Electrochemical immunoassay of membrane P-glycoprotein by immobilization of cells on gold nanoparticles modified on a methoxysilyl-terminated butyrylchitosan matrix

A strategy to detect P-glycoprotein (P-gp) on cell membrane and quantify the cell number using electrochemical immunoassay was developed by effective surface immunoreactions and immobilization of cells on a highly hydrophilic interface, which was constructed by adsorption of colloidal gold nanoparticles on a methoxysilyl-terminated (Mos) butyrylchitosan modified glassy carbon electrode (Au-CS/GCE). Atomic force microscopy studies proved that the nanoparticles adsorbed on Mos-butyrylchitosan were efficient in preventing the cell leakage and retaining the activity of immobilized living K562/ADM leukemic cells. The incubation with P-gp monoclonal antibody and then the secondary alkaline phosphatase (AP) conjugated antibody introduced AP onto the K562/ADM cell immobilized on Au-CS/GCE. The bound AP led to an amperometric response of 1-naphthyl phosphate. Under optimal conditions the response was proportional to the logarithm of cell concentration in the range from 5.0 x 10(4) to 1.0 x 10(7) cells mL(-)(1) with a detection limit of 1.0 x 10(4) cells mL(-)(1). The results were comparable to flow cytometric analysis of P-gp expression. This proposed method was practical, convenient, and significant in the clinic and cytobiology.     

Novel and efficient method for immobilization and stabilization of β-d-galactosidase by covalent attachment onto magnetic Fe3O4–chitosan nanoparticles

A novel and efficient immobilization of β-d-galactosidase from Aspergillus oryzae has been developed by using magnetic Fe₃O₄–chitosan (Fe₃O₄–CS) nanoparticles as support. The magnetic Fe₃O₄–CS nanoparticles were prepared by electrostatic adsorption of chitosan onto the surface of Fe₃O₄ nanoparticles made through co-precipitation of Fe²⁺ and Fe³⁺. The resultant material was characterized by transmission electron microscopy, X-ray diffraction, Fourier transform infrared spectroscopy, vibrating sample magnetometry and thermogravimetric analysis. β-d-Galactosidase was covalently immobilized onto the nanocomposites using glutaraldehyde as activating agent. The immobilization process was optimized by examining immobilized time, cross-linking time, enzyme concentration, glutaraldehyde concentration, the initial pH values of glutaraldehyde and the enzyme solution. As a result, the immobilized enzyme presented a higher storage, pH and thermal stability than the soluble enzyme. Galactooligosaccharide was formed with lactose as substrate by using the immobilized enzyme as biocatalyst, and a maximum yield of 15.5% (w/v) was achieved when about 50% lactose was hydrolyzed. Hence, the magnetic Fe₃O₄–chitosan nanoparticles are proved to be an effective support for the immobilization of β-d-galactosidase.     

Nitrate and phosphate removal by chitosan immobilized Scenedesmus

The effect of chitosan immobilization of Scenedesmus spp. cells on its viability, growth and nitrate and phosphate uptake was investigated. Scenedesmus sp. (strains 1 and 2) and Scenedesmus obliquus immobilized in chitosan beads showed high viability after the immobilization process. Immobilized Scenedesmus sp. strain 1 had a higher growth rate than its free living counterpart. Nitrate and phosphate uptake by immobilized cells of Scenedesmus sp. (strain 1), freely suspended cells and blank chitosan beads (without cells) were evaluated. Immobilized cells accomplished a 70% nitrate and 94% phosphate removal within 12h of incubation while free-living cells removed 20% nitrate and 30% phosphate within 36 h of treatment. Blank chitosan beads were responsible for up to 20% nitrate and 60% phosphate uptake at the end of the experiment. Chitosan is a suitable matrix for immobilization of microalgae, particularly Scenedesmus sp., but this system should be improved before its application for water quality control.     

