Tamio Kamidate

Micelle-mediated extraction

The extraction technique based on phase separation in aqueous micellar solutions is reviewed. The technique has now been utilized for separation and preconcentration of metal chelates, organic compounds, and proteins. Additionally, the phase behavior of the micellar solutions and recent advances in the phase separation technique are also described. In the extraction of metal chelates, distribution equilibria are considered. In contrast to conventional solvent extraction, the distribution of metal chelates into a condensed surfactant phase (surfactant-rich phase) was dependent on metal ions. Proteins were extractable into the surfactant-rich phase according to their hydrophobicity. The recent use of affinity ligands and water-soluble polymers for controlling extractability of proteins are also introduced.

Distribution of metal chelates between aqueous and surfactant phases separated from a micellar solution of a nonionic surfactant

A dilute micellar solution of poly(oxyethylene) 4-nonylphenyl ether with oxyethylene units 7.5 (PONPE-7.5) was separated into two phases (aqueous and surfactant phases) at room temperature. The partition constants of several chelating reagents and their metal chelates between the two phases were determined at 293 K and ionic strength 0.1 (NaClO4). The partition constants of the neutral metal chelates depend on the kind of metal ions and were considerably smaller than those expected from the regular solution theory. These facts suggested that the chelates were incorporated into a hydrocarbon environment in the surfactant phase, whereas the chelating reagents were distributed in the poly(oxyethylene) part of PONPE-7.5. A brief review was also presented on the analytical applications to the extraction of metal ions and organic compounds.

Phase separation in aqueous micellar solutions of nonionic surfactants for protein separation

Abstract The use of phase separation in aqueous micellar solutions of nonionic surfactants is introduced as a separation method for membrane proteins. Recent progress in phase separation is also described.

Kinetics of Peroxidase Catalyzed Decoloration of Orange II. with Hydrogen Peroxide

The decoloration rate of Orange II is measured at 20°C and pH 9.0 in the presence of hydrogen peroxide and such peroxidases (POD) as horseradish POD (HRP), POD from soybean (SPO), and arthromyces ramosus POD (ARP). The decoloration rate of Orange II is expressed as pseudo-first order reaction kinetics for all PODS used. The rate constants increase in the following order. SPO < HRP < ARP. Rate constant values for HRP and ARP are much greater than that for percarbonate. The differences in rate constants between PODS can be explained in terms of the different reactivities of POD-interme diates for Orange II.

Peroxidase-catalysed luminol chemiluminescence method for the determination of glutathione

A luminol chemiluminescence (CL) method was developed for the determination of glutathione (GSH). GSH was indirectly determined by measuring the amount of hydrogen peroxide formed during the Cu(II)-catalysed oxidation of GSH with oxygen. The amount of hydrogen peroxide formed was continuously measured using the Arthromyces ramosus peroxidase-catalysed luminol CL reaction. The CL intensities at maximum light emission were linearly correlated with the concentration of GSH over the range 7.5 x 10(-7)-3.0 x 10(-5) M. The detection limit for GSH was about 10 times better than that of the spectrophotometric method using Ellman reagent.

Polymer‐induced phase separation in aqueous micellar solutions of octyl‐β‐D‐thioglucoside for extraction of membrane proteins

A water-soluble polymer such as polyethylene glycol (PEG), Dextran T-500 (Dx), or diethylaminoethyl-Dextran (DEAE-Dx) induced aqueous micellar solutions of octyl-beta-D-thioglucoside (OTG) to phase separation at 0 degrees C. One of the two phases thus formed is a surfactant-depleted aqueous solution (aqueous phase) of a water-soluble polymer and the other a concentrated OTG solution (surfactant-rich phase). In a combination of OTG with PEG or Dx, cytochrome P450 (P450) and cytochrome b(5) (b(5)) were well extracted into the surfactant-rich phase. The extraction yield of P450 was slightly greater than that of b(5). In contrast to PEG and Dx, DEAE-Dx markedly reduced the extraction of b(5), while that of P450 remained almost unchanged. DEAE-Dx served the dual functions of inducing the phase separation and preventing the extraction of b(5) into the surfactant-rich phase. This depressed extraction of b(5) was reversed by the addition of potassium phosphate. DEAE-Dx and potassium phosphate proved effective in controlling the extractability of b(5). The polymer-induced phase separation provides a new basis for highly efficient extraction of membrane proteins under mild conditions that should be acceptable for thermolabile membrane proteins under physiological conditions.

