Provided herein are charge complementary peptides that can be optionally coupled to a cargo polypeptide that are capable of self-assembling under stimulating conditions. The charge complementary peptides can be capable of forming supramolecular structures. Also provided herein are methods of using the charge complementary peptides provided herein.

Disclosed are methods for producing methemoglobin or polymerized methemoglobin. Also provided are pharmaceutical compositions comprising methemoglobin complexed with haptoglobin or polymerized methemoglobin, as well as methods of using thereof to treat cyanide and hydrogen sulfide poisoning.

A method of preparing extracellularly assembled higher order antigen from a native lower order antigen the method comprising the following steps: (i) contacting lower order antigen with a solution comprising a reducing agent for a time and under 5 conditions sufficient to reduce one or more native cysteines; and (ii) removing or diluting the reducing agent or contacting the reduced lower order antigen with an oxidising agent, to elicit assembly of lower order antigen from (i) into an assembled higher order antigen; wherein at least 10% of the lower order antigen is converted to higher order antigen in step (ii) and whereby the assembled higher order antigen 10 displays at least reduced binding to non-neutralizing antibodies compared to the lower order antigen and retains binding to at least one neutralizing antibody. A method of producing a vaccine composition comprising following the steps of the method and then mixing the assembled higher order antigen with a pharmaceutically or physiologically acceptable diluent, carrier or adjuvant. A composition comprising a 15 higher order extracellularly assembled antigen, wherein the assembled antigen displays at least reduced binding to a non-neutralizing antibody compared to a native control higher order antigen. Use of the assembled higher order antigen to stimulate an immune response or for the detection and/or isolation of an immune cell such as a B-cell specific for the antigen.

A method of refolding proteins expressed in non-mammalian cells present in concentrations of 2.0 g/L or higher is disclosed. The method comprises identifying the thiol pair ratio and the redox buffer strength to achieve conditions under which efficient folding at concentrations of 2.0 g/L or higher is achieved and can be employed over a range of volumes, including commercial scale.

The present invention relates to a method for treating and/or preventing a disease associated with protein aggregation which comprises the step of preventing protein aggregation associated with RNA removal, by stabilising RNA; or reversing protein aggregation associated with RNA removal, by effectively replacing removed RNA.

This application describes a compound represented by Formula (I): (I) wherein: Y is a biologically active organic core group comprising one or more of an aryl group, a heteroaryl aryl group, a nonaromatic hydrocarbyl group, and a nonaromatic heterocyclic group, to which Z is covalently bonded; n is 1, 2, 3, 4 or 5; m is 1 or 2; Z is O, NR, or N; X.sup.1 is a covalent bond or CH.sub.2CH.sub.2, X.sup.2 is O or NR; and R comprises H or a substituted or unsubstituted group selected from an aryl group, a heteroaryl aryl group, a nonaromatic hydrocarbyl group, and a nonaromatic heterocyclic group. Methods of preparing the compounds, methods of using the compounds, and pharmaceutical compositions comprising the compounds are described as well.

Processes and apparatuses for producing biologically-active, protein-rich microparticles under ambient conditions are disclosed. A protein solution is atomized and collected in a dehydration solvent that is being mixed. The resulting protein microparticles retain high specific activity without the need for large amounts of stabilizing excipients.

The present invention relates to a method of producing a collagen membrane that has particular mechanical properties. In particular, the present invention relates to a method A of producing a collagen membrane comprising the steps of (i) isolating a collagen-containing tissue and incubating same in an ethanol solution; (ii) incubating the collagen-containing tissue from step (i) in a first solution comprising an inorganic salt and an anionic surfactant in order to denature non-collagenous proteins contained therein; (iii) incubating the collagen-containing tissue produced in step (ii) in a second solution comprising an inorganic acid until the collagen in said material is denatured; and (iv) incubating the collagen-containing tissue produced in step (iii) in a third solution comprising an inorganic acid with simultaneous mechanical stimulation for sufficient time to enable the collagen bundles in said collagen-containing tissue to align; wherein the mechanical stimulation comprises applying tension cyclically to the collagen-containing tissue.

A method of refolding proteins expressed in non-mammalian cells present in concentrations of 2.0 g/L or higher is disclosed. The method comprises identifying the thiol pair ratio and the redox buffer strength to achieve conditions under which efficient folding at concentrations of 2.0 g/L or higher is achieved and can be employed over a range of volumes, including commercial scale.

Processes and apparatuses for producing biologically-active, protein-rich microparticles under ambient conditions are disclosed. A protein solution is atomized and collected in a dehydration solvent that is being mixed. The resulting protein microparticles retain high specific activity without the need for large amounts of stabilizing excipients.