Design and synthesis of astatinated benzothiazole compounds for their potential use in Targeted Alpha Therapy (TAT) strategies to treat Alzheimer's disease-associated amyloid plaques.

PURPOSE: Alzheimer's disease (AD) is a terminal neurodegenerative disease characterized by the buildup of amyloid fibrils, amorphous aggregates and tauopathies. Several treatment modalities, which rely on various biological processes to reduce disease burden, have been largely ineffective at treating Alzheimer's disease. Targeted alpha therapy (TAT) has demonstrated positive results in the treatment of cancer. Benzothiazole derivatives have been successfully shown to target these plaques and are used in several imaging applications. One such derivative, Flutemetamol (VizamylTM) is an FDA approved diagnostic tool for PET imaging of AD-associated plaques. We report the radiolabeling of benzothiazole derivatives with 211At, a 7.2 h alpha emitting radionuclide, using a copper catalyzed reaction with a boronic acid precursor molecule. Our final compound [211At]3'-At-PIB-OMe had a radiochemical yield of 55% and was found to be stable for at least 3 h in phosphate buffered saline.

Oxidation of p-[125I]Iodobenzoic Acid and p-[211At]Astatobenzoic Acid Derivatives and Evaluation In Vivo.

The alpha particle-emitting radionuclide astatine-211 (211At) is of interest for targeted radiotherapy; however, low in vivo stability of many 211At-labeled cancer-targeting molecules has limited its potential. As an alternative labeling method, we evaluated whether a specific type of astatinated aryl compound that has the At atom in a higher oxidation state might be stable to in vivo deastatination. In the research effort, para-iodobenzoic acid methyl ester and dPEG4-amino acid methyl ester derivatives were prepared as HPLC standards. The corresponding para-stannylbenzoic acid derivatives were also prepared and labeled with 125I and 211At. Oxidization of the [125I]iodo- and [211At]astato-benzamidyl-dPEG4-acid methyl ester derivatives provided materials for in vivo evaluation. A biodistribution was conducted in mice with coinjected oxidized 125I- and 211At-labeled compounds. The oxidized radioiodinated derivative was stable to in vivo deiodination, but unfortunately the oxidized [211At]astatinated benzamide derivative was found to be unstable under the conditions of isolation by radio-HPLC (post animal injection). Another biodistribution study in mice evaluated the tissue concentrations of coinjected [211At]NaAtO3 and [125I]NaIO3. Comparison of the tissue concentrations of the isolated material from the oxidized [211At]benzamide derivative with those of [211At]astatate indicated the species obtained after isolation was likely [211At]astatate.

Evaluation of radioiodinated protein conjugates and their potential metabolites containing lysine-urea-glutamate (LuG), PEG and closo-decaborate(2-) as models for targeting astatine-211 to metastatic prostate cancer.

INTRODUCTION: The use of lysine-urea-glutamate (LuG) for targeting the PSMA antigen on prostate cancer (PCa) is a promising method for delivering the alpha particle-emitting radionuclide astatine-211 (211At) to metastatic PCa. High kidney localization has been a problem with radiolabeled LuG derivatives, but has been adequately addressed in radiometal-labeled DOTA-LuG derivatives by linker optimization. Herein, we report an investigation of an alternate approach to diminishing the kidney concentrations of radiolabeled LuG-containing compounds. METHODS: Our approach involves PEGylated LuG moieties and closo-decaborate (2-) moieties conjugated to streptavidin (SAv) or human serum albumin (HSA). After preparing the LuG conjugates, SAv and HSA conjugates were succinylated to decrease their kidney localization and radioiodinated for evaluation in athymic mice bearing C4-2B osseous PCa tumor xenografts. RESULTS: Covalently attaching LuG to succinylated SAv and HSA significantly reduced kidney localization, but unfortunately succinylation resulted in decreased tumor concentrations. In contrast, a potential metabolite [131I]16b, an unconjugated LuG derivative containing a dPEG4® linker, provided tumor concentrations of ~15% ID/g at 4 h pi. A second unconjugated LuG derivative with a similar structure, but containing a dPEG12® linker, [131I]16a had tumor concentrations of ~4%ID/g at 4 h pi. Those results suggest that long PEG linkers also affect tumor localization in a negative manner. CONCLUSION: Conjugation of PEGylated LuG derivatives to proteins can be an effective approach to diminishing kidney localization of radiolabeled LuG reagents, but the protein, linker and the method of linkage need to be further studied. Additionally, modification of the unconjugated 16b to decrease kidney localization may provide PCa targeting agents for use with radiohalogens, including 211At. Advances in knowledge and implications for patient care: This study is the first to evaluate PEGylated LuG and closo-decaborate (2-) moieties conjugated to proteins as potential methods for diminishing the kidney concentrations of radiolabeled LuG-containing compounds.

Thorium chelators for targeted alpha therapy: Rapid chelation of thorium-226.

