Disclosed herein are compositions and methods for reducing the antigenicity of molecules. The antigenicity of a molecule may be reduced or eliminated by conjugating at least one branched polymer to the molecule to form a molecule-polymer conjugate. The branched polymer may include a backbone and a plurality of side chains, each side chain covalently attached to the backbone.

In an embodiment of the invention, a composition for treating a cell population comprises an Affinity Medicant Conjugate (AMC). The medicant moiety can be a toxin including an acylfulvene or a drug moiety. The affinity moiety can be an antibody, a binding protein, a steroid, a lipid, a growth factor, a protein, a peptide or non peptidic. The affinity moiety can be covalently bound to the medicant via a linker. Novel linkers that can be directed to cysteine, arginine or lysine residues based on solution pH allow greater flexibility in preserving and/or generating specific epitopes in the AMC.

In an embodiment of the invention, a composition for treating a cell population comprises an Affinity Medicant Conjugate (AMC). The medicant moiety can be a toxin including an acylfulvene or a drug moiety. The affinity moiety can be an antibody, a binding protein, a steroid, a lipid, a growth factor, a protein, a peptide or non peptidic. The affinity moiety can be covalently bound to the medicant via a linker. Novel linkers that can be directed to cysteine, arginine or lysine residues based on solution pH allow greater flexibility in preserving and/or generating specific epitopes in the AMC.

The present invention provides dendrimer conjugates. The present invention provides a composition comprising a dendrimer conjugate and a cell, such as a cell covered with dendrimer conjugates, in which dendrimer conjugates home the cell to a target tissue.

A “nanolipogel” is a delivery vehicle including one or more lipid layer surrounding a hydrogel core, which may include an absorbent such as a cyclodextrin or ion-exchange resin. Nanolipogels can be constructed so as to incorporate a variety of different chemical entities that can subsequently be released in a controlled fashion. These different incorporated chemical entities can differ dramatically with respect to size and composition. Nanolipogels have been constructed to contain co-encapsulated proteins as well as small hydrophobic drugs within the interior of the lipid bilayer. Agents incorporated within nanolipogels can be released into the milieu in a controlled fashion, for example, nanolipogels provide a means of achieving simultaneous sustained release of agents that differ widely in chemical composition and molecular weight. Additionally, nanolipogels can favorably modulate biodistribution.

A “nanolipogel” is a delivery vehicle including one or more lipid layer surrounding a hydrogel core, which may include an absorbent such as a cyclodextrin or ion-exchange resin. Nanolipogels can be constructed so as to incorporate a variety of different chemical entities that can subsequently be released in a controlled fashion. These different incorporated chemical entities can differ dramatically with respect to size and composition. Nanolipogels have been constructed to contain co-encapsulated proteins as well as small hydrophobic drugs within the interior of the lipid bilayer. Agents incorporated within nanolipogels can be released into the milieu in a controlled fashion, for example, nanolipogels provide a means of achieving simultaneous sustained release of agents that differ widely in chemical composition and molecular weight. Additionally, nanolipogels can favorably modulate biodistribution.

A peptide-polymer conjugate is provided for use in treating malaria infections, and in particular terminal or drug resistant malaria infections. The conjugate is formed from a polymer to which a peptide having activity against a malaria parasite is co-valently attached. The peptide is a cyclic decapeptide from the closely-related group of tyrocidines, tryptocidines, phenycidines and gramicidin S, and the polymer is a hydrophilic and biocompatible polymer with a terminal thiol, such as poly(N-vinylpyrrolidone) (PVP). The polymer chains can be decorated with a hydrophilic targeting ligand that specifically targets an epitope on red blood cells, and in particular red blood cells infected with a plasmodial parasite. A method for synthesising the peptide-polymer conjugate is also provided.

Disclosed are dendritic anionic lipids which are compounds of Formula (I): wherein R and R.sup.1 are non-polar groups, L is a linking moiety, and Dm is a dendritic moiety of m generations, each as defined herein. These dendritic anionic lipids are useful for delivery and expression of m RNA and encoded protein, e.g., as a component of liposomal delivery vehicle, and accordingly can be useful for treating various diseases, disorders and conditions, such as those associated with deficiency of one or more proteins. ##STR00001##

Disclosed are dendritic anionic lipids which are compounds of Formula (I): wherein R and R.sup.1 are non-polar groups, L is a linking moiety, and Dm is a dendritic moiety of m generations, each as defined herein. These dendritic anionic lipids are useful for delivery and expression of m RNA and encoded protein, e.g., as a component of liposomal delivery vehicle, and accordingly can be useful for treating various diseases, disorders and conditions, such as those associated with deficiency of one or more proteins. ##STR00001##

Here, the inventors describe methods and compositions for targeting a TLR agonist to the tumor cell or stroma. Aspects of the disclosure relate to a polypeptide comprising a tumor targeting agent operatively linked to p(Man-TLR). Also disclosed are compositions and methods for treating cancer in a subject comprising administration of the polypeptide comprising the tumor targeting agent linked to p(Man-TLR) to the subject.