Graphene oxide and adenosine triphosphate as a source for functionalized carbon dots with applications in pH-triggered drug delivery and cell imaging

Zhang, Ming; Zhou, Ninglin; Yuan, Ping; Su, Yutian; Shao, Maoni; Chi, Cheng

doi:10.1039/c6ra27887f

Cited by 26 publications

(18 citation statements)

References 44 publications

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“…Another quantitative spectroscopic technique, XPS was also used to measure the elemental composition and the nature of functional groups present in the surface of the ChOx‐gRGO‐PPy composite. The binding energy (BE) values were chosen based on published works . However there might be slight changes in the BE due to the presence of neighboring groups.…”

Section: Resultsmentioning

confidence: 99%

One Step Electrode Fabrication for Direct Electron Transfer Cholesterol Biosensor Based on Composite of Polypyrrole, Green Reduced Graphene Oxide and Cholesterol Oxidase

2018

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A simple single‐step fabrication of a novel biocomposite electrode was used for cholesterol sensing through direct electron transfer. The bio‐composite was prepared by polypyrrole, green reduced graphene oxide (gRGO) and cholesterol oxidase (ChOx). The graphene oxide (GO) was “green” reduced, with the Paederia foetide (PFL) plant extract at 60 °C to improve its biocompatibility. The adherence of gRGO to the electrode surface was improved through its co‐deposition during electro‐polymerization of pyrrole. Interestingly, the enzyme ChOx also could be immobilized during this co‐deposition process, resulting in one step biosensor fabrication. The optimization of electrochemical deposition parameters on glassy carbon electrode for this enzymatic bioelectrode (ChOx‐gRGO‐PPy/GCE) has resulted in excellent sensitivity (1095.3 μA mM−1 cm−2), wide linear range (0.01–6 mM), and low detection limit (3.78 μM) of cholesterol. Also, the Dubinin‐Radushkevitch (D−R) adsorption study revealed the occurrence of physisorption (ϵ=3.35) process in this bioelectrode, confirming diffusion‐controlled reaction. Reproducibility of electrodeposition procedure, impeccable selectivity in the presence of interferrants, repeatability for multiple use and long‐term stability for practical use were also ensured. This could be used to construct the cost‐effective device for cholesterol diagnosis.

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Section: Resultsmentioning

confidence: 99%

One Step Electrode Fabrication for Direct Electron Transfer Cholesterol Biosensor Based on Composite of Polypyrrole, Green Reduced Graphene Oxide and Cholesterol Oxidase

2018

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“…6,7 PTT converts absorbed light into thermal energy and generates local hyperthermia in the tumor mass to ablate cancer cells without causing damage to surrounding normal tissue. [8][9][10] Photodynamic therapy (PDT), a minimally invasive and high-efficiency anticancer approach, has recently received extensive research attention. PDT involves photosensitizers that absorb light and further transfer energy to oxygen in the surrounding tissue.…”

Section: Introductionmentioning

confidence: 99%

Near-infrared light-mediated photodynamic/photothermal therapy nanoplatform by the assembly of Fe<sub>3</sub>O<sub>4</sub> carbon dots with graphitic black phosphorus quantum dots

Zhang

Wang

Cui

et al. 2018

IJN

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BackgroundRecently, combined photodynamic therapy (PDT) and photothermal therapy (PTT) has become a desired treatment for cancer. However, the development of economic, high-efficiency, and safe photosensitizers/photothermal agents remains a significant challenge.MethodsA novel nanocomposite has been developed via the assembly of iron oxide carbon dot (Fe3O4-CDs) nanoparticles and black phosphorus quantum dots (genipin [GP]-polyglutamic acid [PGA]-Fe3O4-CDs@BPQDs), and this nanocomposite shows a broad light-absorption band and a photodegradable character.ResultsIn vitro and in vivo assays indicated that GP-PGA-Fe3O4-CDs@BPQDs were highly biocompatible and exhibited excellent tumor-inhibition efficacy, due to the synergistic PTT and PDT via a near-infrared laser. Importantly, in vivo tumor magnetic resonance imaging (MRI) results illustrated that GP-PGA-Fe3O4-CDs@BPQDs can be specifically applied for enhanced T2 MRI of tumors. This work presents the first combined application of a PDT and PTT effect deriving from BPQDs and MRI from Fe3O4-CDs, which may promote utilization of black BPQDs in biomedicine.ConclusionAs expected, GP-PGA-Fe3O4-CDs@BPQDs displayed a dramatically enhanced ability to destroy tumor cells, due to the synergistic combination of PTT and PDT.

