Methods for preparing CD7-negative, CD3-positive T cells, which optionally express a chimeric antigen receptor, are provided as is a method of using such cells in a method for treating cancer, in particular a CD7+ cancer. In one aspect, the invention provides a method for preparing a population of CD7-negative, CD3-positive T cells by (a) performing a first selection by depleting, from a population of primary immune cells, cells that express CD7 thereby generating a population of CD7-negative cells; (b) performing a second selection by enriching, from the population of CD7-negative cells, T cells that express CD3 thereby generating a population of CD7-negative and CD3-positive T cells, and (c) incubating the population of CD7-negative and CD3-positive T cells in a culture vessel under stimulating conditions, thereby generating stimulated CD7-negative, CD3-positive T cells.

Provided is a method of purifying a mixture of Fc-containing bioactive peptides by using an affinity column including an affinity matrix containing a protein A ligand, wherein the mixture of Fc-containing bioactive peptides includes a first Fc-containing bioactive peptide and a second Fc-containing bioactive peptide, and the second Fc-containing bioactive peptide includes at least one more human VH3 domain, compared to the first Fc-containing bioactive peptide. According to the purification method, bioactive peptides having the same or similar structures can be precisely separated to the high level of purity while simplification of the process is achieved.

The present invention relates to Fc binding proteins comprising one or more domains with Cysteine in the C-terminal helical region. The invention further relates to affinity matrices comprising the Fc binding proteins of the invention. The invention also relates to a use of these Fc binding proteins or affinity matrices for affinity purification of immunoglobulins and to methods of affinity purification using the Fc binding proteins of the invention.

Methods of maintaining narrow residence time distributions in continuous flow systems, particularly applicable to virus inactivation such as during a protein purification process. Fluid sample is introduced into an axial flow channel and caused to flow therein in discrete packets or zones to minimize residence time distribution and axial dispersion. Embodiments described herein obviate or minimize the need for using large tanks or reservoirs for performing virus inactivation during a protein purification process; reduce the overall time required for virus inactivation, and/or reduce the overall physical space required to perform the virus inactivation operation during a protein purification process, which in turn reduces the overall footprint for the purification process.

The present invention relates to a method for increasing antibody yield during antibody purification from a sample by ion exchange chromatography in flow-through mode by pre-conditioning the sample with Tris without the use of NaCl to adjust the conductivity.

A column is disclosed for removal of sTNF-R2 from a body fluid. The column has a compartment, an inlet coupled to the compartment and configured to receive the body fluid, and a substrate disposed within the compartment. A capture ligand is coupled to the substrate and has a modified sequence with an amino acid substitution in a reference sequence that includes a portion of a natural TNF sequence. The modified sequence has an affinity for the sTNF-R2 that is greater than an affinity of the reference sequence for the sTNF-R2.

Method and system for purifying a sample comprising a biomolecule of interest and impurities, comprising expressing said biomolecule of interest in a bioreactor to form a product sample comprising said biomolecule of interest and impurities; subjecting said product sample to filtration to form a clarified product sample; subjecting said clarified product sample to affinity chromatography to remove impurities; subsequently subjecting said product sample to diafiltration followed by virus filtration and optional concentration. The buffer used during the diafiltration step (and thus in the virus filtration step) is the buffer desired for the final formulation of the product.

The present invention relates to a method of purifying a recombinant polypeptide from Host Cell Proteins (HCP), the method comprising: (a) applying a solution comprising the recombinant polypeptide and HCP to a superantigen chromatography solid support, (b) washing the superantigen chromatography solid support with a wash buffer comprising caprylate and arginine; and (c) eluting the recombinant polypeptide from the superantigen chromatography solid support.

A biological sample purification apparatus is described for purifying a protein from a cell, as well as methods of use of the purification apparatus, and systems comprising the same. The described apparatus comprises a housing comprising a top opening, a bottom opening, and a membrane positioned between said top opening and said bottom opening; and a purification media comprising diatomaceous earth and a resin, wherein the purification media is positioned between the membrane and the top opening; and wherein the purification media is optionally mixed and is substantially dry.

The invention relates to methods for removal of low isoelectric point product-related impurities during cation exchange purification operations.