Targeted molecular imaging agents (TMIAs) are derived from coupling together pre-formed amino acids with imaging agents attached to their side chains. These peptide-based imaging agents may be synthesized from a single or multiple preformed amino acids containing multi-modal, multi-chelated metal, multi-dye imaging agents, or combinations of these, on the side chains of resultant peptides. These imaging amino acids or peptides may be conjugated directly, or activated, or attached to linkers to which targeting groups, such as peptides, proteins, antibodies, aptamers, or small molecule inhibitors, may be conjugated in the final steps of the synthesis to form a wide variety of TMIAs.

The present disclosure provides an isolated, engineered or non-naturally occurring protein comprising an antibody light chain variable domain (V.sub.L) which may comprise at least one negatively charged amino acid positioned between residues 49 to 56 according to the numbering system of Kabat, the protein capable of binding specifically to an antigen.

The present disclosure provides an isolated, engineered or non-naturally occurring protein comprising an antibody light chain variable domain (V.sub.L) which may comprise at least one negatively charged amino acid positioned between residues 49 to 56 according to the numbering system of Kabat, the protein capable of binding specifically to an antigen.

Compounds of general formula (1): X1Y1X2Y2X3Y3X4Y4Y5X5X6Y6X7Y7X8X9X10 wherein X1-X10 are any natural or unnatural amino acids and Y1 is Gln; Y2 is Met or Leu; Y3 is He; Y4 is Pro or Ser; Y5 is His or Gly; Y6 is Gln or Pro; Y7 is He or Tyr or their homolog or ortolog are described; these compounds are able to bind to the VEGF receptors and to modulate the angiogenesis mediated by the VEG.

Compounds of general formula (1): X1Y1X2Y2X3Y3X4Y4Y5X5X6Y6X7Y7X8X9X10 wherein X1-X10 are any natural or unnatural amino acids and Y1 is Gln; Y2 is Met or Leu; Y3 is He; Y4 is Pro or Ser; Y5 is His or Gly; Y6 is Gln or Pro; Y7 is He or Tyr or their homolog or ortolog are described; these compounds are able to bind to the VEGF receptors and to modulate the angiogenesis mediated by the VEG.

Spin labeled ice binding compounds (IBCs) including ice binding proteins (IBPs), also called antifreeze proteins (AFPs) and their analogs are exploited to carry the paramagnetic centers for dynamic nuclear polarization (DNP), for enhancing nuclear magnetic resonance (NMR) signal intensities. Use of spin labeled IBCs to perform DNP exploits the IBCs' ability to homogeneously distribute the paramagnetic centers in frozen water solution at low temperature, leading to high DNP efficiency. Other advantages of using spin labeled IBCs include: (1) ability to cryo-protect biological samples; (2) the relative positions and orientations of the spin labeling groups in an IBC may also be cryo-preserved; (3) positions and orientations of spin labeling groups to an IBC can be selected with great freedom and without technical barrier to making multiple spin labels in an IBC; and (4) water solubilities of spin labeled IBCs are potentially high, enabling use of a solvent that is primarily water for DNP at low temperatures.

Spin labeled ice binding compounds (IBCs) including ice binding proteins (IBPs), also called antifreeze proteins (AFPs) and their analogs are exploited to carry the paramagnetic centers for dynamic nuclear polarization (DNP), for enhancing nuclear magnetic resonance (NMR) signal intensities. Use of spin labeled IBCs to perform DNP exploits the IBCs' ability to homogeneously distribute the paramagnetic centers in frozen water solution at low temperature, leading to high DNP efficiency. Other advantages of using spin labeled IBCs include: (1) ability to cryo-protect biological samples; (2) the relative positions and orientations of the spin labeling groups in an IBC may also be cryo-preserved; (3) positions and orientations of spin labeling groups to an IBC can be selected with great freedom and without technical barrier to making multiple spin labels in an IBC; and (4) water solubilities of spin labeled IBCs are potentially high, enabling use of a solvent that is primarily water for DNP at low temperatures.

The present invention discloses hydrophobin mimics of formula (I) comprising a protein head group, hydrophilic linker and hydrophobic tail and to a process for synthesis of library of hydrophobin mimics thereof. The hydrophobin mimics of the present invention self-assemble to form protein nanoparticles/nanocontainer either alone or in a specified chemical environment. The hydrophobin mimics (I) of the present invention find application in area of bio-nanotechnology.

A compound includes at least one targeting peptide coupled to a detectable moiety. The targeting peptide binds to EDB-FN or EDA-FN and includes at least one of amino acid sequence selected from the group consisting of SEQ ID NOs: 1-30.

A compound includes at least one targeting peptide coupled to a detectable moiety. The targeting peptide binds to EDB-FN or EDA-FN and includes at least one of amino acid sequence selected from the group consisting of SEQ ID NOs: 1-30.