Immobilization and characterization of horseradish peroxidase into chitosan and chitosan/PEG nanoparticles: A comparative study

Chitosan (CS) is considered a suitable biomaterial for enzyme immobilization. CS combination with polyethylene glycol (PEG) can improve the biocompatibility and the properties of the immobilized system. Thus, the present work investigated the effect of the PEG in the horseradish peroxidase (HRP) immobilization into chitosan nanoparticles from the morphological, physicochemical, and biochemical perspectives. CS and CS/PEG nanoparticles were obtained by ionotropic gelation and provided immobilization efficiencies (IE) of 65.8 % and 51.7 % and activity recovery (AR) of 76.4 % and 60.4 %, respectively. The particles were characterized by DLS, ZP, SEM, FTIR, TGA and DSC analysis. Chitosan nanoparticles showed size around 135 nm and increased to 229 nm after PEG addition and HRP immobilization. All particles showed positive surface charges (20−28 mV). Characterizations suggest nanoparticles formation and effective immobilization process. Similar values for optimum temperature and pH for immobilized HRP into both nanoparticles were found (45 °C, 7.0). V_max value decreased by 5.07 to 3.82 and 4.11 mM/min and K_M increased by 17.78 to 18.28 and 19.92 mM for free and immobilized HRP into chitosan and chitosan/PEG nanoparticles, respectively. Another biochemical parameters (K_cat, K_e, and K_α) evaluated showed a slight reduction for the immobilized enzyme in both nanoparticles compared to the free enzyme.     

壳聚糖球固定化酵母细胞的研究

以戊二醛为交联剂,将壳聚糖球交联引入醛基,然后将交联的壳聚糖球浸泡在酵母细胞悬浮液中,制备了固定化酵母细胞壳聚糖球。以苯乙酮酸为底物,催化合成了D-扁桃酸。最优固定化条件是戊二醛的质量分数w(GA)=1%,酵母细胞与交联壳聚糖球的质量比m(Y):m(CB)0=0.5,交联时间为6h,固定化时间为18h,底物浓度为10mmol/L,在此条件下反应最大转化率和产物光学纯度分别高达67.86%和98.05?。固定化酵母壳聚糖球具有良好的重复使用性和贮存稳定性。     

Direct electrochemistry of horseradish peroxidase based on biocompatible carboxymethyl chitosan-gold nanoparticle nanocomposite

The nanocomposite composed of carboxymethyl chitosan (CMCS) and gold nanoparticles was successfully prepared by a novel and in situ process. It was characterized by transmission electron microscopy (TEM) and Fourier transform infrared spectrophotometer (FTIR). The nanocomposite was hydrophilic even in neutral solutions, stable and inherited the properties of the AuNPs and CMCS, which make it biocompatible for enzymes immobilization. HRP, as a model enzyme, was immobilized on the silica sol-gel matrix containing the nanocomposite to construct a novel H(2)O(2) biosensor. The direct electron transfer of HRP was achieved and investigated. The biosensor exhibited a fast amperometric response (5s), a good linear response over a wide range of concentrations from 5.0 x 10(-6) to 1.4 x 10(-3)M, and a low detection limit of 4.01 x 10(-7)M. The apparent Michaelis-Menten constant (K(M)(app)) for the biosensor was 5.7 x 10(-4)M. Good stability and sensitivity were assessed for the biosensor.     

Effects of Carbon Nanotubes in a Chitosan/Collagen-Based Composite on Mouse Fibroblast Cell Proliferation

This study investigated the in vitro cytocompatibility of carbon nanotubes (CNTs) in a chitosan/collagen-based composite. Mouse fibroblasts were cultured on the surface of a novel material consisting of CNTs in a chitosan/collagen-based composite (chitosan/collagen+CNTs group). Chitosan/collagen composites without CNTs served as the control material (chitosan/collagen group) and cells cultured normally in tissue culture plates served as blank controls (blank control group). Cell adhesion and proliferation were observed, and cell apoptosis was measured. The doubling time (DT₁) of cells was significantly shorter in the chitosan/collagen+CNTs group than in the chitosan/collagen group, and that in the chitosan/collagen group was shorter than in the blank control group. The CNTs in the chitosan/collagen-based composites promoted mouse fibroblast adhesion, producing a distinct cytoskeletal structure. At 24 h after culture, the cytoskeleton of the cells in the chitosan/collagen+CNTs group displayed typical fibroblastic morphology, with clear microfilaments. Cells in the chitosan/collagen group were typically round, with an unclear cytoskeleton. The blank control group even had a few unattached cells. At 4 days after incubation, no early apoptosis of cells was detected in the blank control group, whereas early apoptosis of cells was observed in the chitosan/collagen+CNTs and chitosan/collagen groups. No significant difference in the proportion of living cells was detected among the three groups. After entering the plateau stage, the average cell number in the chitosan/collagen+CNTs group was similar to that in the chitosan/collagen group and significantly smaller than that in the blank control group. Early apoptosis of cells in the blank control group was not detectable. There were significant differences in early apoptosis among the three groups. These results suggest that CNTs in a chitosan/collagen-based composite did not cause significant cytotoxic effects on mouse fibroblasts. Compared with chitosan/collagen composites, early adhesion and proliferation of fibroblasts were increased on chitosan/collagen+CNTs. However, at relatively high cell densities, the CNTs in the chitosan/collagen-based composite might exert an inhibitory effect on mouse fibroblast proliferation by inducing apoptosis.     

