Nano-graphene oxide-UCNP-Ce6 covalently constructed nanocomposites for NIR-mediated bioimaging and PTT/PDT combinatorial therapy

Gulzar, Arif; Xu, Jiating; Yang, Dan; Xu, Liangge; He, Fei; Gai, Shili; Yang, Piaoping

doi:10.1039/c7dt04141a

Cited by 88 publications

(89 citation statements)

References 54 publications

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“…These findings promise the potential use of this system for complete tumor ablation and metastasis prevention. Several research groups have designed hybrid materials comprising photosensitizer-linked graphene/GO (GO-fullerene C60) [72], RGO-Ru-PEG [73], folic acid-GO-manganese dioxide [74], GO-enwrapped SiO 2 /TiO 2 hollow nanoparticles loaded with protoporphyrin IX [75], and NGO-UCNP-Ce6 [76] for combined PTT and PDT in a single platform. Effective delivery of photosensitizers for PDT along with enhanced fluorescence imaging was achieved by Yan et al [77].…”

Section: Graphene Substrates For Photothermal Therapy and Photodynamimentioning

confidence: 99%

“…Molecular dynamic simulation studies showed that basic amino acid residues (arginine and lysine) and aromatic residues (tryptophan, tyrosine, and phenylalanine) play a key role in binding the protein onto the surface of graphene Porphyrin-GO -U87-MG cells Photothermal therapy; brain cancer treatment [67] Aptamer-magnetic GO Indocyanine green CCRF-CEM Photothermal, photodynamic therapy [70] GO-fullerene C60 -HeLa cells Photothermal, photodynamic therapy [72] RGO-Ru-PEG Ru(II)-polypyridyl complex A549 cells Multifunctional imaging and phototherapy [73] NGO-UCNP-Ce6 Ce6 HeLa cells; U14 tumor bearing mice Up-conversion luminescence imaging and PDT/PTT [76] Polypyrrole nitrogen-doped fewlayer graphene (PPy-NDFLG)…”

Section: Importance Of Protein Coronamentioning

confidence: 99%

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Comprehensive Application of Graphene: Emphasis on Biomedical Concerns

2019

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HIGHLIGHTS• The introduction of graphene will certainly uncover new advanced materials, and many more future technologies will become realistic in the forthcoming years.• The present review article includes more recent publications about the biomedical application and cellular interaction of graphene. It is also updated with modern approaches such as use of graphene inks for 3D printing application.• Moreover, the importance of protein corona in modulating the cellular interaction, which was overlooked in previous review publications, is also included in this article.• The possible biological outcomes and toxicity when graphene is exposed to living organisms at the cellular and organ level are explained.ABSTRACT Graphene, sp 2 hybridized carbon framework of one atom thickness, is reputed as the strongest material to date. It has marked its impact in manifold applications including electronics, sensors, composites, and catalysis. Current state-of-the-art graphene research revolves around its biomedical applications. The two-dimensional (2D) planar structure of graphene provides a large surface area for loading drugs/biomolecules and the possibility of conjugating fluorescent dyes for bioimaging. The high near-infrared absorbance makes graphene ideal for photothermal therapy. Henceforth, graphene turns out to be a reliable multifunctional material for use in diagnosis and treatment.It exhibits antibacterial property by directly interacting with the cell membrane. Potential application of graphene as a scaffold for the attachment and proliferation of stem cells and neuronal cells is captivating in a tissue regeneration scenario. Fabrication of 2D graphene into a 3D structure is made possible with the help of 3D printing, a revolutionary technology having promising applications in tissue and organ engineering. However, apart from its advantageous application scope, use of graphene raises toxicity concerns. Several reports have confirmed the potential toxicity of graphene and its derivatives, and the inconsistency may be due to the lack of standardized consensus protocols. The present review focuses on the hidden facts of graphene and its biomedical application, with special emphasis on drug delivery, biosensing, bioimaging, antibacterial, tissue engineering, and 3D printing applications.

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Section: Graphene Substrates For Photothermal Therapy and Photodynamimentioning

confidence: 99%

Section: Importance Of Protein Coronamentioning

confidence: 99%

Comprehensive Application of Graphene: Emphasis on Biomedical Concerns

2019

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“…74,80 Another drawback of conventional PDT is the short wavelength of the excitation light, which is mainly located in the ultraviolet or visible region, resulting in limited penetration depth and in easy distribution by various endogenous light chromophores, such as melanin. 87 Li et al developed Nd 3+ sensitized lanthanide nanoparticles as carriers for loading PS; this UC nanoparticle relied on the excitation light wavelength of 808 nm that bypassed the defects of traditional Yb 3+ ions sensitized UC nanoparticles and achieved effective imaging-guided PDT without impairing imaging signals. ICG, IR820 and IR780 are multifunctional PS that rely on NIR laser (808 nm) irradiation with improved penetration and efficacy of PDT.…”

