Nanodiamonds as Intracellular Probes for Imaging in Biology and Medicine

Šlegerová, Jitka; Řehoř, Ivan; Havlík, Jan; Raabová, Helena; Muchová, Eva; Cígler, Petr

doi:10.1007/978-94-017-8896-0_18

Cited by 18 publications

(14 citation statements)

References 171 publications

(346 reference statements)

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“…Fluorescent nanodiamonds (FNDs), recently introduced biocompatible near-infrared fluorescent probes, do not possess any of these disadvantages, which renders them promising nanoparticles for bioimaging applications. [1][2][3] Point defects in the crystal lattice structure called nitrogen-vacancy (NV) centers are responsible for the fluorescence of FNDs. NV centers are non-photobleachable and non-photoblinking fluorophores with maximum emission around 700 nm (ref.…”

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confidence: 99%

Designing the nanobiointerface of fluorescent nanodiamonds: highly selective targeting of glioma cancer cells

et al. 2015

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Core-shell nanoparticles based on fluorescent nanodiamonds coated with a biocompatible N-(2-hydroxypropyl)methacrylamide copolymer shell were developed for background-free near-infrared imaging of cancer cells. The particles showed excellent colloidal stability in buffers and culture media. After conjugation with a cyclic RGD peptide they selectively targeted integrin αvβ3 receptors on glioblastoma cells with high internalization efficacy.

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confidence: 99%

Designing the nanobiointerface of fluorescent nanodiamonds: highly selective targeting of glioma cancer cells

et al. 2015

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“…Furthermore, if properly functionalized, the NDs can anchor themselves to the surface of the cell sample in the targeted areas. [ 160–162 ]…”

Section: Methods and Bio‐applicationsmentioning

confidence: 99%

Is a Quantum Biosensing Revolution Approaching? Perspectives in NV‐Assisted Current and Thermal Biosensing in Living Cells

et al. 2020

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Understanding the human brain is one of the most significant challenges of the 21st century. As theoretical studies continue to improve the description of the complex mechanisms that regulate biological processes, in parallel numerous experiments are conducted to enrich or verify these theoretical predictions also with the aim of extrapolating more accurate models. In the fields of magnetometry and thermometry, among the various sensors proposed for biological application, nitrogen-vacancy (NV) centers are emerging as a promising solution due to their perfect biocompatibility and the possibility of being positioned in close proximity to the cell membrane, thus allowing a nanometric spatial resolution down to the nano-scale. Still many issues must be overcome to obtain either a sensitivity capable of revealing the very weak electromagnetic fields generated by neurons (or other excitable cells) during their firing activity or a spatial resolution sufficient to measure intracellular thermal gradient due to biological processes. However, over the last few years, significant improvements have been achieved in this direction, thanks to the use of innovative techniques. In this review, the new results regarding the application of NV centers will be analyzed and the main challenges that must be afforded for leading to practical applications will be discussed.

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“…The glass face of the chip device was coated with collagen to improve the cell adhesion before seeding. We then introduced carboxylated NDs into HeLa cells by endocytosis, as previously described [55,73]. Figure 6(b) shows a low-magnification bright-field image of HeLa cells in the chip devices.…”

Section: Biological Application: Cultured Cellsmentioning

confidence: 99%

Glass-patternable notch-shaped microwave architecture for on-chip spin detection in biological samples

Oshimi,

Nishimura,

Matsubara

et al. 2022

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We report a notch-shaped coplanar microwave waveguide antenna on a glass plate designed for on-chip detection of optically detected magnetic resonance (ODMR) of fluorescent nanodiamonds (NDs). A lithographically patterned thin wire at the center of the notch area in the coplanar waveguide realizes a millimeter-scale ODMR detection area (1.5 × 2.0 mm 2 ) and gigahertz-broadband characteristics with low reflection (∼ 8%). The ODMR signal intensity in the detection area is quantitatively predictable by numerical simulation. Using this chip device, we demonstrate a uniform ODMR signal intensity over the detection area for cells, tissue, and worms. The present demonstration of a chip-based microwave architecture will enable scalable chip integration of ODMR-based quantum sensing technology into various bioassay platforms.

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Nanodiamonds as Intracellular Probes for Imaging in Biology and Medicine

Cited by 18 publications

References 171 publications

Designing the nanobiointerface of fluorescent nanodiamonds: highly selective targeting of glioma cancer cells

Designing the nanobiointerface of fluorescent nanodiamonds: highly selective targeting of glioma cancer cells

Is a Quantum Biosensing Revolution Approaching? Perspectives in NV‐Assisted Current and Thermal Biosensing in Living Cells

Glass-patternable notch-shaped microwave architecture for on-chip spin detection in biological samples

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