Hybrid graphene–ceramic nanofibre network for spontaneous neural differentiation of stem cells

Kazantseva, Jekaterina; Hussainova, Irina; Ivanov, Roman; Neuman, Toomas; Gasik, Michael

doi:10.1098/rsfs.2017.0037

Cited by 11 publications

(15 citation statements)

References 39 publications

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“…We recently demonstrated that application of cells on graphene-augmented inorganic nanofiber (GAIN) scaffolds can trigger different cell reactions and mechanisms, leading to changes in their morphology, orientation, and gene expression. 30 , 46 It has been shown that some cancer cells can change their behavior depending on the substrate usage. The current work studies this effect in more precise detail.…”

Section: Resultsmentioning

confidence: 99%

“…We earlier showed that GAIN-type scaffolds have a substantial mechanical anisotropy, as measured by the tangential elastic modulus, reaching 400 GPa/5 kPa = 80 × 10 6 . 30 , 46 This range spans for example over the elasticity of F-actin filaments (∼1–5 GPa 16 ), involved in cells adhesion and taxis. This is combined with matched diameter of the nanofibers in GAIN ( Figure 1 ) to actin filaments spacing (20–30 nm) and microtubules (∼25 nm), 16 , 24 , 28 being significantly (500–1000 times) smaller than average cell sizes.…”

Section: Resultsmentioning

confidence: 99%

“…However, it is clear that GAIN scaffolds could be used as the new advanced tool for cancer research, drug development, or in cancer stem cell studies. 30 , 46 …”

Section: Resultsmentioning

confidence: 99%

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Graphene-Augmented Nanofiber Scaffolds Trigger Gene Expression Switching of Four Cancer Cell Types

Kazantseva¹,

Ivanov

Gasik

et al. 2018

ACS Biomater. Sci. Eng.

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Three-dimensional (3D) customized scaffolds are anticipated to provide new frontiers in cell manipulation and advanced therapy methods. Here, we demonstrate the application of hybrid 3D porous scaffolds, representing networks of highly aligned self-assembled ceramic nanofibers, for culturing four types of cancer cells. Ultrahigh aspect ratio (∼107) of graphene augmented fibers of tailored nanotopology is shown as an alternative tool to substantially affect cancerous gene expression, eventually due to differences in local biomechanical features of the cell–matrix interactions. Here, we report a clear selective up- and down-regulation of groups of markers for breast cancer (MDA-MB231), colorectal cancer (CaCO2), melanoma (WM239A), and neuroblastoma (Kelly) depending on only fiber orientation and morphology without application of any other stimulus. Changes in gene expression are also revealed for Mitomycin C treatment of MDA-MB231, making the scaffold a suitable platform for testing of anticancer agents. This allows an opportunity for selective “clean” guidance to a deep understanding of mechanisms of cancer cells progressive growth and tumor formation without possible side effects by manipulation with the specific markers.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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Graphene-Augmented Nanofiber Scaffolds Trigger Gene Expression Switching of Four Cancer Cell Types

Kazantseva¹,

Ivanov

Gasik

et al. 2018

ACS Biomater. Sci. Eng.

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“…The authors have recently demonstrated applications of unique scaffolds, composed of self-aligned graphene-augmented inorganic (alumina) nano-fibers (GAIN). Ultra-high anisotropy (over 10 6 :1) and porosity (over 90%) of fibers were shown to result in thrilling effects over the cell cultures seeded; including but not limited by the suppression of inflammatory markers in human mesenchymal stem cells (hMSC) and peripheral mononuclear blood cells [ 4 ], the neurogenic-type differentiation of hMSC without any specific differentiation media [ 5 ], and the different gene expression and the reactivity of various types of cancer cells [ 6 ]. These findings allowed to formulate a phenomenon of auto-mechanoinduction in the cells, where ultra-high mechanical anisotropy of the substrate acting on two different levels (from 10–20 nm to cm scale) has triggered unusual (mutually confusing) reactions of the cells and, as a result, unexpected gene expression and cells differentiation [ 7 ].…”

Section: Introductionmentioning

confidence: 99%

Biomechanical Features of Graphene-Augmented Inorganic Nanofibrous Scaffolds and Their Physical Interaction with Viruses

et al. 2020

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Nanofibrous substrates and scaffolds are widely being studied as matrices for 3D cell cultures, and disease models as well as for analytics and diagnostic purposes. These scaffolds usually comprise randomly oriented fibers. Much less common are nanofibrous scaffolds made of stiff inorganic materials such as alumina. Well-aligned matrices are a promising tool for evaluation of behavior of biological objects affected by micro/nano-topologies as well as anisotropy. In this work, for the first time, we report a joint analysis of biomechanical properties of new ultra-anisotropic, self-aligned ceramic nanofibers augmented with two modifications of graphene shells (GAIN scaffolds) and their interaction of three different viral types (influenza virus A, picornavirus (human parechovirus) and potato virus). It was discovered that nano-topology and structure of the graphene layers have a significant implication on mechanical properties of GAIN scaffolds resulting in non-linear behavior. It was demonstrated that the viral adhesion to GAIN scaffolds is likely to be guided by physical cues in dependence on mutual steric factors, as the scaffolds lack common cell membrane proteins and receptors which viruses usually deploy for transfection. The study may have implications for selective viral adsorption, infected cells analysis, and potentially opening new tools for anti-viral drugs development.

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“…Kazantseva et al [12] take the topic of graphene-based fibres even further by showing how networks of composite graphene-ceramic fibres can be used in the control of stem cells.…”

Section: Introductionmentioning

confidence: 99%

The biomedical applications of graphene

Edirisinghe¹

2018

Interface Focus.

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One contribution of 13 to a theme issue 'The biomedical applications of graphene'. This issue of Interface Focus is a collection of papers on 'The biomedical applications of graphene'. The idea to put together this theme issue evolved during discussions between Prof. Peter N.T. Wells CBE, FREng, FMedSci, FRS and myself in mid-2016. Very sadly, about a year ago, Prof. Wells passed away. However, before that and even in the various last stages of his life he was intensely involved in planning this theme issue with me. I am deeply indebted to him for his contributions towards this and I dedicate this theme issue to him as a memorial.

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Hybrid graphene–ceramic nanofibre network for spontaneous neural differentiation of stem cells

Cited by 11 publications

References 39 publications

Graphene-Augmented Nanofiber Scaffolds Trigger Gene Expression Switching of Four Cancer Cell Types

Graphene-Augmented Nanofiber Scaffolds Trigger Gene Expression Switching of Four Cancer Cell Types

Biomechanical Features of Graphene-Augmented Inorganic Nanofibrous Scaffolds and Their Physical Interaction with Viruses

The biomedical applications of graphene

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