TY - JOUR
T1 - Massive nanophotonic trapping and alignment of rod-shaped bacteria for parallel single-cell studies
AU - Zhao, Haitao
AU - Chin, Lip Ket
AU - Shi, Yuzhi
AU - Nguyen, Kim Truc
AU - Liu, Patricia Yang
AU - Zhang, Yi
AU - Zhang, Meng
AU - Zhang, Jingbo
AU - Cai, Hong
AU - Yap, Eric Peng Huat
AU - Ser, Wee
AU - Liu, Ai-Qun
PY - 2020/3/1
Y1 - 2020/3/1
N2 - The emerging single-cell technologies call for novel biological tools that can manipulate target cells in a massive and spatially-arranged manner. Here we report a nanophotonic platform, named WANTS (Waveguide-pair Array-based Nanophotonic Trapping System), for massive trapping and alignment of rod-shaped bacteria. This platform leverages silicon waveguide-pair arrays to engineer an optical lattice pattern and the accompanying optical force field. The rod-shaped bacteria inside the field are trapped and aligned by three motions: the out-of-plane rotation, the in-plane rotation, and the translational motion. Massive shigella are arranged into a closely-seated distribution at a trapping rate of ∼12 shigella/min. As a demonstration, we utilize the platform to investigate the bacterial biophysical property and find that the measured bacterial lengths are 23.65% more accurate than the results measured with free solutions. Subsequently, we study the bacterial viability in situ and find that shigella present high heterogeneity in response to chemical stimuli. The WANTS holds significant promise to integrate with lab-on-a-chip technologies and yield a compact and robust platform for practical biological studies at the single-cell level.
AB - The emerging single-cell technologies call for novel biological tools that can manipulate target cells in a massive and spatially-arranged manner. Here we report a nanophotonic platform, named WANTS (Waveguide-pair Array-based Nanophotonic Trapping System), for massive trapping and alignment of rod-shaped bacteria. This platform leverages silicon waveguide-pair arrays to engineer an optical lattice pattern and the accompanying optical force field. The rod-shaped bacteria inside the field are trapped and aligned by three motions: the out-of-plane rotation, the in-plane rotation, and the translational motion. Massive shigella are arranged into a closely-seated distribution at a trapping rate of ∼12 shigella/min. As a demonstration, we utilize the platform to investigate the bacterial biophysical property and find that the measured bacterial lengths are 23.65% more accurate than the results measured with free solutions. Subsequently, we study the bacterial viability in situ and find that shigella present high heterogeneity in response to chemical stimuli. The WANTS holds significant promise to integrate with lab-on-a-chip technologies and yield a compact and robust platform for practical biological studies at the single-cell level.
KW - Lab-On-A-Chip
KW - Nanophotonic trapping
KW - Optical manipulation
KW - Rod-Shaped bacteria
KW - Single-Cell technology
UR - http://www.scopus.com/inward/record.url?scp=85076488633&partnerID=8YFLogxK
UR - https://www.scopus.com/record/pubmetrics.uri?eid=2-s2.0-85076488633&origin=recordpage
U2 - 10.1016/j.snb.2019.127562
DO - 10.1016/j.snb.2019.127562
M3 - RGC 21 - Publication in refereed journal
SN - 0925-4005
VL - 306
JO - Sensors and Actuators, B: Chemical
JF - Sensors and Actuators, B: Chemical
M1 - 127562
ER -