One of the main challenges in targeted alpha therapy is assuring delivery of the α-particle dose to the targeted cells. Thus, it is critical to identify ligands for α-emitting radiometals that will form complexes that are very stable, both in vitro and in vivo. In this investigation, thorium-227 (t1/2 = 18.70 days) chelation of ligands containing hydroxypyridinonate (HOPO) or picolinic acid (pa) moieties and the stability of the resultant complexes were studied. Chelation reactions were followed by reversed-phased HPLC and gamma spectroscopy. Studies revealed that high 227 Th chelation yields could be obtained within 2.5 h or less with ligands containing four Me-3,2-HOPO moieties, 1 (83%) and 2 (65%), and also with ligands containing pa moieties, H4 octapa 3 (65%) and H4 py4pa 6 (87%). No reaction occurred with H4 neunpa-p-Bn-NO2 4, and the chelation reaction with another pa ligand H4 pypa 5 gave inconsistent yields with a very broad radio-HPLC peak. The ligands spermine-(Me-3,2-HOPO)4 1, H4 octapa 3, and H4 py4pa 6 had high stability (i.e., 87% of 227 Th still bound to the ligand) in phosphate-buffered saline at room temperature over a 6-day period. Preliminary studies with ligand 6 demonstrated efficient chelation of thorium-226 (t1/2 = 30.57 min) when heated to 80°C for 5 min.

Investigation of a tellurium-packed column for isolation of astatine-211 from irradiated bismuth targets and demonstration of a semi-automated system.

Astatine-211 is an attractive radionuclide for use in targeted alpha therapy of blood-borne diseases and micrometastatic diseases. Efficient isolation methods that can be adapted to robust automated 211At isolation systems are of high interest for improving the availability of 211At. Based on the early studies of Bochvarova and co-workers involving isolation of 211At from irradiated thorium targets, we developed a method for 211At isolation from bismuth targets using tellurium-packed columns. Dissolution of irradiated bismuth targets is accomplished using HNO3; however, 211At is not captured on the Te column material in this matrix. Our method involves slow addition of aqueous NH2OH·HCl to the Bi target dissolved in HNO3 to convert to a HCl matrix. The amount of NH2OH·HCl was optimized because (1) the quantity of NH2OH·HCl used appears to affect the radiolabeling yield of phenethyl-closo-decaborate(2-) (B10)-conjugated antibodies and (2) reducing the volume of NH2OH·HCl solution can effectively shorten the overall isolation time. A proof-of-concept semi-automated process has been demonstrated using targets containing ~0.96 GBq (~26 mCi) of 211At. High isolation yields (88-95%) were obtained. Radiochemical purity of the isolated 211At was assessed by radio-HPLC. Concentrations of Bi and Te contaminants in the 211At and the astatinated antibodies were evaluated using ICP-MS.

cGMP production of astatine-211-labeled anti-CD45 antibodies for use in allogeneic hematopoietic cell transplantation for treatment of advanced hematopoietic malignancies.

The objective of this study was to translate reaction conditions and quality control methods used for production of an astatine-211(211At)-labeled anti-CD45 monoclonal antibody (MAb) conjugate, 211At-BC8-B10, from the laboratory setting to cGMP production. Five separate materials were produced in the preparation of 211At-BC8-B10: (1) p-isothiocyanato-phenethyl-closo-decaborate(2-) (B10-NCS), (2) anti-CD45 MAb, BC8, (3) BC8-B10 MAb conjugate, (4) [211At]NaAt, and (5) 211At-BC8-B10. The 211At-labeling reagent, B10-NCS, was synthesized as previously reported. BC8 was produced, then conjugated with B10-NCS under cGMP conditions to form BC8-B10. [211At]NaAt was produced by α-irradiation of Bi targets, followed by isolation of the 211At using a "wet chemistry" method. The clinical product, 211At-BC8-B10, was prepared by reacting [211At]NaAt with BC8-B10 in NH4OAc buffer (pH 5.5) for 2 min at room temperature, followed by size-exclusion chromatography purification. Quality control tests conducted on the 211At-BC8-B10 included evaluations for purity and identity, as well as pyrogen and sterility tests. Stability of the 211At-BC8-B10 in 25 mg/mL sodium ascorbate solution was evaluated at 1, 2, 4, 6 and 21 h post isolation. For qualification, three consecutive 211At-BC8-B10 clinical preparations were successfully conducted in the cGMP suite, and an additional cGMP clinical preparation was carried out to validate each step required to deliver 211At-BC8-B10 to a patient. These cGMP preparations provided 0.80-1.28 Gbq (21.5-34.5 mCi) of 211At-BC8-B10 with radiochemical purity of >97%. The preparations were found to be sterile and have a pyrogen level <0.50 EU/mL. Cell binding was retained by the 211At-BC8-B10. 211At-BC8-B10 in ascorbic acid solution demonstrated a radiochemical stability of >95% for up to 21 h at room temperature. The experiments conducted have defined conditions for translation of 211At-BC8-B10 production from the laboratory to cGMP suite. This study has allowed the initiation of a phase I/II clinical trial using 211At-BC8-B10 (NCT03128034).

Reagents for astatination of biomolecules. 6. An intact antibody conjugated with a maleimido-closo-decaborate(2-) reagent via sulfhydryl groups had considerably higher kidney concentrations than the same antibody conjugated with an isothiocyanato-closo-decaborate(2-) reagent via lysine amines.

