The present invention provides compositions for removal of arsenic or heavy metal contaminants in the process of fluid filtration comprising an organically modified inorganic adsorbent, wherein the composition is produced by reaction with 1,3-dipolar compounds prior to filtration. Also provided are systems for fluid filtration, comprising compositions as provided herein, in a column or column-like format, wherein a fluid is provided to the column such that the fluid flows through the organically modified inorganic adsorbent, and wherein contaminants present in the fluid are bound to the composition. Additionally provided are methods for fluid filtration, comprising contacting a fluid sample with the composition of claim 1 and collecting the filtered fluid sample after filtration.

The present invention provides compositions for removal of arsenic or heavy metal contaminants in the process of fluid filtration comprising an organically modified inorganic adsorbent, wherein the composition is produced by reaction with 1,3-dipolar compounds prior to filtration. Also provided are systems for fluid filtration, comprising compositions as provided herein, in a column or column-like format, wherein a fluid is provided to the column such that the fluid flows through the organically modified inorganic adsorbent, and wherein contaminants present in the fluid are bound to the composition. Additionally provided are methods for fluid filtration, comprising contacting a fluid sample with the composition of claim 1 and collecting the filtered fluid sample after filtration.

The present invention relates to a chromatography column (100; 100′) comprising a tubular side wall (110) having an inner wall (112), an adaptor assembly (120) and a base assembly (125). An enclosed bed space (130) is defined between said adaptor assembly (120), said base assembly (125) and said inner wall (112) of said tubular side wall (110). The adaptor assembly (120) is axially movable inside said tubular side wall (110) in relation to said base assembly (125). The inner wall (112) comprises at least one groove (180; 180′; 180″; 180′″) which is positioned in a lower half of the tubular side wall (110) of the chromatography column (100), via which groove (180; 180′; 180″; 180′″) air and other fluid can pass the adaptor assembly (120) when the adaptor assembly is positioned in a priming position, in which priming position said adaptor assembly intersects with at least a part of the at least one groove (180; 180′; 180″; 180′″).

The present invention relates to a chromatography column (100; 100′) comprising a tubular side wall (110) having an inner wall (112), an adaptor assembly (120) and a base assembly (125). An enclosed bed space (130) is defined between said adaptor assembly (120), said base assembly (125) and said inner wall (112) of said tubular side wall (110). The adaptor assembly (120) is axially movable inside said tubular side wall (110) in relation to said base assembly (125). The inner wall (112) comprises at least one groove (180; 180′; 180″; 180′″) which is positioned in a lower half of the tubular side wall (110) of the chromatography column (100), via which groove (180; 180′; 180″; 180′″) air and other fluid can pass the adaptor assembly (120) when the adaptor assembly is positioned in a priming position, in which priming position said adaptor assembly intersects with at least a part of the at least one groove (180; 180′; 180″; 180′″).

A method for separating at least two metals from each other in a metal refining process, the method comprising: injecting a feed solution comprising the metals into a column or flow pipe comprising a monolithic solid body having a plurality of channels; and flowing the feed solution through the plurality of channels in the monolithic solid body to separate the metals.

The invention discloses a method for individually assessing the cleanness of at least one of an upper (2) and a lower (3) bed support in a process column (1). The method comprises the steps of: a) providing a process column (1) comprising an upper (2) and a lower (3) bed support, a column chamber, a movable adaptor (5), an upper outlet (6) and a lower outlet (7); b) conveying liquid through one of the lower (3) and upper (2) bed supports, e.g. by moving the adaptor (5) downwards at a predetermined rate with one of the upper and lower outlets closed and the other open to force liquid through one of the lower and upper bed supports, and; c) measuring the differential pressure over the bed support through which liquid passes.

The invention discloses a method for individually assessing the cleanness of at least one of an upper (2) and a lower (3) bed support in a process column (1). The method comprises the steps of: a) providing a process column (1) comprising an upper (2) and a lower (3) bed support, a column chamber, a movable adaptor (5), an upper outlet (6) and a lower outlet (7); b) conveying liquid through one of the lower (3) and upper (2) bed supports, e.g. by moving the adaptor (5) downwards at a predetermined rate with one of the upper and lower outlets closed and the other open to force liquid through one of the lower and upper bed supports, and; c) measuring the differential pressure over the bed support through which liquid passes.

A chromatographic cassette includes a cassette including a chamber, chromatographic media disposed within the cassette chamber, a distribution network fluidly coupled to the chromatographic media and an inlet port and an outlet port coupled to the distribution network. A hyper-productive chromatography technique includes providing a scalable and stackable chromatographic cassette, loading a sample to be processed, operating the scalable chromatographic cassette having an adsorptive chromatographic bed having a volume greater than 0.5 liter by establishing a flow at a linear velocity greater than 500 cm/hr with a residence time of the loading step of less than one minute.

A chromatographic cassette includes a cassette including a chamber, chromatographic media disposed within the cassette chamber, a distribution network fluidly coupled to the chromatographic media and an inlet port and an outlet port coupled to the distribution network. A hyper-productive chromatography technique includes providing a scalable and stackable chromatographic cassette, loading a sample to be processed, operating the scalable chromatographic cassette having an adsorptive chromatographic bed having a volume greater than 0.5 liter by establishing a flow at a linear velocity greater than 500 cm/hr with a residence time of the loading step of less than one minute.

An object of the present invention is to provide a method for purifying efficiently and easily a .sup.226Ra-containing solution obtained when .sup.225Ac is produced from a .sup.226Ra target, a method for producing a .sup.226Ra target by using the purified .sup.226Ra-containing solution obtained by the above purification method, and a method for producing .sup.225Ac including these above methods. The method for purifying a .sup.226Ra-containing solution according to the present invention is characterized by including an adsorption step (R1) of allowing .sup.226Ra ions to adsorb onto a carrier having a function of selectively adsorbing divalent cations by bringing a .sup.226Ra-containing solution (a) into contact with the carrier under an alkaline condition; and an elution step (R2) of eluting the .sup.226Ra ions from the carrier under an acidic condition.