Isoelectric focusing on cellulose acetate membranes: an up-date on materials and methods

The method of isoelectric focusing proteins on cellulose acetate membranes has been improved by the introduction of: (i) plastic-backed membranes, (ii) a commercially available Mini-IEF cell and (iii) sensitive colloidal gold staining. The improved methodology is described with applications for clinical laboratories.     

Development of a simple ampholyte-free isoelectric focusing slab electrophoresis for protein fractionation

Sample preparation is often necessary to separate and concentrate various compounds prior to analysis of complex samples. In this regard, isoelectric focusing (IEF) is one of the best sample preparation methods. With this approach, however, carrier ampholytes have to be introduced into the samples, which may result in matrix interferences. In this paper, a simple ampholyte-free IEF free-flow electrophoresis design was developed for the separation of proteins. beta-Lactoglobulin, hemoglobin, myoglobin and cytochrome c were selected as model analytes. The experimental design took advantage of the electrolysis-driven production of H(+) and OH(-) ions that migrated from the anode and cathode, respectively, establishing a pH gradient spanning from 2.3 to 8.9. The separation chamber was filled with silanized glass beads as a support medium. Dialysis membranes were mounted at the two sides of the separation chamber (made of glass slides) and sealed with 2% agarose gel. The separated proteins drained from the outlets of the separation chamber and could be successfully collected into small glass tubes. The focusing process was visually observed and the separation was confirmed by capillary isoelectric focusing (cIEF) with pI markers.     

Carrier ampholyte-free solution isoelectric focusing as a prefractionation method for the proteomic analysis of complex protein mixtures

The field of proteomics requires methods that offer high sensitivity and wide dynamic range. One of the strategies used to improve the dynamic range is sample prefractionation, such as microsolution isoelectric focusing (IEF). We have modified a commercial solution IEF instrument, the Rotofor, to prefractionate protein mixtures by carrier ampholyte-free solution IEF. The focusing chamber of the Rotofor was divided into several compartments by polyacrylamide membranes with imbedded Immobiline mixtures of specific pH values. When an electric field is applied, each protein migrates to the compartment confined by membranes with pH values flanking its isoelectric point. The approach was demonstrated for the focusing of myoglobin into a predicted compartment, as well as the separation of a complex soluble yeast protein mixture into several distinct fractions. The proteins were dissolved in water or 30% isopropanol. The method is applicable to both gel-based and solution-phase protein identification methods, without the need for further sample preparation.     

Free-flow zone electrophoresis and isoelectric focusing using a microfabricated glass device with ion permeable membranes

This paper describes a microfabricated free-flow electrophoresis device with integrated ion permeable membranes. In order to obtain continuous lanes of separated components an electrical field is applied perpendicular to the sample flow direction. This sample stream is sandwiched between two sheath flow streams, by hydrodynamic focusing. The separation chamber has two open side beds with inserted electrodes to allow ventilation of gas generated during electrolysis. To hydrodynamically isolate the separation compartment from the side electrodes, a photo-polymerizable monomer solution is exposed to UV light through a slit mask for in situ membrane formation. These so-called salt-bridges resist the pressure driven fluid, but allow ion transport to enable electrical connection. In earlier devices the same was achieved by using open side channel arrays. However, only a small fraction of the applied voltage was effectively utilized across the separation chamber during free-flow electrophoresis and free-flow isoelectric focusing. Furthermore, the spreading of the carrier ampholytes into the side channels resulted in a very restricted pH gradient inside the separation chamber. The chip presented here allows at least 10 times more efficient use of the applied potential and a nearly linear pH gradient from pH 3 to 10 during free-flow isoelectric focusing could be established. Furthermore, the application of hydrodynamic focusing in combination with free-flow electrophoresis can be used for guiding the separated components to specific chip outlets. As a demonstration, several standard fluorescent markers were separated and focused by free-flow zone electrophoresis and by free-flow isoelectric focusing employing a transversal voltage of up to 150 V across the separation chamber.     