Immobilization of yeast cells by adhesion on tuff granules

Summary A method for immobilizing yeast cells (Saccharomyces cerevisiae) possessing invertase activity by direct adhesion on tuff granules coated with insolubilized gelatin is described. The immobilized cells, firmly fixed as a monolayer onto the surface of the support granules display catalytic properties (in terms of apparent K _m) close to free cells and are particularly suitable for continuous sucrose hydrolysis in a fixed-bed reactor. From an industrial point of view, the immobilization method described here has two advantages over other immobilization methods, i.e. the immobilized yeast cells have a fairly good operational stability and their proliferation on tuff granules can be controlled.     

A chemical surface modification of chitosan by glycoconjugates to enhance the cell-biomaterial interaction

The use of wheat germ agglutinin (WGA), a lectin molecule, to modify chitosan and enhance the cell-biomaterial interaction was examined. The percentage of living fibroblast cells on the surfaces of tissue culture polystyrene (TCPS) control, WGA-modified chitosan, and unmodified chitosan films increased to 99%, 99%, and 85%, respectively, after seeding for 48 h. DNA staining revealed that a portion of fibroblasts cultivated on chitosan films( )were undergoing apoptosis. In contrast, fibroblasts growing on WGA-modified chitosan film surfaces did not show any indication of apoptosis. The number of fibroblast cells was the highest on the WGA-modified chitosan surfaces, followed by the TCPS and unmodified chitosan surfaces. This WGA-mediated enhancement on the fibroblast cell-biomaterial interaction was cell type dependent. Other types of cells may need different lectin molecules for enhanced interaction with biomaterials. Further, the evaluation of the heat shock protein (HSP) mRNA expression indicated that HSP 90 expression was increased in the fibroblast cells cultivated on chitosan films and decreased to basal levels on the WGA-modified chitosan films. Taken together, our data suggest that the use of WGA and other lectin molecules to enhance the cell-biomaterial interaction via oligosaccharide-mediated cell adhesion is a promising way to improve cell adhesion and proliferation, the two key issues in tissue engineering.     

Immobilization of pectawamorine G10x by gel entrapment

Polyacrylamide gel immobilization of pectawamorine G10x was investigated. Its pectinesterase and polygalacturonase activity and stability in storage were measured. The degree of pectawamorine binding during gel immobilization was 80--90%, 55% of initial activity being retained. Thermal stability of the immobilized and native preparations was equal. Pectinesterase activity of the gel immobilized enzyme increased during storage.     

Magnetic catechol-chitosan with bioinspired adhesive surface: preparation and immobilization of ω-transaminase

The magnetic chitosan nanocomposites have been studied intensively and been used practically in various biomedical and biological applications including enzyme immobilization. However, the loading capacity and the remained activity of immobilized enzyme based on existing approaches are not satisfied. Simpler and more effective immobilization strategies are needed. Here we report a simple catechol modified protocol for preparing a novel catechol-chitosan (CCS)-iron oxide nanoparticles (IONPs) composites carrying adhesive moieties with strong surface affinity. The ω-transaminase (ω-TA) was immobilized onto this magnetic composite via nucleophilic reactions between catechol and ω-TA. Under optimal conditions, 87.5% of the available ω-TA was immobilized on the composite, yielding an enzyme loading capacity as high as 681.7 mg/g. Furthermore, the valuation of enzyme activity showed that ω-TA immobilized on CCS-IONPs displayed enhanced pH and thermal stability compared to free enzyme. Importantly, the immobilized ω-TA retained more than 50% of its initial activity after 15 repeated reaction cycles using magnetic separation and 61.5% of its initial activity after storage at 4°C in phosphate buffered saline (PBS) for 15 days. The results suggested that such adhesive magnetic composites may provide an improved platform technology for bio-macromolecules immobilized.     

