Provided herein are methods and compositions, such as kits, related to compositions comprising synthetic nanocarriers comprising an immunosuppressant and compositions comprising an uricase and a composition comprising an anti-inflammatory therapeutic. Also provided herein are methods and compositions for the treatment of subjects in need of administration or treatment with the uricase.

Provided is a urate oxidase preparation. The urate oxidase preparation includes polyethylene glycol-modified urate oxidase as an active ingredient and a buffer reagent as an excipient.

Provided is a method for preparing a polyethylene glycol-modified urate oxidase, at least 11 of the following amino acid sites of the polyethylene glycol-modified urate oxidase have a PEG modification: T.sup.1, K.sup.3, K.sup.4, K.sup.30, K.sup.35, K.sup.76, K.sup.79, K.sup.97, K.sup.112, K.sup.116, K.sup.120, K.sup.152, K.sup.179, K.sup.222, K.sup.231, K.sup.266, K.sup.272, K.sup.285, K.sup.291, and K.sup.293, and the preparation method includes: performing a coupling reaction between urate oxidase and polyethylene glycol, wherein the polyethylene glycol is provided in the form of an acidic solution, and a molar ratio of the urate oxidase to the polyethylene glycol is 1: (56 to 94), to obtain the polyethylene glycol-modified urate oxidase.

Provided herein are charge complementary peptides coupled to a cargo polypeptide (e.g., a uricase protein) (e.g., uricase) 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 (e.g., to treat gout).

A uricase derivative co-conjugated with fatty acid-linked polyethylene glycol derivatives and optionally, alkoxy polyethylene glycol derivatives is presented. The uricase may be intramolecularly crosslinked. The uricase derivative of the present invention is intended for use as a treatment for gout or hyperuricemia.

The subject invention provides a method for purifying a target protein from a mixture comprising the target protein and contaminating protein, comprising the steps of exposing the mixture to an effective amount of a cationic surfactant such that the contaminating protein is preferentially precipitated and recovering the target protein. Proteins purified according to the method of the invention are also provided.

Provided herein are materials and methods that include utilizing atom transfer radical polymerization (ATRP) initiator molecules that maintain a positive charge during biomacro-initiator synthesis.

Described are improved uricase sequences having beneficial effects and methods of treating patients suffering from hyperuricemia.

Methods and kits for predicting infusion reaction risk and antibody-mediated loss of response during intravenous PEGylated uricase therapy in gout patients is provided. Routine SUA monitoring can be used to identify patients receiving PEGylated uricase who may no longer benefit from treatment and who are at greater risk for infusion reactions.

Methods and kits for predicting infusion reaction risk and antibody-mediated loss of response during intravenous PEGylated uricase therapy in gout patients is provided. Routine SUA monitoring can be used to identify patients receiving PEGylated uricase who may no longer benefit from treatment and who are at greater risk for infusion reactions.