Your search keyword '"Calleja M"' showing total 8 results

1. Development of a methodology for reversible chemical modification of silicon surfaces with application in nanomechanical biosensors.

Author

Sato RH, Kosaka PM, Omori ÁT, Ferreira EA, Petri DFS, Malvar Ó, Domínguez CM, Pini V, Ahumada Ó, Tamayo J, Calleja M, Cunha RLOR, and Fiorito PA

Subjects

Base Sequence genetics, Nanostructures chemistry, Nucleic Acid Hybridization, Sulfhydryl Compounds chemistry, Surface Properties, Biosensing Techniques, DNA chemistry, Silicon chemistry, Tellurium chemistry

Abstract

Hypervalent tellurium compounds have a particular reactivity towards thiol compounds which are related to their biological properties. In this work, this property was assembled to tellurium-functionalized surfaces. These compounds were used as linkers in the immobilization process of thiolated biomolecules (such as DNA) on microcantilever surfaces. The telluride derivatives acted as reversible binding agents due to their redox properties, providing the regeneration of microcantilever surfaces and allowing their reuse for further biomolecules immobilizations, recycling the functional surface. Initially, we started from the synthesis of 4-((3-((4-methoxyphenyl) tellanyl) phenyl) amino)-4-oxobutanoic acid, a new compound, which was immobilized on a silicon surface. In nanomechanical systems, the detection involved a hybridization study of thiolated DNA sequences. Fluorescence microscopy technique was used to confirm the immobilization and removal of the telluride-DNA system and provided revealing results about the potentiality of applying redox properties to chalcogen derivatives at surfaces., (Copyright © 2019 Elsevier B.V. All rights reserved.)

Published

2019

2. Effect of water-DNA interactions on elastic properties of DNA self-assembled monolayers.

Author

Domínguez CM, Ramos D, Mendieta-Moreno JI, Fierro JLG, Mendieta J, Tamayo J, and Calleja M

Subjects

Algorithms, DNA, Single-Stranded chemistry, Elastic Modulus, Molecular Dynamics Simulation, Nucleic Acid Conformation, DNA chemistry, Models, Theoretical, Water chemistry

Abstract

DNA-water interactions have revealed as very important actor in DNA mechanics, from the molecular to the macroscopic scale. Given the particularly useful properties of DNA molecules to engineer novel materials through self-assembly and by bridging organic and inorganic materials, the interest in understanding DNA elasticity has crossed the boundaries of life science to reach also materials science and engineering. Here we show that thin films of DNA constructed through the self-assembly of sulfur tethered ssDNA strands demonstrate a Young's modulus tuning range of about 10 GPa by simply varying the environment relative humidity from 0% up to 70%. We observe that the highest tuning range occurs for ssDNA grafting densities of about 3.5 × 10 13 molecules/cm 2 , where the distance between the molecules maximizes the water mediated interactions between the strands. Upon hybridization with the complementary strand, the DNA self-assembled monolayers significantly soften by one order of magnitude and their Young's modulus dependency on the hydration state drastically decreases. The experimental observations are in agreement with molecular dynamics simulations.

Published

2017

3. Hydration induced stress on DNA monolayers grafted on microcantilevers.

Author

Domínguez CM, Kosaka PM, Mokry G, Pini V, Malvar O, del Rey M, Ramos D, San Paulo A, Tamayo J, and Calleja M

Subjects

Humidity, Kinetics, Microscopy, Atomic Force, Surface Properties, DNA chemistry, Nanotechnology, Water chemistry

Abstract

Surface tethered single-stranded DNA films are relevant biorecognition layers for oligonucleotide sequence identification. Also, hydration induced effects on these films have proven useful for the nanomechanical detection of DNA hybridization. Here, we apply nanomechanical sensors and atomic force microscopy to characterize in air and upon varying relative humidity conditions the swelling and deswelling of grafted single stranded and double stranded DNA films. The combination of these techniques validates a two-step hybridization process, where complementary strands first bind to the surface tethered single stranded DNA probes and then slowly proceed to a fully zipped configuration. Our results also demonstrate that, despite the slow hybridization kinetics observed for grafted DNA onto microcantilever surfaces, ex situ sequence identification does not require hybridization times typically longer than 1 h, while quantification is a major challenge.

Published

2014

4. Quantification of the surface stress in microcantilever biosensors: revisiting Stoney's equation.

Author

Tamayo J, Ruz JJ, Pini V, Kosaka P, and Calleja M

Subjects

Algorithms, Biosensing Techniques methods, Gold chemistry, Stress, Mechanical, Surface Properties, Biosensing Techniques instrumentation, DNA chemistry

Abstract

Microcantilever biosensors in the static operation mode translate molecular recognition into a surface stress signal. Surface stress is derived from the nanomechanical cantilever bending by applying Stoney's equation, derived more than 100 years ago. This equation ignores the clamping effect on the cantilever deformation, which induces significant errors in the quantification of the biosensing response. This leads to discrepancies in the surface stress induced by biomolecular interactions in measurements with cantilevers with different sizes and geometries. So far, more accurate solutions have been precluded by the formidable complexity of the theoretical problem that involves solving the two-dimensional biharmonic equation. In this paper, we present an accurate and simple analytical expression to quantify the response of microcantilever biosensors. The equation exhibits an excellent agreement with finite element simulations and DNA immobilization experiments on gold-coated microcantilevers.