We are investigating the use of an (211)At-labeled anti-CD45 monoclonal antibody (mAb) as a replacement of total body irradiation in conditioning regimens designed to decrease the toxicity of hematopoietic cell transplantation (HCT). As part of that investigation, dose-escalation studies were conducted in dogs using (211)At-labeled anticanine CD45 mAb, CA12.10C12, conjugated with a maleimido-closo-decaborate(2-) derivative, 4. Unacceptable renal toxicity was noted in the dogs receiving doses in the 0.27-0.62 mCi/kg range. This result was not anticipated, as no toxicity had been noted in prior biodistribution and toxicity studies conducted in mice. Studies were conducted to understand the cause of the renal toxicity and to find a way to circumvent it. A dog biodistribution study was conducted with (123)I-labeled CA12.10C12 that had been conjugated with 4. The biodistribution data showed that 10-fold higher kidney concentrations were obtained with the maleimido-conjugate than had been obtained in a previous biodistribution study with (123)I-labeled CA12.10C12 conjugated with an amine-reactive phenylisothiocyanato-CHX-A″ derivative. The difference in kidney concentrations observed in dogs for the two conjugation approaches led to an investigation of the reagents. SE-HPLC analyses showed that the purity of the CA12.10C12 conjugated via reduced disulfides was lower than that obtained with amine-reactive conjugation reagents, and nonreducing SDS-PAGE analyses indicated protein fragments were present in the disulfide reduced conjugate. Although we had previously prepared closo-decaborate(2-) derivatives with amine-reactive functional groups (e.g., 6 and 8), a new, easily synthesized, amine-reactive (phenylisothiocyanate) derivative, 10, was prepared for use in the current studies. A biodistribution was conducted with coadministered (125)I- and (211)At-labeled CA12.10C10 conjugated with 10. In that study, lower kidney concentrations were obtained for both radionuclides than had been obtained in the earlier study of the same antibody conjugated with 4 after reduction of disulfide bonds.

Reagents for astatination of biomolecules. 5. Evaluation of hydrazone linkers in (211)At- and (125)I-labeled closo-decaborate(2-) conjugates of Fab' as a means of decreasing kidney retention.

Evaluation of monoclonal antibody (mAb) fragments (e.g., Fab', Fab, or engineered fragments) as cancer-targeting reagents for therapy with the α-particle emitting radionuclide astatine-211 ((211)At) has been hampered by low in vivo stability of the label and a propensity of these proteins localize to kidneys. Fortunately, our group has shown that the low stability of the (211)At label, generally a meta- or para-[(211)At]astatobenzoyl conjugate, on mAb Fab' fragments can be dramatically improved by the use of closo-decaborate(2-) conjugates. However, the higher stability of radiolabeled mAb Fab' conjugates appears to result in retention of radioactivity in the kidneys. This investigation was conducted to evaluate whether the retention of radioactivity in kidney might be decreased by the use of an acid-cleavable hydrazone between the Fab' and the radiolabeled closo-decaborate(2-) moiety. Five conjugation reagents containing sulfhydryl-reactive maleimide groups, a hydrazone functionality, and a closo-decaborate(2-) moiety were prepared. In four of the five conjugation reagents, a discrete poly(ethylene glycol) (PEG) linker was used, and one substituent adjacent to the hydrazone was varied (phenyl, benzoate, anisole, or methyl) to provide varying acid sensitivity. In the initial studies, the five maleimido-closo-decaborate(2-) conjugation reagents were radioiodinated ((125)I or (131)I), then conjugated with an anti-PSMA Fab' (107-1A4 Fab'). Biodistributions of the five radioiodinated Fab' conjugates were obtained in nude mice at 1, 4, and 24 h post injection (pi). In contrast to closo-decaborate(2-) conjugated to 107-1A4 Fab' through a noncleavable linker, two conjugates containing either a benzoate or a methyl substituent on the hydrazone functionality displayed clearance rates from kidney, liver, and spleen that were similar to those obtained with directly radioiodinated Fab' (i.e., no conjugate). The maleimido-closo-decaborate(2-) conjugation reagent containing a benzoate substituent on the hydrazone was chosen for study with (211)At. That reagent was conjugated with 107-1A4 Fab', then labeled (separately) with (125)I and (211)At. The radiolabeled Fab' conjugates were coinjected into nude mice bearing LNCaP human tumor xenografts, and biodistribution data were obtained at 1, 4, and 24 h pi. Tumor targeting was achieved with both (125)I- and (211)At-labeled Fab', but the (211)At-labeled Fab' reached a higher concentration (25.56 ± 11.20 vs 11.97 ± 1.31%ID/g). Surprisingly, while the (125)I-labeled Fab' was cleared from kidney similar to earlier studies, the (211)At-labeled Fab'was not (i.e., kidney conc. for (125)I vs (211)At; 4 h, 13.14 ± 2.03 ID/g vs 42.28 ± 16.38%D/g; 24 h, 4.23 ± 1.57 ID/g vs 39.52 ± 15.87%ID/g). Since the Fab' conjugate is identical in both cases except for the radionuclide, it seems likely that the difference in tissue clearance seen is due to an effect that (211)At has on either the hydrazone cleavage or on the retention of a metabolite. Results from other studies in our laboratory suggest that the latter case is most likely. The hydrazone linkers tested do not provide the tissue clearance sought for (211)At, so additional hydrazones linkers will be evaluated. However, the results support the use of hydrazone linkers when Fab' conjugated with closo-decaborate(2-) reagents are radioiodinated.

Design and synthesis of bis-biotin-containing reagents for applications utilizing monoclonal antibody-based pretargeting systems with streptavidin mutants.

