Dendritic upconverting nanoparticles enable in vivo multiphoton microscopy with low-power continuous wave sources

Esipova, Tatiana V.; Ye, Xingchen; Collins, Joshua E.; Sakadžić, Sava; Mandeville, Emiri T.; Murray, Christopher B.; Vinogradov, Sergei A.

doi:10.1073/pnas.1213291110

Cited by 87 publications

(75 citation statements)

References 56 publications

(63 reference statements)

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“…980 nm) that could lead to tissue heating, but also slower scanning speed (20~200 μs/pixel) due to long fluorescence lifetimes. 23,24 Fluorescent polymers or silica typically suffers from dye leaching after their biodegradation. QDs, although excitable with a wide range of wavelengths, suffer from potential cadmium ion toxicity.…”

Section: Resultsmentioning

confidence: 99%

Optically enhanced blood-brain-barrier crossing of plasmonic-active nanoparticles in preclinical brain tumor animal models

Yuan

Wilson

et al. 2014

SPIE Proceedings

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Nanotechnology provides tremendous biomedical opportunities for cancer diagnosis, imaging, and therapy. In contrast to conventional chemotherapeutic agents where their actual target delivery cannot be easily imaged, integrating imaging and therapeutic properties into one platform facilitates the understanding of pharmacokinetic profiles, and enables monitoring of the therapeutic process in each individual. Such a concept dubbed "theranostics" potentiates translational research and improves precision medicine. One particular challenging application of theranostics involves imaging and controlled delivery of nanoplatforms across blood-brain-barrier (BBB) into brain tissues. Typically, the BBB hinders paracellular flux of drug molecules into brain parenchyma. BBB disrupting agents (e.g. mannitol, focused ultrasound), however, suffer from poor spatial confinement. It has been a challenge to design a nanoplatform not only acts as a contrast agent but also improves the BBB permeation. In this study, we demonstrated the feasibility of plasmonic gold nanoparticles as both high-resolution optical contrast agent and focalized tumor BBB permeation-inducing agent. We specifically examined the microscopic distribution of nanoparticles in tumor brain animal models. We observed that most nanoparticles accumulated at the tumor periphery or perivascular spaces. Nanoparticles were present in both endothelial cells and interstitial matrices. This study also demonstrated a novel photothermal-induced BBB permeation. Fine-tuning the irradiating energy induced gentle disruption of the vascular integrity, causing short-term extravasation of nanomaterials but without hemorrhage. We conclude that our gold nanoparticles are a powerful biocompatible contrast agent capable of inducing focal BBB permeation, and therefore envision a strong potential of plasmonic gold nanoparticle in future brain tumor imaging and therapy.

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Section: Resultsmentioning

confidence: 99%

Optically enhanced blood-brain-barrier crossing of plasmonic-active nanoparticles in preclinical brain tumor animal models

Yuan

Wilson

et al. 2014

SPIE Proceedings

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“…Since then, lanthanide doped NPs have been efficiently detected when injected deep in a rat and have allowed tracking cells in live animals [28]. Vinogradov and co-workers reported the use of UCNP doped with both Yb 3+ and Er 3+ to acquire vascular images with high contrast and resolution up to 340 mm deep into a mouse brain (see Figure 2b) [48 ]. To enhance the depth of in vivo imaging, further works focused on the synthesis of biocompatible NIR-to-NIR up conversion nanoparticles [49].…”

Section: Nonlinear Excitation/upconversionmentioning

confidence: 96%

“…NDs fluorescence, for example, depends on the spin properties of their ground state, and can therefore be modulated by an external magnetic field or a microwave irradiation. Since autofluorescence 68 Nanobiotechnology [48 ] with permission from the National Academy of Sciences); (c) whole-body imaging of a nude mouse injected via tail vein with NIR-to-NIR core-shell nanoparticles. (Reproduced from ref.…”

Section: Compoundmentioning

confidence: 99%

Enhancing fluorescence in vivo imaging using inorganic nanoprobes

Bouccara¹,

Sitbon²,

Fragola³

et al. 2015

Current Opinion in Biotechnology

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Fluorescence imaging is a versatile tool for biological and preclinical studies with steady improvements in performance thanks to instrumentation and probe developments. The sensitive detection and imaging of deep targets in vivo is especially challenging due to the diffusion and absorption of light by the tissues and to the emission of autofluorescence from intrinsic chromophores. Fluorescent inorganic nanoparticles present interesting optical properties that may significantly differ from organic dyes. In this short review, we present recent developments in the design of these nanoprobes and their use for new in vivo fluorescence modalities which provide enhanced imaging capabilities.

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“…NIRF is a high sensitivity technique, with relatively poor resolution. A variety of different nanomaterial-based delivery systems have been developed for NIRF, including fluorochrome-labelled PEG, dextran, silica and other polymeric nanomaterials [88, 89] as well as surface-stabilized quantum dots [90, 91]. Lobatto et al recently correlated MRI images of vascular permability in atherosclerotic lesions with the uptake of liposomal nanoparticles conjugated to the NIRF dye Cy7 both in vivo and ex vivo [69].…”

Section: Nanomaterials To Enhance the Imaging Of Atherosclerosismentioning

confidence: 99%

Engineering Nanomaterials to Address Cell-Mediated Inflammation in Atherosclerosis

Allen

Liu²,

Scott

2016

Regen. Eng. Transl. Med.

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Atherosclerosis is an inflammatory disorder with a pathophysiology driven by both innate and adaptive immunity and a primary cause of cardiovascular disease (CVD) worldwide. Vascular inflammation and accumulation of foam cells and their products induce maturation of atheromas, or plaques, which can rupture by metalloprotease action, leading to ischemic stroke or myocardial infarction. Diverse immune cell populations participate in all stages of plaque maturation, many of which directly influence plaque stability and rupture via inflammatory mechanisms. Current clinical treatments for atherosclerosis focus on lowering serum levels of low-density lipoprotein (LDL) using therapeutics such as statins, administration of antithrombotic drugs, and surgical intervention. Strategies that address cell-mediated inflammation are lacking, and consequently have recently become an area of considerable research focus. Nanomaterials have emerged as highly advantageous tools for these studies, as they can be engineered to target specific inflammatory cell populations, deliver therapeutics of wide-ranging solubilities and enhance analytical methods that include imaging and proteomics. Furthermore, the highly phagocytic nature of antigen presenting cells (APCs), a diverse cell population central to the initiation of immune responses and inflammation, make them particularly amenable to targeting and modulation by nanoscale particulates. Nanomaterials have therefore become essential components of vaccine formulations and treatments for inflammation-driven pathologies like autoimmunity, and present novel opportunities for immunotherapeutic treatments of CVD. Here, we review recent progress in the design and use of nanomaterials for therapeutic assessment and treatment of atherosclerosis. We will focus on promising new approaches that utilize nanomaterials for cell-specific imaging, gene therapy and immunomodulation.

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Dendritic upconverting nanoparticles enable in vivo multiphoton microscopy with low-power continuous wave sources

Cited by 87 publications

References 56 publications

Optically enhanced blood-brain-barrier crossing of plasmonic-active nanoparticles in preclinical brain tumor animal models

Optically enhanced blood-brain-barrier crossing of plasmonic-active nanoparticles in preclinical brain tumor animal models

Enhancing fluorescence in vivo imaging using inorganic nanoprobes

Engineering Nanomaterials to Address Cell-Mediated Inflammation in Atherosclerosis

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