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Journal ArticleDOI

Large-scale nanopatterning of single proteins used as carriers of magnetic nanoparticles

Ramses V. Martinez1, Javier Martínez1, Marco Chiesa1, Ricardo Garcia1, Eugenio Coronado2, Elena Pinilla-Cienfuegos2, Sergio Tatay2 
Spanish National Research Council1, University of Valencia2
02 Feb 2010-Advanced Materials (Wiley)-Vol. 22, Iss: 5, pp 588-591
TL;DR: A variety of methods based on Coulomb-force-directed assembly of nanoparticles have been proposed, but the supramolecular organization attained from the ‘‘bottom-up’’ approaches either does not allow accurate placement of the desired structures on a specific region of an inhomogeneous surface.
Abstract: However, the supramolecular organization attained from‘‘bottom-up’’approachesiseitherdifficulttoextendfromnano-tomesoscopic length scales or does not allow accurate placement ofthe desired structures on a specific region of an inhomogeneoussurface. Similarly, a variety of methods based on Coulomb-force-directed assembly of nanoparticles have been proposed.

Summary (1 min read)

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Summary

  • Accurate and reproducible patterning of proteins and functional nanoparticles is essential to exploit their properties in nano and microscale devices [1].
  • Electrostatic interactions, capillary forces, surface functionalization and nanolithography can be used in combination or independently to achieve the desired protein organization [2].
  • Here, the authors report a simple yet efficient method to deposit ferritin proteins with nanoscale accuracy over large areas.
  • The selective deposition is driven by the electrostatic interactions existing between the proteins and nanoscale features.
  • By combining a top-down tip-based nanolithography [3] and bottom-up electrostatic interactions the authors have formed regular arrays of ferritin molecules with an accuracy that matches the protein size (~10 nm).
  • Magnetic force measurements confirm the magnetic activity of the deposited nanoparticles.

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Figures (2)

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NanoSpain2010 23-26 March, 2010 Malaga-Spain
Large-scale nanopatterning of single proteins used as carriers of magnetic nanoparticles
Ramsés V. Martínez, Javier Martínez, Marco Chiesa, Ricardo García
Instituto de Microelectrónica de Madrid, CSIC, Isaac Newton 8, 28760 Tres Cantos, Madrid
(Spain)
mchiesa@imm.cnm.csic.es
Accurate and reproducible patterning of proteins and functional nanoparticles is essential to
exploit their properties in nano and microscale devices [1]. Electrostatic interactions, capillary
forces, surface functionalization and nanolithography can be used in combination or
independently to achieve the desired protein organization [2]. Here, we report a simple yet
efficient method to deposit ferritin proteins with nanoscale accuracy over large areas. The
selective deposition is driven by the electrostatic interactions existing between the proteins
and nanoscale features. The efficiency of the deposition process can be controlled by
changing the pH of the solution. By combining a top-down tip-based nanolithography [3] and
bottom-up electrostatic interactions we have formed regular arrays of ferritin molecules with
an accuracy that matches the protein size (~10 nm). Magnetic force measurements confirm
the magnetic activity of the deposited nanoparticles.
References:
[1] W. Cheng, T. Walter, D. Luo et al., Nature Nanotechnology 3 (2008) 682.
[2] R.V. Martinez, R. Garcia, E. Coronado et al., Adv. Mater. 19 (2007) 291.
[3] R.V. Martínez, J. Martínez, M. Chiesa et al., Adv. Mater. DOI: 10.1002/adma.200902568
Figures:
Fig. 1: Patterning of ferritin molecules by local oxidation nanolithography and silicon functionalization by
APTES at low pH values.
Local Oxidation
pH 3
APTES
Ferritin deposition
Si
250 nm
25 nm
Oral
NanoSpain2010 23-26 March, 2010 Malaga-Spain
Fig. 2: Patterning of ferritin molecules over cm
2
areas by controlled dewetting and surface functionalization at
neutral pH values.
PDMS stamp
Liquid film
Pattern
replication
APTES
pH 6.5
5 µm
10
nm
500 nm
Oral
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References
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Micro- and Nanopatterning of Spin-Transition Compounds into Logical Structures

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Massimiliano Cavallini, Ilaria Bergenti, Silvia Milita, Giampiero Ruani, Ivan Šalitroš, Zhi-Rong Qu, Rajadurai Chandrasekar, Mario Ruben 
27 Oct 2008-Angewandte Chemie

158 citations

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Nanografting for Surface Physical Chemistry

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Maozi Liu1, Nabil A. Amro, Gang-yu Liu2
Agilent Technologies1, University of California, Davis2
04 Apr 2008-Annual Review of Physical Chemistry
TL;DR: The enabling aspects of nanografting (an atomic force microscopy-based lithography technique) in surface physical chemistry are revealed and one can investigate systematically the influence of ligand local structure on biorecognition and protein immobilization by precisely engineering ligand nanostructures.
Abstract: This article reveals the enabling aspects of nanografting (an atomic force microscopy–based lithography technique) in surface physical chemistry. First, we characterize self-assembled monolayers and multilayers using nanografting to place unknown molecules into a matrix with known structure or vice versa. The availability of an internal standard in situ allows the unknown structures to be imaged and quantified. The same approaches are applied to reveal the orientation and packing of biomolecules (ligands, DNA, and proteins) upon immobilization on surfaces. Second, nanografting enables systematic investigations of size-dependent mechanics at the nanometer scale by producing a series of designed nanostructures and measuring their Young's modulus in situ. Third, one can investigate systematically the influence of ligand local structure on biorecognition and protein immobilization by precisely engineering ligand nanostructures. Finally, we also demonstrate the regulation of the surface reaction mechanism, kin...

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Nanopatterning Soluble Multifunctional Materials by Unconventional Wet Lithography

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Massimiliano Cavallini, Cristiano Albonetti, Fabio Biscarini
20 Mar 2009-Advanced Materials
TL;DR: In this paper, the authors highlight some of the recent advances of solution-based fabrication of multifunctional materials and highlight their ability to yield patterns and structures whose feature sizes range from nanometers to micrometers.
Abstract: Molecular multifunctional materials have potential applications in many fields of technology, such as electronics, optics and optoelectronics, information storage, sensing, and energy conversion and storage. These materials are designed exhibit enhanced properties, and at the same time are endowed with functional groups that control their interactions, and hence self-organization, into a variety ofsupramolecular architectures. Since most of the multifunctional materials are soluble, lithographic methods suitable for solutions are attracting increasing interest for the manufacturing of the new materials and their applications. The aim of this paper is to highlight some of the recent advances of solution-based fabrication of multifunctional materials. We explain and examine the principles, processes, materials, and limitations of this class of patterning techniques, which we term unconventional wet lithographies (UWLs). We describe their ability to yield patterns and structures whose feature sizes range from nanometers to micrometers. In the following sections, we focus our attention on micromolding in capillaries, lithographically controlled wetting, and grid-assisted deposition, the most used methods demonstrated to lead to fully operating devices.

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