Michelle T. Ma

Highly Efficient p-Type Dye-sensitized Solar Cells based on Tris(1,2-diaminoethane)Cobalt(II)/(III) Electrolytes

Co-produced: using [Co(en)(3)](2+/3+) based-electrolytes in p-type dye-sensitized solar cells (p-DSCs) gives record energy conversion efficiencies of 1.3 % and open-circuit voltages up to 709 mV under simulated sun light. The increase in photovoltage is due to the more negative redox potential of [Co(en)(3)](2+/3+) compared to established mediators.

Comparison of 64Cu-Complexing Bifunctional Chelators for Radioimmunoconjugation: Labeling Efficiency, Specific Activity, and in Vitro/in Vivo Stability

High radiolabeling efficiency, preferably to high specific activity, and good stability of the radioimmunoconjugate are essential features for a successful immunoconjugate for imaging or therapy. In this study, the radiolabeling efficiency, in vitro stability, and biodistribution of immunoconjugates with eight different bifunctional chelators labeled with (64)Cu were compared. The anti-CD20 antibody, rituximab, was conjugated to four macrocyclic bifunctional chelators (p-SCN-Bn-DOTA, p-SCN-Bn-Oxo-DO3A, p-SCN-NOTA, and p-SCN-PCTA), three DTPA derivatives (p-SCN-Bn-DTPA, p-SCN-CHX-A″-DTPA, and ITC-2B3M-DTPA), and a macrobicyclic hexamine (sarcophagine) chelator (sar-CO2H) = (1-NH2-8-NHCO(CH2)3CO2H)sar where sar = sarcophagine = 3,6,10,13,16,19-hexaazabicyclo[6.6.6]icosane). Radiolabeling efficiency under various conditions, in vitro stability in serum at 37 °C, and in vivo biodistribution and imaging in normal mice over 48 h were studied. All chelators except sar-CO2H were conjugated to rituximab by thiourea bond formation with an average of 4.9 ± 0.9 chelators per antibody molecule. Sar-CO2H was conjugated to rituximab by amide bond formation with 0.5 chelators per antibody molecule. Efficiencies of (64)Cu radiolabeling were dependent on the concentration of immunoconjugate. Notably, the (64)Cu-NOTA-rituximab conjugate demonstrated the highest radiochemical yield (95%) under very dilute conditions (31 nM NOTA-rituximab conjugate). Similarly, sar-CO-rituximab, containing 1/10th the number of chelators per antibody compared to that of other conjugates, retained high labeling efficiency (98%) at an antibody concentration of 250 nM. In contrast to the radioimmunoconjugates containing DTPA derivatives, which demonstrated poor serum stability, all macrocyclic radioimmunoconjugates were very stable in serum with <6% dissociation of (64)Cu over 48 h. In vivo biodistribution profiles in normal female Balb/C mice were similar for all the macrocyclic radioimmunoconjugates with most of the activity remaining in the blood pool up to 48 h. While all the macrocyclic bifunctional chelators are suitable for molecular imaging using (64)Cu-labeled antibody conjugates, NOTA and sar-CO2H show significant advantages over the others in that they can be radiolabeled rapidly at room temperature, under dilute conditions, resulting in high specific activity.

Macrobicyclic cage amine ligands for copper radiopharmaceuticals: A single bivalent cage amine containing two Lys3-bombesin targeting peptides

The synthesis of new cage amine macrobicyclic ligands with pendent carboxylate functional groups designed for application in copper radiopharmaceuticals is described. Reaction of [Cu((NH(2))(2)sar)](2+) (sar = 3,6,10,13,16,19-hexaazabicyclo[6.6.6]icosane) with either succinic or glutaric anhydride results in selective acylation of the primary amine atoms of [Cu((NH(2))(2)sar)](2+) to give derivatives with either one or two aliphatic carboxylate functional groups separated from the cage amine framework by either a four- or five-atom linker. The Cu(II) serves to protect the secondary amine nitrogen atoms from acylation, and can be removed to give the free ligands. The newly appended carboxylate functional groups can be used as sites of attachment for cancer-targeting peptides such as Lys(3)-bombesin. The synthesis of the first dimeric sarcophagine-peptide conjugate, possessing two Lys(3)-bombesin peptides tethered to a single cage amine, is presented. This species has been radiolabeled with copper-64 at ambient temperature and there is minimal dissociation of Cu(II) from the conjugate even after two days of incubation in human serum.