Previous studies have shown that pretargeting protocols, using cancer-targeting fusion proteins, composed of 4 anti-CD20 single chain Fv (scFv) fragments and streptavidin (scFv(4)-SAv), followed by a biotinylated dendrimeric N-acetyl-galactosamine blood clearing agent (CA), 1, then a radiolabeled DOTA-biotin derivative (a monobiotin), 3a, can provide effective therapy for lymphoma xenografts in mouse models. A shortcoming in this pretargeting system is that endogenous biotin may affect its efficacy in patients. To circumvent this potential problem, we investigated a pretargeting system that employs anti-CD20 scFv(4)-SAv mutant fusion proteins with radioiodinated bis-biotin derivatives. With that combination of reagents, good localization of the radiolabel to lymphoma tumor xenografts was obtained in the presence of endogenous biotin. However, the blood clearance reagents employed in the studies were ineffective, resulting in abnormally high levels of radioactivity in other tissues. Thus, in the present investigation a bis-biotin-trigalactose blood clearance reagent, 2, was designed, synthesized, and evaluated in vivo. Additionally, another DOTA-biotin derivative (a bis-biotin), 4a, was designed and synthesized, such that radiometals (e.g., (111)In, (90)Y, (177)Lu) could be used in the pretargeting protocols employing scFv(4)-SAv mutant fusion proteins. Studies in mice demonstrated that the CA 2 was more effective than CA 1 at removing [(125)I]scFv(4)-SAv-S45A mutant fusion proteins from blood. Another in vivo study compared tumor targeting and normal tissue concentrations of the new reagents (2 and [(111)In]4b) with standard reagents (1 and [(111)In]3b) used in pretargeting protocols. The study showed that lymphoma xenografts could be targeted in the presence of endogenous biotin when anti-CD20 fusion proteins containing SAv mutants (scFv(4)-SAv-S45A or scFv(4)-SAv-Y43A) were employed in combination with CA 2 and [(111)In]4b. Importantly, normal tissue concentrations of [(111)In]4b were similar to those obtained using the standard reagents (1 and [(111)In]3b), except that the blood and liver concentrations were slightly higher with the new reagents. While the reasons for the higher blood and liver concentrations are unknown, the differences in the galactose structures of the clearance agents 1 and 2 may play a role.

Preparation and in vivo evaluation of radioiodinated closo-decaborate(2-) derivatives to identify structural components that provide low retention in tissues.

INTRODUCTION: In vivo deastatination of (211)At-labeled biomolecules can severely limit their use in endoradiotherapy. Our studies have shown that the use of closo-decaborate(2-) moiety for (211)At-labeling of biomolecules provides high in vivo stability towards deastatination. However, data from those studies have also been suggestive that some astatinated closo-decaborate(2-) catabolites may be retained in tissues. In this study, we investigated the in vivo distributions of several structurally simple closo-decaborate(2-) derivatives to gain information on the effects of functional groups if catabolites are released into the blood system from the carrier biomolecule. METHODS: Thirteen closo-decaborate(2-) derivatives were synthesized and radioiodinated for evaluation. Tissue concentrations of the radioiodinated compounds were obtained in groups of five mice at 1 and 4 h postinjection (pi). Dual-label ((125)I and (131)I) experiments permitted evaluation of two compounds in each set of mice. RESULTS: All of the target compounds were readily synthesized. Radioiodination reactions were conducted with chloramine-T and Na[(125/131)I]I in water to give high yields (75-96%) of the desired compounds. Biodistribution data at 1 and 4 h pi (representing catabolites released into the blood system) showed small differences in tissue concentrations for some compounds, but large differences for others. The results indicate that formal (overall) charge on the compounds could not be used as a predictor of tissue localization or retention. However, derivatives containing carboxylate groups generally had lower tissue concentrations. Acid cleavable hydrazone functionalities appeared to be the best candidates for further study. CONCLUSIONS: Further studies incorporating hydrazone functionalities into pendant groups for biomolecule radiohalogenation are warranted.

Reagents for astatination of biomolecules. 4. Comparison of maleimido-closo-decaborate(2-) and meta-[(211)At]astatobenzoate conjugates for labeling anti-CD45 antibodies with [(211)At]astatine.

An investigation was conducted to compare the in vivo tissue distribution of a rat antimurine CD45 monoclonal antibody (30F11) and an irrelevant mAbs (CA12.10C12) labeled with (211)At using two different labeling methods. In the investigation, the mAbs were also labeled with (125)I to assess the in vivo stability of the labeling methods toward deastatination. One labeling method employed N-hydroxysuccinimidyl meta-[(211)At]astatobenzoate, [(211)At]1c, and N-hydroxysuccinimidyl meta-[(125)I]iodobenzoate, [(125)I]1b, in conjugation reactions to obtain the radiolabeled mAbs. The other labeling method involved conjugation of a maleimido-closo-decaborate(2-) derivative, 2, with sulfhydryl groups on the mAbs, followed by labeling of the mAb-2 conjugates using Na[(211)At]At or Na[(125)I]I and chloramine-T. Concentrations of the (211)At/(125)I pair of radiolabeled mAbs in selected tissues were examined in BALB/c mice at 1, 4, and 24 h post injection (pi). The co-injected anti-CD45 mAb, 30F11, labeled with [(125)I]1b and [(211)At]1c targeted the CD45-bearing cells in the spleen with the percent injected dose (%ID) of (125)I in that tissue being 13.31 ± 0.78; 17.43 ± 2.56; 5.23 ± 0.50; and (211)At being 6.56 ± 0.40; 10.14 ± 1.49; 7.52 ± 0.79 at 1, 4, and 24 h pi (respectively). However, better targeting (or retention) of the (125)I and (211)At was obtained for 30F11 conjugated with the closo-decaborate(2-), 2. The %ID in the spleen of (125)I (i.e., [(125)I]30F11-2) being 21.15 ± 1.33; 22.22 ± 1.95; 12.41 ± 0.75; and (211)At (i.e., [(211)At]30F11-2) being 22.78 ± 1.29; 25.05 ± 2.35; 17.30 ± 1.20 at 1, 4, and 24 h pi (respectively). In contrast, the irrelevant mAb, CA12.10C12, labeled with (125)I or (211)At by either method had less than 0.8% ID in the spleen at any time point, except for [(211)At]CA12.10C12-1c, which had 1.62 ± 0.14%ID and 1.21 ± 0.08%ID at 1 and 4 h pi. The higher spleen concentrations in that conjugate appear to be due to in vivo deastatination. Differences in (125)I and (211)At concentrations in lung, neck, and stomach indicate that the meta-[(211)At]benzoyl conjugates underwent deastatination, whereas the (211)At-labeled closo-decaborate(2-) conjugates were very stable to in vivo deastatination. In summary, using the closo-decaborate(2-) (211)At labeling approach resulted in higher concentrations of (211)At in target tissue (spleen) and higher stability to in vivo deastatination in this model. These findings, along with the simpler and higher-yielding (211)At-labeling method, provide the basis for using the closo-decaborate(2-) labeling reagent, 2, in our continued studies of the application of (211)At-labeled mAbs for conditioning in hematopoietic cell transplantation.

