was act as competitive inhibitor, and the inhibition constant (K_i) was 2.6 mg/ml.     

Functional characteristics of shrimp chitosan and its membranes as affected by the degree of deacetylation

The functional properties of three shrimp chitosan preparations with different degrees of deacetylation (75%, 87% and 96% DD) but with a constant molecular weight (about 810 kDa) were investigated. Chitosan with 75% DD had a 1.5 times higher water absorption, probably due to its 20% lower level of crystallinity. Membranes cast from this chitosan also exhibited 1.5 times more water absorption and 2 times higher permeability. However, chitosan with 87% and 96% DD had 1.5-2 times higher absorption of fat and the orange II dye. This is attributed to the higher content of positively charged amine groups in the polymer. Cast into membrane, chitosan of higher degree of deacetylation showed a higher tensile strength and a higher elongation at break, probably due to the higher level of crystallinity.     

Cytotoxic activities of water-soluble chitosan derivatives with different degree of deacetylation

Chitosans with different degree of deacetylation (DD) (90% and 50% deacetylated chitosan) were prepared by N-deacetylation followed by grafted onto chitosan to form water-soluble aminoethyl-chitosan (AE-chitosan), and dimetylaminoethyl-chitosan (DMAE-chitosan), diethylaminoethyl-chitosan (DEAE-chitosan). In the present study, cytotoxic activities of the chitosan derivatives were evaluated using three tumor cell lines and two normal cell lines, and structure-activity relationship was suggested. The cytotoxic activity was dependent on their DD and substituted group.     

Effects of degree of deacetylation on enzyme immobilization in hydrophobically modified chitosan

Chitosan is a deacetylated form of the polysaccharide chitin. Over the last decade, researchers have employed reductive amination to hydrophobically modify chitosan to induce a micellar structure. These micellar polymers have been used for a variety of purposes including drug delivery and enzyme immobilization and stabilization. However, commercial sources of chitosan vary in their degree of deacetylation and there remains a paucity of information regarding how this can impact the modified polymer’s functionality for enzyme immobilization. This paper, therefore, evaluates the effect that the degree of deacetylation has on the hydrophobic modification of medium molecular weight chitosan via reductive amination with long chain aldehydes and the resulting changes in enzyme activity after the immobilization of glucose oxidase in the micellar polymeric structure. The chitosan was deacetylated to differing degrees via autoclaving in 40–45% NaOH solutions and characterized using NMR, viscosity measurements, and differential scan calorimetry. Results suggest that a high degree of deacetylation provides optimal enzyme immobilization properties (i.e. high activity), but that the deacetylation method begins to significantly decrease the polymer molecular weight after a 20 min autoclave treatment, which negatively affects immobilized enzyme activity.     

Reactive oxygen species scavenging activity of aminoderivatized chitosan with different degree of deacetylation

Chitosans with different degree of deacetylation were prepared from crab shell chitin in the presence of alkali. Aminoderivatized chitosan derivatives were prepared in addition of amino functional groups at a hydroxyl site in the chitosan backbone. Six kinds of aminoderivatized chitosan such as aminoethyl-chitosan (AEC90), dimethylaminoethyl-chitosan (DMAEC90), and diethylaminoethyl-chitosan (DEAEC90), which were prepared from 90% deacetylated chitosan, and AEC50, DMAEC50 and DEAEC50, which were prepared from 50% deacetylated chitosan, were prepared and their reactive oxygen species (ROS) scavenging activities were investigated against hydroxyl radical, superoxide anion radical and hydrogen peroxide. The electron spin resonance (ESR) spectrum revealed that AEC90 showed the highest scavenging effects against hydroxyl and superoxide anion radical, the effects were 91.67% and 65.34% at 0.25 and 5 mg/mL, respectively. For hydrogen peroxide scavenging effect, DEAEC90 exhibited the strongest activity. These results suggest that the scavenging effect depends on their degree of deacetylation and substituted group.     

Enzymatic method for determination of the degree of deacetylation of chitosan.

