Graphene: a versatile nanoplatform for biomedical applications

Zhang, Yin; Nayak, Tapas R.; Hong, Hao; Cai, Weibo

doi:10.1039/c2nr31040f

Cited by 472 publications

(347 citation statements)

References 96 publications

(139 reference statements)

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“…7,8 A number of these applications capitalise on the selective interaction of biomolecules with graphitic interfaces, in aqueous conditions. To better exploit these bio-nanotechology applications it is necessary to gain greater understanding of the the structure/property relationships of biomolecules at graphitic inter- † Electronic Supplementary Information (ESI) available: Details of the REST simulations; the side-chain contact sites; cluster populations of peptides both in solution and adsorbed to the graphene interface; analysis of aromaticaromatic residue interactions of P1 in solution; analysis of the intra-peptide hydrogen bonding of P1 and P1A3 in solution; free energy of adsorption profiles of amino acids to graphene interface; enthalpies of adsorption of amino acids to graphene interface from previous studies; exemplar replica mobilities; number of clusters identified as a function of MD steps from the REST simulations; composition of the secondary structure of the peptides via analysis of their backbone dihedral angles; probability distribution of distances of residues from graphene interface during the REST simulations.…”

Section: Introductionmentioning

confidence: 99%

What makes a good graphene-binding peptide? Adsorption of amino acids and peptides at aqueous graphene interfaces

2015

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Investigation of the non-covalent interaction of biomolecules with aqueous graphene interfaces is a rapidly expanding area. However, reliable exploitation of these interfaces in many applications requires that the links between the sequence and binding of the adsorbed peptide structures be clearly established. Molecular dynamics (MD) simulations can play a key role in elucidating the conformational ensemble of peptides adsorbed at graphene interfaces, helping to elucidate these rules in partnership with experimental characterisation. We apply our recently-developed polarisable force-field for biomolecule-graphene interfaces, GRAPPA, in partnership with advanced simulation approaches, to probe the adsorption behaviour of peptides at aqueous graphene. First we determine the free energy of adsorption of all twenty naturally occurring amino acids (AAs) via metadynamics simulations, providing a benchmark for interpreting peptide-graphene adsorption studies. From these free energies, we find that strong-binding amino acids have flat and/or compact side chain groups, and we relate this behaviour to the interfacial solvent structuring. Second, we apply replica exchange with solute tempering simulations to efficiently and widely sample the conformational ensemble of two experimentally-characterised peptide sequences, P1 and its alanine mutant P1A3, in solution and adsorbed on graphene. For P1 we find a significant minority of the conformational ensemble possesses a helical structure, both in solution and when adsorbed, while P1A3 features mostly extended, random-coil conformations. In solution this helical P1 configuration is stabilised through favourable intra-peptide interactions, while the adsorbed structure is stabilised via interaction of four strongly-binding residues, identified from our metadynamics simulations, with the aqueous graphene interface. Our findings rationalise the performance of the P1 sequence as a known graphene binder.

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Section: Introductionmentioning

confidence: 99%

What makes a good graphene-binding peptide? Adsorption of amino acids and peptides at aqueous graphene interfaces

2015

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“…Since two eminent scientists, Andre Geim and Konstantin Novoselov, were given the 2010 Nobel Prize in Physics for 2-dimensional sheet-like material graphene, the research in this field has exponentially expanded its territory beyond electronics and chemistry with developing an ultrafast conductor toward biological and biomedical field [1][2][3][4][5][6][7]. Known for its remarkable structural and physicochemical properties, graphene has attracted a substantial amount of interest in numerous fields in science including/especially in nanoscience/ medicine/technology.…”