Reagents for astatination of biomolecules. 3. Comparison of closo-decaborate(2-) and closo-dodecaborate(2-) moieties as reactive groups for labeling with astatine-211.

In vivo deastatination has been a major problem in the development of reagents for therapeutic applications of the alpha-particle emitting radionuclide (211)At. Our prior studies demonstrated that the use of a closo-decaborate(2-) ([closo-B(10)H(9)R](2-)) moiety for (211)At labeling of biomolecules provides conjugates that are stable to in vivo deastatination. In this investigation, the closo-decaborate(2-) moiety was compared with the structurally similar closo-dodecaborate(2-) ([closo-B(12)H(11)R](2-)) to determine if one has more favorable properties than the other for use in pendant groups as (211)At labeling molecules. To determine the differences, two sets of structurally identical molecules, with the exception that they contained either a closo-decaborate(2-) or a closo-dodecaborate(2-) moiety, were compared with regard to their synthesis, radiohalogenation, stability to in vivo deastatination and tissue distribution. Quite different rates of reaction were noted in the synthetic steps for the two closo-borate(2-) moieties, but ultimately the yields were similar, making these differences of little importance. Differences in radiohalogenation rates were also noted between the two closo-borate(2-) moieties, with the more electrophilic closo-decaborate(2-) reacting more rapidly. This resulted in somewhat higher yields of astatinated closo-decaborate(2-) derivatives (84% vs 53%), but both cage moieties gave good radioiodination yields (e.g., 79-96%). Importantly, both closo-borate(2-) cage moieties were shown to have high stability to in vivo deastatination. The largest differences between pairs of compounds containing the structurally similar boron cage moieties were in their in vivo tissue distributions. For example, [Et(3)NH](2)B(12)H(10)I-CONHpropyl, [(125)I]2b had high concentrations in kidney (1 h, 19.8%ID/g; 4 h, 26.5%ID/g), whereas [Et(3)NH](2)B(10)H(8)I-CONHpropyl, [(125)I]1e had much lower concentrations in kidney (1 h, 6.6%ID/g; 4 h, 0.27%ID/g). Interestingly, when another salt of the closo-decaborate(2-), [nBu(4)N](2)B(10)H(8)I-CONHpropyl, [(125)I]1b, was evaluated, the route of excretion appeared to be hepatobiliary rather than renal. Identical biotin derivatives containing the two closo-borate(2-) cage moieties had similar tissue distributions, except the closo-decaborate(2-) derivative had lower concentrations in kidney (1 h, 19.9%ID/g; 4 h, 24.4%ID/g vs 1 h, 38.9%ID/g; 4 h, 40.6%ID/g). In summary, the higher reactivity, faster tissue clearance, and lower kidney concentrations make the closo-decaborate(2-) more favorable for further studies using them in reactive groups for (211)At labeling of biomolecules.

Streptavidin in antibody pretargeting. 5. chemical modification of recombinant streptavidin for labeling with the alpha-particle-emitting radionuclides 213Bi and 211At.

We are investigating the use of recombinant streptavidin (rSAv) as a carrier molecule for the short-lived alpha-particle-emitting radionuclides 213Bi ( t 1/2 = 45.6 min) and 211At ( t 1/2 = 7.21 h) in cancer therapy. To utilize rSAv as a carrier, it must be modified in a manner that permits rapid chelation or bonding with these short-lived radionuclides and also modified in a manner that diminishes its natural propensity for localization in the kidney. Modification for labeling with (213)Bi was accomplished by conjugation of rSAv with the DTPA derivative p-isothiocyanato-benzyl-CHX-A'' (CHX-A''), 3a. Modification for direct labeling with 211At was accomplished by conjugation of rSAv with an isothiocyanatophenyl derivative of a nido-carborane (nCB), 3b, or an isothiocyanatophenyl-dPEG/decaborate(2-) derivative, 3c. After conjugation of the chelating or bonding moiety, rSAv was further modified by reaction with an excess (50-100 equivalents) of succinic anhydride. Succinylation of the lysine amines has previously been shown to greatly diminish kidney localization. rSAv modified by conjugation with 3a and succinylated rapidly radiolabeled with 213Bi (<5 min), providing a 72% isolated yield. 211At labeling of modified rSAv was accomplished in aqueous solution using chloramine-T as the oxidant. Astatination of rSAv conjugated with 3b and succinylated occurred very rapidly (<1 min), providing a 50% isolated radiochemical yield. Astatination of rSAv conjugated with 3c and succinylated was also very rapid (<1 min) providing 66-71% isolated radiochemical yields. Astatination of succinylated rSAv, 2a, which did not have conjugated borane cage moieties, resulted in a much lower radiolabeling yield (18%). The 213Bi or 211At-labeled modified rSAv preparations were mixed with the corresponding 125 I-labeled rSAv, and dual-label in vivo distributions were obtained in athymic mice. The in vivo data show that 213Bi-labeled succinylated rSAv [ 213Bi] 6a has tissue concentrations similar to those of 125 I-labeled modified rSAv [ 125 I] 6b, suggesting that (213)Bi is quite stable toward release from the chelate in vivo. In vivo data also indicate that the (211)At-labeled rSAv conjugated with 3b or 3c and succinylated are stable to in vivo deastatination, whereas succinylated rSAv lacking a boron cage moiety is subject to some deastatination. The modified rSAv conjugated with nido-carborane derivative 3b has a higher retention in many tissues than rSAv without the carborane conjugated. Interestingly, the rSAv conjugated with 3c, which also contains an m-dPEG 12 moiety, has significantly decreased concentrations in blood and other tissues when compared with those of direct-labeled rSAv, suggesting that it may be a good candidate for further study. In conclusion, rSAv that has been modified with CHX-A'' and succinylated (i.e., 5a) may be useful as a carrier of 213Bi. The encouraging results obtained with the PEGylated decaborate(2-) derivative 3c and succinylated (i.e., 5c) suggests that its further study as a carrier of 211At in pretargeting protocols is warranted.