Highly efficient proteome analysis with combination of protein pre-fractionation by preparative microscale solution isoelectric focusing and identification by μRPLC-MS/MS with serially coupled long microcolumn

To improve the efficiency of proteome analysis, a strategy with the combination of protein pre-fractionation by preparative microscale solution isoelectric focusing, peptide separation by μRPLC with serially coupled long microcolumn and protein identification by ESI-MS/MS was proposed. By preparative microscale solution isoelectric focusing technique, proteins extracted from whole cell lysates of Escherichia coli were fractionated into five chambers divided by isoelectric membranes, respectively with pH range from 3.0 to 4.6, 4.6 to 5.4, 5.4 to 6.2, 6.2 to 7.0 and 7.0 to 10.0. Compared to the traditional on-gel IFF, the protein recovery could be obviously improved to over 95%. Subsequently, the enriched and fractionated proteins in each chamber were digested, and further separated by a 30-cm long serially coupled RP microcolumn. Through the detection by ESI-MS/MS, about 200 proteins were identified in each fraction, and in total 835 proteins were identified even with one-dimensional μRPLC-MS/MS system. All these results demonstrate that by such a combination strategy, highly efficient proteome analysis could be achieved, not only due to the in-solution protein enrichment and pre-fractionation with improved protein recovery but also owing to the increased separation capacity of serially coupled long μRPLC columns.     

Preparative isoelectric focusing in a cellulose‐based separation medium

An improved preparative method based on isoelectric focusing of analytes in a cellulose‐based separation medium is described in this study. Cellulose is suspended in an aqueous solution of simple buffers, ethylene glycol, glycerol, nonionic surfactant, and colored pI markers. Water partially evaporates during focusing run and the separation takes place in an in situ generated layer of cellulose, which has a gel‐like appearance at the end of analysis. Final positions of analytes are indicated by the positions of zones of focused pI markers. Fractions, segments of the separation medium with analytes, can be simply collected by spatula and analyzed by downstream analytical methods. Good focusing ability of the new method and almost quantitative recovery of model proteins, cytochrome c and bovine serum albumin, was verified by gel electrophoresis and capillary isoelectric focusing of the collected fractions.     

CELLULOSE ACETATE AND EPOXY RESIN BLEND ULTRAFILTRATION MEMBRANES: REPARATION,CHARACTERIZATION, AND APPLICATION

ABSTRACT

Membranes based on cellulose acetate used in ultrafiltration applications lack good, chemical, mechanical and thermal resistance. In order to prepare membranes with improved properties, modification of cellulose acetate with epoxy resin through solution blending was attempted. In the present work, the membrane casting solutions with different polymer blend compositions of cellulose acetate and diglycidyl ether of bisphenol-A (DGEBA) were prepared at 30±2°C. The maximum percent compatibility of the two polymers, cellulose acetate and diglycidyl ether of bisphenol-A, was estimated to be 60/40%. Ultrafiltration blend membranes based on various blend compositions were prepared, characterized in terms of compaction, pure water flux, water content, membrane hydraulic resistance and molecular weight cut-off. The application of these membranes, in rejection of proteins of various molecular weights, are discussed.     

Narrow-band fractionation of proteins from whole cell lysates using isoelectric membrane focusing and nonporous reversed-phase separations

Preparative isoelectric focusing (PIEF) is used to achieve narrow-band fractionation of proteins from whole cell lysates of Escherichia coli (E. coli). Isoelectric membranes create well-defined pH ranges that fractionate proteins by isoelectric point (pI) upon application of an electric potential. A commercial IsoPrime device (Amersham-Pharmacia BioTech) is modified for the PIEF separation to lessen run volumes significantly. Two-dimensional polyacrylamide gel electrophoresis (2-D PAGE) analysis of chamber contents indicates that excellent pH fractionation is achieved with little overlap between chambers. PIEF pH fractions are further separated using nonporous reversed-phase high-performance liquid chromatography (NPS-RP-HPLC) and HPLC eluent is analyzed on-line by electrospray ionization-time of flight-mass spectrometry (ESI-TOF-MS) for intact protein molecular weight (MW) analysis. The result is a pI versus MW map of bacterial protein content. IEF fractionation down to 0.1 pH units combined with intact protein MW values result in a highly reproducible map that can be used for comparative analysis of different E. coli strains.     

