Patrick Wunderbaldinger scite author profile

Superparamagnetic nanoparticles have a number of important biomedical applications, serving as MR contrast agents for imaging specific molecular targets, as reagents for cell labeling and cell tracking, and for the isolation of specific classes of cells. We have determined the physical and biological properties of MION-47 and amino-CLIO, nanoparticles which serve as precursors for the synthesis of targeted MR contrast agents, and Tat-CLIO, a nanoparticle used as a cell labeling reagent. Blood half-lives for MION-47 and amino-CLIO were 682 +/- 34 and 655 +/- 37 min, respectively. The attachment of 9.7 tat peptides per crystal to amino-CLIO resulted in a reduction in blood half-life to 47 +/- 6 min. MION-47, amino-CLIO, and Tat-CLIO were present in highest concentrations in liver and spleen and lymph nodes, where concentrations for all three nanoparticles ranged from 8.80 to 6.11% of injected dose per gram. Twenty-four hours after the intravenous injection of amino-CLIO, the nanoparticle was concentrated in cells surrounding hepatic blood vessels (endothelial and Kupffer cells), in a fashion similar to that obtained with other nanoparticle preparations. In contrast, Tat-CLIO was present as numerous discrete foci of intense fluorescence throughout the parenchyma. Using the peptide as a component of future nanoparticles, it might be possible to design sensors for the detection of macromolecules present in intracellular compartments.

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Brain tumour imaging with PET: a comparison between [ 18 F]fluorodopa and [ 11 C]methionine

Becherer

Karanikas

Szabó

et al. 2003

European Journal of Nuclear Medicine and Molecular Imaging

253

155

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Imaging of amino acid transport in brain tumours is more sensitive than fluorine-18 2-fluoro-deoxyglucose positron emission tomography (PET). The most frequently used tracer in this field is carbon-11 methionine (MET), which is unavailable for PET centres without a cyclotron because of its short half-life. The purpose of this study was to evaluate the performance of 3,4-dihydroxy-6-[(18)F]fluoro-phenylalanine (FDOPA) in this setting, in comparison with MET. Twenty patients with known supratentorial brain lesions were referred for PET scans with FDOPA and MET. The diagnoses were 18 primary brain tumours, one metastasis and one non-neoplastic cerebral lesion. All 20 patients underwent PET with FDOPA (100 MBq, 20 min p.i.), and 19 of them also had PET scans with MET (800 MBq, 20 min p.i.). In all but one patient a histological diagnosis was available. In 15 subjects, histology was known from previous surgical interventions; in five of these patients, as well as in four previously untreated patients, histology was obtained after PET. In one untreated patient, confirmation of PET was possible solely by correlation with MRI; a histological diagnosis became available 10 months later. MET and FDOPA images matched in all patients and showed all lesions as hot spots with higher uptake than in the contralateral brain. Standardised uptake value ratios, tumour/contralateral side (mean+/-SD), were 2.05+/-0.91 for MET and 2.04+/-0.53 for FDOPA (NS). The benign lesion, which biopsy revealed to be a focal demyelination, was false positive, showing increased uptake of MET and FDOPA. We conclude that FDOPA is accurate as a surrogate for MET in imaging amino acid transport in malignant cerebral lesions for the purpose of visualisation of vital tumour tissue. It combines the good physical properties of (18)F with the pharmacological properties of MET and might therefore be a valuable PET radiopharmaceutical in brain tumour imaging.

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Cystic Fibrosis: CT Assessment of Lung Involvement in Children and Adults

Helbich¹,

Heinz-Peer²,

Eichler³

et al. 1999

Radiology

205

137

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Tumor microvascular changes in antiangiogenic treatment: Assessment by magnetic resonance contrast media of different molecular weights

Turetschek

Preda

Novikov

et al. 2004

Magnetic Resonance Imaging

111

115

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Purpose:To test magnetic resonance (MR) contrast media of different molecular weights (MWs) for their potential to characterize noninvasively microvascular changes in an experimental tumor treatment model. Materials and Methods:MD-MBA-435, a poorly differentiated human breast cancer cell line, was implanted into 31 female homozygous athymic rats. Animals were assigned randomly to a control (saline) or drug treatment (monoclonal antibody vascular endothelial growth factor (Mab-VEGF) antibody) group. In both groups, dynamic MR imaging (MRI) was performed in each animal using up to three different contrast media on sequential days at baseline and follow-up examination. The MWs of the contrast media used ranged from 557 Da to 92 kDa. Using a bidirectional kinetic model, tumor microvessel characteristics, including the fractional plasma volume (fPV) and transendothelial permeability (K PS ), were estimated for each contrast medium. These microvascular characteristics were compared between drug and control groups and between contrast media of different MWs.Results: Tumors grew significantly slower (P Ͻ 0.0005) in the drug treatment group than in the control group. Mean K PS and fPV values decreased significantly (P Ͻ 0.05) in the Mab-VEGF antibody-treated group compared to baseline values using intermediate or macromolecular contrast media (MMCM), but did not change significantly using small molecular contrast media (SMCM). In the control groups, mean K PS and mean fPV values did not reach statistical significance for any of the contrast media used. Conclusion:Therapeutic effects of a Mab-VEGF antibody on tumor microvessel characteristics can be monitored by dynamic MRI. Intermediate-size agents, such as Gadomer-17, offer a substantial dynamic range and are less limited by imaging precision and therefore should be considered a practical alternative to monitor antiangiogenesis treatment effects in a clinical setting.

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