Adsorption of spin-labeled flocculants on E. coli cells

The interaction of intact E. coli cells with polymeric flocculants polyethylenimine and dextran was being studied by spin-labelling. The nitroxyl groups of spin-labelled polymers are reduced during formation of the adsorption layer on the cell surface. Some peculiarities of redox reactions between polymer macroradicals and units of the bacterial electron-transport chain were studied depending of temperature and flocculation regime. The course of the reduction of spin-labelled polymer radicals and characteristics of EPR spectra of the flocculant give evidence on the formation of a loose polymeric layer on the surface of E. coli cells.     

Continuous production of steroid glycoalkaloids by immobilized plant cells

Summary Non-permeablilized cells ofSolanum aviculare were immobilized by their adsorption and covalent linkage on activated polymeric adsorbent. The retention of extracellular production of steroid glycoalkaloids was studied in a packed-column recycle reactor.     

Attachment of Acidithiobacillus ferrooxidans onto different solid substrates and fitting through Langmuir and Freundlich equations

Attachments of Acidithiobacillus ferrooxidans ATCC 23270 onto elemental sulfur, quartz and complex chalcopyrite were investigated by analysis of its extracellular polymeric substances as well as applying Langmuir and Freundlich equations. The two equations fitted the adsorption equilibrium data with significant correlation coefficient over 0.9. This indicated that bacterial attachment is complicated and involves Langmuir and Freundlich characterizations. Sulfur-grown cells showed the highest affinity for the three solid substrates. The investigated complex chalcopyrite possessed a higher maximum adsorption capacity for A. ferrooxidans than elemental sulfur or quartz. The Freundlich fitting parameters suggested that quartz had a weaker adsorption capacity and smaller adsorption areas than elemental sulfur or the complex chalcopyrite. It is not the content of total carbohydrates or proteins in EPS but their ratios that determine the affinity differences between cells and substrates.     

Sorption immobilization of alpha-amylase from Bacillus subtilis using meshed carboxyl polyelectrolytes

Immobilization of alpha-amylase from Bacillus subtilis by adsorption on carboxyl polyelectrolytes, copolymers of methacrylic acid and ethylene glycol dimethacrylate, was being investigated depending on the structure of the polymeric matrix. It is demonstrated that cation exchange resins can be successfully used for reversible sorption and immobilization of alpha-amylase. It was found that the more heterogeneous the structure of the polymeric carrier, the higher is reversibility of the enzyme adsorption. The isothermic process of Bac. subtilis alpha-amylase adsorption on copolymers of different structures was studied as well. The equilibrium of the sorption system was proved to be true.     

Controlling the thickness of polymeric shell on magnetic nanoparticles loaded with doxorubicin for targeted delivery and MRI contrast agent

The polymeric functionalization of superparamagnetic iron oxides nanoparticles is developed for cancer targeting capability and magnetic resonance imaging. Here the nanoparticles (NP) are decorated through the adsorption of a polymeric layer around the particle surface for the formation of core-shell. The synthesized magnetic nanoparticles (MNPs) are conjugated with fluorescent dye, targeting ligand, and drug molecules for improvement of target specific diagnostic and possible therapeutics applications. In this investigation doxorubicin was loaded into the shell of the MNPs and release study was carried out at different pH. The core-shell structure of magnetic NP coated chitosan matrix was visualized by TEM observation. The cytotoxicity of these magnetic NPs is investigated using MTT assay and receptor mediated internalization by HeLa and NIH3T3 cells are studied by fluorescence microscopy. Moreover, compared with T₂-weighted magnetic resonance imaging (MRI) in the above cells, the synthesized nanoparticles are showed stronger contrast enhancements towards cancer cells.     

The selective adsorption of polysaccharides on polyaromatic surfaces

A new matrix, polymeric 1,3-diaminobenzene-coated Celite, which selectively adsorbs monomeric and polymeric carbohydrates, has been prepared. This matrix adsorbs glycogen and other branched polysaccharides, as opposed to neutral or charged monosaccharides. Other solid supports were coated with polymeric 1,3-diaminobenzene; some of these (coated Sephadex G10 and coated Bioglas 1,000) had better physical form for column packing. Coated Celite was considered to be the best support in view of its greater stability. The effects of ionic concentration, pH, temperature, and the concentration of carbohydrate solution on the adsorption of glycogen on to coated Celite were studied, and methods to prevent adsorption and remove adsorbed carbohydrate were investigated. A comparison is made with the adsorption of heterocyclic compounds by cross-linked dextran gels.     