Reagents for astatination of biomolecules. 2. Conjugation of anionic boron cage pendant groups to a protein provides a method for direct labeling that is stable to in vivo deastatination.

Cancer-targeting biomolecules labeled with 211At must be stable to in vivo deastatination, as control of the 211At distribution is critical due to the highly toxic nature of alpha-particle emission. Unfortunately, no astatinated aryl conjugates have shown in vivo stability toward deastatination when (relatively) rapidly metabolized proteins, such as monoclonal antibody Fab' fragments, are labeled. As a means of increasing the in vivo stability of 211At-labeled proteins, we have been investigating antibody conjugates of boron cage moieties. In this investigation, protein-reactive derivatives containing a nido-carborane (2), a bis-nido-carborane derivative (Venus Flytrap Complex, 3), and four 2-nonahydro-closo-decaborate(2-) derivatives (4-7) were prepared and conjugated with an antibody Fab' fragment such that subsequent astatination and in vivo tissue distributions could be obtained. To aid in determination of stability toward in vivo deastatination, the Fab'-borane conjugates were also labeled with 125I, and that material was coinjected with the 211At-labeled Fab'. For comparison, direct labeling of the Fab' with 125I and 211At was conducted. Direct labeling with Na[125I]I and Chloramine-T gave an 89% radiochemical yield. However, direct labeling of the Fab' with Na[211At]At and Chloramine-T resulted in a yield of <1% after quenching with NaS2O5. As another comparison, the same Fab' was conjugated with p-[211At]astatobenzoate NHS ester, [211At]1c-Fab', and (separately) with p-[125I]iodobenzoate NHS ester, [125I]1b-Fab'. An evaluation in athymic mice demonstrated that [211At]1c-Fab' underwent deastatination. In contrast, the high in vivo stability of [125I]1b-Fab' allowed it to be used as a tracer control for the natural distribution of Fab'. Although found to be much more stable in vivo than [211At]1c-Fab', the biodistributions of nido-carborane conjugated Fab' ([125I]2-Fab'/ [211At]2-Fab') and the bis-nido-carborane (VFC) ([125I]3-Fab'/[211At]3-Fab') had very different in vivo distributions than the control [125I]1b-Fab'. Biodistributions of closo-decaborate(2-) conjugates ([125I]4-Fab'/[211At]4-Fab', [125I]6-Fab'/[211At]6-Fab', and [125I]7-Fab'/[211At]7-Fab') demonstrated that they were stable to in vivo deastatination and had distributions similar to that of the control [125I]1b-Fab'. In contrast, a benzyl-modified closo-decaborate(2-) derivative evaluated in vivo ([125I]5-Fab'/[211At]5-Fab') had a very different tissue distribution from the control. This study has shown that astatinated protein conjugates of closo-decaborate(2-) are quite stable to in vivo deastatination and that some derivatives have little effect on the distribution of Fab'. Additionally, direct 211At labeling of Fab' conjugated with closo-decaborate(2-) derivatives provide very high (e.g., 58-75%) radiochemical yields. However, in vivo data also indicate that the closo-decaborate(2-) may cause some retention of radioactivity in the liver. Studies to optimize the closo-decaborate(2-) conjugates for protein labeling are underway.

Biodistribution of 211At labeled HER-2 binding affibody molecules in mice.

The size of affibody molecules makes them suitable as targeting agents for targeted radiotherapy with the alpha-emitter 211At, since their biokinetic properties match the short physical half-live of 211At. In this study, the potential for this approach was investigated in vivo. Two different HER-2 binding affibody molecules were radiolabeled with 211At using both the linker PAB (N-succinimidyl-para-astatobenzoate) and a decaborate-based linker, and the biodistribution in tumor-bearing nude mice was investigated. The influence of L-lysine and Na-thiocyanate on the 211At uptake in normal tissues was also studied. Based on the biokinetic information obtained, the absorbed dose was calculated for different organs. Compared with a previous biodistribution with 125I, the 211At biodistribution using the PAB linker showed higher uptake in lungs, stomach, thyroid and salivary glands, indicating release of free 211At. When the decaborate-based linker was used, the uptake in those organs was decreased, but instead, high uptake in kidneys and liver was found. The uptake, when using the PAB linker, could be significantly reduced in some organs by the use of L-lysine and/or Na-thiocyanate. In conclusion, affibody molecules have suitable blood-kinetics for targeted radionuclide therapy with 211At. However, the labeling chemistry affects the distribution in normal organs to a high degree and needs to be improved to allow clinical use.