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confidence: 99%

“…These properties of graphene have provided a stepping-stone for the development of nanocarriers for drug and gene delivery, biosensors, cell imaging, and phototherapy of cancer [9][10][11][12][13][14][15][16][17][18][19][20]. Doxorubicin loaded onto PEG-NGO conjugate is a primary example that utilizes the delocalized surface π-electrons in graphene to enhance the solubility of poorly soluble drugs [6]. The cationic polyethylenimine (PEI) polymer that has a strong electrostatic interaction with the negatively charged phosphate of RNA or DNA can be easily decorated onto the surface of graphene in gene therapy, which enables it to treat genetic disorders like cystic fibrosis, Parkinson's disease, and cancer whilst significantly lowering the cytotoxicity of PEI [6].…”

mentioning

confidence: 99%

“…Doxorubicin loaded onto PEG-NGO conjugate is a primary example that utilizes the delocalized surface π-electrons in graphene to enhance the solubility of poorly soluble drugs [6]. The cationic polyethylenimine (PEI) polymer that has a strong electrostatic interaction with the negatively charged phosphate of RNA or DNA can be easily decorated onto the surface of graphene in gene therapy, which enables it to treat genetic disorders like cystic fibrosis, Parkinson's disease, and cancer whilst significantly lowering the cytotoxicity of PEI [6]. Furthermore, the ability to adsorb single-stranded DNA onto graphene sheets, the capacity to quench electron donors, and the function of transportation in living cells and in vivo systems has made graphene even more promising [21].…”

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confidence: 99%

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Radio-graphene in Theranostic Perspectives

Hwang

2016

Nucl Med Mol Imaging

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Owing to its unique physicochemical properties such as high surface area, notable biocompatibility, robust mechanical strength, high thermal conductivity, and ease of functionalization, 2D-layered graphene has received tremendous attention as a futuristic nanomaterial and its-associated research has been rapidly evolving in a variety of fields. With the remarkable advances of graphene especially in the biomedical realm, in vivo evaluation techniques to examine in vivo behavior of graphene are largely demanded under the hope of clinical translation. Many different types of drugs such as the antisense oligomer and chemotherapeutics require optimal delivery conveyor and graphene is now recognized as a suitable candidate due to its simple and high drug loading property. Termed as 'radio-graphene', radioisotope-labeled graphene approach was recently harnessed in the realm of biomedicine including cancer diagnosis and therapy, contributing to the acquisition of in vivo information for targeted drug delivery. In this review, we highlight current examples for bioapplication of radiolabeled graphene with brief perspectives on future strategies in its extensive bio-or clinical applications.

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“…Functionalized graphene oxide (GO; 2-D)-based nanocomposites have attracted attention in biomedical applications in recent years, because of their unique and highly enriched physical and chemical properties, [19][20][21][22][23][24][25] such as excellent biocompatibility, ready cellular uptake, flexible chemical modifications, unique optical properties, and thermal and electrical conductivity. In recent years, graphenebased nanomaterials have also attracted significant interest in biological fields, such as biomedicine, biosensors, drug delivery and bioimaging.…”

Section: Introductionmentioning

confidence: 99%

Nano-graphene oxide composite for in vivo imaging

Jang¹,

Kang²,

Lee³

et al. 2018

IJN

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Introduction Positron emission tomography (PET) tracers has the potential to revolutionize cancer imaging and diagnosis. PET tracers offer non-invasive quantitative imaging in biotechnology and biomedical applications, but it requires radioisotopes as radioactive imaging tracers or radiopharmaceuticals. Method This paper reports the synthesis of 18 F-nGO-PEG by covalently functionalizing PEG with nano-graphene oxide, and its excellent stability in physiological solutions. Using a green synthesis route, nGO is then functionalized with a biocompatible PEG polymer to acquire high stability in PBS and DMEM. Results and discussion The radiochemical safety of 18 F-nGO-PEG was measured by a reactive oxygen species and cell viability test. The biodistribution of 18 F-nGO-PEG could be observed easily by PET, which suggested the significantly high sensitivity tumor uptake of 18 F-nGO-PEG and in a tumor bearing CT-26 mouse compared to the control. 18 F-nGO-PEG was applied successfully as an efficient radiotracer or drug agent in vivo using PET imaging. This article is expected to assist many researchers in the fabrication of 18 F-labeled graphene-based bio-conjugates with high reproducibility for applications in the biomedicine field.

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Graphene: a versatile nanoplatform for biomedical applications

Cited by 472 publications

References 96 publications

What makes a good graphene-binding peptide? Adsorption of amino acids and peptides at aqueous graphene interfaces

What makes a good graphene-binding peptide? Adsorption of amino acids and peptides at aqueous graphene interfaces

Radio-graphene in Theranostic Perspectives

Nano-graphene oxide composite for in vivo imaging

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