桑椹红色素纯化的动态吸附条件研究

桑椹红色素是一种安伞、无毒的食用天然色素。本实验埘8种大孔吸附树脂进行筛选,然后通过单因素试验、正交试验和方差分析确定了吸附桑椹红色素的最佳操作条件。结果表明,LSA-21树脂对桑椹红色素的吸附和解吸性能较好;确定的最佳吸附条件为：料液浓度(以吸光度计)为0．425Abs,上柱速度3．5BV／h,料液pH1．57。     

Role of extracellular polymeric substances in Cu(II) adsorption on Bacillus subtilis and Pseudomonas putida

The effect of extracellular polymeric substances (EPS) of Gram-positive Bacillus subtilis and Gram-negative Pseudomonas putida on Cu(II) adsorption was investigated using a combination of batch adsorption, potentiometric titrations, Fourier transform infrared spectroscopy. Both the potentiometric titrations and the Cu(II) adsorption experiments indicated that the presence of EPS in a biomass sample significantly enhance Cu(II) adsorption capacity. Surface complexation modeling showed that the pK_a values for the three functional groups (carboxyl, phosphate and hydroxyl) were very similar for untreated and EPS-free cells, indicating no qualitative difference in composition. However, site concentrations on the untreated cell surface were found to be significantly higher than those on the EPS-free cell surface. Infrared analysis provided supporting evidence and demonstrated that carboxyl and phosphate groups are responsible for Cu(II) adsorption on the native and EPS-free cells.     

A simple purification of calmodulin by reversed phase chromatography with hydrophobic polymer 3520

A new adsorption chromatography procedure for the purification of calmodulin from bovine brain was developed using polymeric adsorbent 3520. Calmodulin was first isolated by DEAE-Cellulose column chromatography and further purified to apparent homogeneity following elution with 50% ethanol from the adsorbent column. Polyacrylamide gel electrophoresis showed one band either in the presence of Ca2+ or EGTA. The polymeric adsorbent 3520 is a non-polar polymer lacking exchangeable groups. The selective adsorption of calmodulin is based on hydrophobic interaction within the matrix, and is Ca2+ independent. Neither high salt (0.5 M NaC1) nor EGTA (5 mM) was able to elute the CaM from the adsorption column whereas ethanol (50%) eluted it completely. This method is simple to use and it provides highly purified calmodulin with high yield.     

Protein adsorption and transport in cation exchangers with a rigid backbone matrix with and without polymeric surface extenders

We compare the properties and protein adsorption characteristics of two polymeric cation exchangers: UNOsphere S, which has an open macroporous architecture, and Nuvia S, which is based on a very similar backbone matrix but contains sulfonated polymeric surface extenders. A monoclonal IgG and lysozyme were used as model adsorbates. The characteristic pore sizes, determined by inverse size exclusion chromatography, were about 140 nm for UNOsphere S, and only about 10 nm for Nuvia S, indicating that the polymeric extenders occupy a substantial portion of the base matrix pores. Greater exclusion limits were found for Nuvia S in 1 M NaCl and for a similar matrix containing uncharged surface extenders, suggesting that the polymeric extenders collapse partially at high ionic strength or when they are uncharged. Large equilibrium binding capacities were obtained for Nuvia S, approaching 320 ± 10 mg/mL of particle volume for both proteins in comparison with the UNOsphere S values of 170 ± 10 and 120 ± 10 mg/mL for lysozyme and IgG, respectively. Much higher adsorption rates were also found for Nuvia S, and the rate was nearly independent of protein concentration in solution. Confocal laser scanning microscopy showed very sharp intraparticle protein concentration profiles for UNOsphere S, consistent with a pore diffusion mechanism but diffuse concentration profiles for Nuvia S, consistent with a solid diffusion mechanism. The improved capacity and transport afforded by the polymeric extenders provide substantial potential benefits for bioprocess applications without sacrificing the desirable flow properties of the backbone matrix.     