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“…[16] Recently,p hotothermal therapy (PTT) in synergy with chemotherapy or other therapeutic modalities have been extensively investigated by numerous researchers. [17] Killing cancer cells via heat generated by laser irradiation of NIR light-absorbing agents instead of simple traditional heatinga pproachh as drew great attention. Moreover,s uch temperature has been provedt ok ill cancer cells via hyperthermia-induced cell necrosis and am ild photothermal heating (43-45 8C).…”

Section: Introductionmentioning

confidence: 99%

“…[18] Additionally, integrating an umber of imaging methods such as fluorescent imaginga nd magnetic resonance imaging (MRI) with imagingguided therapy makesi tpossible to monitor the behaviors of nanocarriers (NCs) and then to optimize the therapeutic windows, which would then be useful to accurately personalize therapiesw ith furtheri mproved therapeutic effects andr educed side effects. [17] Many photothermal agents for building NIR-triggeredn anodrug carriers have been extensivelye xplored over recent years. Despite that large number of photothermala gents (e.g.,C uS NPs, [19] MoS 2 NPs, [20] polymers NPs, [21] Au NPs, [22] Cu 2Àx Se NPs, [23] Pd-based nanosheets, [24] Ge NPs, [25] and Sb NPs [26] )c an be used for buildingN IR-triggered nanodrug carriers, little is known about their potential long-term toxicity, which hampers their clinical translation.…”

Section: Introductionmentioning

confidence: 99%

Black Phosphorus Quantum Dots Gated, Carbon‐Coated Fe₃O₄ Nanocapsules (BPQDs@ss‐Fe₃O₄@C) with Low Premature Release Could Enable Imaging‐Guided Cancer Combination Therapy

Zhang

Wang

et al. 2018

Chemistry A European J

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Combination therapies for tumors based on different therapeutic approaches should try to improve treatment efficacy, but also to reduce side-effects related to the exogenous stimulus and premature release. In the following study, we established and validated a pH/near-infrared (NIR)/glutathione (GSH)/-responsive multifunctional disulfide cross-linked Fe O @C nanocarriers (ss-Fe O @C NCs) with black phosphorus quantum dots (BPQDs) as a capping agent. BPQDs and carbon shell of Fe O @C nanoparticles (NPs) were used as a photothermal agents, while the inner empty nucleus that allows for a high drug payload served as an effective drug carrier. These magnetofluorescent BPQDs@DOX@ss-Fe O @C NPs were conjugated with a targeting aptamer (epidermal growth factor receptor: EGFR), denoted as BPQDs@DOX@ss-Fe O @C-EGFR NPs, for targeting dual modal magnetic resonance (MR)/fluorescence imaging. The synthetic NCs showed that drug release was dependent on pH, near-infrared (NIR), and intracellular GSH levels, with minimum systemic release in the blood and maximum drug release within the tumors. Also, the photothermal effect resulting from the Fe O @C NPs and BPQDs upon application to NIR light caused a rapid rise in local temperature, which accounted for the highest enhancement of cell cytotoxicity. Thus, a theranostic system consisting of BPQDs@DOX@ss-Fe O @C-EGFR NPs is shown to generate excellent advantages in combined chemotherapy/photothermal therapy (PTT) with minimal side effects.

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Graphene oxide and adenosine triphosphate as a source for functionalized carbon dots with applications in pH-triggered drug delivery and cell imaging

Abstract: A folate-functionalized carbon dot-based nanocarrier system has been successfully synthesized for cancer cell targeted drug delivery.

Cited by 26 publications

References 44 publications

One Step Electrode Fabrication for Direct Electron Transfer Cholesterol Biosensor Based on Composite of Polypyrrole, Green Reduced Graphene Oxide and Cholesterol Oxidase

One Step Electrode Fabrication for Direct Electron Transfer Cholesterol Biosensor Based on Composite of Polypyrrole, Green Reduced Graphene Oxide and Cholesterol Oxidase

Near-infrared light-mediated photodynamic/photothermal therapy nanoplatform by the assembly of Fe<sub>3</sub>O<sub>4</sub> carbon dots with graphitic black phosphorus quantum dots

Black Phosphorus Quantum Dots Gated, Carbon‐Coated Fe₃O₄ Nanocapsules (BPQDs@ss‐Fe₃O₄@C) with Low Premature Release Could Enable Imaging‐Guided Cancer Combination Therapy

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Graphene oxide and adenosine triphosphate as a source for functionalized carbon dots with applications in pH-triggered drug delivery and cell imaging

Abstract: A folate-functionalized carbon dot-based nanocarrier system has been successfully synthesized for cancer cell targeted drug delivery.

Cited by 26 publications

References 44 publications

One Step Electrode Fabrication for Direct Electron Transfer Cholesterol Biosensor Based on Composite of Polypyrrole, Green Reduced Graphene Oxide and Cholesterol Oxidase

One Step Electrode Fabrication for Direct Electron Transfer Cholesterol Biosensor Based on Composite of Polypyrrole, Green Reduced Graphene Oxide and Cholesterol Oxidase

Near-infrared light-mediated photodynamic/photothermal therapy nanoplatform by the assembly of Fe<sub>3</sub>O<sub>4</sub> carbon dots with graphitic black phosphorus quantum dots

Black Phosphorus Quantum Dots Gated, Carbon‐Coated Fe3O4 Nanocapsules (BPQDs@ss‐Fe3O4@C) with Low Premature Release Could Enable Imaging‐Guided Cancer Combination Therapy

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Black Phosphorus Quantum Dots Gated, Carbon‐Coated Fe₃O₄ Nanocapsules (BPQDs@ss‐Fe₃O₄@C) with Low Premature Release Could Enable Imaging‐Guided Cancer Combination Therapy