A new method was developed for the accurate determination of the degree of deacetylation of chitosan. The method involves the complete hydrolysis of chitosan to glucosamine and N-acetylglucosamine by a cooperative action of chitosanolytic enzymes exo-beta-D-glucosaminidase, beta-N-acetylhexosaminidase, and chitosanase, and subsequent determination of the monosaccharides by specific colorimetric assays or HPLC. The conditions required for the complete hydrolysis of chitosan were examined and the degree of deacetylation of several chitosan samples was determined.     

Effects of molecular weight and deacetylation degree of chitin/chitosan on wound healing

We studied the effects of chitin/chitosan on wound healing with reference to chemical properties using a linear incisional wound model in rats. Wound break strength of the chitosan group (D-glucosamine (GlcN), chito-oligosaccharide (COS), chitosan) was higher than the chitin group (N-acetyl-D-glucosamine (GlcNAc), chiti-oligosaccharide (NACOS), chitin). Collagenase activity was also higher in the chitosan group than the chitin group. There was no significant change between the concentration of the sample and the break strength and collagenase activity in all samples. In histological findings, collagen fibers run perpendicular against the incisional line in the oligosaccharide group (NACOS, COS), and many activated fibroblasts were observed around the wound in the chitosan group. As for the deacetylation degree, the higher the deacetylation degree becomes, the more the stronger the break strength becomes. Also, activated fibroblasts appeared more in the higher deacetylation degree.     

High yield production of monomer-free chitosan oligosaccharides by pepsin catalyzed hydrolysis of a high deacetylation degree chitosan

The high molecular weight of chitosan, which results in a poor solubility at neutral pH values and high viscosity aqueous solutions, limits its potential uses in the fields of food, health and agriculture. However, most of these limitations are overcome by chitosan oligosaccharides obtained by enzymatic hydrolysis of the polymer. Several commercial enzymes with different original specificities were assayed for their ability to hydrolyze a 93% deacetylation degree chitosan and compared with a chitosanase. According to the patterns of viscosity decrease and reducing end formation, three enzymes--cellulase, pepsin and lipase A--were found to be particularly suitable for hydrolyzing chitosan at a level comparable to that achieved by chitosanase. Unlike the appreciable levels of both 2-amino-2-deoxy-D-glucose and 2-acetamido-2-deoxy-D-glucose monomers released from chitosan by the other enzymes after a 20h-hydrolysis (4.6-9.1% of the total product weight), no monomer could be detected following pepsin cleavage. As a result, pepsin produced a higher yield of chitosan oligosaccharides than the other enzymes: 52% versus as much as 46%, respectively. Low molecular weight chitosans accounted for the remaining 48% of hydrolysis products. The calculated average polymerization degree of the products released by pepsin was around 16 units after 20h of hydrolysis. This product pattern and yield are proposed to be related to the bond cleavage specificity of pepsin and the high deacetylation degree of chitosan used as substrate. The optimal reaction conditions for hydrolysis of chitosan by pepsin were 40 degrees C and pH 4.5, and an enzyme/substrate ratio of 1:100 (w/w) for reactions longer than 1h.     

Effects of concentration, degree of deacetylation and molecular weight on emulsifying properties of chitosan

Chitosan has excellent emulsifying properties. Emulsifying activity and stability of chitosan were determined by integrated light scattering technique and turbidimetric method. The effects of concentration, degree of deacetylation and molecular weight on emulsifying properties of chitosan were systematically studied in the paper. Emulsifying activity of chitosan initially increased, arrived at the peak at 0.75% and then declined, while emulsifying stability continuously increased with a rise of chitosan concentration from 0.25% to 1.25%. Emulsifying activity and stability of chitosan initially decreased and reached the minimum, then increased with the rise of degree of deacetylation. Chitosan with DD 60.5% and 86.1% showed superior emulsifying activity and stability. Chitosan with low Mw exhibited better emulsifying activity than those with high Mw. Chitosan with Mw 410 kDa and 600 kDa showed superior emulsifying activity in the test range. Emulsifying stability of chitosan increased with a rise of Mw.     

