Spectroscopic and Computational Characterization of Diethylenetriaminepentaacetic Acid/Transplutonium Chelates: Evidencing Heterogeneity in the Heavy Actinide(III) Series

Deblonde, Gauthier J.‐P.; Kelley, Morgan; Su, Jing; Batista, Enrique R.; Yang, Ping; Booth, C. H.; Abergel, Rebecca J.

doi:10.1002/ange.201709183

Cited by 5 publications

(6 citation statements)

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“…This likely has broader consequences in terms of addressing Cf II chemistry. It is now known that Cf−L bonds are shorter than expected, 29,90 and rather than possessing an effective ionic radius similar to that of Gd III as originally predicted, it now appears that the effective radius parallels smaller lanthanides like Er 3+ . 90 The ionic radius of Cf II remains unknown, and it appears that extrapolating from the size of Ln II cations is unwise.…”

Section: Inorganic Chemistrymentioning

confidence: 68%

“…It is now known that Cf−L bonds are shorter than expected, 29,90 and rather than possessing an effective ionic radius similar to that of Gd III as originally predicted, it now appears that the effective radius parallels smaller lanthanides like Er 3+ . 90 The ionic radius of Cf II remains unknown, and it appears that extrapolating from the size of Ln II cations is unwise. Thus, it is apparent that, if cryptands are to be employed to stabilize Cf II , they will likely need to be smaller than 2.2.2-cryptand.…”

Section: Inorganic Chemistrymentioning

confidence: 68%

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Electrochemical Studies of Selected Lanthanide and Californium Cryptates

et al. 2019

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Efforts to quantitatively reduce CfIII → CfII in solution as well as studies of its cyclic voltammetry have been hindered by its scarcity, significant challenges associated with manipulating an unusually intense γ emitter, small reaction scales, the need for nonaqueous solvents, and its radiolytic effects on ligands and solvents. In an effort to overcome these impediments, we report on the stabilization of CfII by encapsulation in 2.2.2-cryptand and comparisons with the readily reducible lanthanides, Sm3+, Eu3+, and Yb3+. Cyclic voltammetry measurements suggest that CfIII/II displays electrochemical behavior with characteristics of both SmIII/II and YbIII/II. The °E 1/2 values of −1.525 and −1.660 V (vs Fc/Fc+ in tetrahydrofuran (THF)) for [Cf(2.2.2-crypt)]3+/2+ and [Sm(2.2.2-crypt)]3+/2+, respectively, are similar. However, the ΔE values upon complexation by 2.2.2-cryptand for CfIII/II more closely parallels YbIII/II with postencapsulation shifts of 705 and 715 mV, respectively, whereas the shift of SmIII/II (520 mV) mirrors that of EuIII/II (524 mV). This suggests more structural similarities between CfII and YbII in solution than with SmII that likely originates from more similar ionic radii and local coordination environments, a supposition that is corroborated by crystallographic and extended X-ray absorption fine structure measurements from other systems. Competitive-ion binding experiments between EuIII/II, SmIII/II, and YbIII/II were also performed and show less favorable binding by YbIII/II. Connectivity structures of [Ln(2.2.2-cryptand)(THF)][BPh4]2 (Ln = EuII, SmII) are reported to show the important role that THF plays in these redox reactions.

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Section: Inorganic Chemistrymentioning

confidence: 68%

Section: Inorganic Chemistrymentioning

confidence: 68%

Electrochemical Studies of Selected Lanthanide and Californium Cryptates

et al. 2019

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“…52,53 From previous experimental and theoretical reports, it is likely that covalency driven preferential bonding to actinides over lanthanides by certain ligands is a key marker in choosing extractants for minor actinide partitioning. Though a considerable amount of work has been done on the separation of minor actinides (Am, Cm) from lanthanides, there are only few reports [11][12][13]18,46 in the literature involving complexation of heavy actinides, particularly, Bk and Cf, because of their radiological toxicity and close chemical similarities with heavy lanthanides.…”

Section: Introductionmentioning

confidence: 99%

Uncovering Heavy Actinide Covalency: Implications for Minor Actinide Partitioning

Chandrasekar

Ghanty

2019

Inorg. Chem.

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Across the actinide period, the stability of the trivalent oxidation state predominates in the heavy actinides, making their chemical nature close to that of rare earth elements. The resemblance in their chemistry poses difficulties in separating heavy actinides from lanthanides, which is a vital separation in the minor actinide partitioning process. Actinide contraction has conventionally implied electrostatic actinide-ligand interactions among the heavy actinides. The present study challenges this conventional understanding and reveals increasing covalency in the actinide-ligand bond across Am to Cf. Complexes of Am, Cm, Bk, and Cf have been examined for their electronic structure with a focus on the nature of their interactions with different ligands within the framework of density functional theory, where the relativistic effects have been incorporated by using zero-order regular approximation and spin–orbit coupling. The choice of ligands selected for this study facilitates the effect of the donor atom as well as denticity to be accounted for. Hence, heavy actinide complexes of the N- and O-donor ligand dipicolinic acid, S and O mixed donor ligands of the Cyanex type, and an octadentate ligand N,N,N′N′-tetrakis[(6-carboxypyridin-2-yl)methyl]ethylenediamine have been optimized and evaluated. In each case energy decomposition analysis has been used to explicitly decompose the metal–ligand interaction energy into components which have then been analyzed. Irrespective of the hard–soft characteristics of donor atoms or the denticity of the ligands, steadily increased covalency has been observed across Am to Cf. Inspection of the ligand highest energy occupied molecular orbitals and metal orbitals sheds light on the origin of the unexpected covalency. An overall increase in bonding and also the orbital contribution along the Am–Cf series is clearly due to the enhancement in covalency, which is complementary to the orbital degeneracy induced covalency proposed very recently by Batista and co-workers.