In vitro modeling of cell-scaffold interaction

A simple method of controlling the efficiency of surface ligand-cell receptor interaction has been developed in the course of modeling the specific adhesion of cells on a support with their subsequent proliferation and bone tissue formation, using affinity chromatography on macroporous monolithic sorbents. The biospecific peptide GRGDSP played the role of an active ligand on the support, whereas cells were simulated by polymeric (polystyrene) microparticles with the peptide EDYPVDIYYLMDLSYSMKDD immobilized on their surface. The latter peptide is part of the active site of the integrin molecule responsible for binding the RGD sequence. Thus, the monolithic ultrashort column (CIM® disk) represented a simplified model of the support (structural scaffold) possessing biospecific properties. The parameters of the interaction of affinity partners were quantitatively estimated by frontal analysis involving the construction of adsorption isotherms, followed by their linearization and mathematical processing. The data obtained indicate a high specificity of biological pairing, which is supported by the results of cell culture experiments.     

Adsorption affinity of tea catechins onto polymeric resins: Interpretation from molecular orbital theory

Adsorption of certain tea catechins such as (+) catechin (C), (−) epicatechin (EC), (+) gallocatechin (GC), (−) epigallocatechin (EGC), (+) catechin gallate (CG), (−) epicatechin gallate (ECG), (+) gallocatechin gallate (GCG), and (−) epigallocatechin gallate (EGCG) have been studied using three types of polymeric resins as adsorbents. Adsorption affinity expressed as the slope of the linear region of the isotherm for a solute is found to be different for different adsorbents, and this difference can be interpreted from the chemical nature of the sorbents. Molecular interactions on polymeric resins have been studied based on molecular orbital theory. Electronic states of adsorbent and adsorbate were calculated using the semiempirical molecular orbital (MO) method from which energy of adsorption in aqueous solution was estimated. The adsorptive interaction on the polymeric resins computed on the basis of frontier orbital theory seems to correlate well with the experimentally measured adsorption affinity and enthalpy.     

The Use of the Ex Vivo Chandler Loop Apparatus to Assess the Biocompatibility of Modified Polymeric Blood Conduits

The foreign body reaction occurs when a synthetic surface is introduced to the body. It is characterized by adsorption of blood proteins and the subsequent attachment and activation of platelets, monocyte/macrophage adhesion, and inflammatory cell signaling events, leading to post-procedural complications. The Chandler Loop Apparatus is an experimental system that allows researchers to study the molecular and cellular interactions that occur when large volumes of blood are perfused over polymeric conduits. To that end, this apparatus has been used as an ex vivo model allowing the assessment of the anti-inflammatory properties of various polymer surface modifications. Our laboratory has shown that blood conduits, covalently modified via photoactivation chemistry with recombinant CD47, can confer biocompatibility to polymeric surfaces. Appending CD47 to polymeric surfaces could be an effective means to promote the efficacy of polymeric blood conduits. Herein is the methodology detailing the photoactivation chemistry used to append recombinant CD47 to clinically relevant polymeric blood conduits and the use of the Chandler Loop as an ex vivo experimental model to examine blood interactions with the CD47 modified and control conduits.     

The effect of chitosan on the in vitro biological performance of chitosan-poly(butylene succinate) blends

