V. Solis-Tinoco scite author profile

V. Solis-Tinoco

2Publications

29Citation Statements Received

78Citation Statements Given

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Affiliations

Institut Català de Nanociència i Nanotecnologia, Biomedical Research Networking Center in Bioengineering, Biomaterials and Nanomedicine

Publications

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Building of a flexible microfluidic plasmo-nanomechanical biosensor for live cell analysis

Solis-Tinoco

Márquez

Quesada‐López

et al. 2019

Sensors and Actuators B: Chemical

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Biosensor devices can constitute an advanced tool for monitoring and study complex dynamic biolog ical processes, as for example cellular adhesion. Cellular adhesion is a multipart process with crucial implications in physiology (i.e. immune response, tissue nature, architecture maintenance, or behavior and expansion of tumor cells). This work focuses on offering a controlled methodology in order to fabricate a flexible plasmo-nanomechanical biosensor placed within a microfluidic channel as a new tool for future cell adhesion studies. We designed, fabricated, and optically and mechanically characterized this novel optical biosensor. As a proof-of-concept of its functionality, the biosensor was employed to observe fibroblasts adhesion in a cell culture. The device is configured by an hexagonal array of flexible rigid/soft polymeric nanopillars capped with plasmonic gold nanodisks integrated inside a microfluidic channel. The fabrication employs low-cost and large-scale replica molding techniques using two different polymers materials (EPOTECK OG142 and 310M). By using those materials the spring constant of the polymer nanopillars (k) can be fabricated from 1.19E-02 [N/m] to 5.35E +00 [N/m] indicating different mechanical sensitivities to shear stress. Therefore, the biosensor has the feasibility to mimic soft and rigid tissues important for the description of cellular nanoscale behaviours. The biosensor exhibits a suitable bulk sensitivity of 164 nm or 206 nm/refractive index unit respectively, depending on the base material. The range of calculated forces goes from ≈1.98 nN to ≈.942 µN. This supports that the plasmo-nanomechanical biosensors could be employed as novel tool to study living cells behavior.

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Tailored Height Gradients in Vertical Nanowire Arrays via Mechanical and Electronic Modulation of Metal‐Assisted Chemical Etching

Otte

Solis-Tinoco

Prieto

et al. 2015

Small

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In current top-down nanofabrication methodologies the design freedom is generally constrained to the two lateral dimensions, and is only limited by the resolution of the employed nanolithographic technique. However, nanostructure height, which relies on certain mask-dependent material deposition or etching techniques, is usually uniform, and on-chip variation of this parameter is difficult and generally limited to very simple patterns. Herein, a novel nanofabrication methodology is presented, which enables the generation of high aspect-ratio nanostructure arrays with height gradients in arbitrary directions by a single and fast etching process. Based on metal-assisted chemical etching using a catalytic gold layer perforated with nanoholes, it is demonstrated how nanostructure arrays with directional height gradients can be accurately tailored by: (i) the control of the mass transport through the nanohole array, (ii) the mechanical properties of the perforated metal layer, and (iii) the conductive coupling to the surrounding gold film to accelerate the local electrochemical etching process. The proposed technique, enabling 20-fold on-chip variation of nanostructure height in a spatial range of a few micrometers, offers a new tool for the creation of novel types of nano-assemblies and metamaterials with interesting technological applications in fields such as nanophotonics, nanophononics, microfluidics or biomechanics.

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V. Solis-Tinoco

Building of a flexible microfluidic plasmo-nanomechanical biosensor for live cell analysis

Tailored Height Gradients in Vertical Nanowire Arrays via Mechanical and Electronic Modulation of Metal‐Assisted Chemical Etching

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