John F. Valliant

The medicinal chemistry of carboranes

The medicinal chemistry of dicarba-closo-dodecaboranes (otherwise referred to as carboranes) has traditionally centered on their use in boron neutron capture therapy (BNCT). More recently, work has begun to exploit the unique chemical and physical properties of carboranes for the preparation of novel inorganic pharmaceuticals and biological probes. This review is designed to highlight some of the recent work concerning medicinal carborane chemistry including the synthesis and testing of new BNCT agents. Following this review, as an appendix, is an illustrated summary of reactions involving carboranes reported in literature since 1992.

Technetium and Gallium Derived Radiopharmaceuticals: Comparing and Contrasting the Chemistry of Two Important Radiometals for the Molecular Imaging Era

ment of therapies, allows for selection of the most potent interventions, and is a way to assess early on during therapy * Corresponding authors: (J.F.V.) E-mail: valliant@mcmaster.ca. Fax: 905522-7776. Tel.: 905-525-9140 ext. 22840. (J.Z.) E-mail: jazubiet@syr.edu. Fax: 315-443-4070. Tel.: 315-443-2547. † Syracuse University. ‡ McMaster University. § Current address: Children’s Hospital Boston, Division of Nuclear Medicine, Department of Radiology, 300 Longwood Avenue, Boston, MA 02115. Mark Daniel Bartholomä was born in Neunkirchen (Germany) and received his diploma (2002) and his doctoral degree (2007) from the Saarland University in Saarbrücken (Germany) under the supervision of Prof. Kaspar Hegetschweiler on the synthesis and complex formation of multidentate derivatives of 1,3,5-triamino-1,3,5-trideoxy-cis-inositol. After a postdoctoral appointment in Prof. Jon Zubieta’s research group at Syracuse University working on Re/Tc conjugated nucleoside analogues for noninvasive imaging from 2007 to 2009, he joined Prof. Alan Packard’s group in 2010 at Harvard Medical School to study 18F radiolabeled perfusion tracers. Educated as a coordination chemist, his research interests focus on the development of novel ligand systems and investigation of their corresponding complex formation as well as their biochemical background and medical applications including the development of radiopharmaceuticals.

Synthesis, radiolabeling, and bio-imaging of high-generation polyester dendrimers.

A series of aliphatic polyester dendrons, generations 1 through 8, were prepared with a core p-toluenesulfonyl ethyl (TSe) ester as an easily removable protecting group that can be efficiently replaced with a variety of nucleophiles. Using amidation chemistry, a tridentate bis(pyridyl)amine ligand which is known to form stable complexes with both Tc(I) and Re(I) was introduced at the dendrimer core. Metalation of the core ligand with (99m)Tc was accomplished for generations 5 through 7, and resulted in regioselective radiolabeling of the dendrimers. The distribution of the radiolabeled dendrimers was evaluated in healthy adult Copenhagen rats using dynamic small-animal single photon emission computed tomography (SPECT). The labeled dendrimers were cleanly and rapidly eliminated from the bloodstream via the kidneys with negligible nonspecific binding to organs or tissues being observed. These data were corroborated by a quantitative biodistribution study on the generation 7 dendrimer following necropsy. The quantitative biodistribution results were in excellent agreement with the data obtained from the dynamic SPECT images.

Isostructural fluorescent and radioactive probes for monitoring neural stem and progenitor cell transplants

A construct for tagging neurospheres and monitoring cell transplantations was developed using a new technology for producing luminescent and radiolabeled probes that have identical structures. The HIV1-Tat basic domain derivatives NAcGRKKRRQRRR(SAACQ)G (SAACQ-1) and [NAcGRKKRRQRRR(Re(CO)3SAACQ)G]+ (ReSAACQ-1) were prepared in excellent yields using the single amino acid chelate-quinoline (SAACQ) ligand and its Re(I) complex and conventional automated peptide synthesis methods. The distribution of the luminescent Re probe, using epifluorescence microscopy, showed that it localized primarily in the cell nucleus with a significant degree of association on the nuclear envelope. A smaller amount was found to be dispersed in the cytoplasm. The 99m Tc analogue was then prepared in 43+/-7% (n=12) yield and very high effective specific activity. Following incubation, average uptake of the probe in neurospheres ranged between 10 and 20 Bq/cell. As determined by colorimetric assays, viability for cells labeled with high effective specific activity 99m TcSAACQ-1 was 97+/-4% at 2 h postlabeling and 85+/-25% at 24 h postlabeling for incubation activities ranging from 245 to 8900 Bq/cell. DNA analysis showed that at these levels, there was no significant difference between the extent of DNA damage in the treated cells versus control cells. A series of preliminary SPECT/CT studies of transplants in mice were performed, which showed that the strategy is convenient and feasible and that it is possible to routinely assess procedures noninvasively and determine the number of cells transplanted.