Chitosan blends with synthetic biodegradable polymers have been proposed for various biomedical applications due to their versatile mechanical properties and easier processing. However, details regarding the main surface characteristics that may benefit from the blending of these two types of materials are still missing. Hence, this work aims at investigating the surface properties of chitosan-based blends, illustrating the way these properties determine the material-proteins interactions and ultimately the behavior of osteoblast-like cells. The surface characteristics of modified and nonmodified blends were assessed using complimentary techniques such as optical microscopy, scanning electron microscopy (SEM), Fourier transform infrared spectroscopy (FTIR-ATR), X-ray photoelectron spectroscopy (XPS), contact angle measurements and surface energy calculations. The adsorption of human serum albumin (HSA) and human plasma fibronectin (HFN) onto the different surfaces was quantified by association of an indirect method with a colorimetric assay. It was found that the presence of chitosan on the surface promoted the adsorption of proteins. Moreover, a preferential adsorption of albumin over fibronectin was registered. The in vitro biological performance of the studied materials was further investigated by a direct contact assay with an osteoblastic-like cell line (SaOs-2). A synergistic effect of the two components of the blend was observed. While the synthetic polyester promoted the adhesion of SaOs-2, the presence of chitosan significantly enhanced the osteoblastic activity of these cells. This work further confirmed the interest in designing polymeric blends with natural polymers as a successful strategy to enhance the biological performance of a biomaterial.     

HIV-inhibiting activity of polyanion matrices and related substances containing adamantane and norbornene pharmacophores]

Analysis of molecular mechanisms of HIV-infection and targets for therapeutic intervention allowed to offer strategy for design of new effective anti-HIV/AIDS agents on the basis of two key principles: 1) intervention to infectious process beginning from the earliest stages of the virus penetration into cells; 2) blockade of not only one but several molecular targets of the HIV life cycle. The paper presents the results of the in vitro investigation of the anti-HIV activity (against several HIV-1 strains, including AZT-resistant ones) of new generation complex substances synthesized with application of the molecular substrategy for bifunctional inhibitors on the basis of a combination of nonspecific antiviral active polymeric anions with selective virus sensitive membranotropic pharmacophores of the adamantane and norbornene lines. The HIV-1 inhibiting potential of polymeric carboxylic acids (PKA) of various nature: synthetic polymeric analogues of succinic acid and carboxymethylated dextran was evaluated. It was shown that the antiviral action of PKA is located at the initial stages of HIV-1 penetration into cells and is markedly defined by balance of electrostatic activity and conformational mobility of the macromolecules. This corresponds to the evidence of the negatively charged macromolecules ability to bind the positively charged V3 loop within the viral protein gp120, preventing the HIV-1 adsorption on the surface of permissive cells. Chemical conjugation of the PKA with derivatives of the adamantane (amantadine and rimantadine analogues) or norbornene (related to deitiforin and natural bicyclic therpenoids) via spacer groups provides synergistic elevation of the anti-HIV-1 activity, first of all for the flexible chain PKA. The obtained result experimentally confirmed the theoretically predicted expansion of the anti-HIV-1 action of the bifunctional kind antivirals due to cooperation of the electrostatic potential of PKA with the virus specific hydrophobic activity needed to block postadsorption events of the HIV-1 life cycle, including both the virus penetration into cells and the virus posterity release from the infected cells. Additional cooperation of PKA with some special vectors targeted towards "Raft" domains of cellular membranes, epicentres for natural location of initial and completed stages of the HIV-1 replication cycle was also shown promising. The structure-function optimized samples exhibit high indexes of anti-HIV-1 selectivity up to IS50 = 10000.     

Separation of polymeric tannins from white wine by a combination of 2-butanol extraction and column chromatography

A new procedure was developed for the separation of polymeric tannins from a high-tannin white table Koshu wine by extraction with organic solvent and adsorption chromatography. The wine was adjusted to pH 1.0, sodium chloride was added to give a final concentration of 12.5% NaCl, then phenolic compounds including phenolic acids and tannin phenolics were extracted with 2-butanol. About 95% of the total phenolics was extractable.Polymeric tannins were separated from the extract by chromatography on Bio-Gel P-2, which adsorbs polymeric tannins in the presence of 10% acetic acid-50% ethanol, and recovered quantitatively by subsequent elution with 50% acetone. The phenolic acids and flavonoid tannins of low molecular weight that were eluted first using 10% acetic acid-50% ethanol, and the tannin phenolics of high molecular weight subsequently eluted using 50% acetone, were both free of potassium and sodium ions.This method, including the extraction and chromatography, is useful for rough separation of polymeric tannins and other phenolics from white wines.     