Successful removal of p-quinone with chitosan in an aqueous phase in relation to degree of deacetylation

Phenol oxidant is successfully removed by using chitosan particles in the aqueous phase. Removal of p-quinone by chitosan from crab shells was investigated kinetically from molecular weight (MW) of chitosan, deacetylation degree (DD) and reaction temperature. The rate constant assuming first-ordered reaction on removal of p-quinone in aqueous phase primarily depended on the MW of chitosan, not on the DD. Quantities of chitosan exceeding 5 x 10(5) MW are able to obtain a sufficiently high rate constant (10(-3) s(-1)). At higher temperatures, higher rate constants were obtained in the entire experimental MW and DD. The activation energy obtained was 43.8 kJ x mol(-1).     

Limitations of pH-potentiometric titration for the determination of the degree of deacetylation of chitosan

The degree of deacetylation (DDA) of chitosan determines the biopolymer's physico-chemical properties and technological applications. pH-Potentiometric titration seems to offer a simple and convenient means of determining DDA. However, to obtain accurate pH-potentiometric DDA values, several factors have to be taken into consideration. We found that the moisture content of the air-dry chitosan samples can be as high as 15%, and a reasonable fraction of this humidity cannot be removed by ordinary drying. Corrections have to be made for the ash content, as in some samples it can be as high as 1% by weight. The method of equivalence point determination was also found to cause systematic variations in the results and in some samples extra acid as high as 1 mol% of the free amino content was also identified. To compensate for the latter effect, the second equivalence point of the titration has to be determined separately and the analytical concentration of the acid be corrected for it. All the corrections listed here are necessary to obtain DDA values that are in reasonable agreement with those obtained from (1)H NMR and IR spectroscopic measurements. The need for these corrections severely limits the usefulness of pH-metry for determining accurate DDA values and thus potentiometry is hardly able to compete with other standard spectroscopic procedures, that is, (1)H NMR spectroscopy.     

A new linear potentiometric titration method for the determination of deacetylation degree of chitosan

The degree of deacetylation (DD) is one of the most important properties of chitosan. Therefore, a simple, rapid and reliable method for the determination of DD of chitosan is essential. In this report, two new potentiometric titration functions are derived for the determination of DD of chitosan. The effects of the precipitation and the errors induced in pH measurement are discussed in detail. To make this method more simple and reliable, two universal pH regions for the accurate plotting of different DD chitosan samples are proposed for the new potentiometric titration functions. The DD values of three chitosan samples obtained with this new method show good agreement with those yielded from elemental analysis and ¹H-NMR.     

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.     

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.     

Effect of molecular weight of chitosan with the same degree of deacetylation on the thermal, mechanical, and permeability properties of the prepared membrane

Different molecular weight, 90% deacetylated chitosans were obtained by ultrasonic degradation on 90% deacetylated chitosan at 80 °C for various times.

Ninety percent deacetylated chitosan was prepared from alkali treatment of chitin that was obtained from red shrimp waste. Number average-, viscosity average- molecular weights were measured by gel permeation chromatography and the viscometric method, respectively. Degree of deacetylation was measured by the titration method. Enthalpy, maximum melting temperature, tensile strength and elongation of the membranes, flow rate of permeates and water are properties measured to elucidate the effect of molecular weight of chitosan on the above thermal, mechanical, and permeation properties, respectively of the prepared membranes. Results show tensile strength, tensile elongation, and enthalpy of the membrane prepared from high molecular weight chitosans were higher than those from low molecular weight. However, the permeability show membranes prepared from high molecular weight chitosans are lower than that from those of low molecular weight.     

Growth inhibitory effect of bestatin on choriocarcinoma cell finesin vitro

Bestatin, one of the biological response modifiers (BRMs), is an inhibitor of aminopeptidase B (AP-B), leucine aminopeptidase (LAP) and aminopeptidase M (AP-M). In this report, we investigated the direct effect of bestatin on the growth of cancer cells in vitro using established four choriocarcinoma cell lines. In vitro chemosensitivity was evaluated by the succinate dehydrogenase inhibition (SDI) test. Bestatin showed the growth-inhibitory effect on all the choriocarcinoma cell lines dose-dependently, especially on NaUCC-4 cells. Both an isomer of bestatin with no inhibitory activity against aminopeptidases, (2R, 3S)-AHPA-(R)-Leu, and another isomer with stronger inhibitory activity against AP-B than bestatin, (2S, 3S)-AHPA-(R)-Leu, did not show growth inhibition on NaUCC-4 cells. So it is suggested that one of the possible mechanisms responsible for the direct action of bestatin on the choriocarcinoma cells may be related to the inhibition of activity of LAP or AP-M rather than that of AP-B. Furthermore, cytotoxicity of actinomycin D on the choriocarcinoma cells was significantly enhanced by combination with bestatin. These results suggest that bestatin has not only an indirect host-mediated anti-tumor activity, but also a direct growth-inhibitory effect on some kinds of cancer cell lines.     