Peptide targeted copper-64 radiopharmaceuticals

Peptide targeted ⁶⁴Cu-labelled diagnostic agents for positron emission tomography are viable candidates for molecular imaging of cancer. In a clinical setting, optimal image quality relies on selective tumor uptake of the ⁶⁴Cu-labelled radiotracer. The three components of the radiotracer construct--the chelate group, linker and targeting peptide--all influence the biodistribution of the ⁶⁴Cu-labelled radiotracer in vivo. Low or moderate Cu complex stability in vivo results in transmetallation of ⁶⁴Cu to endogenous proteins, giving rise to high background activity. The length and the nature of the linker group affect the affinity of the ⁶⁴Cu-labelled radiotracer for the target receptor. Variations in the peptide sequence can impact on the metabolic stability and therefore the bioavailability and tumor retention of the ⁶⁴Cu-labelled radiotracer in vivo. Lastly, the hydrophilicity of the construct can influence radiotracer metabolism and clearance pathways. Recent advances in the field of peptide targeted ⁶⁴Cu-labelled radiopharmaceuticals involve GRPR-targeted and αvβ3 integrin receptor-targeted constructs. These constructs are based on the bombesin peptide sequence and the RGD recognition motif respectively. These examples are reviewed as case studies in the optimisation of ⁶⁴Cu radiotracer design.

A new bifunctional chelator for copper radiopharmaceuticals

A new sarcophagine cage amine ligand with a pendent carboxylate functional group has been synthesised; the ligand has been conjugated to tumour targeting peptides ([Tyr3]-octreotate and [Lys3]-bombesin) and the conjugates radiolabelled with copper-64.

Metal clips that induce unstructured pentapeptides to be α-helical in water

Short peptides corresponding to protein helices do not form thermodynamically stable helical structures in water, a solvent that strongly competes for hydrogen-bonding amides of the peptide backbone. Metalloproteins often feature metal ions coordinated to amino acids within hydrogen-bonded helical regions of protein structure, so there is a prospect of metals stabilizing or inducing helical structures in short peptides. However, this has only previously been observed in nonaqueous solvents or under strongly helix-favoring conditions in water. Here cis-[Ru(NH(3))(4)(solvent)(2)](2+) and [Pd(en)(solvent)(2)](2+) are compared in water for their capacity as metal clips to induce alpha-helicity in completely unstructured peptides as short as five residues, Ac-HARAH-NH(2) and Ac-MARAM-NH(2). More alpha-helicity was observed for the latter pentapeptide and, when chelated to ruthenium, it showed the greatest alpha-helicity yet reported for a short metallopeptide in water (approximately 80%). Helicity was clearly induced rather than stabilized, and the two methionines were 10(13)-fold more effective than two histidines in stabilizing the lower oxidation state Ru(II) over Ru(III). The study identifies key factors that influence stability of an alpha-helical turn in water, suggests metal ions as tools for peptide folding, and raises an intriguing possibility of transiently coordinated metal ions playing important roles in native folding of polypeptides in water.

Tripodal tris(hydroxypyridinone) ligands for immunoconjugate PET imaging with 89Zr4+: comparison with desferrioxamine-B

Due to its long half-life (78 h) and decay properties (77% electron capture, 23% β(+), Emax = 897 keV, Eav = 397 keV, Eγ = 909 keV, Iγ = 100%) (89)Zr is an appealing radionuclide for immunoPET imaging with whole IgG antibodies. Derivatives of the siderophore desferrioxamine-B (H3DFO) are the most widely used bifunctional chelators for coordination of (89)Zr(4+) because the radiolabeling of the resulting immunoconjugates is rapid under mild conditions. (89)Zr-DFO complexes are reportedly stable in vitro but there is evidence that (89)Zr(4+) is released in vivo, and subsequently taken up by the skeleton. We have evaluated a novel tripodal tris(hydroxypyridinone) chelator, H3CP256 and its bifunctional maleimide derivative, H3YM103, for coordination of Zr(4+) and compared the NMR spectra, and the (89)Zr(4+) radiolabeling, antibody conjugation, serum stability and in vivo distribution of radiolabelled immunoconjugates with those of H3DFO and its analogues. H3CP256 coordinates (89)Zr(4+) at carrier-free concentrations forming [(89)Zr(CP256)](+). Both H3DFO and H3CP256 were efficiently radiolabelled using [(89)Zr(C2O4)4](4-) at ambient temperature in quantitative yield at pH 6-7 at millimolar concentrations of chelator. Competition experiments demonstrate that (89)Zr(4+) dissociates from [(89)Zr(DFO)](+) in the presence of one equivalent of H3CP256 (relative to H3DFO) at pH 6-7, resulting largely in [(89)Zr(CP256)](+). To assess the stability of H3DFO and H3YM103 immunoconjugates radiolabelled with (89)Zr, maleimide derivatives of the chelators were conjugated to the monoclonal antibody trastuzumab via reduced cysteine side chains. Both immunoconjugates were labelled with (89)Zr(4+) in >98% yield at high specific activities and the labeled immunoconjugates were stable in serum with respect to dissociation of the radiometal. In vivo studies in mice indicate that (89)Zr(4+) dissociates from YM103-trastuzumab with significant amounts of activity becoming associated with bones and joints (25.88 ± 0.58% ID g(-1) 7 days post-injection). In contrast, <8% ID g(-1) of (89)Zr activity becomes associated with bone in animals administered (89)Zr-DFO-trastuzumab over the course of 7 days. The tris(hydroxypyridinone) chelator, H3CP256, coordinates (89)Zr(4+) rapidly under mild conditions, but the (89)Zr-labelled immunoconjugate, (89)Zr-YM103-trastuzumab was observed to release appreciable amounts of (89)Zr(4+)in vivo, demonstrating inferior stability when compared with (89)Zr-DFO-trastuzumab. The significantly lower in vivo stability is likely to be a result of lower kinetic stability of the Zr(4+) tris(hydroxypyridinone complex) relative to that of DFO and its derivatives.

