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Wafer-scale integration of sacrificial nanofluidic chips for detecting and manipulating single DNA molecules

Author

Listed:
  • Chao Wang

    (IBM T.J. Watson Research Center
    School of Electrical, Computer and Energy Engineering, and Biodesign Center for Molecular Design & Biomimetics, Arizona State University)

  • Sung-Wook Nam

    (IBM T.J. Watson Research Center
    Present address: Department of Molecular Medicine, School of Medicine, Kyungpook National University, 807 Hogukro, Bukgu, Daegu 41404, South Korea)

  • John M. Cotte

    (IBM T.J. Watson Research Center)

  • Christopher V. Jahnes

    (IBM T.J. Watson Research Center)

  • Evan G. Colgan

    (IBM T.J. Watson Research Center)

  • Robert L. Bruce

    (IBM T.J. Watson Research Center)

  • Markus Brink

    (IBM T.J. Watson Research Center)

  • Michael F. Lofaro

    (IBM T.J. Watson Research Center)

  • Jyotica V. Patel

    (IBM T.J. Watson Research Center)

  • Lynne M. Gignac

    (IBM T.J. Watson Research Center)

  • Eric A. Joseph

    (IBM T.J. Watson Research Center)

  • Satyavolu Papa Rao

    (IBM T.J. Watson Research Center
    Present address: 257 Fuller Road, SUNY Poly SEMATECH, Albany, New York 12203, USA)

  • Gustavo Stolovitzky

    (IBM T.J. Watson Research Center
    Icahn School of Medicine at Mount Sinai)

  • Stanislav Polonsky

    (IBM T.J. Watson Research Center
    Present address: Samsung R&D Institute Russia, 12/1 Dvintsev street, Moscow 127018, Russia)

  • Qinghuang Lin

    (IBM T.J. Watson Research Center)

Abstract

Wafer-scale fabrication of complex nanofluidic systems with integrated electronics is essential to realizing ubiquitous, compact, reliable, high-sensitivity and low-cost biomolecular sensors. Here we report a scalable fabrication strategy capable of producing nanofluidic chips with complex designs and down to single-digit nanometre dimensions over 200 mm wafer scale. Compatible with semiconductor industry standard complementary metal-oxide semiconductor logic circuit fabrication processes, this strategy extracts a patterned sacrificial silicon layer through hundreds of millions of nanoscale vent holes on each chip by gas-phase Xenon difluoride etching. Using single-molecule fluorescence imaging, we demonstrate these sacrificial nanofluidic chips can function to controllably and completely stretch lambda DNA in a two-dimensional nanofluidic network comprising channels and pillars. The flexible nanofluidic structure design, wafer-scale fabrication, single-digit nanometre channels, reliable fluidic sealing and low thermal budget make our strategy a potentially universal approach to integrating functional planar nanofluidic systems with logic circuits for lab-on-a-chip applications.

Suggested Citation

  • Chao Wang & Sung-Wook Nam & John M. Cotte & Christopher V. Jahnes & Evan G. Colgan & Robert L. Bruce & Markus Brink & Michael F. Lofaro & Jyotica V. Patel & Lynne M. Gignac & Eric A. Joseph & Satyavol, 2017. "Wafer-scale integration of sacrificial nanofluidic chips for detecting and manipulating single DNA molecules," Nature Communications, Nature, vol. 8(1), pages 1-9, April.
    • Handle: RePEc:nat:natcom:v:8:y:2017:i:1:d:10.1038_ncomms14243
    DOI: 10.1038/ncomms14243
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