Comparison of oligoclonal immunoglobulin G bands in multiple sclerosis cerebrospinal fluid by immunoblotting and immunofixation

We previously analyzed unconcentrated cerebrospinal fluid (CSF) from patients with multiple sclerosis (MS) and other neurologic diseases by isoelectric focusing in agarose gel. We have now developed an immunoblot method for detection of oligoclonal IgG bands in unconcentrated MS CSF. The oligoclonal IgG band patterns seen after immunoblotting were compared with those of conventional immunofixation. Although immunoblotting was found to be rapid the resolution and intensity of oligoclonal IgG bands were somewhat better after immunofixation. Since immunofixation is simpler than immunoblotting, we recommend that clinical laboratories use immunofixation after isoelectric focusing to detect oligoclonal IgG bands in CSF.     

Removal of aromatic compounds in the aqueous solution via micellar enhanced ultrafiltration: Part 1. Behavior of nonionic surfactants

The effects of nonionic surfactants having different hydrophilicity and membranes having different hydrophobicity and molecular weight cut-off on the performance of micellar-enhanced ultrafiltration (MEUF) process were examined. A homologous series of polyethyleneglycol (PEG) alkylether having different numbers of methylene groups and ethylene oxide groups was used for nonionic surfactants. Polysulfone membranes and cellulose acetate membranes having different molecular cut-off were used for hydrophobic membranes and hydrophilic membranes, respectively. The concentration of surfactant added to pure water was fixed at the value of 100 times of critical micelle concentration (CMC). The flux through polysulfone membranes decreased remarkably due to adsorption mainly caused by hydrophobic interactions between surfactant and membrane material. The decline of solution flux for cellulose acetate membranes was not as serious as that for polysulfone membranes because of hydrophilic properties of cellulose acetate membranes. The surfactant rejections for the cellulose acetate membranes increased with decreasing membrane pore size and with increasing the hydrophobicity of surfactant. On the other hand the surfactant rejections for polysulfone membranes showed totally different rejection trends with those for cellulose acetate membranes. The surfactant rejections for the polysulfone membranes depend on the strength of hydrophobic interactions between surfactant and membrane material and molecular weight of surfactants.     

Multi-chamber apparatus for preparative isoelectric focusing

A multi-chamber apparatus for preparative isoelectric focusing is described. The apparatus is constructed of 32 separation chambers and 2 electrode chambers, all separated by uncharged porous membranes. The total volume of the 32 separation chambers is 660 mL. A cooling system and a stirring system are built in. Human serum proteins were separated by isoelectric focusing in a natural pH gradient. The fractionation was monitored by fused rocket immunoelectrophoresis. The number of proteins in each fraction was monitored by crossed immunoelectrophoresis. The apparent pI values of IgG, transferrin and alpha-1-antitrypsin are as found in the literature. Orosomucoid (alpha-1-acid glycoprotein) (pI = 1.8) is concentrated at the acid end of the pH gradient.     

CHARACTERIZATION OF REGENERATED CELLULOSE MEMBRANES HYDROLYZED FROM CELLULOSE ACETATE

A series of cellulose acetate membranes were prepared by using formamide as additive, and then were hydrolyzedin 4 wt% aqueous NaOH solution for 8 h to obtain regenerated cellulose membranes. The dependence of degree ofsubstitution, structure, porous properties, solubility and thermal stability on hydrolysis time was studied by chemical titration,Fourier transform infrared spectroscopy, scanning electron microscopy, wide-angle X-ray diffraction, and differentialscanning calorimetry, respectively. The results indicated that the pore size of the regenerated cellulose membranes wasslightly smaller than that of cellulose acetate membrane, while solvent-resistance, crystallinity and thermostability weresignificantly improved. This work provides a simple way to prepare the porous cellulose membranes, which not only kept thegood pore characteristics of cellulose acetate membranes, but also possessed solvent-resistance, high crystallinity andthermostability. Therefore, the application range ofcellulose acetate membranes can be expanded.     

