A method of producing substantially pure rare earth elements (REEs) from a mixture, including the steps of dissolving a mixture containing REEs in a strong acid to result in a dissolved mixture of metal ions, including that of REEs, capturing metal ions of REEs in a first set of chromatographic columns comprising strong acid cation exchange resins, washing said first set of chromatographic columns with a salt solution to remove non-adsorbing metal ions, eluting metal ions of REES from said first set of chromatographic columns with a first ligand solution to result in a solution of enriched metal ions of REEs, loading said solution of enriched metal ions of REEs onto a second set of chromatographic columns, and eluting bound metal ions of REEs stepwise from said second set of chromatographic columns using a second ligand solution to afford a substantially pure REE. The second set of chromatographic columns comprises hydrous polyvalent metal oxide selected from the group consisting of TiO.sub.2, ZrO.sub.2, or SnO.sub.2. The ligand of the second ligand solution coordinates with said hydrous polyvalent metal oxide.

A method for the manufacture of highly purified .sup.68Ge material for radiopharmaceutical purposes. The invention particularly concerns the production of .sup.68Ge-API (API=Active Pharmaceutical Ingredient) solution complying with the Guidelines for good manufacturing practices (GMP). Starting material for the method of the present invention can be a .sup.68Ge stock solution of commercial or other origin as raw material. Such .sup.68Ge containing raw solutions are purified from potential metal and organic impurities originating from production processes. The radiochemical method disclosed is based on a twofold separation of .sup.68Ge from organic and metallic impurities with two different adsorbent materials. During the first separation phase .sup.68Ge is purified from both organic and metallic impurities by adsorption in germanium tetrachloride form, after which hydrolyzed .sup.68Ge is purified from remaining metallic impurities by cation exchange. The final .sup.68Ge-API-product e.g. fulfills the regulatory requirements for specifications of the GMP production of .sup.68Ge/.sup.68Ga generators.

The invention features compact systems and methods for vacuum liquid purification and extraction of a liquid sample.

Disclosed here includes a method for purifying a biologic composition, comprising diafiltering the biologic composition into a composition comprising phosphate buffered saline (PBS) to obtain a purified composition. The method disclosed here can be particularly useful for removing one or more impurities from the biologic composition, such as bis(2-hydroxyethyl)amino-tris(hydroxymethyl)methane (Bis-tris).

The present invention provides a method for manufacturing antibodies or a fragment thereof with reduced levels of antibody reduction related impurities.

The invention relates to a method for producing a fructose composition comprising the following successive stages: provision of an initial composition comprising glucose; concentration of the initial composition by evaporation of water to obtain a concentrated initial composition; isomerization of glucose to fructose from the concentrated initial composition, making it possible to obtain an intermediate composition; purification of the intermediate composition in a multicolumn chromatography system, making it possible to obtain a glucose-rich raffinate and a fructose-rich extract; concentration of the extract by evaporation of water; wherein the intermediate composition is not subjected to a concentration step by evaporation of water between the isomerization step and the purification step.

A vitamin E production method and a vitamin E production device which can highly purify vitamin E in a vitamin E concentrated fraction are provided. A raw oil supply section supplies a raw oil to a series column in which two or more columns including a strongly basic anion exchanger are coupled in series to adsorb vitamin E included in the raw oil on the strongly basic anion exchanger of at least one column from among the series column. A desorption solution supply section supplies a desorption solution to a column on which vitamin E has been adsorbed to desorb vitamin E from the strongly basic anion exchanger of the column.

The present invention provides novel chromatographic materials, e.g., for chromatographic separations, processes for its preparation and separations devices containing the chromatographic material; separations devices, chromatographic columns and kits comprising the same; and methods for the preparation thereof. The chromatographic materials of the invention are high purity chromatographic materials comprising a chromatographic surface wherein the chromatographic surface comprises a hydrophobic surface group and one or more ionizable modifier.

The invention relates to a method for purifying a fructose-containing mixture to be separated in a multicolumn chromatography system, the method comprising successively and cyclically: a step of collecting a raffinate, a step of injecting the mixture to be separated, a step of collecting an extract and a step of injecting eluent;
wherein the mixture to be separated has a dry matter mass concentration of 45 to 55%, the method being carried out at a temperature of 50 to 62° C.

Methods for achieving complete sequence coverage of monoclonal antibodies by trypsin digestion and dual-column LC-MS system are provided. The disclosed method improves upon current techniques for standard peptide mapping.