Abstract: Disclosed are peptide conjugates comprising an active agent, a spacer moiety, and a dimeric collagen hybridizing peptide comprising a first and second collagen hybridizing peptide, a linker; and a branch point, wherein the first and second collagen hybridizing peptides comprise the sequence of at least (GXY)n, wherein G is glycine, wherein X and Y are any amino acid, and wherein n is any number between 3 and 12. Also disclosed are methods of detecting denatured collagen in a sample comprising contacting a composition comprising any one of the disclosed peptide conjugates to a sample, wherein the active agent comprises a therapeutic agent, and detecting the presence or absence of binding of the peptide conjugate to denatured collagen, the presence of binding indicating the presence of denatured collagen in the sample.

Abstract: Disclosed are methods of enriching collagen fragments in a sample comprising combining a sample comprising collagen fragments with a composition comprising any one of the dimeric CHPs described herein, and wherein the first CHP and second CHP bind to and form a triple helix with a collagen fragment; and removing the bound collagen fragments from the dimeric CHP providing a product enriched with collagen fragments. Disclosed are methods of detecting collagen in a sample comprising enriching collagen fragments from a sample, wherein enriching the collagen fragments comprises combining a sample comprising collagen fragments with a composition comprising a dimeric CHP, wherein the dimeric CHP comprises a first CHP and a second CHP, one or more linkers, and a branch point, wherein the collagen fragments bind the dimeric CHP; and detecting the binding of the collagen fragments to the dimeric CHP.

Abstract: Disclosed are peptide conjugates comprising an active agent, a spacer moiety, and a dimeric collagen hybridizing peptide comprising a first and second collagen hybridizing peptide, a linker; and a branch point, wherein the first and second collagen hybridizing peptides comprise the sequence of at least (GXY)n, wherein G is glycine, wherein X and Y are any amino acid, and wherein n is any number between 3 and 12. Also disclosed are methods of detecting denatured collagen in a sample comprising contacting a composition comprising any one of the disclosed peptide conjugates to a sample, wherein the active agent comprises a therapeutic agent, and detecting the presence or absence of binding of the peptide conjugate to denatured collagen, the presence of binding indicating the presence of denatured collagen in the sample.

Abstract: Disclosed are peptide conjugates comprising an active agent, a spacer moiety, and a dimeric collagen hybridizing peptide comprising a first and second collagen hybridizing peptide, a linker; and a branch point, wherein the first and second collagen hybridizing peptides comprise the sequence of at least (GXY)n, wherein G is glycine, wherein X and Y are any amino acid, and wherein n is any number between 3 and 12. Also disclosed are methods of detecting denatured collagen in a sample comprising contacting a composition comprising any one of the disclosed peptide conjugates to a sample, wherein the active agent comprises a therapeutic agent, and detecting the presence or absence of binding of the peptide conjugate to denatured collagen, the presence of binding indicating the presence of denatured collagen in the sample.

Abstract: The present invention provides both a caged collagen mimetic peptide (CCMP) having the formula: L-S-Zm-[Gly-X-Y]n-LGly-X-Y-[Gly-X-Y]n (SEQ ID NO: 19); wherein L is one or more detectable moieties; S is one or more spacer molecules; Zm is any amino acid where m is an integer of 1 to 10; X is proline or modified proline; Y is proline or modified proline; Gly is glycine; n is an integer from 1 to 20; and LGly is a glycine covalently linked to a cage moiety comprising a labile protecting group, as well as a collagen mimetic peptides lacking the labile protecting group (CMP). The inventions are useful for binding collagen and denatured collagen and/or gelatin both in vitro and in vivo, and are useful for targeting any organ or tissue where collagen is present, and can be used for research and diagnostic imaging (both in vivo and in vitro) and also for in vivo therapeutic applications.

Abstract: Disclosed are peptide conjugates comprising an active agent, a spacer moiety, and a dimeric collagen hybridizing peptide comprising a first and second collagen hybridizing peptide, a linker; and a branch point, wherein the first and second collagen hybridizing peptides comprise the sequence of at least (GXY)n, wherein G is glycine, wherein X and Y are any amino acid, and wherein n is any number between 3 and 12. Also disclosed are methods of detecting denatured collagen in a sample comprising contacting a composition comprising any one of the disclosed peptide conjugates to a sample, wherein the active agent comprises a therapeutic agent, and detecting the presence or absence of binding of the peptide conjugate to denatured collagen, the presence of binding indicating the presence of denatured collagen in the sample.

Abstract: Techniques for controlling alignment of conditions between modular functional blocks in an integrated circuit having a hierarchical network of modular functional blocks. The output of each functional block can be logically determined by its external inputs combined with internal state feedback and internal state and is derived from a pattern of prior external inputs. Alignment of output conditions from independent and interdependent functional blocks within the hierarchical network of functional blocks is induced to provide unique conditions by modifying internal state and timing alignments with internal data and internal controls within one or more of the modular functional blocks. Functional outputs from one or more of the modular functional blocks can be monitored based on the modified internal state and timing alignments. Pattern results can be generated based on the monitoring. Test results based on the pattern results can be stored.