Nano-structuring for molecular motor control

Mercy Lard; L. Ten Siethoff; S. Kumar; M. Persson; G. te Kronnie; A. Månsson; H. Linke

doi:10.1007/978-94-017-9133-5_28

Abstract

The interaction of self-propelled biological molecular-motors and cytoskeletal filaments holds relevance for a variety of applications such as biosensing, drug screening, diagnostics and biocomputation. The use of these systems for lab-on-a-chip biotechnology applications shows potential for replacement of microfluidic flow by active, molecular-motor driven transport of filaments. The ability to control, confine and detect motile objects in such a system is possible by development of nanostructured surfaces for on-chip applications and fundamental studies of molecular-motors. Here we describe the localized detection (Lard et al., Sci Rep 3:1092, 2013) and fast transport of actin filaments by myosin molecular-motors (Lard et al., Biosens Biolectron 48(0):145–152, 2013), inserted within nanostructures, as a method for biocomputation and molecular concentration. These results include extensive myosin driven concentration of actin filaments on a miniaturized detector, of relevance for use of molecular-motors in a diagnostics platform. Also, we discuss the local enhancement of the fluorescence signal of filaments, relevant for use in a biocomputation device where tracking of potentially thousands of motile objects is of primary significance.

Original language	English
Pages	459-459
Number of pages	1
DOIs	https://doi.org/10.1007/978-94-017-9133-5_28
Publication status	Published - 2015
Event	NATO Advanced Study Institute on Nano-Structures for Optics and Photonics: Optical Strategies for Enhancing Sensing, Imaging, Communication, and Energy Conversion - Erice, Italy Duration: 2013 Jul 4 → 2013 Jul 19

Conference

Conference	NATO Advanced Study Institute on Nano-Structures for Optics and Photonics: Optical Strategies for Enhancing Sensing, Imaging, Communication, and Energy Conversion
Country/Territory	Italy
City	Erice
Period	2013/07/04 → 2013/07/19

Subject classification (UKÄ)

Other Medical Engineering

Access to Document

10.1007/978-94-017-9133-5_28

Cite this

Lard, M., Ten Siethoff, L., Kumar, S., Persson, M., te Kronnie, G., Månsson, A., & Linke, H. (2015). Nano-structuring for molecular motor control. 459-459. Abstract from NATO Advanced Study Institute on Nano-Structures for Optics and Photonics: Optical Strategies for Enhancing Sensing, Imaging, Communication, and Energy Conversion, Erice, Italy. https://doi.org/10.1007/978-94-017-9133-5_28

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title = "Nano-structuring for molecular motor control",

abstract = "The interaction of self-propelled biological molecular-motors and cytoskeletal filaments holds relevance for a variety of applications such as biosensing, drug screening, diagnostics and biocomputation. The use of these systems for lab-on-a-chip biotechnology applications shows potential for replacement of microfluidic flow by active, molecular-motor driven transport of filaments. The ability to control, confine and detect motile objects in such a system is possible by development of nanostructured surfaces for on-chip applications and fundamental studies of molecular-motors. Here we describe the localized detection (Lard et al., Sci Rep 3:1092, 2013) and fast transport of actin filaments by myosin molecular-motors (Lard et al., Biosens Biolectron 48(0):145–152, 2013), inserted within nanostructures, as a method for biocomputation and molecular concentration. These results include extensive myosin driven concentration of actin filaments on a miniaturized detector, of relevance for use of molecular-motors in a diagnostics platform. Also, we discuss the local enhancement of the fluorescence signal of filaments, relevant for use in a biocomputation device where tracking of potentially thousands of motile objects is of primary significance.",

author = "Mercy Lard and {Ten Siethoff}, L. and S. Kumar and M. Persson and {te Kronnie}, G. and A. M{\aa}nsson and H. Linke",

year = "2015",

doi = "10.1007/978-94-017-9133-5_28",

language = "English",

pages = "459--459",

note = "NATO Advanced Study Institute on Nano-Structures for Optics and Photonics: Optical Strategies for Enhancing Sensing, Imaging, Communication, and Energy Conversion ; Conference date: 04-07-2013 Through 19-07-2013",