An investigation on the short-term biodegradability of chitosan with various molecular weights and degrees of deacetylation

Research efforts have been devoted to demonstrating that the pH-sensitive characteristics of poly NIPAAm/chitosan nanoparticles can be applied to targeting tumors. A copolymer of (NIPAAm) and chitosan (4:1, m/m) was synthesized, and its drug release characteristics investigated. The results revealed that drug-loaded nanoparticles which encapsulation and loading efficiencies were 85.7% and 9.6%, respectively, exhibited pH-sensitive responses to tumor pH. The cumulative release rate was significantly enhanced below pH 6.8 and decreased rapidly above pH 6.9 at 36.5 ± 0.5 °C. MTT assay and fluorescence microscopic study showed that drug release was drastically promoted in tumor surroundings while exerting less effect in normal conditions. For mice treated with nanoparticles, the decrease in body weight was limited, and significant tumor regression was observed with complete regression in more than 50% of the mice. The life span of tumor-bearing mice was significantly increased when they were treated with nanoparticles. Thereby, the super pH-sensitive poly NIPAAm/chitosan nanoparticles may provide outstanding advantages for anti-cancer drug delivery.     

Growth inhibitory effect of quercetin on SW 872 human liposarcoma cells

Adipocytic tumors represent the largest single group of soft tissue tumors. In the present study, we investigated the antiproliferative potential of quercetin in SW 872 human liposarcoma cells. Cell viability was significantly influenced by quercetin treatment in a time- and dose-dependent manner. Flow cytometric analyses of SW 872 human liposarcoma cells exposed to quercetin showed that the increase of apoptotic cells was time- and dose-dependent. The percentages of normal cells were decreased and apoptotic cells (including early apoptotic and late apoptotic) were increased with increasing concentrations of quercetin. Quercetin-induced apoptosis in SW 872 human liposarcoma cells was associated with the loss of mitochondrial membrane potential (DeltaPsi(m)). The apoptosis in SW 872 human liposarcoma cells induced by quercetin was mediated through the activation of caspase-3, Bax, and Bak and then cleavage of PARP and downregulation of Bcl-2. These results demonstrate that quercetin may prevent atypical lipomatous tumors/well-differentiated liposarcomas from mature adipocytic proliferation, which may contribute to its antiproliferative function.     

Relationships between the molecular structure and moisture-absorption and moisture-retention abilities of carboxymethyl chitosan. II. Effect of degree of deacetylation and carboxymethylation

Carboxymethyl chitosans (CM-chitosan) of various degrees of deacetylation (DD 28-95%) and substitution (DS 0.15-1.21) were successfully prepared from N-acetylchitosans in NaOH of varying concentrations. Infrared spectroscopy (IR), elemental analysis, potentiometric titration, 13C NMR, X-ray diffraction and gel-permeation chromatographic (GPC) techniques were used to characterize their molecular structures. The moisture-absorption (R(a)) and -retention (R(h)) abilities of CM-chitosan are closely related to the DD and DS values. Under conditions of high relative humidity, the maximum R(a) and R(h) were obtained at DD values of about 50%, and when the DD value deviated from 50%, R(a) and R(h) decreased. Under dry conditions, when the DD value was 50%, the R(h) was the lowest. With the DS value increasing, R(a) and R(h) increased. However, further increase of the DS value above 1.0 reduced the increasing tendency of R(a) and R(h), and even some decreases in R(a) and R(h) were observed. Intermolecular hydrogen bonds play a very important role in moisture-absorption and retention ability of CM-chitosan.