Published

2012

5. Arrays of dual nanomechanical resonators for selective biological detection.

Author

Ramos D, Arroyo-Hernández M, Gil-Santos E, Tong HD, Van Rijn C, Calleja M, and Tamayo J

Subjects

Biosensing Techniques instrumentation, Fluorescent Dyes chemistry, Gold chemistry, Nucleic Acid Hybridization, Silicon Compounds chemistry, Biosensing Techniques methods, DNA chemistry, Nanoparticles chemistry

Abstract

Arrays of small nanomechanical resonators with dual geometry have been fabricated for sensitive biological detection. The arrays consist of silicon nitride resonating 100 nm thick cantilevers with sensing gold areas alternately placed on the free and fixed cantilever ends. The Au areas act as sensing regions as can be functionalized by means of thiol chemistry. The nanomechanical arrays provide a double flavor of the adsorbed molecules: the added mass reported by the cantilevers with the Au area at the tip and the nanoscale elasticity reported by the cantilevers with the Au area at the clamp. The devices were applied for DNA detection based on Watson-Crick pairing rules. The proposed design for nanomechanical resonators provides higher specificity for DNA sensing in comparison with conventional single cantilevers. The nanoscale elasticity induced by the DNA hybridization arises from the intermolecular interactions between the adsorbates bound to the cantilever and the surface stress.

Published

2009

6. Label-free detection of DNA hybridization based on hydration-induced tension in nucleic acid films.

Author

Mertens J, Rogero C, Calleja M, Ramos D, Martín-Gago JA, Briones C, and Tamayo J

Subjects

Staining and Labeling, Surface Tension, Biosensing Techniques methods, DNA chemistry, DNA genetics, In Situ Hybridization methods, Membranes, Artificial, Nanotechnology methods, Water chemistry

Abstract

The properties of water at the nanoscale are crucial in many areas of biology, but the confinement of water molecules in sub-nanometre channels in biological systems has received relatively little attention. Advances in nanotechnology make it possible to explore the role played by water molecules in living systems, potentially leading to the development of ultrasensitive biosensors. Here we show that the adsorption of water by a self-assembled monolayer of single-stranded DNA on a silicon microcantilever can be detected by measuring how the tension in the monolayer changes as a result of hydration. Our approach relies on the microcantilever bending by an amount that depends on the tension in the monolayer. In particular, we find that the tension changes dramatically when the monolayer interacts with either complementary or single mismatched single-stranded DNA targets. Our results suggest that the tension is mainly governed by hydration forces in the channels between the DNA molecules and could lead to the development of a label-free DNA biosensor that can detect single mutations. The technique provides sensitivity in the femtomolar range that is at least two orders of magnitude better than that obtained previously with label-free nanomechanical biosensors and with label-dependent microarrays.

Published

2008

7. Highly sensitive polymer-based cantilever-sensors for DNA detection.

Author

Calleja M, Nordström M, Alvarez M, Tamayo J, Lechuga LM, and Boisen A

Subjects

Polymers, Biosensing Techniques instrumentation, Biosensing Techniques methods, DNA isolation & purification, Nanotechnology instrumentation, Nanotechnology methods

Abstract

We present a technology for the fabrication of cantilever arrays aimed to develop an integrated biosensor microsystem. The fabrication process is based on spin coating of the photosensitive polymer and near-ultraviolet exposure. Arrays of up to 33 microcantilevers are fabricated in the novel polymer material SU-8. The low Young's modulus of the polymer, 40 times lower than that of silicon, enables to improve the sensitivity of the sensor device for target detection. The mechanical properties of SU-8 cantilevers, such as spring constant, resonant frequency and quality factor are characterized as a function of the dimensions and the medium. The devices have been tested for measurement of the adsorption of single stranded DNA and subsequent interstitial adsorption of lateral spacer molecules. We demonstrate that sensitivity is enhanced by a factor of six compared to that of commercial silicon nitride cantilevers.

Published

2005

8. Observation of spermidine-induced attractive forces in self-assembled monolayers of single stranded DNA using a microcantilever sensor.

Author

Mertens, J., Tamayo, J., Kosaka, P., and Calleja, M.

Subjects

SPERMIDINE, CONDENSATION, DNA, CANTILEVERS, CONDENSATION products (Chemistry)

Abstract

Despite the biological relevance, the physical origin of attraction between highly negatively charged DNA strands in condensation remains an open question. We have used microcantilever sensors to study the forces involved in DNA condensation by spermidine. The experiments were performed under flow conditions with gold-coated cantilevers sensitized with thiolated single stranded DNA. The experiments show that above a critical concentration of spermidine, the DNA strands abruptly experiences large attractive forces. The critical spermidine concentration for the transition increases with the monovalent salt concentration. The experiments provide a direct insight of the forces responsible of condensation. [ABSTRACT FROM AUTHOR]

Published

2011