Enhancement of the excluded-volume effect in protein extraction using triblock copolymer-based aqueous micellar two-phase systems

Abstract Triblock copolymer surfactants consisting of poly(ethylene oxide) (PEO) and poly(propylene oxide) (PPO), Pluronic L61 (PEO–PPO–PEO, L61) and Pluronic 25R2 (PPO–PEO–PPO, 25R2) were exploited in aqueous micellar two-phase systems for the protein extraction. The extraction was based on the phase separation into surfactant-depleted and -condensed phases (an aqueous and a surfactant-rich phases, respectively) upon warming aqueous micellar solutions of triblock copolymer. In both systems, hydrophilic proteins such as albumin were not extracted into the surfactant-rich phase. On the other hand, hydrophobic cytochrome b 5 was well extracted in the L61 system due to hydrophobic interaction. However, the extraction of cytochrome b 5 was not observed in the 25R2 system. This abnormal extractability of cytochrome b 5 in the 25R2 system was explained by the enhanced excluded-volume interaction between cytochrome b 5 and 25R2 micellar network in the surfactant-rich phase, which overcomes the hydrophobic interaction. Additionally, ionic surfactants were added into the systems for controlling extractability of proteins. In the 25R2 system, cationic tetradecyltrimethylammonium was effective for extracting anionic cytochrome b 5 against the excluded-volume effect, while not for anionic albumin because of its large molecular weight. In 25R2 system containing ionic surfactant, the partitioning of proteins were found to be governed by the hydrophobic, excluded-volume, and electrostatic interactions. Micellar network formed by 25R2 type of surfactant with a strong excluded-volume interaction could provide new selective extraction systems for the separation of proteins.

Microchip reversed-phase liquid chromatography with packed column and electrochemical flow cell using polystyrene/poly(dimethylsiloxane)

A microchip pressure-driven liquid chromatography (LC) with a packed column and an electrochemical flow cell has been developed by using polystyrene (PS) and poly(dimethylsiloxane) (PDMS). The cylindrical separation column with packed octadecyl silica particles was fabricated in the PS substrate. The three electrode system (working, reference, and counter electrode) for amperometric detection was fabricated onto the PS substrate, using the Au deposition, photolithography, and chemical etching. The detector flow cell was formed by sealing the electrode system with a PDMS chip containing a channel. In this flow cell, the effect of working electrode width (in the direction of flow) on chromatographic parameters, such as peak width and peak resolution were studied in electrode width ranging 50-5,000 microm. The effect of electrode width on sensitivity (current intensity, current density, and S/N ratio) was also examined. The sensitivity was discussed by simulating the concentration profile generated around the working electrode. The effects of the column packing size and the column size on the separation efficiency were examined. In this study, a good separation of three catechins was successfully achieved and the detection limits for (+)-catechin, epicatechin, and epigallocatechin gallate were 350, 450, and 160 nM, respectively.

Colorimetric method for enzymatic screening assay of ATP using Fe(III)-xylenol orange complex formation.

In hygiene management, recently there has been a significant need for screening methods for microbial contamination by visual observation or with commonly used colorimetric apparatus. The amount of adenosine triphosphate (ATP) can serve as the index of a microorganism. This paper describes the development of a colorimetric method for the assay of ATP, using enzymatic cycling and Fe(III)-xylenol orange (XO) complex formation. The color characteristics of the Fe(III)-XO complexes, which show a distinct color change from yellow to purple, assist the visual observation in screening work. In this method, a trace amount of ATP was converted to pyruvate, which was further amplified exponentially with coupled enzymatic reactions. Eventually, pyruvate was converted to the Fe(III)-XO complexes through pyruvate oxidase reaction and Fe(II) oxidation. As the assay result, yellow or purple color was observed: A yellow color indicates that the ATP concentration is lower than the criterion of the test, and a purple color indicates that the ATP concentration is higher than the criterion. The method was applied to the assay of ATP extracted from Escherichia coli cells added to cow milk.

Separation of microsomal cytochrome b5 via phase separation in a mixed solution of Triton X-114 and charged dextran

The successful introduction of a charged dextran into the Triton X-114 phase separation system for the selective extraction of cytochrome b5 (cyt. b5) in liver microsomes is described. In the absence of charged dextran, 55% of total microsomal proteins and 84% of cyt. b5 were extracted into the surfactant-rich phase. In the presence of anionic dextran sulfate, the extractability of total microsomal proteins was greatly reduced while that of cyt. b5 was increased. After triplicate extraction, cyt. b5 was purified more than 10-fold from microsomes with a recovery of 91% in the surfactant-rich phase. In view of its operational simplicity, this method provides a good means for the partial purification of cyt. b5 prior to chromatographic separations.