Luminescent Lanthanide Chelate Contrast Agents and Detection of Lesions in the Hamster Oral Cancer Model

Bornhop, Darryl J.; Griffin, John M. M.; Goebel, Timothy S.; Sudduth, Mark R.; Bell, Brent A.; Motamedi, Massoud

doi:10.1366/000370203769699063

Cited by 31 publications

(15 citation statements)

References 36 publications

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“…[25] Tb III -based chelates have also proved useful, as exemplified by a lipid-conjugated chelate that functions as a membrane-staining agent in morphological studies of Swiss albino mouse 3T3 cultured cells, [22] or by Bornhops high brightness macrocyclic labels for in vitro and in vivo analysis of abnormal tissues. [18,26,27] More recently, Parker and co-workers have designed Eu III complexes that specifically stain the nucleoli of several cell lines (CHO, COS, NIH 3T3, HeLa, and HDF). [15,[28][29][30] Most lanthanide ions are also paramagnetic and possess an anisotropic susceptibility tensor that makes them useful for the structural investigation of axial complexes [31] or proteins [32] by NMR spectroscopy, while Gd III has emerged as a universal contrast agent for 3D imaging of biological structures (MRI).…”

Section: IIImentioning

confidence: 99%

A Versatile Ditopic Ligand System for Sensitizing the Luminescence of Bimetallic Lanthanide Bio‐Imaging Probes

Chauvin

Comby

Song

et al. 2008

Chemistry A European J

109

106

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The homoditopic ligand 6,6'-[methylenebis(1-methyl-1H-benzimidazole-5,2-diyl)]bis(4-{2-[2-(2-methoxyethoxy)ethoxy]ethoxy}pyridine-2-carboxylic acid) (H(2)L(C2)) has been tailored to self-assemble with lanthanide ions (Ln(III)), which results in the formation of neutral bimetallic helicates with the overall composition [Ln(2)(L(C2))(3)] and also provides a versatile platform for further derivatization. The grafting of poly(oxyethylene) groups onto the pyridine units ensures water solubility, while maintaining sizeable thermodynamic stability and adequate antenna effects for the excitation of both visible- and NIR-emitting Ln(III) ions. The conditional stability constants (log beta(23)) are close to 25 at physiological pH and under stoichiometric conditions. The ligand triplet state features adequate energy (0-phonon transition at approximately 21 900 cm(-1)) to sensitize the luminescence of Eu(III) (Q=21 %) and Tb(III) (11 %) in aerated water at pH 7.4. The emission of several other VIS- and NIR-emitting ions, such as Sm(III) (Q=0.38 %) or Yb(III) (0.15 %), for which in cellulo luminescence is evidenced for the first time, is also sensitized. The Eu(III) emission spectrum arises from a main species with pseudo-D(3) symmetry and without coordinated water. The cell viability of several cancerous cell lines (MCF-7, HeLa, Jurkat and 5D10) is unaffected if incubated with up to 500 microM [Eu(2)(L(C2))(3)] during 24 h. Bright Eu(III) emission is seen for incubation concentrations above 10 microM and after a 15-minute loading time; similar images are obtained with Tb(III) and Sm(III). The helicates probably permeate into the cytoplasm of HeLa cells by endocytosis. The described luminescent helical stains are robust chemical species which remain undissociated in the cell medium and in presence of other complexing agents, such as edta, dtpa, citrate or L-ascorbate. Their derivatization, which would open the way to the sensing of targeted in cellulo phenomena, is currently under investigation.

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Section: IIImentioning

confidence: 99%

A Versatile Ditopic Ligand System for Sensitizing the Luminescence of Bimetallic Lanthanide Bio‐Imaging Probes

Chauvin

Comby

Song

et al. 2008

Chemistry A European J

109

106

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“…The luminescent lanthanide complexes are the promising probes for the detection of the early states of the cancer [1][2][3][4]. In such an application the administered complexes are directed to a particular tissue and they are cumulated in the proximity of the cancer cells to a greater extent than around the healthy cells.…”

Section: Introductionmentioning

confidence: 99%

Efficiency of the energy transfer in lanthanide-organic chelates; spectral overlap integral

Smentek

̧dziorski

2010

Journal of Luminescence

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“…11 The poor solubility below pH ¼ 6 and the precipitation of the ligand L at pH ¼ 4 prevent the determination of the other protonation constants which were estimated to be at about 5.4 for log K LH 4 and lower than 2 for log K LH 5 and log K LH6 . 15 Under very acidic conditions, below pH ¼ 2, L re-dissolves, due to protonation of the carboxylate functions.…”

Section: Properties Of Ligand L and Dinuclear Europium(iii) Triplestrmentioning

confidence: 99%

“…3b Furthermore, the long excited state lifetimes of several Ln(III) ions are ideally suited for the engineering of immunoassays using time-resolved luminescence for the separation of the probe phosphorescence from the background fluorescence. 2a,b Finally, stimulating developments are presently taking place in which lanthanide probes emitting in the visible allow the imaging of cancer cells, 4 and this methodology is being extended to the near infrared (Nd, Er, Yb), a spectral range in which biological tissues have little absorption. 5 These applications require the design of lanthanide chelates with high thermodynamic stability and kinetic inertness under physiological conditions.…”

Section: Introductionmentioning

confidence: 99%

Proton-assisted dissociation of a triple-stranded dinuclear europium helicate

Elhabiri¹,

Hamacek²,

Humbert³

et al. 2004

New J. Chem.

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A fruitful combination of absorption and gated luminescence spectrophotometry allowed us to gain insight into the proton-assisted dissociation of a triple-stranded dinuclear europium helicate in water. This process involves a key dimetallic double-stranded complex Eu 2 L 2 as already observed in the self-assembly process of the triple helicate. The slow unravelling of the first strand, which is triggered by the protonation of its two carboxylate groups, dominates the whole disentangling mechanism of the supramolecular edifice. The solvolytic dissociation in water is rather slow (k D ¼ 4(1) Â 10 À4 s À1) and is catalysed by). These lanthanide helicates, which are characterised by high kinetic inertness over a wide range of pH and high thermodynamic stability in water, are promising building blocks for the development of novel fluorescent biomarkers.

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Luminescent Lanthanide Chelate Contrast Agents and Detection of Lesions in the Hamster Oral Cancer Model

Cited by 31 publications

References 36 publications

A Versatile Ditopic Ligand System for Sensitizing the Luminescence of Bimetallic Lanthanide Bio‐Imaging Probes

A Versatile Ditopic Ligand System for Sensitizing the Luminescence of Bimetallic Lanthanide Bio‐Imaging Probes

Efficiency of the energy transfer in lanthanide-organic chelates; spectral overlap integral

Proton-assisted dissociation of a triple-stranded dinuclear europium helicate

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