Interfacing Live Cells with Nanocarbon Substrates

Agarwal, Shuchi; Zhou, Xiaozhu; Feng, Ying; He, Qiyuan; Chen, George C. K.; Soo, Jianchow; Boey, Freddy Yin Chiang; Zhang, Hua; Chen, Peng

doi:10.1021/la9048743

Cited by 290 publications

(222 citation statements)

References 28 publications

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“…In a similar way, Agarwal et al 87 recently demonstrated the biocompatibility of reduced GOs with proteins and further used them after protein functionalization to create biosensors for detecting various metals in real time with high sensitivity. 81 These reports already confirm the potential of graphene for sensing in aqueous electrolytes, however, detailed understandings of the graphene/ electrolyte interface and the effect of the electrolyte on the electronic transport in graphene are still lacking.…”

Section: Grapheneàdetection In Liquid Environmentmentioning

confidence: 99%

“…This indicates that they were measuring a signal that was averaged from different points across the outer membrane of the beating cells. In another recent work, Agarwal et al 87 demonstrated the biocompatibility of reduced GOs with live cells, such as neuroendocrine PC12 cells, and further used them to create biosensors for detecting the dynamic secretion of the hormonal catecholamine molecules from living cells. 80 Pursuing the development of a graphene-based technology that can detect action potentials from electrically active cells, Hess et al 84 recently reported using arrays of CVD-grown graphene FETs for the extracellular detection of action potentials from electrogenic cells (Figures 7c and d).…”

Section: Fet Biosensors S Liu and X Guomentioning

confidence: 99%

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Carbon nanomaterials field-effect-transistor-based biosensors

2012

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Carbon nanomaterials field-effect transistor (FET)-based electrical biosensors provide significant advantages over the current gold standards, holding great potential for realizing direct, label-free, real-time electrical detection of biomolecules in a multiplexed manner with ultrahigh sensitivity and excellent selectivity. The feasibility of integrating them with current complementary metal oxide semiconductor platform and a fluid handling module using standard microfabrication technology opens up new opportunities for the development of low-cost, low-noise, portable electrical biosensors for use in practical future devices. In this article, we review recent progress in the rapidly developing area of biomolecular interaction detection using FET-based biosensors based on the carbon nanomaterials single-walled carbon nanotubes (SWNTs) and graphene. Detection scenarios include DNA-DNA hybridization, DNA-protein interaction, protein function and cellular activity. In particular, we will highlight an amazing property of SWNT-or graphene-FETs in biosensing: their ability to detect biomolecules at the single-molecule level or at the single-cell level. This is due to the size comparability and the surface compatibility of the carbon nanomaterials with biological molecules. We also summarize some current challenges the scientific community is facing, including device-to-device heterogeneity and the lack of system integration for uniform device array mass production. Keywords: biosensor; carbon nanotube; field-effect transistor; graphene A biosensor is an analytical device that incorporates a biological recognition element in direct spatial contact with a transduction element. This integration ensures the rapid and convenient conversion of the biological events to detectable signals. 1 With the discovery of rich nanomaterials and the development of exquisite nanofabrication tools, such as electron beam lithography, focused ion beam and nanoimprint lithography, new avenues have been opened up in the field of biosensors in the last two decades. 2,3 In particular, researchers around the world have been tailor-making a multitude of nanomaterials-based electrical biosensors and developing new strategies to apply them in ultrasensitive biosensing. Examples of such nanomaterials include carbon nanotubes, 4-13 nanowires, 11,14-21 nanoparticles, 6,22-25 nanopores, 26,27 nanoclusters 28 and graphene. 5,[29][30][31][32] Compared with conventional optical, biochemical and biophysical methods, nanomaterial-based electronic biosensing offers significant advantages, such as high sensitivity and new sensing mechanisms, high spatial resolution for localized detection, facile integration with standard wafer-scale semiconductor processing and label-free, real-time detection in a nondestructive manner.Among diverse electrical biosensing architectures, devices based on field-effect transistors (FETs) have attracted great attention because they are an ideal biosensor that can directly translate the interactions between target biological mole...

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Section: Grapheneàdetection In Liquid Environmentmentioning

confidence: 99%

Section: Fet Biosensors S Liu and X Guomentioning

confidence: 99%

Carbon nanomaterials field-effect-transistor-based biosensors

2012

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“…Additionally, cytotoxicities of graphene and graphene-based materials have also been tested in mice cell lines and have been shown to have negligible toxicity at low concentrations. 239,240 Interestingly, similar low concentrations have been linked to cytotoxic effects when using other carbon-based materials like CNTs. [240][241][242] The negligible toxicity of graphene towards cell lines has resulted in various research groups using graphene-based materials as scaffolds for cell growth.…”

Section: Environmental and Biological Toxicity Of Graphenementioning

confidence: 97%

“…250,251 Various in vitro toxicity studies have been conducted to determine the toxicity of graphene towards cancer [234][235][236][237][238] and human cell lines. 229,239 The cytotoxicity towards the cancer cell lines A549 was shown to depend largely on the cell culture medium components. 234,235 In particular it was noted that fetal bovine serum played a very important role, as it seems to coat the graphene sheets making them less toxic towards cell lines.…”

Section: Environmental and Biological Toxicity Of Graphenementioning

confidence: 99%

“…239 The authors showed the benet of using reduced graphene oxide over SWNTs, which displayed an inhibition effect in the growth of the human cell lines. Liao and co-workers have shown that graphene oxide displays minimal cytotoxicity towards human erythrocytes and skin broblast cells, however graphite oxide and reduced graphene oxide were shown to inhibit cell growth.…”

Section: Environmental and Biological Toxicity Of Graphenementioning

confidence: 99%

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Environmental applications using graphene composites: water remediation and gas adsorption

et al. 2013

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This review deals with wide-ranging environmental studies of graphene-based materials on the adsorption of hazardous materials and photocatalytic degradation of pollutants for water remediation and the physisorption, chemisorption, reactive adsorption, and separation for gas storage. The environmental and biological toxicity of graphene, which is an important issue if graphene composites are to be applied in environmental remediation, is also addressed.

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