The use of a composition which comprises lignosulfonate and is substantially free of elemental sulphur for the prevention and treatment of pathogenic and medical disorders in humans and animals. In some embodiments the lignosulfonate is radically polymerized. In some embodiments the composition is formulated as an animal feed additive or supplement. The disclosure also encompasses a method of preventing or treating a pathogenic or medical disorder in a human or animal subject by administering the composition to the subject in an effective dose to attenuate the pathogenic effect of a pathogen or other biological agent, thereby enabling the subject to mount an effective immune response to the pathogen or other biological agent. The composition can be used in the prevention or treatment of a wide range of pathogenic or medical disorders including disorders caused by microbial pathogens; disorders caused by viral pathogens; disorders caused by prions; disorders caused by protists; disorders caused by fungi; disorders caused by parasites; lung and airway disorders; bone, joint and muscle disorders; digestive disorders; hormonal disorders; cancer; auto immune disorders; neurodegenerative disorders; skin disorders; and sexual and reproductive disorders. In one particular embodiment the composition is formulated for treatment of Type I diabetes.

A microbial infection in an eye of a subject is treated or prevented by topically administering to the eye an effective amount of a macromolecule or a pharmaceutically acceptable salt thereof that includes a dendrimer of 1 to 8 generations with one or more sulfonic acid- or sulfonate-containing moieties attached to one or more surface groups of the outermost generation of the dendrimer. Compositions containing the macromolecule or salt are useful in these methods.

A microbial infection in an eye of a subject is treated or prevented by topically administering to the eye an effective amount of a macromolecule or a pharmaceutically acceptable salt thereof that includes a dendrimer of 1 to 8 generations with one or more sulfonic acid- or sulfonate-containing moieties attached to one or more surface groups of the outermost generation of the dendrimer. Compositions containing the macromolecule or salt are useful in these methods.

Polymer/copper combinations that can selectively target and kill cancer cells are described. Materials can include the reaction product of a biocompatible hydrophilic polymer and pyridine-2-thiol containing monomer. The copolymer reaction product can include pyridine-2-thiol side groups pendant to the backbone via a disulfide linkage. The hydrophilic component can form the polymer backbone and/or can form hydrophilic pendant groups off of the backbone. Copper ions can be associated with the copolymer.

Polymer/copper combinations that can selectively target and kill cancer cells are described. Materials can include the reaction product of a biocompatible hydrophilic polymer and pyridine-2-thiol containing monomer. The copolymer reaction product can include pyridine-2-thiol side groups pendant to the backbone via a disulfide linkage. The hydrophilic component can form the polymer backbone and/or can form hydrophilic pendant groups off of the backbone. Copper ions can be associated with the copolymer.

Polymer/copper combinations that can selectively target and kill cancer cells are described. Materials can include the reaction product of a biocompatible hydrophilic polymer and pyridine-2-thiol containing monomer. The copolymer reaction product can include pyridine-2-thiol side groups pendant to the backbone via a disulfide linkage. The hydrophilic component can form the polymer backbone and/or can form hydrophilic pendant groups off of the backbone. Copper ions can be associated with the copolymer.

Oral sorbent compositions that bind small and charged toxins and methods of use.

Oral sorbent compositions that bind small and charged toxins and methods of use.

Polythioaminal polymers are made from hexahydrotriazine precursors and dithiol precursors. The precursors are blended together and subjected to mild heating to make the polymers. The polymers have the general structure

##STR00001##

wherein each R.sup.1 is independently an organic or hetero-organic group, each R.sup.2 is independently a substituent having molecular weight no more than about 120 Daltons, X and Z are each a sulfur-bonded species, at least one of X and Z is not hydrogen, and n is an integer greater than or equal to 1. X and Z may be hydrogen or a functional group, such as a thiol-reactive group. The reactive thiol groups of the polythioaminal may be used to attach thiol-reactive end capping species. By using water soluble or water degradable dithiols, such as polyether dithiols, water soluble polythioaminals may be made. Some such polymers may be used to deliver therapeutics with non-toxic aqueous degradation products.

Polythioaminal polymers are made from hexahydrotriazine precursors and dithiol precursors. The precursors are blended together and subjected to mild heating to make the polymers. The polymers have the general structure

##STR00001##

wherein each R.sup.1 is independently an organic or hetero-organic group, each R.sup.2 is independently a substituent having molecular weight no more than about 120 Daltons, X and Z are each a sulfur-bonded species, at least one of X and Z is not hydrogen, and n is an integer greater than or equal to 1. X and Z may be hydrogen or a functional group, such as a thiol-reactive group. The reactive thiol groups of the polythioaminal may be used to attach thiol-reactive end capping species. By using water soluble or water degradable dithiols, such as polyether dithiols, water soluble polythioaminals may be made. Some such polymers may be used to deliver therapeutics with non-toxic aqueous degradation products.