Section: Recent Advance Of Nanoparticle-based Pdtmentioning

confidence: 99%

“…86 Gulzar et al designed graphene oxide as a carrier with chlorin e6 loading under 808 nm NIR laser excitation for imagingguided PDT. 87 Li et al developed Nd 3+ sensitized lanthanide nanoparticles as carriers for loading PS; this UC nanoparticle relied on the excitation light wavelength of 808 nm that bypassed the defects of traditional Yb 3+ ions sensitized UC nanoparticles and achieved effective imaging-guided PDT without impairing imaging signals. 88 The efficacy of PDT is restricted by hypoxic tumor microenvironment owing to the imbalance between the supply and consumption of oxygen in solid tumors.…”

Section: Recent Advance Of Nanoparticle-based Pdtmentioning

confidence: 99%

Nanoparticle‐based photothermal and photodynamic immunotherapy for tumor treatment

Hou

Tao

Pang

et al. 2018

Intl Journal of Cancer

186

123

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Nanoparticle-based phototherapies, such as photothermal therapy (PTT) and photodynamic therapy (PDT), exhibit strong efficacy, minimal invasion and negligible side effects in tumor treatment. These phototherapies have received considerable attention and been extensively studied in recent years. In addition to directly killing tumor cells through heat and reactive oxygen species, PTT and PDT can also induce various antitumor effects. In particular, the resultant massive tumor cell death after PTT and PDT triggers immune responses, including the redistribution and activation of immune effector cells, the expression and secretion of cytokines and the transformation of memory T lymphocytes. The antitumor effects can be enhanced by immune checkpoint blockage therapy. This article reviewed the recent advances of nanoparticle-based PTT and PDT, summarized the studies on nanoparticle-based photothermal and photodynamic immunotherapies in vitro and in vivo, and discussed challenges and future research directions.

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“…Utilizing upconversion nanocrystals is a promising method for NIR light-mediated bioimaging and photothermal and photodynamic therapy. Gulzar et al [131,174] covalently functionalized nGO with core-shell structured unconversion nanoparticles in the steps as shown in Figure 7. Oleic acid stabilized NaGdF 4 : Yb 3+ , Er 3+ was firstly synthesized followed by the formation of a NaGdF 4 : Nd 3+ , Yb 3+ shell around it.…”

Section: Nanoparticle Functionalized Graphene-based Materialsmentioning

confidence: 99%

Functionalization of Carbon Nanomaterials for Biomedical Applications

Liu

Speranza

2019

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Over the past decade, carbon nanostructures (CNSs) have been widely used in a variety of biomedical applications. Examples are the use of CNSs for drug and protein delivery or in tools to locally dispense nucleic acids to fight tumor affections. CNSs were successfully utilized in diagnostics and in noninvasive and highly sensitive imaging devices thanks to their optical properties in the near infrared region. However, biomedical applications require a complete biocompatibility to avoid adverse reactions of the immune system and CNSs potentials for biodegradability. Water is one of the main constituents of the living matter. Unfortunately, one of the disadvantages of CNSs is their poor solubility. Surface functionalization of CNSs is commonly utilized as an efficient solution to both tune the surface wettability of CNSs and impart biocompatible properties. Grafting functional groups onto the CNSs surface consists in bonding the desired chemical species on the carbon nanoparticles via wet or dry processes leading to the formation of a stable interaction. This latter may be of different nature as the van Der Waals, the electrostatic or the covalent, the π-π interaction, the hydrogen bond etc. depending on the process and on the functional molecule at play. Grafting is utilized for multiple purposes including bonding mimetic agents such as polyethylene glycol, drug/protein adsorption, attaching nanostructures to increase the CNSs opacity to selected wavelengths or provide magnetic properties. This makes the CNSs a very versatile tool for a broad selection of applications as medicinal biochips, new high-performance platforms for magnetic resonance (MR), photothermal therapy, molecular imaging, tissue engineering, and neuroscience. The scope of this work is to highlight up-to-date using of the functionalized carbon materials such as graphene, carbon fibers, carbon nanotubes, fullerene and nanodiamonds in biomedical applications.

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Nano-graphene oxide-UCNP-Ce6 covalently constructed nanocomposites for NIR-mediated bioimaging and PTT/PDT combinatorial therapy

Cited by 88 publications

References 54 publications

Comprehensive Application of Graphene: Emphasis on Biomedical Concerns

Comprehensive Application of Graphene: Emphasis on Biomedical Concerns

Nanoparticle‐based photothermal and photodynamic immunotherapy for tumor treatment

Functionalization of Carbon Nanomaterials for Biomedical Applications

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