Design of TiO2~DNA nanocomposites for penetration into cells

Methods of noncovalent immobilization of DNA fragments on titanium dioxide nanoparticles (TiO₂) were developed to design TiO₂～DNA nanocomposites, which were capable of penetrating through cell membranes. TiO₂ nanoparticles of different forms (amorphous, anatase, brookite) with enhanced agglomeration stability were synthesized. The particles were characterized by X-ray diffraction, small-angle X-ray scattering, infrared spectroscopy and atomic force microscopy. Three approaches to the preparation of nanocomposites are described: 1) sorption of polylysine-containing oligonucleotides onto TiO₂ nanoparticles, 2) the electrostatic binding of oligonucleotides to TiO₂ nanoparticles bearing immobilized polylysine, and 3) sorption of oligonucleotides on TiO₂ nanoparticles in the presence of cetyltrimethylammonium bromide (cetavlon). All three methods provide an efficient and stable immobilization of DNA fragments on nanoparticles that leads to nanocomposites with a capacity of up to 40 nmol/mg for an oligonucleotide. DNA fragments in nanocomposites were shown to retain their ability to form complementary complexes. It was demonstrated by confocal laser microscopy that the proposed nanocomposites penetrated into cells without transfection agents and other methods of exposure.     

A hydroquinone biosensor using modified core-shell magnetic nanoparticles supported on carbon paste electrode

A hydroquinone biosensor was developed and used to determine hydroquinone concentration in compost extracts based on the immobilization of laccase on the surface of modified magnetic core-shell (Fe(3)O(4)-SiO2) nanoparticles. Laccase was covalently immobilized on the magnetic nanoparticles by glutaraldehyde, which was modified with amino groups on its surface. The obtained magnetic bio-nanoparticles were attached to the surface of carbon paste electrode with the aid of a permanent magnet to determine hydroquinone. A good microenvironment for retaining the bioactivity of laccase was provided by the immobilization matrix. The linear range for hydroquinone determination was 1 x 10(-7) to 1.375 x 10(-4)M, with a detection limit of 1.5 x 10(-8)M. The current reached 95% of the steady-state current within about 60s. Hydroquinone concentration in compost extracts was determined by laccase biosensor and HPLC, the results of the two methods were approximately the same.     

Depositing Cu2O of different morphology on chitosan nanoparticles by an electrochemical method

The chitosan nanoparticles were prepared with the least chemical productions by adding sodium sulfate. The cuprous oxide (Cu₂O)/chitosan nanocomposites were prepared by electrochemical deposition of nanocrystalline Cu₂O on chitosan nanoparticles. With the change of the reaction conditions, it was found that Cu₂O nanoparticles could be leafage-like or big spherical particles coated on the surface of chitosan nanoparticles. The composition of the resulting Cu₂O/chitosan composites was confirmed by using SEM images, XRD pattern, and XPS spectrum. The chemical interaction between Cu₂O and chitosan nanoparticles was probed into by FTIR spectrum. The Cu₂O/chitosan nanocomposites make it possible of seeking materials that can degrade pollutants with minimal energy and the least reagent under biocompatible and environmentally friendly conditions.     

Degradation of carbazole by microbial cells immobilized in magnetic gellan gum gel beads

Polycyclic aromatic heterocycles, such as carbazole, are environmental contaminants suspected of posing human health risks. In this study, we investigated the degradation of carbazole by immobilized Sphingomonas sp. strain XLDN2-5 cells. Four kinds of polymers were evaluated as immobilization supports for Sphingomonas sp. strain XLDN2-5. After comparison with agar, alginate, and kappa-carrageenan, gellan gum was selected as the optimal immobilization support. Furthermore, Fe(3)O(4) nanoparticles were prepared by a coprecipitation method, and the average particle size was about 20 nm with 49.65-electromagnetic-unit (emu) g(-1) saturation magnetization. When the mixture of gellan gel and the Fe(3)O(4) nanoparticles served as an immobilization support, the magnetically immobilized cells were prepared by an ionotropic method. The biodegradation experiments were carried out by employing free cells, nonmagnetically immobilized cells, and magnetically immobilized cells in aqueous phase. The results showed that the magnetically immobilized cells presented higher carbazole biodegradation activity than nonmagnetically immobilized cells and free cells. The highest biodegradation activity was obtained when the concentration of Fe(3)O(4) nanoparticles was 9 mg ml(-1) and the saturation magnetization of magnetically immobilized cells was 11.08 emu g(-1). Additionally, the recycling experiments demonstrated that the degradation activity of magnetically immobilized cells increased gradually during the eight recycles. These results support developing efficient biocatalysts using magnetically immobilized cells and provide a promising technique for improving biocatalysts used in the biodegradation of not only carbazole, but also other hazardous organic compounds.     

