Methods of identifying surrogate imaging agents for alpha emitter radiopharmaceuticals and their use in treatment of disease

1 . An imaging surrogate composition comprising: a) at least one detectable moiety conjugated to a targeting moiety, wherein the imaging surrogate composition has a pharmacokinetic profile which is significantly similar to an alpha-emitting radionuclide conjugated to the same targeting moiety (alphaRPT); b) wherein the pharmacokinetic profile of the imaging surrogate is determined by comparing the pharmacokinetic profile of the imaging surrogate to the pharmacokinetic profile of the alphaRPT in one or more preclinical models; and c) wherein the imaging surrogate composition derived alphaRPT dosimetry is within 1-20% of directly calculated alphaRPT dosimetry to a dose-limiting organ in said one or more preclinical models. 2 .- 3 . (canceled) 4 . The imaging surrogate composition of claim 1 , wherein the detectable moiety of the imaging surrogate composition is selected from the group consisting of 18 F, 11 C, 13 N and 15 O, 75 Br, 76 Br, 124 I, 201 Tl, 99m Tc, 123 I, 111 In, 68 Ga, 64 Cu, 89 Zr and 131 I. 5 . The imaging surrogate composition of claim 1 , wherein the imaging surrogate composition comprises 111 In and has a pharmacokinetic profile which is significantly similar to an alphaRPT comprising 213 Bi, or 225 Ac, or 212 Pb. 6 . The imaging surrogate composition of claim 1 , wherein the imaging surrogate composition is elected from the group consisting of 131 I, 123 I, or 124 I and has a pharmacokinetic profile which is significantly similar to an alphaRPT comprising 211 At. 7 . The imaging surrogate composition of claim 6 , wherein the imaging surrogate composition comprises 131 I and has a pharmacokinetic profile which is significantly similar to an alphaRPT comprising 211 At. 8 . The imaging surrogate composition of claim 1 , wherein the imaging surrogate composition comprises 89 Zr and has a pharmacokinetic profile which is significantly similar to an alphaRPT comprising 225 Ac. 9 .- 12 . (canceled) 13 . A method for determining an appropriate dosage level of an alphaRPT of interest in a subject comprising: a) administering an imaging surrogate composition to the subject, wherein the imaging surrogate comprises at least one detectable moiety conjugated to a targeting moiety, and wherein the imaging surrogate composition has a pharmacokinetic profile which is significantly similar to an alphaRPT comprising the same targeting moiety labeled with alpha-emitting isotope; b) measuring the pharmacokinetic profile of the imaging surrogate composition in the subject using radionuclide imaging; c) if necessary, performing pharmacokinetic modeling to account for differences between the imaging surrogate composition and the alphaRPT; and d) determining the appropriate dosage level of the alphaRPT of interest for the subject. 14 . the method of claim 13 , wherein the imaging surrogate comprises 111 In or 68 Ga or 89 Zr conjugated to a targeting moiety, and wherein the imaging surrogate composition has a pharmacokinetic profile which is significantly similar to an alphaRPT conjugated to the same targeting moiety labeled with an alpha-emitting isotope selected from the group consisting of 213 Bi, 225 Ac and 212 Pb. 15 . the method of claim 13 , a wherein the imaging surrogate comprises 131 I conjugated to a targeting moiety, and wherein the imaging surrogate composition has a pharmacokinetic profile which is significantly similar to an alphaRPT conjugated to the same targeting moiety labeled with 211 At. 16 . A method of treatment of a disease in a subject comprising: a) administering an imaging surrogate composition to the subject, wherein the imaging surrogate comprises at least one detectable moiety conjugated to a targeting moiety, and wherein the imaging surrogate composition has a pharmacokinetic profile which is significantly similar to an alphaRPT comprising the same targeting moiety labeled with alpha-emitting isotope; b) measuring the pharmacokinetic profile of the imaging surrogate in the subject using imaging; c) if necessary, performing pharmacokinetic modeling to account for differences between the imaging surrogate and the alphaRPT; d) using the information from b) and/or c) to determine the appropriate dosage level of the alphaRPT of interest for the subject; and e) administering to the subject the alphaRPT of interest at the dosage level determined in d) to treat the disease in the subject. 17 . The method of claim 16 , wherein the disease is selected from the group consisting of cancer, autoimmune disease, trigeminal neuralgia, acoustic neuromas, severe thyroid eye disease, pterygium, pigmented villonodular synovitis, atherosclerotic plaques, prevention of keloid scar growth, vascular restenosis, and heterotopic ossification. 18 . The method of claim 16 , wherein the disease is cancer and the imaging surrogate is a targeting moiety conjugated with 131 I or 123 I or 124 I, and wherein the alphaRPT comprises the same targeting moiety conjugated with an alpha-emitting isotope selected from the group consisting of 213 Bi, 225 Ac and 212 Pb. 19 . The method of claim 16 , wherein the disease is cancer and the imaging surrogate is a targeting moiety conjugated with 131 I or 123 I or 124 I, and wherein the alphaRPT comprises the same targeting moiety conjugated with 211 At. 20 . The method of claim 16 , wherein the disease is OS and the imaging surrogate is [ 89 Zr]Zr-DFO-trastuzumab and the alphaRPT is 225 Ac-DOTA-trastuzumab. 21 . The method of claim 16 , wherein the pharmacokinetic profile of the imaging surrogate in the subject is measured using planar or SPECT or PET imaging.