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“…It bears three tertiary amines and five sterically unconstrained carboxylic acids that can coordinate metal ions or be used as functionalization handles. 22,23 The DTPA chelate has been widely used in nuclear chemistry due to the fact that it forms stable coordination compounds with various metal ions including indium 24 (formation constant log β = 29.0−29.5), yttrium 24 (log β = 21.2−22.5), gallium 24 (log β = 25.5), and lanthanides like gadolinium 25 (log β = 22.46). 22,23,[26][27][28][29][30][31][32] Inradiolabeled antibodies that incorporated the DTPA chelate have received clinical approval for SPECT imaging.…”

Section: ■ Introductionmentioning

confidence: 99%

“…22,23 The DTPA chelate has been widely used in nuclear chemistry due to the fact that it forms stable coordination compounds with various metal ions including indium 24 (formation constant log β = 29.0−29.5), yttrium 24 (log β = 21.2−22.5), gallium 24 (log β = 25.5), and lanthanides like gadolinium 25 (log β = 22.46). 22,23,[26][27][28][29][30][31][32] Inradiolabeled antibodies that incorporated the DTPA chelate have received clinical approval for SPECT imaging. These include 111 In-satumomab pendetide for the diagnosis of colorectal and ovarian carcinomas, 33 and 111 In-capromab pendetide for prostate cancer therapy.…”

Section: ■ Introductionmentioning

confidence: 99%

Synthesis and Photochemical Studies on Gallium and Indium Complexes of DTPA-PEG₃-ArN₃ for Radiolabeling Antibodies

Gut

Holland

2019

Inorg. Chem.

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Photochemistry is a rich source of inspiration for developing alternative methods to functionalize proteins with drug molecules, fluorophores, and radioactive probes. Here, we report the synthesis and photochemical reactivity of a modified diethylenediamine pentaacetic acid chelate that was derivatized with a light-responsive aryl azide group (DTPA-PEG3-ArN3, compound 1). The corresponding nonradioactive and radioactive nat/68Ga3+ and nat/111In3+ complexes of DTPA-PEG3-ArN3 were synthesized and their physical and photochemical properties were studied to evaluate the potential of employing this ligand system in the photochemical synthesis of radiolabeled antibodies. Photodegradation kinetics revealed that irradiation with ultraviolet light (365 nm) induced rapid photoactivation of compound 1 and the metal complexes nat/68Ga-1-and nat/111In-1-. Light-induced reactions were complete in <100 s, with measured first-order rate constants of 0.078 ± 0.045 s-1, 0.093 ± 0.009 s-1, and 0.117 ± 0.054 s-1 (n = 2, per species) for compound 1, natGa-1-, and natIn-1-, respectively. Photochemically induced bioconjugation reactions between DTPA-PEG3-ArN3 and the monoclonal antibody trastuzumab, as well as pre-and postconjugation 68Ga-and 111In-radiolabeling experiments, were performed using either a one-pot or two-step strategy. Both approaches yielded radiolabeled trastuzumab ([68Ga]GaDTPA-azepin-trastuzumab) with average radiochemical conversions of 3.9 ± 1.0% (n = 4, onepot), and 10.0 ± 1.0% (n = 3, two-step). One-pot radiolabeling reactions with [111In]InCl3 produced the corresponding [111In]InDTPA-azepin-trastuzumab radiotracer in a similar radiochemical conversion of 5.4 ± 0.8% (n = 3). Radiochemical conversions for the desired bimolecular coupling between the chelate and the protein were comparatively low. This observation is likely caused by the high photoinduced reactivity of the compounds and subsequent competition with background reactions. Nevertheless, access to DTPA-PEG3-ArN3 increases the scope of photoradiochemical methods to include metal ions like In3+ that form complexes with higher coordination numbers.

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Spectroscopic and Computational Characterization of Diethylenetriaminepentaacetic Acid/Transplutonium Chelates: Evidencing Heterogeneity in the Heavy Actinide(III) Series

Cited by 5 publications

References 54 publications

Electrochemical Studies of Selected Lanthanide and Californium Cryptates

Electrochemical Studies of Selected Lanthanide and Californium Cryptates

Uncovering Heavy Actinide Covalency: Implications for Minor Actinide Partitioning

Synthesis and Photochemical Studies on Gallium and Indium Complexes of DTPA-PEG₃-ArN₃ for Radiolabeling Antibodies

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Spectroscopic and Computational Characterization of Diethylenetriaminepentaacetic Acid/Transplutonium Chelates: Evidencing Heterogeneity in the Heavy Actinide(III) Series

Cited by 5 publications

References 54 publications

Electrochemical Studies of Selected Lanthanide and Californium Cryptates

Electrochemical Studies of Selected Lanthanide and Californium Cryptates

Uncovering Heavy Actinide Covalency: Implications for Minor Actinide Partitioning

Synthesis and Photochemical Studies on Gallium and Indium Complexes of DTPA-PEG3-ArN3 for Radiolabeling Antibodies

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Product

Resources

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Synthesis and Photochemical Studies on Gallium and Indium Complexes of DTPA-PEG₃-ArN₃ for Radiolabeling Antibodies