Functionality is Key: Recent Progress in the Surface Modification of Nanodiamond

Krueger, Anke; Lang, Daniel G.

doi:10.1002/adfm.201102670

Cited by 530 publications

(460 citation statements)

References 152 publications

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“…[4][5][6] In addition, they can host photostable optically active defects, such as the nitrogen vacancy (NV) or the silicon vacancy (SiV) that have already been shown as effective bioimaging probes. [7][8][9][10] Moreover, single NV defects can be leveraged for high resolution magnetometry and sensing of single spins and individual biomolecules with unprecedented sensitivity.…”

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confidence: 99%

Enhanced photoluminescence from single nitrogen-vacancy defects in nanodiamonds coated with phenol-ionic complexes

et al. 2015

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Fluorescent nanodiamonds are attracting major attention in the field of bio-sensing and biolabeling. In this work we demonstrate a robust approach to surface functionalize individual nanodiamonds with metal-phenolic networks that enhance the photoluminescence from single nitrogen vacancy (NV) centers. We show that single NV centres in the coated nanodiamonds also exhibit shorter lifetimes, opening another channel for high resolution sensing. We propose that the nanodiamond encapsulation suppresses the non-radiative decay pathways of the NV color centers. Our results provide a versatile and assessable way to enhance photoluminescence from nanodiamond defects that can be used in a variety of sensing and imaging applications.

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confidence: 99%

Enhanced photoluminescence from single nitrogen-vacancy defects in nanodiamonds coated with phenol-ionic complexes

et al. 2015

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“…First, atomic changes in ND structure produces bright optical defects that possess unrivalled photostability, even for the smallest NDs (~5-10 nm) [4,5]. Second, being made of carbon, they are biocompatible, non-toxic and highly amenable to surface functionalization, enabling the conjugation of biomolecules such as DNA and proteins [6][7][8]. Despite these promising features, further improvement of the optical properties of NDs could enhance their utility as fluorescent biomarkers.…”

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confidence: 99%

Nanodiamonds with silicon vacancy defects for nontoxic photostable fluorescent labeling of neural precursor cells

et al. 2013

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Nanodiamonds (NDs) containing silicon vacancy (SiV) defects were evaluated as a potential biomarker for the labeling and fluorescent imaging of neural precursor cells (NPCsFluorescent biomarkers for labeling cellular and molecular targets are emerging as increasingly important tools in biomedical research and medicine. The range of potential applications is diverse, from monitoring drug or tumor localization within the body [1], to assessing the migration of transplanted stem cells used in cell based therapies [2]. A major goal is to develop improved fluorescent labeling reagents that achieve optimal fluorescence intensity without photo-bleaching or blinking. These latter properties are observed with most currently used fluorescent proteins, quantum dots, metallic and dielectric beads and hinders their use for long-term repeated imaging applications [3]. An additional goal is to generate fluorescent biomarkers that can be specifically targeted to distinct cellular or molecular targets via the conjugation of antibodies, growth factors, organic chemicals or drugs. In these respects, nanodiamonds (NDs) offer several advantages. First, atomic changes in ND structure produces bright optical defects that possess unrivalled photostability, even for the smallest NDs (~5-10 nm) [4,5]. Second, being made of carbon, they are biocompatible, non-toxic and highly amenable to surface functionalization, enabling the conjugation of biomolecules such as DNA and proteins [6][7][8]. Despite these promising features, further improvement of the optical properties of NDs could enhance their utility as fluorescent biomarkers. The most common optical defect that can be "naturally" incorporated into the NDs is a nitrogen vacancy center (NV), a nitrogen atom close to a vacancy in the diamond lattice [9]. NV emits over a broad range of wavelengths (575 -800 nm), and has been explored as a potential candidate for atomic resolution magnetic resonance imaging [10]. However despite its promising properties for magnetic sensing, the optical properties of NV centers are not ideal. Specifically, its peak absorption at 532 nm overlaps with wavelengths that excite cellular auto-fluorescence and the

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“…62 So as a unique quasi one-dimensional material, they have been explored as novel delivery vehicles for drugs, 63 proteins 64 and so on. Another intrinsic property of SWNTs is their strong optical absorbance in the NIR region, [65][66][67][68] which makes SWNTs appropriate to be used as agents for PAI.…”

Section: Carbon Npmentioning

confidence: 99%

Photoacoustic molecular imaging with functional nanoparticles

Qin

2017

J. Innov. Opt. Health Sci.

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Photoacoustic imaging (PAI) breaks through the optical di®usion limit by making use of the PA e®ect. By converting incident photons into ultrasonic waves, PAI combines high contrast of optical imaging and high spatial resolution in depth tissue of ultrasound imaging in a single imaging modality. This imaging modality has now shown potential for molecular imaging, which enables visualization of biological processes with systemically introduced functional nanoparticles. In the current review, the potentials of di®erent optical nanoprobes as PAI contrast agents were elucidated and discussed.

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Functionality is Key: Recent Progress in the Surface Modification of Nanodiamond

Cited by 530 publications

References 152 publications

Enhanced photoluminescence from single nitrogen-vacancy defects in nanodiamonds coated with phenol-ionic complexes

Enhanced photoluminescence from single nitrogen-vacancy defects in nanodiamonds coated with phenol-ionic complexes

Nanodiamonds with silicon vacancy defects for nontoxic photostable fluorescent labeling of neural precursor cells

Photoacoustic molecular imaging with functional nanoparticles

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