Graphene Quantum Dots with High Yield and High Quality Synthesized from Low Cost Precursor of Aphanitic Graphite

Shen, Shuling; Wang, Junjie; Wu, Zhujun; Du, Zheng; Tang, Zhihong; Yang, Jing

doi:10.3390/nano10020375

Cited by 45 publications

(32 citation statements)

References 47 publications

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“…32 Nonetheless, their emissions can be tuned (mostly from blue to orange) by heteroatoms and the size of sp 2 carbon systems in the particle. [33][34][35] CNDs have similar properties to generic N-doped carbon nanodots. They possess a higher fluorescence quantum yield (QY) than typical CDs and usually have emission wavelengths skewed towards the blue light.…”

Section: Carbon Dotsmentioning

confidence: 94%

Carbon Dots: A Future Blood–Brain Barrier Penetrating Nanomedicine and Drug Nanocarrier

Zhang

Sigdel

Mintz

et al. 2021

IJN

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Drug delivery across the blood–brain barrier (BBB) is one of the biggest challenges in modern medicine due to the BBB’s highly semipermeable property that limits most therapeutic agents of brain diseases to enter the central nervous system (CNS). In recent years, nanoparticles, especially carbon dots (CDs), exhibit many unprecedented applications for drug delivery. Several types of CDs and CD-ligand conjugates have been reported successfully penetrating the BBB, which shows a promising progress in the application of CD-based drug delivery system (DDS) for the treatment of CNS diseases. In this review, our discussion of CDs includes their classification, preparations, structures, properties, and applications for the treatment of neurodegenerative diseases, especially Alzheimer’s disease (AD) and brain tumor. Moreover, abundant functional groups on the surface, especially amine and carboxyl groups, allow CDs to conjugate with diverse drugs as versatile drug nanocarriers. In addition, structure of the BBB is briefly described, and mechanisms for transporting various molecules across the BBB and other biological barriers are elucidated. Most importantly, recent developments in drug delivery with CDs as BBB-penetrating nanodrugs and drug nanocarriers to target CNS diseases especially Alzheimer’s disease and brain tumor are summarized. Eventually, future prospects of the CD-based DDS are discussed in combination with the development of artificial intelligence and nanorobots.

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Section: Carbon Dotsmentioning

confidence: 94%

Carbon Dots: A Future Blood–Brain Barrier Penetrating Nanomedicine and Drug Nanocarrier

Zhang

Sigdel

Mintz

et al. 2021

IJN

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“…Oxygen-containing functional groups are responsible for good solubility in polar solvents such as water or ethanol [7,8] in the concentration of 5 mg mL −1 [9] or even higher, > 15 mg mL −1 [10]. Properties that distinguish GQDs from other carbon nanomaterials such as carbon nanotubes and graphene, are high dispersibility in water and polar organic solvents, photoluminescence [11], good biocompatibility [12].…”

Section: Introductionmentioning

confidence: 99%

Gamma irradiation of graphene quantum dots with ethylenediamine: Antioxidant for ion sensing

Jovanović

Dorontić

Jovanović

et al. 2020

Ceramics International

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“…The variance in application outcomes usually depends on the morphology and material properties, which are primarily determined by the method of synthesis [47]. GQDs consisting of carbon-rich materials used as precursors, such as graphite, polysaccharides, fullerene, graphene oxide (GO), CNT, and carbon fiber (CF) [48,49]. To synthesize GQDs, there are two main methods used, namely, top-down and bottom-up strategies.…”

Section: Synthetic Routes Of Gqdsmentioning

confidence: 99%

Outstanding Graphene Quantum Dots from Carbon Source for Biomedical and Corrosion Inhibition Applications: A Review

et al. 2021

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Graphene quantum dots (GQD) is an efficient nanomaterial composed of one or more layers of graphene with unique properties that combine both graphene and carbon dots (CDs). It can be synthesized using carbon-rich materials as precursors, such as graphite, macromolecules polysaccharides, and fullerene. This contribution emphasizes the utilization of GQD-based materials in the fields of sensing, bioimaging, energy storage, and corrosion inhibitors. Inspired by these numerous applications, various synthetic approaches have been developed to design and fabricate GQD, particularly bottom-up and top-down processes. In this context, the prime goal of this review is to emphasize possible eco-friendly and sustainable methodologies that have been successfully employed in the fabrication of GQDs. Furthermore, the fundamental and experimental aspects associated with GQDs such as possible mechanisms, the impact of size, surface alteration, and doping with other elements, together with their technological and industrial applications have been envisaged. Till now, understanding simple photo luminance (PL) operations in GQDs is very critical as well as there are various methods derived from the optical properties of manufactured GQDs can differ. Lack of determining exact size and morphology is highly required without loss of their optical features. Finally, GQDs are promising candidates in the after-mentioned application fields.

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Graphene Quantum Dots with High Yield and High Quality Synthesized from Low Cost Precursor of Aphanitic Graphite

Cited by 45 publications

References 47 publications

Carbon Dots: A Future Blood–Brain Barrier Penetrating Nanomedicine and Drug Nanocarrier

Carbon Dots: A Future Blood–Brain Barrier Penetrating Nanomedicine and Drug Nanocarrier

Gamma irradiation of graphene quantum dots with ethylenediamine: Antioxidant for ion sensing

Outstanding Graphene Quantum Dots from Carbon Source for Biomedical and Corrosion Inhibition Applications: A Review

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