Highly Ordered MWNT-Based Matrixes:  Topography at the Nanoscale Conceived for Tissue Engineering

Firkowska, Izabela; Olek, M.; Pazos-Pérez, Nicolás; Rojas-Chapana, José; Giersig, Michael

doi:10.1021/la053067e

Cited by 56 publications

(41 citation statements)

References 24 publications

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“…Patterns on a substrate to create macromolecular structures with CNTs are present in the forms of patterned spots for CNT deposition (Gabay et al 2005) and organized polystyrene beads coated with layers of CNT (Firkowska et al 2006); however, limited information is available in the literature on organized CNTs themselves as a template for tissue engineering. Vertically grown multiwall carbon nanotubes (MWNTs) on the surface of a silicon substrate can be functionalized in a way to create a 3D network of cavities that favor cell attachment and growth (Correa-Duarte et al 2004).…”

Section: Introductionmentioning

confidence: 99%

Morphology of fibroblasts grown on substrates formed by dielectrophoretically aligned carbon nanotubes

Yuen¹,

Zak²,

Waldman³

et al. 2007

Cytotechnology

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Multiwall carbon nanotube templates formed on the surfaces of planar interdigitated microelectrode arrays by means of AC electric field-guided assembly are being explored as potential substrates for tissue engineering. The objective of the present study is to examine whether surface patterns of aligned multiwall carbon nanotubes can have an effect on cell growth, morphology, and alignment. Bovine fibroblasts grown on aligned carbon nanotubes for a period of 2 weeks were found to have raised bodies and pronounced cell extensions for anchoring themselves to the substrate similar to that of the cells found in native tissues. On the other hand, cells grown on various control surfaces had a flat, circular morphology. The cell cultures were visualized by means of SEM imaging and the resulting morphologies were statistically analyzed and compared.

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Section: Introductionmentioning

confidence: 99%

Morphology of fibroblasts grown on substrates formed by dielectrophoretically aligned carbon nanotubes

Yuen¹,

Zak²,

Waldman³

et al. 2007

Cytotechnology

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“…The biocompatibility of the nanotube substrates were studied very widely. This problem was also the subject of the research in the team of Prof. Giersig [9]. The obtained results indicate excellent cells responding to the micro-and nanotopographical cues present on the nanostructured surface.…”

Section: Carbon Nanotube Substrates For Tissue Engineering Applicationsmentioning

confidence: 66%

“…For the numerical simulation, the linear elastic material model was used, where the Young's modulus E = 4 GPa and Poisson's ratio ν = 0.3 were assumed. Such a simplification is allowed because of size of the modeled structures and is in agreement with the experiment [9]. For the mechanical tests, two load cases were chosen -shear and compression of the structure, as a representation of possible loads in the multiwalled carbon nanotubes matrices.…”

Section: Numerical Analysismentioning

confidence: 94%

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Nanostructured bone-like scaffolds for restoration of trabecular bone remodeling capability

Nowak¹,

Firkowska²,

Giersig³

2011

Bulletin of the Polish Academy of Sciences: Technical Sciences

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Abstract. This paper presents the theoretical study about carbon nanotube substrates for tissue engineering and its applications. Because the replacement of bone tissue with artificial tissue can violate the remodeling process completely, the artificial material should not only consist of the same material properties, but also exhibit other characteristics which are equally important and need to be taken into consideration. These are above all the mechanosensation. Besides replacing natural tissue, the nanostructured scaffolds presented in the paper can help the tissue growth by stimulating this process. The developed trabecular bone remodeling simulation method responsible for the nanostructured scaffold behavior is implemented here. Thus, the nanostructured bone-like scaffolds reflect the remodeling capability of the biological system, not only due to their application as replacement of natural tissue, but also due to their effects in the field of mechanosensation.

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“…Such a method is also applicable for multi-wall carbon nanotubes (MWNT). 82) To provide hydrophilic surfaces, the author and co-workers focused on the use of imogolite, a naturally occurring clay mineral nanotube whose inner diameter is ca. 1 nm and the outer diameter is ca 2 nm (Fig.…”

Section: Nanotubesmentioning

confidence: 99%

Effective use of flexible low-dimensional colloidal particles and colloidal crystals for the control of hierarchically porous materials

Kuroda

2015

J. Ceram. Soc. Japan

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Hierarchically porous materials are useful materials because characteristics of pores in various length scales (e.g., micro-, meso-, and macropores) can synergistically be integrated in a material. In this review, preparation of hierarchically porous materials by templating methods is summarized from the viewpoint of flexibilities of colloidal particles and colloidal assemblies as building blocks and templates, respectively. Low-dimensional colloidal particles, such as nanosheets and nanotubes, are used as flexible building blocks to form three-dimensional networks on templates with few defects. Because such colloidal particles can have interand intraparticle pores, their assembly on templates is effective to form pores in various length scales. Colloidal crystals, assemblies of uniform colloidal particles, have been used as templates of macroporous and hierarchically porous materials. Recently, the use of colloidal crystals as flexible templates is reported and attracts much attention. A stress due to confined growth of gold within the interstices of the colloidal crystals causes their structural changes, retaining their periodic structure, which direct one-or two-dimensional growth of gold. It is regarded as a novel concept for the preparation of hierarchical nanostructured materials with high crystallinity. The utilization of flexibilities of colloidal particles and colloidal assemblies is promising for the creation of hierarchically porous materials with unique nanostructures.

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Highly Ordered MWNT-Based Matrixes: Topography at the Nanoscale Conceived for Tissue Engineering

Cited by 56 publications

References 24 publications

Morphology of fibroblasts grown on substrates formed by dielectrophoretically aligned carbon nanotubes

Morphology of fibroblasts grown on substrates formed by dielectrophoretically aligned carbon nanotubes

Nanostructured bone-like scaffolds for restoration of trabecular bone remodeling capability

Effective use of flexible low-dimensional colloidal particles and colloidal crystals for the control of hierarchically porous materials

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