Studies on cellulose acetate-carboxylated polysulfone blend ultrafiltration membranes--Part I

Hydrophilic polysulfone ultrafiltration (UF) membranes were prepared from blends of cellulose acetate with carboxylated polysulfone of 0.14 degree of carboxylation. The effects of blend polymer composition on compaction, pure water flux, water content and membrane hydraulic resistance (R_m), have been investigated to evaluate the performance of the membranes. The performance of the blend membranes of various blend polymer compositions were compared with that of membranes prepared from pure cellulose acetate and blends of cellulose acetate and pure polysulfone. The hydrophilic cellulose acetate-carboxylated polysulfone blend UF membranes showed better performance compared to membranes prepared from pure cellulose acetate and blends of cellulose acetate and pure polysulfone.     

Potentiometric ion- and bio-selective electrodes based on asymmetric cellulose acetate membranes

The potentiometric response properties of ammonium-, carbonate-, and proton-selective electrodes prepared by incorporating appropriate neutral carriers within novel asymmetric cellulose acetate membranes are reported. The membranes are formed by first casting a thin layer of cellulose triacetate without carrier, hydrolyzing one side of this film with base, and then on the other side casting a second layer of cellulose triacetate containing the membrane active components. The resulting asymmetric ion-selective membranes function equivalently, in terms of selectivity and response slopes, to non-asymmetric cellulose triacetate membranes and conventional poly(vinyl chloride)-based membranes. The hydrolyzed surface of the asymmetric membranes can be activated in aqueous solution with carbonyldiimidazole for the direct immobilization of proteins on the surface of the membranes, without loss in potentiometric ion-response. As an example, the immobilization of urease on the surfaces of ammonium- and carbonate-selective membranes yields potentiometric bio-selective urea-probes with desirable dynamic response properties.     

A comparison of Tris-glycine and Tris-tricine buffers for the electrophoretic separation of major serum proteins

This paper compares different buffer systems for the electrophoretic separation of the five most abundant serum proteins on native-PAGE gel and cellulose membranes. A modified Tris-tricine system was shown to be superior for the separation of these serum proteins in a 7% m/v native-PAGE gel as compared with the traditionally used Tris-glycine and Tris-tricine methods. This modified Tris-tricine buffer system was also employed for the separation of serum proteins using a cellulose acetate membrane and very effective separation was observed as compared with the traditionally used Tris-barbital and Tris-glycine buffer systems.     

Immunochemical detection of peptides and proteins on press-blots after direct tissue gel isoelectric focusing

A sensitive method is described for the detection of tissue peptides and proteins. They are separated by tissue isoelectric focusing using thin large-pore polyacrylamide gels, containing detergent and dimethylformamide, and are fixed with either glutaraldehyde or formaldehyde in gelatin-coated nitrocellulose membranes using press-blotting. The fixed peptide and protein antigens are visualized by immunoperoxidase staining. The spectrum of fixed tissue constituents may also be used to test antiserum reactivity and specificity in immunocytochemical staining procedures. Isoelectric focusing of 2 microL homogenates of the neurointermediate lobe of the pituitary allowed the immunodetection of peptides and proteins of various sizes and the determination of isoelectric points. However, direct application onto gels of small pieces of frozen tissue sections, sliced in a cryostat, appeared to be more efficient. By direct tissue isoelectric focusing of brain tissue, peptides were effectively eluted and separated from sections up to 100 microns thickness. This allowed the detection of small peptides with a detection limit of approximately 10 pg/section.     

