Targeted Gold Nanoparticles Enable Molecular CT Imaging of Cancer

Popovtzer, Rachela; Agrawal, Ashish Kumar; Kotov, Nicholas A.; Popovtzer, Aron; Balter, James M.; Carey, Thomas E.; Kopelman, Raoul

doi:10.1021/nl8029114

Cited by 723 publications

(570 citation statements)

References 31 publications

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“…Our extensive in vivo studies (in mice, pigs, and dogs) have confirmed that gold nanoparticles (AuNPs) show significantly higher x-ray absorption characteristics than iodinated CT agents (8,9,14,15). Recently, Kopelman and co-workers have demonstrated the feasibility of using targeted AuNPs embedded in cancer cells for CT imaging under in vitro conditions (16). Despite considerable progress achieved to date toward the development of target-specific AuNPs for use in early cancer detection, a vast majority of these systems perform well only under in vitro profiles and fail to maintain target specificity/efficacy under in vivo conditions (17).…”

mentioning

confidence: 76%

Bombesin functionalized gold nanoparticles show in vitro and in vivo cancer receptor specificity

Chanda¹,

Kattumuri²,

Shukla³

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

293

245

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Development of cancer receptor-specific gold nanoparticles will allow efficient targeting/optimum retention of engineered gold nanoparticles within tumors and thus provide synergistic advantages in oncology as it relates to molecular imaging and therapy. Bombesin (BBN) peptides have demonstrated high affinity toward gastrin-releasing peptide (GRP) receptors in vivo that are overexpressed in prostate, breast, and small-cell lung carcinoma. We have synthesized a library of GRP receptor-avid nanoplatforms by conjugating gold nanoparticles (AuNPs) with BBN peptides. Cellular interactions and binding affinities (IC 50 ) of AuNP-BBN conjugates toward GRP receptors on human prostate cancer cells have been investigated in detail. In vivo studies using AuNP-BBN and its radiolabeled surrogate 198 AuNP-BBN, exhibiting high binding affinity (IC 50 in microgram ranges), provide unequivocal evidence that AuNP-BBN constructs are GRP-receptor-specific showing accumulation with high selectivity in GRP-receptor-rich pancreatic acne in normal mice and also in tumors in prostate-tumor-bearing, severe combined immunodeficient mice. The i.p. mode of delivery has been found to be efficient as AuNP-BBN conjugates showed reduced RES organ uptake with concomitant increase in uptake at tumor targets. The selective uptake of this new generation of GRP-receptor-specific AuNP-BBN peptide analogs has demonstrated realistic clinical potential in molecular imaging via x-ray computed tomography techniques as the contrast numbers in prostate tumor sites are severalfold higher as compared to the pretreatment group (Hounsfield unit = 150).gold nanoparticles | bombesin | gastrin-releasing peptide receptor | prostate cancer | computed tomography imaging

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mentioning

confidence: 76%

Bombesin functionalized gold nanoparticles show in vitro and in vivo cancer receptor specificity

Chanda¹,

Kattumuri²,

Shukla³

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

293

245

View full text Add to dashboard Cite

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“…Furthermore, NPs can be attached to antibodies to actively target key tumour characteristics in order to inform treatment options and prognosis (Popovtzer et al 2008, Jiao et al 2011.…”

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confidence: 99%

An x-ray fluorescence imaging system for gold nanoparticle detection

et al. 2013

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Gold nanoparticles (GNPs) may be used as a contrast agent to identifytumour location and can be modified to target-and image-specific tumour biological parameters. There are currently no imaging systems in the literature that have sufficient sensitivity to GNP concentration and distribution measurement at sufficient tissue depth for use in in vivo and in vitro studies. We have demonstrated that high detecting sensitivity of GNPs can be achieved using x-ray fluorescence; furthermore this technique enables higher depth imaging in comparison to optical modalities. Two x-ray fluorescence systems were developed and used to image a range of GNP imaging phantoms. The first system consisted of a 10 mm 2 silicon drift detector coupled to a slightly focusing polycapillary optic which allowed 2D energy resolved imaging in step and scan mode. The system has sensitivity to GNP concentrations as low as 1 ppm. GNP concentrations different by a factor of 5 could be resolved, offering potential to distinguish tumour from non-tumour. The second system was designed to avoid slow step and scan image acquisition; the feasibility of excitation of the whole specimen with a wide beam and detection of the fluorescent x-rays with a pixellated controlled drift energy resolving detector without scanning was investigated. A parallel polycapillary optic coupled to the detector was successfully used to ascertain the position where fluorescence was emitted. The tissue penetration of the technique was demonstrated to be sufficient for nearsurface small-animal studies, and for imaging 3D in vitro cellular constructs. Previous work demonstrates strong potential for both imaging systems to form quantitative images of GNP concentration.

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“…Macrophages are known as 'big eaters', that phagocytose nanomaterials like GNP with high rate [86]. The GNP have long been used in the detection and imaging of biological processes and diseases [46,47,61,62,70,87]. The broad range of GNP applications is based on their unique chemical and physical properties and, in particular, on their optical properties from the visible to the IR region, depending on the particle size, shape, and structure [88,89].…”

Section: Magnetic Particlesmentioning

confidence: 99%

Nanoparticle uptake by macrophages in vulnerable plaques for atherosclerosis diagnosis

Melzer

Ankri

Fixler

et al. 2015

Journal of Biophotonics

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The composition of atherosclerotic (AS) plaques is crucial concerning rupture, thrombosis and clinical events. Two plaque types are distinguished: stable and vulnerable plaques. Vulnerable plaques are rich in inflammatory cells, mostly only M1 macrophages, and are highly susceptible to rupture. These plaques represent a high risk particularly with the standard invasive diagnosis by coronary angiography. So far there are no non‐invasive low‐risk clinical approaches available to detect and distinguish AS plaque types in vivo. The perspective review introduces a whole work‐flow for a novel approach for non‐invasive detection and classification of AS plaques using the diffusion reflection method with gold nanoparticle loaded macrophages in combination with flow and image cytometric analysis for quality assurance. Classical biophotonic methods for AS diagnosis are summarized. Phenotyping of monocytes and macrophages are discussed for specific subset labelling by nanomaterials, as well as existing studies and first experimental proofs of concept for the novel approach are shown.

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Targeted Gold Nanoparticles Enable Molecular CT Imaging of Cancer

Cited by 723 publications

References 31 publications

Bombesin functionalized gold nanoparticles show in vitro and in vivo cancer receptor specificity

Bombesin functionalized gold nanoparticles show in vitro and in vivo cancer receptor specificity

An x-ray fluorescence imaging system for gold nanoparticle detection

Nanoparticle uptake by macrophages in vulnerable plaques for atherosclerosis diagnosis

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