Abstract: This invention resides in using metal complex-activated particles to bind molecules, polymers and other particles to each other, so as to produce multifunctional conjugates having controlled ratios of two or more different molecules.

Abstract: This invention resides in using metal complex-activated particles to bind molecules, polymers and other particles to each other, so as to produce multifunctional conjugates having controlled ratios of two or more different molecules.

Abstract: The present invention relates to a method of forming a cured conductive binder material, to a method of forming a curable binder formulation, to a curable binder formulation, to a cured conductive binder material and to an electrochemical cell. In one embodiment, the method of forming a cured conductive binder material includes the steps of: (i) providing a liquid formulation comprising a liquid carrier, at least one active material, at least one polymeric binder and at least one modified metal coordination complex; and (ii) curing the liquid formulation of step (i), to thereby form a cured conductive binder material.

Abstract: The present invention relates to a method of controlled competitive exchange of a first agent bound to a metal coordination complex with a competing agent, with selection of the nature of the first agent allowing a tailoring of the binding strength and thereby allowing for a desired level of control for subsequent displacement by the selected competing agent. The method may be employed for release of therapeutic agents, sequestration of larger molecules from a sample, generation of a preferred binding surface and the like.

Abstract: The invention relates to formulations comprising: (i) a first active material; (ii) a second active material; and (iii) a metal-coordination complex, wherein the first active material and the second active material have at least one surface property which is different, one from the other. Such formulations are more homogenous than those formed without the metal-coordination complex and can be used to form composite materials, such as those forming part of a conductive interface, having advantageous properties and providing for improvement in functionality of the conductive interface.

Abstract: The present invention relates to the coating of a range of functional heparins onto the surface of a substrate for which hemocompatibility is a key functional characteristic, such that the functionality of the functional heparin is maintained. The approach employs a metal coordination complex to bind to the substrate with the functional heparin binding to the metal coordination complex to thereby impart hemocompatibility.

Abstract: The present invention relates to reagents and methods for binding compounds to surfaces that are hydrophobic. More specifically, the invention relates to simple methods for coating of hydrophobic planar, membrane or particle surfaces to facilitate binding of molecules such as labels, dyes, synthetic and biological polymers and/or nanoparticles thereto.

Abstract: The present invention describes the use of metal-ligand complexes within the active material of an electrode to provide for improvement in operation as well as to mitigate the cyclic stresses of swelling of the active material during charging and discharging operations and to provide resistance to dissolution of electrode active materials.

Abstract: The invention relates to formulations comprising: (i) a first active material; (ii) a second active material; and (iii) a metal-coordination complex, wherein the first active material and the second active material have at least one surface property which is different, one from the other. Such formulations are more homogenous than those formed without the metal-coordination complex and can be used to form composite materials, such as those forming part of a conductive interface, having advantageous properties and providing for improvement in functionality of the conductive interface.

Abstract: The present invention relates to a method of controlled competitive exchange of a first agent bound to a metal coordination complex with a competing agent, with selection of the nature of the first agent allowing a tailoring of the binding strength and thereby allowing for a desired level of control for subsequent displacement by the selected competing agent. The method may be employed for release of therapeutic agents, sequestration of larger molecules from a sample, generation of a preferred binding surface and the like.

Abstract: The present invention relates to the coating of a range of functional heparins onto the surface of a substrate for which hemocompatibility is a key functional characteristic, such that the functionality of the functional heparin is maintained. The approach employs a metal coordination complex to bind to the substrate with the functional heparin binding to the metal coordination complex to thereby impart hemocompatibility.

Abstract: The present invention describes the use of metal-ligand complexes within the active material of an electrode to provide for improvement in operation as well as to mitigate the cyclic stresses of swelling of the active material during charging and discharging operations and to provide resistance to dissolution of electrode active materials.

Abstract: The present invention relates to reagents and methods for binding compounds to surfaces that are hydrophobic. More specifically, the invention relates to simple methods for coating of hydrophobic planar, membrane or particle surfaces to facilitate binding of molecules such as labels, dyes, synthetic and biological polymers and/or nanoparticles thereto.

Abstract: This invention resides in using metal complex-activated particles to bind molecules, polymers and other particles to each other, so as to produce multifunctional conjugates having controlled ratios of two or more different molecules.

Abstract: A method of adapting a synthetic substrate for immobilisation of a target molecule thereon.

Abstract: The present invention relates generally to a grafting process comprising the formation of a grafted polymeric structure having a substrate polymer in hybrid formation with one or more of the same or other polymers or monomeric subunits thereof. More particularly, the present invention contemplates a method of generating a homogenous or heterogenous grafted polymer by inducing or otherwise facilitating free radical formation to initiate polymerization of monomer units corresponding to the same or different polymers to a substrate polymer previously subjected to physical stress means. The resulting hybrid polymer may comprise a substrate polymer and a population of a second or further polymers in homogenous or heterogenous hybrid formation with the substrate polymer. A homogenous population includes a grafted population of the same polymer whereas a heterogenous population comprises a grafted population of two or more different polymers.

Abstract: The present invention relates generally to a polymer having co-continuous architecture. More particularly, the present invention is directed to a single or plurality of polymer layers in polymeric, co-polymeric, hybrid or blend formation comprising at least one polymer layer having co-continuous architecture. The co-continuous architecture of the one or more polymers permits or otherwise facilitates accessibility of functional groups to an external environment or at least one polymeric layer. The accessible, i.e. co-continuous, nature of the functional groups, in or on the one or more polymers facilitates solid phase chemical processes, chromatography and ion exchange applications. The one or more polymers may also be used as a solid support for a range of diagnostic applications.

Abstract: The present invention relates generally to a grafting process comprising the formation of a grafted polymeric structure having a substrate polymer in hybrid formation with one or more of the same or other polymers or monomeric subunits thereof. More particularly, the present invention contemplates a method of generating a homogenous or heterogenous grafted polymer by inducing or otherwise facilitating free radical formation to initiate polymerization of monomer units corresponding to the same or different polymers to a substrate polymer previously subjected to physical stress means. The resulting hybrid polymer may comprise a substrate polymer and a population of a second or further polymers in homogenous or heterogenous hybrid formation with the substrate polymer. A homogenous population includes a grafted population of the same polymer whereas a heterogenous population comprises a grafted population of two or more different polymers.

Abstract: The present invention generally relates to polymers, including substrate polymers and hybrid polymers, having co-continuous architecture. The co-continuous architecture of the polymers of the present invention facilitates accessibility of functional groups to an external environment thereby making the polymers useful for a number of applications including solid phase chemistry, chromatography, and diagnostics. The present invention provides a number of methods for generating substrate polymers and hybrid polymers having co-continuous architecture including methods of grafting and macroporous formulation.

Abstract: A synthesis member preferably comprises two elements: a crown and a stem. The stem includes a tag, such as a transponder, that is used to identify the synthesis member and/or the synthetic history of the synthesis member when used in the automated synthesis of compound libraries containing large numbers (e.g. 1000 or more) compounds. The crown provides the location at which compounds are synthesized. The combination of a crown for use with compound synthesis and stem allows the tracking of individual synthesis members from a library containing thousands of such synthesis members. Because each synthesis member is individually tracked and can be logged into a database and/or process flow control system, the synthesis of several thousand individual compounds in conventional containers, such as round bottom flasks is made possible using only traditional compound synthesis approaches.