Electrochemically deposited chitosan hydrogel for horseradish peroxidase immobilization through gold nanoparticles self-assembly

A new strategy for immobilization of horseradish peroxidase (HRP) has been presented by self-assembling gold nanoparticles on chitosan hydrogel modified Au electrode. From a mildly acidic chitosan solution, a chitosan film is electrochemically deposited on Au electrode surface via a negative voltage bias. This process is accompanied by the hydrogen evolution reaction, and the released hydrogen gas made the deposited chitosan film with porous structure, which facilitates the assembly of gold nanoparticles and HRP. The resulting substrates were characterized by atomic force microscopy (AFM) and electrochemical impedance spectroscopy (EIS). The immobilized HRP displayed an excellent catalytic property to the reduction of H2O2 in the presence of methylene blue mediator. The resulting biosensor (HRP-modified electrode) showed a wide dynamic range of 8.0 microM-15 mM H2O2, and the linear ranges were 8.0 microM-0.12 mM and 0.50-12 mM, with a detection limit of 2.4 microM estimated at a signal-to-noise ratio of 3. Moreover, the biosensor remained about 85% of its original sensitivity after four weeks' storage.     

Heparin-functionalized chitosan scaffolds for bone tissue engineering

The aim of this study is to investigate the effects of heparin-functionalized chitosan scaffolds on the activity of preosteoblasts. The chitosan scaffolds having the pore size of ∼100 μm were prepared by a freeze-drying method. Two different methods for immobilization of heparin to chitosan scaffolds were successfully performed. In the first method, functionalization of the scaffolds was achieved by means of electrostatic interactions between negatively charged heparin and positively charged chitosan. The covalent immobilization of heparin to chitosan scaffolds by 1-(3-dimethylaminopropyl)-3-ethylcarbodiimide (EDAC) and N-hydroxysuccinimide (NHS) was used as a second immobilization method. Morphology, proliferation, and differentiation of MC3T3-E1 preosteoblasts on heparin-functionalized chitosan scaffolds were investigated in vitro. The results indicate that covalently bound heparin containing chitosan scaffolds (CHC) stimulate osteoblast proliferation compared to other scaffolds, that is, unmodified chitosan scaffolds (CH), electrostatically bound heparin containing chitosan scaffolds (EHC), and CH+free heparin (CHF). SEM images also proved the stimulative effect of covalently bound heparin on the proliferation of preosteoblasts. Alkaline phosphatase (ALP) and osteocalcin (OCN) levels of cells proliferated on CHC and EHC were also higher than those for CH and CHF. In vitro studies have demonstrated that chitosan scaffolds increase viability and differentiation of MC3T3-E1 cells especially in the presence of immobilized heparin.     

Optimized immobilization of endoglucanase Cel9A onto glutaraldehyde activated chitosan nanoparticles by response surface methodology: The study of kinetic behaviors

Immobilization of enzyme onto nanoparticles such as chitosan can have biotechnological importance. In this study, chitosan nanoparticles (ChNPs) were prepared by Ionic gelation method and Endoglucanase Cel9A from Alicyclobacillus acidocaldariius (AaCel9A) immobilized on the nanoparticles. The FTIR results showed that the enzymes were immobilized on the ChNPs. The dynamic light scattering and scanning electron microscope (SEM) results illustrated that the AaCel9A-ChNPs approximately had 40 nm diameters. For optimizing enzyme immobilization, response surface methodology was employed using different variables (pH, enzyme immobilization time, and enzyme to ChNPs ratio [E/Cs]). The results showed that the high immobilization efficiency was achieved in pH 7, E/Cs of 0.4 in 2.63 hr. The enzyme activity results showed that, immobilization increased optimum pH for activity (from 6.5 to 7.5) and the enzyme K_m (from 3.703 to 12.195 [mg/ml]), which make it suitable to use in some industries such as detergents.