Biotin reagents for antibody pretargeting. 7. Investigation of chemically inert biotinidase blocking functionalities for synthetic utility.

An investigation was conducted to evaluate three biotin derivatives designed to block biotinidase cleavage of the biotinamide bond. Difficulties in multistep syntheses of molecules containing tert-butyl protected hydroxymethyl and carboxylate groups positioned alpha to a biotinamide bond led to the investigation of alternative biotinidase-blocking moieties that do not require protection and deprotection. The targeted biotin derivatives contained serine-O-methyl ether, 2-aminobutyric acid, and valine moieties conjugated to the biotin carboxylate functionality. Those derivatives were further modified with a radioiodinated aryl ring to study their biotinidase stability. As a comparison to previously studied biotin derivatives, radioiodinated versions of biotin conjugates that contained (a) no biotinidase stabilizing group, (b) an N-methyl (sarcosine) stabilizing group, (c) an alpha-carboxylate (aspartate) stabilizing group and hydroxymethyl (serine) stabilizing group were also prepared and tested. When tested in human serum, all of the radioiodinated biotinidase-stabilized biotin derivatives had <1% biotinamide cleavage. Thus, under the conditions studied, all of the tested biotinidase blocking moieties appeared to be equal with regards to protection from biotinidase cleavage. Further testing of the biotin derivatives included a HPLC assay to determine their relative dissociation from recombinant streptavidin (rSAv). The dissociation of cyanocobalamin (CN-Cbl) adducts of biotin-serine-O-methyl ether, biotin-aminobutyric acid, and biotin-valine were compared with the CN-Cbl adduct of biotin-sarcosine. The relative rates of dissociation found were biotin-sarcosine-CN-Cbl > biotin-valine-CN-Cbl > biotin-serine-O-methyl ether-CN-Cbl > biotin-aminobutyric acid-CN-Cbl. Due to the high cost of serine-O-ethyl ether (and its N-Boc derivative) and difficulty in syntheses of its biotin derivatives, that adduct is not an attractive candidate for application to compounds used in vivo. The higher lipophilicity and diminished binding of the biotin-valine adduct also makes its use in vivo less attractive. Thus, the biotin-aminobutyric acid adduct appears to be the best candidate for incorporation into biotin derivatives used in vivo, as it simplifies the synthetic procedures, has low cost, and provides effective blocking of biotinidase while retaining high binding affinity.

Biotin reagents in antibody pretargeting. 6. Synthesis and in vivo evaluation of astatinated and radioiodinated aryl- and nido-carboranyl-biotin derivatives.

An investigation has been conducted to prepare and evaluate several radiohalogenated biotin derivatives as part of our studies to develop reagents for carrying (211)At in cancer pretargeting protocols. The primary goal of the investigation was to determine the in vivo stability and distribution properties of astatinated biotin derivatives. In addition to astatination, the biotin derivatives were radioiodinated for in vitro and in vivo comparison. Biodistributions were conducted in athymic mice, with sacrifice times of 1, 4, and 24 h to correspond to 9%, 32%, and 90% of (211)At decay (t(1/2) = 7.21 h). In the investigation, two biotin derivatives, 1a and 2a, were synthesized which had structures that contain a biotin moiety, a biotinidase-blocking moiety, an ether linker moiety, and an aryl stannane moiety for radiohalogenation. Biotin derivatives 1a and 2a were radiolabeled with (125/131)I to give [(125)/(131)I]1b or [(125)I]2b and with (211)At to give [(211)At]1c or [(211)At]2c. In vivo studies demonstrated that co-injected [(125)I]2b and [(131)I]1b had very similar tissue distributions in athymic mice. Co-injection of [(211)At]2c and [(125)I]2b provided data that indicated that rapid deastatination occurred in vivo. A second set of biotin derivatives, 3a, 4a, and 5a, were synthesized which had structures that contain a biotin moiety, a biotinidase-blocking moiety, and an anionic nido-carborane moiety for radiohalogenation. The biotin derivatives 4a and 5a contained an aryl moiety not present in 3a, and 5a had a trialkylamine functionality not present in 3a or 4a. Biotin derivative 3a was radioiodinated, but was not further investigated. Biotin derivatives 4a and 5a were radiolabeled with (211)At and (125)I to produce [(125)I]4b/[(211)At]4c and [(125)I]5b/[(211)At]5c. Comparison of [(125)I]4b and (separately) [(125)I]5b with [(131)I]1b showed that the nido-carborane containing biotin derivatives were retained in blood and tissue more than the aryl iodide derivative. In vivo evaluations of [(211)At]4c/[(125)I]4b and (separately) [(211)At]5c/[(125)I]5b indicated that some deastatination occurred in these compounds, but it was much less than observed for the aryl derivative [(211)At]2c. While the nido-carborane containing biotin derivatives provide a significant improvement in astatine stability over biotin derivatives previously studied, additional derivatives need to be prepared and studied to further improve the in vivo stability and blood/tissue clearance of these compounds.

Synthesis, radioiodination, and biodistribution of some nido- and closo-monocarbon carborane derivatives.

