The present invention relates to a kit for radiolabelling a targeting agent with gallium-68. The present invention also relates to the use of said kit for radiolabelling a targeting agent, a method for radiolabelling a targeting agent with gallium-68 using said kit, said kit and a method of preparation.

New chelators such as H.sub.3L1, H.sub.3L2, H.sub.3L3, H.sub.3L26 and derivatives were synthesized for the complexation of {Al.sup.18F}.sup.2+. These new chelators are able to complex {AI.sup.18F}.sup.2+ with good radiochemical yields using a labeling temperature of 37° C. The stability of the new Al.sup.18F-complexes was tested in phosphate buffered saline (PBS) at pH 7 and in rat serum. AI.sup.18F-L3 and AI.sup.18F-L26 showed a stability comparable to that of the previously reported Al.sup.18F-NODA. Moreover, the biodistribution of Al.sup.18F-L3 and AI.sup.18F-L26 showed absence of in vivo demetallation since only very limited bone uptake was observed, whereas the major fraction of activity 60 min p.i. was observed in liver and intestine due to hepatobiliary clearance of the radiolabeled ligand. The chelators H.sub.3L3 and Al.sup.18F-L26 demonstrated to be a good lead candidates for the labeling of heat sensitive biomolecules with .sup.18F-fluorine and derivatives have been synthesized. We have explored the complexation of {AI.sup.18F}.sup.2+ with new chelators and obtained very favourable radiochemical yields (>85%) using a labeling temperature of 37° C. The stability of the new Al.sup.18F-complexes was tested in phosphate buffered saline (PBS) at pH 7 and in rat serum at 37° C., where AI.sup.18F-L3 and AI.sup.18F-L26 showed a stability comparable to that of the previously reported Al.sup.18F-NODA. Moreover, the biodistribution of Al.sup.18F-L3 and Al.sup.18F-L26 showed high stability, since only very limited bone uptake—which would be an indication of release of fluorine-18 in the form of fluoride—was observed, whereas the major fraction of activity 60 min p.i. was observed in liver and intestines due to hepatobiliary clearance of the radiolabeled ligand. The chelators H.sub.3L3 and H.sub.3L26 demonstrated to be good lead candidates for the labeling of heat sensitive biomolecules with .sup.18F-fluorine and several derivatives have been synthesized.

The present invention relates to the field of radiopharmaceuticals for in vivo imaging, in particular to radiotracer compositions which comprises .sup.18F-labelled c-Met binding peptides. The invention provides said compositions, as well as associated automated methods of preparation and cassettes.

The present invention relates to a method for radioiodination or radioastatination of a biomolecule such as proteins and antibodies by reacting a biomolecule carrying a hetero(aryl) boronic acid group with a radioiodide or astatide salt, in the presence of a catalyst and a ligand, in a buffer solution, in order to obtain a radioiodo- or astatolabeled biomolecule. The method of the invention is thus a single step method easy to be implemented and efficient for both radioiodination and radioastatination of antibodies.

The present invention relates to a compound according to formula (V): or a pharmaceutically acceptable salt thereof, optionally containing a chelated radioactive cation and wherein F is optionally .sup.18F.

##STR00001##

The present disclosure relates to a method for labeling a radioisotope, a radiolabeling compound, a kit including the same, and a method for labeling a radioisotope, including: providing a diaminophenyl compound represented by Chemical Formula I below and including a biomolecule, a fluorescent dye or a nanoparticle compound bound thereto; and reacting the diaminophenyl compound and a radioisotope-labeled aldehyde compound represented by Chemical Formula II below at room temperature; and a related technology: ##STR00001## in Chemical Formula I, A is CH.sub.2 or O; a is 0 or an integer of 1 to 10; X is CH.sub.2 or —CONH—; Y is CH.sub.2 or ##STR00002##  and Z is the biomolecule, the fluorescent dye or the nanoparticle compound, ##STR00003## in Chemical Formula II, b is 0 or an integer of 1 to 10; and L is CH.sub.2 or —CONH—; and Q is ##STR00004## M, M′ and M″ in Q are radioisotopes.

The present invention refers to reagents and methods for preparing a peptide sequence having a [.sup.18F]fluoro-aromatic amino acid side which may be further substituted, in particular a 4-[.sup.18F]fluoro-phenylalanine side chain in peptide sequences, by chemoselective radio-deoxyfluorination of an aromatic amino acid residue, in particular a tyrosine residue using a traceless-activating group and the reagents used in said process.

A binding moiety (B) for Carbonic Anhydrase IX (CAIX), the binding moiety comprising:

##STR00001##

The binding moiety is univalent, bivalent, or multivalent. A targeted therapeutic agent may comprise the binding moiety. The invention also includes a method for treating a disease expressing elevated levels of CAIX by administering the targeted therapeutic agent.

The present invention relates to probes for use in the detection, imaging, diagnosis, targeting, treatment, etc. of cancers expressing the gastrin releasing peptide receptor (GRPR). For example, such probes may be molecules conjugated to detectable labels which are preferably moieties suitable for detection by gamma imaging and SPECT or by positron emission tomography (PET) or magnetic resonance imaging (MRI) or fluorescence spectroscopy or optical imaging methods.

The present invention relates the use of metal inhibitor in radiolabelling reactions using radioactive metals.