Targeted In Vivo Labeling of Receptors for Vascular Endothelial Growth Factor

Lu, Erxiong; Wagner, William R.; Schellenberger, Ute; Abraham, Judith A.; Klibanov, Alexander L.; Woulfe, Steven R.; Csikari, Melissa; Fischer, David W.; Schreiner, George F.; Brandenburger, Gary H.; Villanueva, Flordeliza S.

doi:10.1161/01.cir.0000079100.38176.83

Cited by 106 publications

(64 citation statements)

References 33 publications

(39 reference statements)

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“…Recombinant human VEGF 121 has been labeled with 111 In for identification of ischemic tissue in a rabbit model, where unilateral hind limb ischemia was created by femoral artery excision (18). However, virtually no difference was observed between the ischemic hind limb and the contralateral hind limb.…”

Section: Imaging Vegf and Vegfr Expressionmentioning

confidence: 99%

“…It was found that antibody distribution and clearance were quite heterogeneous not only between patients but also between individual tumors of the same patient, suggesting that intra-patient dose escalation approaches or more precisely defined patient cohorts would be preferred in the design of phase I studies with antiangiogenic antibodies such as HuMV833. 18 F for PET imaging applications as good tumor-to-background ratio was achieved as early as 1 to 2 hours after injection.…”

Section: Imaging Vegf and Vegfr Expressionmentioning

confidence: 99%

“…Monomeric RGD peptide c(RGDyV) was first labeled with 125 I by Haubner et al (48). A glycopeptide based on c(RGDfK) was later labeled with 18 F via a 2-[ 18 F]fluoropropionate prosthetic group, and the resulting [ 18 F]galacto-RGD exhibited integrin a v h 3 -specific tumor uptake in integrin-positive M21 melanoma xenograft model (49). Initial clinical trials in healthy volunteers and a limited number of cancer patients revealed that this tracer can be safely given to patients and is able to delineate certain lesions that are integrin positive ( Fig.…”

Section: Non^radionuclide-based Imaging Of Integrinmentioning

confidence: 99%

“…We have labeled a series of RGD peptides with 18 F for PET imaging, using PEGylation and polyvalency to improve the tumor-targeting efficacy and pharmacokinetics (51 -56). Fig.…”

Section: Non^radionuclide-based Imaging Of Integrinmentioning

confidence: 99%

“…In addition to 18 F, 64 Cu-labeled RGD peptides are also of considerable interest. Copper-64 is an attractive radionuclide for both PET imaging and targeted radiotherapy of cancer.…”

Section: Non^radionuclide-based Imaging Of Integrinmentioning

confidence: 99%

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How molecular imaging is speeding up antiangiogenic drug development

Cai¹,

Rao²,

Gambhir

et al. 2006

Molecular Cancer Therapeutics

172

149

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Drug development is a long process that generally spans about 10 to 15 years. The shift in recent drug discovery to novel agents against specific molecular targets highlights the need for more robust molecular imaging platforms. Using molecular probes, molecular imaging can aid in many steps of the drug development process, such as providing whole body readout in an intact system, decreasing the workload and speeding up drug development/validation, and facilitating individualized anticancer treatment monitoring and dose optimization. The main focus of this review is the recent advances in tumor angiogenesis imaging, and the targets include vascular endothelial growth factor and vascular endothelial growth factor receptor, integrin A v B 3 , matrix metalloproteinase, endoglin (CD105), and E-selectin. Through tumor angiogenesis imaging, it is expected that a robust platform for understanding the mechanisms of tumor angiogenesis and evaluating the efficacy of novel antiangiogenic therapies will be developed, which can help antiangiogenic drug development in both the preclinical stage and the clinical settings. Molecular imaging has enormous potential in improving the efficiency of the drug development process, including the specific area of antiangiogenic drugs.

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Section: Imaging Vegf and Vegfr Expressionmentioning

confidence: 99%

Section: Imaging Vegf and Vegfr Expressionmentioning

confidence: 99%

Section: Non^radionuclide-based Imaging Of Integrinmentioning

confidence: 99%

“…We have labeled a series of RGD peptides with 18 F for PET imaging, using PEGylation and polyvalency to improve the tumor-targeting efficacy and pharmacokinetics (51 -56). Fig.…”

Section: Non^radionuclide-based Imaging Of Integrinmentioning

confidence: 99%

“…In addition to 18 F, 64 Cu-labeled RGD peptides are also of considerable interest. Copper-64 is an attractive radionuclide for both PET imaging and targeted radiotherapy of cancer.…”

Section: Non^radionuclide-based Imaging Of Integrinmentioning

confidence: 99%

See 3 more Smart Citations

How molecular imaging is speeding up antiangiogenic drug development

Cai¹,

Rao²,

Gambhir

et al. 2006

Molecular Cancer Therapeutics

172

149

View full text Add to dashboard Cite

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Cardiac Imaging

Santos

Ledesma-Carbayo

2006

Wiley Encyclopedia of Biomedical Engineering

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The aim of cardiac imaging is to contribute to the diagnosis of cardiac and vascular diseases by detecting early signs of abnormal activity, and to contribute to therapy follow‐up. Cardiac imaging attempts to detect global or local abnormalities in morphology, function, perfusion, and metabolism of the heart and vessels, including the evaluation of myocardial viability and artery plaques. The main imaging modalities are presented here. X‐ray angiography is useful for assessing heart and vessel anatomy, although it is an invasive modality requiring catheterization. Echocardiography is a widespread, cheap, and non‐invasive modality that can analyze cardiac anatomy, tissue and blood motion, and perfusion. Traditionally, nuclear imaging with thallium or technetium has been used to detect myocardial perfusion defects. Recently, molecular imaging, using positron emission tomography, has been proposed to identify molecular processes like angiogenesis or apoptosis. Cardiac magnetic resonance imaging is attracting increasing interest as it can now produce high‐quality images with good spatial resolution. Apart from evaluating anatomy, it also allows assessment of tissue and blood motion, perfusion, and myocardial viability. Finally, ultrafast computed tomography may also produce high‐resolution images of the heart and great vessels, showing and characterizing their function and assessing plaques in coronary arteries. As will be seen, currently available imaging modalities are complementary, showing different characteristics of cardiovascular structures and helping to achieve an accurate and early diagnosis of cardiovascular diseases.

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