Implementation of Multi-Curie Production of 99mTc by Conventional Medical Cyclotrons

99mTc is currently produced by an aging fleet of nuclear reactors, which require enriched uranium and generate nuclear waste. We report the development of a comprehensive solution to produce 99mTc in sufficient quantities to supply a large urban area using a single medical cyclotron. Methods: A new target system was designed for 99mTc production. Target plates made of tantalum were coated with a layer of 100Mo by electrophoretic deposition followed by high-temperature sintering. The targets were irradiated with 18-MeV protons for up to 6 h, using a medical cyclotron. The targets were automatically retrieved and dissolved in 30% H2O2. 99mTc was purified by solid-phase extraction or biphasic exchange chromatography. Results: Between 1.04 and 1.5 g of 100Mo were deposited on the tantalum plates. After high-temperature sintering, the 100Mo formed a hard, adherent layer that bonded well with the backing surface. The targets were irradiated for 1–6.9 h at 20–240 μA of proton beam current, producing up to 348 GBq (9.4 Ci) of 99mTc. The resulting pertechnetate passed all standard quality control procedures and could be used to reconstitute typical anionic, cationic, and neutral technetium radiopharmaceutical kits. Conclusion: The direct production of 99mTc via proton bombardment of 100Mo can be practically achieved in high yields using conventional medical cyclotrons. With some modifications of existing cyclotron infrastructure, this approach can be used to implement a decentralized medical isotope production model. This method eliminates the need for enriched uranium and the radioactive waste associated with the processing of uranium targets.

The bioinorganic and medicinal chemistry of carboranes: from new drug discovery to molecular imaging and therapy

The role of carboranes in medicinal chemistry has diversified in recent years and now extends into areas of drug discovery, molecular imaging, and targeted radionuclide therapy. An introduction to carborane chemistry is provided to familiarize the non-expert with some key properties of these molecules, followed by an overview of current medicinally-orientated research involving carboranes. The broad-ranging nature of this research is illustrated, with emphasis placed on recent highlights and advances in this field.

Comprehensive Radiolabeling, Stability, and Tissue Distribution Studies of Technetium-99m Single Amino Acid Chelates (SAAC)

Technetium tricarbonyl chemistry has been a subject of interest in radiopharmaceutical development over the past decade. Despite the extensive work done on developing chelates for Tc(I), a rigorous investigation of the impact of changing donor groups and labeling conditions on radiochemical yields and/or distribution has been lacking. This information is crucially important if these platforms are going to be used to develop molecular imaging probes. Previous studies on the coordination chemistry of the {M(CO)(3)}(+) core have established alkylamine, aromatic nitrogen heterocycles, and carboxylate donors as effective chelating ligands. These observations led to the design of tridentate ligands derived from the amino acid lysine. Such amino acid analogues provide a tridentate donor set for chelation to the metal and an amino acid functionality for conjugation to biomolecules. We recently developed a family of single amino acid chelates (SAAC) that serve this function and can be readily incorporated into peptides via solid-phase synthesis techniques. As part of these continuing studies, we report here on the radiolabeling with technetium-99m ((99m)Tc) and stability of a series of SAAC analogues of lysine. The complexes studied include cationic, neutral, and anionic complexes. The results of tissue distribution studies with these novel complexes in normal rats demonstrate a range of distribution in kidney, liver, and intestines.

Preparation and Evaluation of Carborane Analogues of Tamoxifen

A stereoselective synthesis of closo carborane analogues of tamoxifen was developed where the products represent a new approach to developing metabolically robust SERMs. The A-ring found in the backbone of tamoxifen was replaced with an ortho carborane cluster; the product was determined to be the desired Z isomer, which showed superior chemical stability to tamoxifen both in solution and in the solid state. By use of microwave heating, it was possible to convert some of the Z carborane tamoxifen analogue to the corresponding E isomer. Cell growth assays using both isomers and a carborane that is known to target the ER were conducted using estrogen receptor (ER) positive and ER negative human breast cancer cells with and without the presence of estradiol (E2). The Z carborane isomer was able to inhibit cell proliferation better than tamoxifen in an E2 free environment, while the E isomer inhibited cell growth better than tamoxifen when E2 was present.

A new approach for the synthesis of isonitrile carborane derivatives. Ligands for metal based boron neutron capture therapy (BNCT) and boron neutron capture synovectomy (BNCS) agents

A new approach for the synthesis of carborane isonitrile derivatives was developed. This approach involved the dehydration of both boron and carbon derived formamides using the Burgess reagent. The products, some of which were characterized by X-ray crystallography, can now be used as ligands for the synthesis of transition metal based boron neutron capture therapy and synovectomy agents and targeted radiopharmaceuticals.

Single amino acid chelate complexes of the M(CO)3+ core for correlating fluorescence and radioimaging studies (M = 99mTc or Re)†

Single amino acid chelates (SAACs) and SAAC-like bifunctional ligands can be exploited in the design of a variety of bioconjugates for facile metallation with the M(CO)3 (+) unit with M = (99m) Tc or Re. When the donor groups of the ligand are quinolone, thiazole or other similarly conjugated heterocycles, the rhenium complexes are fluorescent, affording complementary and isostructural fluorescent probes to the radioactive (99m) Tc analogues. The versatility of the approach has been demonstrated by the preparation of bioconjugates incorporating peptides, biotin, folic acid, thymidine and vitamin B12 . In addition, the unusual photophysical properties observed for rhenium of the [bisthiazole-diamino butane-Re(CO)3 (+) ] derivative [BTBA-Re(CO)3 ](+) are discussed.