Role of membrane surface morphology in colloidal fouling of cellulose acetate and composite aromatic polyamide reverse osmosis membranes

Laboratory-scale colloidal fouling tests, comparing the fouling behavior of cellulose acetate and aromatic polyamide thin-film composite reverse osmosis (RO) membranes, are reported. Fouling of both membranes was studied at identical initial permeation rates so that the effect of the transverse hydrodynamic force (permeation drag) on the fouling of both membranes is comparable. Results showed a significantly higher fouling rate for the thin-film composite membranes compared to that for the cellulose acetate membranes. Addition of an anionic surfactant (sodium dodecyl sulfate, SDS) to mask variations in chemical and electrokinetic surface characteristics of the cellulose acetate and aromatic polyamide membranes resulted in only a small change in the fouling behavior. The higher fouling rate for the thin-film composite membranes is attributed to surface roughness which is inherent in interfacially polymerized aromatic polyamide composite membranes. AFM and SEM images of the two membrane surfaces strongly support this conclusion. These surface images reveal that the thin-film composite membrane exhibits large-scale surface roughness of ridge-and-valley structure, while the cellulose acetate membrane surface is relatively smooth.     

Improved Membranes for Hemodialysis

Asymmetric membranes of cellulose acetate and cellulose acetate modified with pendant amino groups have been evaluated for ultrafiltration and dialysis properties. Ultrafiltration rates from 4 to 30 times that of Cuprophan were obtained. During the ultrafiltration test, up to 89% of inulin in the test solution permeated with the ultrafitrate in contrast to the 14% permeation of inulin through a Cuprophan membrane. In spite of the apparently facile permeation of high molecular weight species (e.g., inulin) through the experimental membranes, human albumin was quantitatively reflected. Dialysis tests indicate that cellulose acetate membranes 38 μ or less in thickness should surpass 23-μ-thick (wet) Cuprophan in purely diffusional transport of blood solutes of low molecular weight.

In addition to their promising ultrafiltration and dialysis properties, membranes made from a blend of cellulose acetate and N,N-diethylaminoethylcellulose acetate were found to sorb heparin strongly. The clotting time of rabbit blood in contact with the heparinized membranes was extended, in some cases indefinitely.     

固化pH梯度毛细管等电聚焦整体柱的制备及在蛋白质等电点分析中的应用

通过聚合物原位聚合反应，制备了部分填充的毛细管整体柱。pH 3~10的载体两性电解质被固化在该毛细管整体柱上。在引入八通进样阀、三通阀和四通连接单元的基础上，构建了适用于固化pH梯度毛细管等电聚焦整体柱（M-IPG）的平台。在蛋白质药物测定过程中，用M-IPG柱和羟丙基纤维素（HPC）涂层毛细管柱同时对曲托珠单抗和依那西谱的等电点进行了测定。结果表明，两种等电聚焦柱都能够同时分离混合蛋白质样品并测定蛋白质类药物中单抗和融合蛋白质的等电点（pI），M-IPG柱所测的pI值与HPC涂层毛细管柱测定的结果基本一致，表明了该柱在进一步构建多维分离平台进行蛋白质组学研究方面的潜力。     

Separation of proteins in a multicompartment electrolyzer with chambers defined by a bed of gel beads

Multicompartment electrolyzers (MEs) with isoelectric membranes were introduced in 1989 for purifying proteins in an electric field. At the basis of ME technology there are membranes consisting of cross-linked copolymers of acrylamide and acrylamido monomers bearing protolytic groups. The technology employed for casting the membranes is an extension of the isoelectric focusing in immobilized pH gradient technique for which specific acrylamido monomers, known with the trade name of Immobiline, have been developed. However, the use of continuous membranes presents several disadvantages. Due to the mechanical characteristics of polyacrylamide, the gel must physically adhere onto a rigid support, which prevents it from collapsing. The support must have a highly porous structure in order to be permeable to proteins. The mechanical fragility of the membranes is one of the main problems that hinders the industrial scale application of ME separators. In order to overcome this problem, we propose to substitute the continuous membranes with a bed of gel beads of identical comonomer composition, obtained by an inverse emulsion polymerization process.