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Lard, M, Ten Siethoff, L, Kumar, S, Persson, M, te Kronnie, G, Månsson, A & Linke, H 2015, 'Nano-structuring for molecular motor control', NATO Advanced Study Institute on Nano-Structures for Optics and Photonics: Optical Strategies for Enhancing Sensing, Imaging, Communication, and Energy Conversion, Erice, Italy, 2013/07/04 - 2013/07/19 pp. 459-459. https://doi.org/10.1007/978-94-017-9133-5_28

Nano-structuring for molecular motor control. / Lard, Mercy; Ten Siethoff, L.; Kumar, S. et al.
2015. 459-459 Abstract from NATO Advanced Study Institute on Nano-Structures for Optics and Photonics: Optical Strategies for Enhancing Sensing, Imaging, Communication, and Energy Conversion, Erice, Italy.

Research output: Contribution to conference › Abstract › peer-review

TY - CONF

T1 - Nano-structuring for molecular motor control

AU - Lard, Mercy

AU - Ten Siethoff, L.

AU - Kumar, S.

AU - Persson, M.

AU - te Kronnie, G.

AU - Månsson, A.

AU - Linke, H.

PY - 2015

Y1 - 2015

N2 - The interaction of self-propelled biological molecular-motors and cytoskeletal filaments holds relevance for a variety of applications such as biosensing, drug screening, diagnostics and biocomputation. The use of these systems for lab-on-a-chip biotechnology applications shows potential for replacement of microfluidic flow by active, molecular-motor driven transport of filaments. The ability to control, confine and detect motile objects in such a system is possible by development of nanostructured surfaces for on-chip applications and fundamental studies of molecular-motors. Here we describe the localized detection (Lard et al., Sci Rep 3:1092, 2013) and fast transport of actin filaments by myosin molecular-motors (Lard et al., Biosens Biolectron 48(0):145–152, 2013), inserted within nanostructures, as a method for biocomputation and molecular concentration. These results include extensive myosin driven concentration of actin filaments on a miniaturized detector, of relevance for use of molecular-motors in a diagnostics platform. Also, we discuss the local enhancement of the fluorescence signal of filaments, relevant for use in a biocomputation device where tracking of potentially thousands of motile objects is of primary significance.

AB - The interaction of self-propelled biological molecular-motors and cytoskeletal filaments holds relevance for a variety of applications such as biosensing, drug screening, diagnostics and biocomputation. The use of these systems for lab-on-a-chip biotechnology applications shows potential for replacement of microfluidic flow by active, molecular-motor driven transport of filaments. The ability to control, confine and detect motile objects in such a system is possible by development of nanostructured surfaces for on-chip applications and fundamental studies of molecular-motors. Here we describe the localized detection (Lard et al., Sci Rep 3:1092, 2013) and fast transport of actin filaments by myosin molecular-motors (Lard et al., Biosens Biolectron 48(0):145–152, 2013), inserted within nanostructures, as a method for biocomputation and molecular concentration. These results include extensive myosin driven concentration of actin filaments on a miniaturized detector, of relevance for use of molecular-motors in a diagnostics platform. Also, we discuss the local enhancement of the fluorescence signal of filaments, relevant for use in a biocomputation device where tracking of potentially thousands of motile objects is of primary significance.

U2 - 10.1007/978-94-017-9133-5_28

DO - 10.1007/978-94-017-9133-5_28

M3 - Abstract

AN - SCOPUS:84943311770

SP - 459

EP - 459

T2 - NATO Advanced Study Institute on Nano-Structures for Optics and Photonics: Optical Strategies for Enhancing Sensing, Imaging, Communication, and Energy Conversion

Y2 - 4 July 2013 through 19 July 2013