The preparation of D-phenylalanine imprinted microbeads by a novel method of modified suspension polymerization

Molecularly imprinted polymeric microbeads (MIPMs) were prepared by the suspension and modified suspension polymerization methods using D-phenylalanine as the template, methacrylic acid as the functional monomer, ethylene glycol dimethacrylate as the cross-linker, toluene as the porogen, polyvinyl alcohol as the stabilizer, and sodium dodecyl sulfate as the surfactant. The addition of a surfactant to the conventional suspension polymerization mixture decreased the mean particle size of the MIPMs and increased the adsorption selectivity. For the modified suspension polymerization method, the mean particle size of the MIPMs was smaller than the particle size of MIPMs prepared via conventional suspension polymerization. Moreover, the adsorption selectivity improved considerably compared to the adsorption selectivities of MIPs reported previously.     

Dynamic behavior of adsorber membranes for protein recovery

In recent years there has been a considerable interest in developing membrane chromatography systems that function as a short, wide chromatographic column in which the adsorptive packing consists of one or more microporous membranes. This study reports the use of new adsorber membranes prepared by the incorporation of various types of ion exchange resins into an EVAL porous membrane for protein recovery. The obtained heterogeneous matrixes composed of solid particles surrounded by the polymeric film possess a good accessibility for the protein to the adsorptive sites. Furthermore, small particles can be embedded into porous polymeric structures without the disadvantages of classical chromatographic columns (high pressure drop, fouling and plugging sensitivity, low flow rate), but with the advantages of membrane technology (easy scale-up, low-pressure drop, high flow rate). The adsorptive membranes feature high static as well as dynamic protein adsorption capacities for operating flow rates ranging from 200 to 400 L h bar per m(2) and ionic strength of 20-200 mM. In a sequential desorption step by changing the pH and/or the ionic strength of the eluent, up to 90% protein recovery was obtained. Next to the separation, the mixed matrix adsorber membrane functions as a concentration medium since the protein can be concentrated up to 20-fold in the eluent. The adsorber membranes can be reused in multiple adsorption/desorption cycles with good adsorption performances.     

The effect of chain length on protein solubilization in polymer-based vesicles (polymersomes)

Using a mean-field analysis we derive a consistent model for the perturbation of a symmetric polymeric bilayer due to the incorporation of transmembrane proteins, as a function of the polymer molecular weight and the protein dimensions. We find that the mechanism for the inhibition of protein incorporation in polymeric bilayers differs from that of their inclusion in polymer-carrying lipid vesicles; in polymersomes, the equilibrium concentration of transmembrane proteins decreases as a function of the thickness mismatch between the protein and the bilayer core, whereas in liposomes the presence of polymer chains affects the protein adsorption kinetics. Despite the increased stiffness of polymer bilayers (when compared to lipid ones), their perturbation decay length and range of protein-protein interaction is found to be relatively long. The energetic penalty due to protein adsorption increases relatively slowly as a function of the polymer chain length due to the self-assembled nature of the polymer bilayer. As a result, we predict that transmembrane proteins may be incorporated in significant numbers even in bilayers where the thickness mismatch is large.     

Transmission and regulation of biochemical stimulus via a nanoshell directly adsorbed on the cell membrane to enhance chondrogenic differentiation of mesenchymal stem cell

A nanoscale artificial extracellular matrix (nanoshell) formed by layer-by-layer adsorption can enhance and modulate the function of stem cells by transferring biochemical stimulus to the cell directly. Here, the nanoshell composed of fibronectin (FN) and chondroitin sulfate (CS) is demonstrated to promote chondrogenic differentiation of mesenchymal stem cells (MSCs). The multilayer structure of nanoshell is formed by repeating self-assembly of FN and CS, and its thickness can be controlled through the number of layers. The expression of chondrogenic markers in MSCs coated with the FN/CS nanoshell was increased as the number of bilayers in the nanoshell increased until four, but when it exceeds five bilayers, the effect began to decrease. Finally, the MSCs coated with optimized four bilayers of FN/CS nanoshell have high chondrogenic differentiation efficiency and showed the potential to increase formation of cartilage tissue when it is transplanted into mouse kidney. So, the precise regulation of stem cell fate at single cell level can be possible through the cellular surface modification by self-assembled polymeric film.