Yttria containing hybrid organic-inorganic sol-gels may be used in coatings for capillary microextraction, optionally hyphenated to online HPLC analysis. The sol-gel reaction mixture can use an yttrium trialkoxyalkoxide, such as yttrium trimethoxyethoxide, and a [bis(hydroxyalkyl)-amino-alkyl]-terminated polydialkyl/arylsiloxane, such as [bis(hydroxyethyl)-amine] (BHEA)-terminated polydimethylsiloxane, that can undergo hydrolysis and polycondensation, to form coating materials. Capillaries coated with such sol-gels can have improved extraction efficiency compared, e.g., to pure yttria-based coatings. The CME-HPLC can analyze water samples containing analytes of varied polarity, with excellent extraction of amides, phenols, alcohols, ketones, aldehydes, and polyaromatic hydrocarbons and detection limits ranging from 0.18 to 7.35 ng/mL (S/N=3). Such capillaries can exhibit solvent stability at pH 0 to 14, RSD % between 0.6 to 6.8% (n=3), at a preparative reproducibility RSD between 4.1 and 9.9%.

A purification agent which includes a compound having a betaine structure, and which is for a sugar chain having a length equal to or longer than that of a monosaccharide or for a glycopeptide having a sugar chain having a length equal to or longer than that of a monosaccharide.

Provided are a technique for preparing a porous cellulose medium without using a special gelling agent for a solution in which cellulose acetate serving as a raw material is dissolved; and a porous cellulose medium and the like produced using the technique. A method for producing a porous cellulose medium comprises the step of preparing a flowable homogeneous composition comprising cellulose acetate, a basic compound, and a solvent including water, and gelling the composition by deacetylation reaction of the cellulose acetate.

Provided are a technique for preparing a porous cellulose medium without using a special gelling agent for a solution in which cellulose acetate serving as a raw material is dissolved; and a porous cellulose medium and the like produced using the technique. A method for producing a porous cellulose medium comprises the step of preparing a flowable homogeneous composition comprising cellulose acetate, a basic compound, and a solvent including water, and gelling the composition by deacetylation reaction of the cellulose acetate.

An object of the present invention is to provide a material which can remove an activated leukocyte-activated platelet complex with high efficiency. The present invention provides a material for removing an activated leukocyte-activated platelet complex, the material being a water-insoluble carrier to the surface of which carrier a compound(s) having a charged functional group(s) is(are) bound, wherein an extending length ratio of the surface is 4 to 7.

An object of the present invention is to provide a material which can remove an activated leukocyte-activated platelet complex with high efficiency. The present invention provides a material for removing an activated leukocyte-activated platelet complex, the material being a water-insoluble carrier to the surface of which carrier a compound(s) having a charged functional group(s) is(are) bound, wherein an extending length ratio of the surface is 4 to 7.

Solid supports and ligands are provided for purification of biomolecules by mixed-mode anion exchange-hydrophobic chromatography. Compositions can have the formula Support-(X)N(R1, R2)-R3-L-Ar, or a salt thereof, wherein: Support is a chromatographic solid support; X is a spacer or absent; R1 and R2 are each selected from hydrogen and an alkyl comprising 1-6 carbons; R3 is an alkyl comprising 1-6 carbons or a cyclo alkyl comprising 1-6 carbons; L is NR4, O, or S; wherein R4 is hydrogen or an alkyl comprising 1-6 carbons; and Ar is an aryl. Methods are also provided for using solid supports and ligands to purify biomolecules such as monomeric antibodies.

Solid supports and ligands are provided for purification of biomolecules by mixed-mode anion exchange-hydrophobic chromatography. Compositions can have the formula Support-(X)N(R1, R2)-R3-L-Ar, or a salt thereof, wherein: Support is a chromatographic solid support; X is a spacer or absent; R1 and R2 are each selected from hydrogen and an alkyl comprising 1-6 carbons; R3 is an alkyl comprising 1-6 carbons or a cyclo alkyl comprising 1-6 carbons; L is NR4, O, or S; wherein R4 is hydrogen or an alkyl comprising 1-6 carbons; and Ar is an aryl. Methods are also provided for using solid supports and ligands to purify biomolecules such as monomeric antibodies.

Direct polymerization of lipid monomers or polymer scaffolding of non-lipid monomers coupled with irradiation or redox polymerization performed at neutral pH resulted in stabilized lipid assemblies. An initiator-buffer component and NaHS03 redox mixture polymerizes reactive lipid monomers at near neutral pH conditions to preserve functionality of reconstituted membrane proteins. Improved stability of black lipid membranes (BLMs) is attained by chemical cross-linking of polymerizable, hydrophobic and commercially available non-lipid monomers partitioned into the suspended lipid membranes, and by suspending the BLMs across low surface energy apertures. Substrate apertures having low surface energy modifiers with amphiphobic properties facilitated a reproducible formation of BLMs by promoting interactions between the lipid tail and the substrate material. In addition, polymeric lipid bilayer membranes were prepared by photochemical or redox initiated polymerization of polymerizable lipid monomers, and disposed onto supporting substrates for use in chromatography columns.

Direct polymerization of lipid monomers or polymer scaffolding of non-lipid monomers coupled with irradiation or redox polymerization performed at neutral pH resulted in stabilized lipid assemblies. An initiator-buffer component and NaHS03 redox mixture polymerizes reactive lipid monomers at near neutral pH conditions to preserve functionality of reconstituted membrane proteins. Improved stability of black lipid membranes (BLMs) is attained by chemical cross-linking of polymerizable, hydrophobic and commercially available non-lipid monomers partitioned into the suspended lipid membranes, and by suspending the BLMs across low surface energy apertures. Substrate apertures having low surface energy modifiers with amphiphobic properties facilitated a reproducible formation of BLMs by promoting interactions between the lipid tail and the substrate material. In addition, polymeric lipid bilayer membranes were prepared by photochemical or redox initiated polymerization of polymerizable lipid monomers, and disposed onto supporting substrates for use in chromatography columns.