New Tris(hydroxypyridinone) Bifunctional Chelators Containing Isothiocyanate Groups Provide a Versatile Platform for Rapid One-Step Labeling and PET Imaging with 68Ga3+

Two new bifunctional tris(hydroxypyridinone) (THP) chelators designed specifically for rapid labeling with 68Ga have been synthesized, each with pendant isothiocyanate groups and three 1,6-dimethyl-3-hydroxypyridin-4-one groups. Both compounds have been conjugated with the primary amine group of a cyclic integrin targeting peptide, RGD. Each conjugate can be radiolabeled and formulated by treatment with generator-produced 68Ga3+ in over 95% radiochemical yield under ambient conditions in less than 5 min, with specific activities of 60–80 MBq nmol–1. Competitive binding assays and in vivo biodistribution in mice bearing U87MG tumors demonstrate that the new 68Ga3+-labeled THP peptide conjugates retain affinity for the αvβ3 integrin receptor, clear within 1–2 h from circulation, and undergo receptor-mediated tumor uptake in vivo. We conclude that bifunctional THP chelators can be used for simple, efficient labeling of 68Ga biomolecules under mild conditions suitable for peptides and proteins.

68Ga-THP-PSMA: a PET imaging agent for prostate cancer offering rapid, room temperature, one-step kit-based radiolabeling

The clinical impact and accessibility of 68Ga tracers for the prostate-specific membrane antigen (PSMA) and other targets would be greatly enhanced by the availability of a simple, 1-step kit-based labeling process. Radiopharmacy staff are accustomed to such procedures in the daily preparation of 99mTc radiopharmaceuticals. Currently, chelating agents used in 68Ga radiopharmaceuticals do not meet this ideal. The aim of this study was to develop and evaluate preclinically a 68Ga radiotracer for imaging PSMA expression that could be radiolabeled simply by addition of 68Ga generator eluate to a cold kit. Methods: A conjugate of a tris(hydroxypyridinone) (THP) chelator with the established urea-based PSMA inhibitor was synthesized and radiolabeled with 68Ga by adding generator eluate directly to a vial containing the cold precursors THP-PSMA and sodium bicarbonate, with no further manipulation. It was analyzed after 5 min by instant thin-layer chromatography and high-performance liquid chromatography. The product was subjected to in vitro studies to determine PSMA affinity using PSMA-expressing DU145-PSMA cells, with their nonexpressing analog DU145 as a control. In vivo PET imaging and ex vivo biodistribution studies were performed in mice bearing xenografts of the same cell lines, comparing 68Ga-THP-PSMA with 68Ga-HBED-CC-PSMA. Results: Radiolabeling was complete (>95%) within 5 min at room temperature, showing a single radioactive species by high-performance liquid chromatography that was stable in human serum for more than 6 h and showed specific binding to PSMA-expressing cells (concentration giving 50% inhibition of 361 ± 60 nM). In vivo PET imaging showed specific uptake in PSMA-expressing tumors, reaching 5.6 ± 1.2 percentage injected dose per cubic centimeter at 40–60 min and rapid clearance from blood to kidney and bladder. The tumor uptake, biodistribution, and pharmacokinetics were not significantly different from those of 68Ga-HBED-CC-PSMA except for reduced uptake in the spleen. Conclusion: 68Ga-THP-PSMA has equivalent imaging properties but greatly simplified radiolabeling compared with other 68Ga-PSMA conjugates. THP offers the prospect of rapid, simple, 1-step, room-temperature syringe-and-vial radiolabeling of 68Ga radiopharmaceuticals.

Hydroxypyridinone Chelators: From Iron Scavenging to Radiopharmaceuticals for PET Imaging with Gallium-68

Derivatives of 3,4-hydroxypyridinones have been extensively studied for in vivo Fe3+ sequestration. Deferiprone, a 1,2-dimethyl-3,4-hydroxypyridinone, is now routinely used for clinical treatment of iron overload disease. Hexadentate tris(3,4-hydroxypyridinone) ligands (THP) complex Fe3+ at very low iron concentrations, and their high affinities for oxophilic trivalent metal ions have led to their development for new applications as bifunctional chelators for the positron emitting radiometal, 68Ga3+, which is clinically used for molecular imaging in positron emission tomography (PET). THP-peptide bioconjugates rapidly and quantitatively complex 68Ga3+ at ambient temperature, neutral pH and micromolar concentrations of ligand, making them amenable to kit-based radiosynthesis of 68Ga PET radiopharmaceuticals. 68Ga-labelled THP-peptides accumulate at target tissue in vivo, and are excreted largely via a renal pathway, providing high quality PET images.