Iodination and radioiodination reactions of several anionic nido- and closo-monocarbon carboranes were conducted. Iodinations occurred more rapidly with nido-carboranes than with closo-carboranes. The most rapid iodination and radioiodination reactions occurred with unsubstituted carboranes. C-amino and C-ammonium derivatives did not iodinate under the conditions studied. Both nido- and closo-carboranes with C-NH-acetyl and C-NH-succinyl substituents iodinated, but the nido-carboranes iodinated under milder reaction conditions. Biodistributions of nido-1-succinylamido-[(131)I]carborane and closo-1-succinylamido-[(125)I]carborane were similar in mice, but blood clearance of the nido- compound was slower.

Reagents for astatination of biomolecules: comparison of the in vivo distribution and stability of some radioiodinated/astatinated benzamidyl and nido-carboranyl compounds.

An investigation has been conducted to assess the in vivo stability of a series of astatinated benzamides and astatinated nido-carborane compounds in mice. It was hypothesized that the higher bond strength of boron-astatine bonds in the nido-carboranes might provide increased stability toward in vivo deastatination. Four tri-n-butylstannylbenzamides were prepared for radiohalogenation and evaluation in vivo. Those compounds were N-propyl-4-(tri-n-butylstannyl)benzamide 1a, N-propyl-3-(tri-n-butylstannyl)benzamide 2a, ethyl 4-tri-n-butylstannylhippurate 3a, and 4-tri-n-butylstannyl-hippuric acid 4a. Seven mono-nido-carboranyl derivatives were prepared for radiohalogenation and in vivo evaluation. Four of the seven mono-carboranyl derivatives (5a, 6a, 7a, 13a) contained a 3-(nido-carboranyl)propionamide functionality, and the remaining compounds (8a, 8g, 10a) contained a 4-(nido-carboranyl)aniline functionality. Two additional derivatives (11a, 12a) were prepared that contained bis-(nido-carboranylmethyl)benzene moieties (also referred to as Venus flytrap complexes (VFCs). All benzamide and nido-carborane compounds underwent facile iodination and radiohalogenation, except a 4-(nido-carboranyl)aniline derivative, 8a. Iodination of 8a resulted in a mixture, of which the desired iodinated product was a minor component. Therefore, radiohalogenation was not attempted. It is believed that the mixture of products is due to the presence of a thiourea bond. Previous studies have shown that thiourea bonds can interfere with halogenation reactions. In vivo comparisons of the compounds were conducted by co-injection of dual labeled (125/131I and 211At) compounds. Tissue distribution data were obtained at 1 and 4 h postinjection of the radiolabeled compounds, as that was sufficient to determine if astatine was being released. Stability of the astatinated compound was assessed by the difference in concentration of radioiodine and astatine in lung and spleen. All of the benzamides were found to undergo rapid deastatination in vivo. The nido-carborane derivatives appeared to be slightly more stable to in vivo deastatination; however, they had long blood residence times. The surprising finding was that the VFC derivatives did not release 211At in vivo, even though they rapidly localized to liver. This finding provides encouragement that stable conjugates of 211At may be attained if appropriate modifications of the VFC can be made to redirect their excretion through the renal system.

Trifunctional conjugation reagents. Reagents that contain a biotin and a radiometal chelation moiety for application to extracorporeal affinity adsorption of radiolabeled antibodies.

A method of removing radiolabeled monoclonal antibodies (mAbs) from blood using a device external to the body, termed extracorporeal affinity-adsorption (EAA), is being evaluated as a means of decreasing irradiation of noncancerous tissues in therapy protocols. The EAA device uses an avidin column to capture biotinylated-radiolabeled mAbs from circulated blood. In this investigation, three trifunctional reagents have been developed to minimize the potential deleterious effect on antigen binding brought about by the combination of radiolabeling and biotinylation of mAbs required in the EAA approach. The studies focused on radiolabeling with (111)In and (90)Y, so the chelates CHX-A' '-DTPA and DOTA, which form stable attachments to these radionuclides, were incorporated in the trifunctional reagents. The first trifunctional reagent prepared did not incorporate a group to block the biotin cleaving enzyme biotinidase, but the two subsequent reagents coupled aspartic acid to the biotin carboxylate for that purpose. All three reagents used 4,7,10-trioxa-1,13-tridecanediamine as water-soluble spacers between an aminoisophthalate core and the biotin or chelation group. The mAb conjugates were radioiodinated to evaluate cell binding as a function of substitution. Radioiodination was used so that a direct comparison with unmodified mAb could be made. Evaluation of the number of conjugates per antibody versus cell binding immunoreactivities indicated that minimizing the number of conjugates was best. Interestingly, a decrease of radioiodination yield as a function of the number of isothiocyanate containing conjugates per mAb was noted. The decreased yields were presumably due to the presence of thiourea functionality formed in the conjugation reaction. Radiolabeling with (111)In and (90)Y was facile at room temperature for conjugates containing the CHX-A' ', but elevated temperature (e.g., 45 degrees C) was required to obtain good yields with the DOTA chelate. Stability of (90)Y labeled mAb in serum, and when challenged with 10 mM EDTA, was high. However, challenging the (90)Y labeled mAb with 10 mM DTPA demonstrated high stability for the DOTA containing conjugate, but low stability for the CHX-A' ' containing conjugate. Thus, the choice between these two chelating moieties might be made on requirements for facile and gentle labeling versus very high in vivo stability. Application of the trifunctional biotinylation reagents to the blood clearance of labeled antibodies in EAA is under investigation. The new reagents may also be useful for other applications.