Mairead A. Wood scite author profile

Substrate topography plays a vital role in cell and tissue structure and function in situ, where nanometric features, for example, the detail on single collagen fibrils, influence cell behaviour and resultant tissue formation. In vitro investigations demonstrate that nanotopography can be used to control cell reactions to a material surface, indicating its potential application in tissue engineering and implant fabrication. Developments in the catalyst, optical, medical and electronics industries have resulted in the production of nanopatterned surfaces using a variety of methods. The general protocols for nanomanufacturing require high resolution and low cost for fabricating devices. With respect to biological investigations, nanotopographies should occur across a large surface area (ensuring repeatability of experiments and patterning of implant surfaces), be reproducible (allowing for consistency in experiments), and preferably, accessible (limiting the requirement for specialist equipment). Colloidal lithography techniques fit these criteria, where nanoparticles can be utilized in combination with a functionalized substrate to produce in-plane nanotopographies. Subsequent lithographic processing of colloidal substrates utilizing, for example, reactive ion etching allows the production of modified colloidal-derived nanotopographies. In addition to two-dimensional in-plane nanofabrication, functionalized structures can be dip coated in colloidal sols, imparting nanotopographical cues to cells within a three-dimensional environment.

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In vitro bone growth responds to local mechanical strain in three-dimensional polymer scaffolds

Baas

Kuiper

Yang

et al. 2010

Journal of Biomechanics

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The Effects of Colloidal Nanotopography on Initial Fibroblast Adhesion and Morphology

Wood

Wilkinson

Curtis

2006

IEEE Trans.on Nanobioscience

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Abstract-Colloidal lithography offers a simple, inexpensive method of producing irregular nanotopographies, a pattern not easily attainable utilizing conventional serial writing processes. Colloids with 20-or 50-nm diameter were utilized to produce such an irregular topography and were characterized by calculating the percentage area coverage of particles. Interparticle and nearest neighbor spacing were also assessed for the individual colloids in the pattern. Two-way analysis of variance (ANOVA) indicated significant differences between the number of fibroblasts adhering to planar, 20-, and 50-nm-diameter colloidal topographies, the number of fibroblasts adhering to the substrates at the time intervals studied, namely 20 min, 1 h, and 3 h and significant interaction between time and topography on fibroblast adhesion

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Mairead A. Wood

Substratum nanotopography and the adhesion of biological cells. Are symmetry or regularity of nanotopography important?

The use of materials patterned on a nano- and micro-metric scale in cellular engineering

Colloidal lithography and current fabrication techniques producing in-plane nanotopography for biological applications

In vitro bone growth responds to local mechanical strain in three-dimensional polymer scaffolds

The Effects of Colloidal Nanotopography on Initial Fibroblast Adhesion and Morphology

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