TY - JOUR
T1 - Over One Million DNA and Protein Events Through Ultra-Stable Chemically-Tuned Solid-State Nanopores
AU - Saharia, Jugal
AU - Bandara, Yapa Mudiyanselage Nuwan Dhananjaya Yapa
AU - Karawdeniya, Buddini Iroshika
AU - Dwyer, Jason Rodger
AU - Kim, Min Jun
N1 - Publisher Copyright:
© 2023 Wiley-VCH GmbH.
PY - 2023/7/19
Y1 - 2023/7/19
N2 - Stability, long lifetime, resilience against clogging, low noise, and low cost are five critical cornerstones of solid-state nanopore technology. Here, a fabrication protocol is described wherein >1 million events are obtained from a single solid-state nanopore with both DNA and protein at the highest available lowpass filter (LPF, 100 kHz) of the Axopatch 200B–the highest event count mentioned in literature. Moreover, a total of ≈8.1 million events are reported in this work encompassing the two analyte classes. With the 100 kHz LPF, the temporally attenuated population is negligible while with the more ubiquitous 10 kHz, ≈91% of the events are attenuated. With DNA experiments, the pores are operational for hours (typically >7 h) while the average pore growth is merely ≈0.16 ± 0.1 nm h−1. The current noise is exceptionally stable with traces typically showing <10 pA h−1 increase in noise. Furthermore, a real-time method to clean and revive pores clogged with analyte with the added benefit of minimal pore growth during cleaning (< 5% of the original diameter) is showcased. The enormity of the data collected herein presents a significant advancement to solid-state pore performance and will be useful for future ventures such as machine learning where large amounts of pristine data are a prerequisite.
AB - Stability, long lifetime, resilience against clogging, low noise, and low cost are five critical cornerstones of solid-state nanopore technology. Here, a fabrication protocol is described wherein >1 million events are obtained from a single solid-state nanopore with both DNA and protein at the highest available lowpass filter (LPF, 100 kHz) of the Axopatch 200B–the highest event count mentioned in literature. Moreover, a total of ≈8.1 million events are reported in this work encompassing the two analyte classes. With the 100 kHz LPF, the temporally attenuated population is negligible while with the more ubiquitous 10 kHz, ≈91% of the events are attenuated. With DNA experiments, the pores are operational for hours (typically >7 h) while the average pore growth is merely ≈0.16 ± 0.1 nm h−1. The current noise is exceptionally stable with traces typically showing <10 pA h−1 increase in noise. Furthermore, a real-time method to clean and revive pores clogged with analyte with the added benefit of minimal pore growth during cleaning (< 5% of the original diameter) is showcased. The enormity of the data collected herein presents a significant advancement to solid-state pore performance and will be useful for future ventures such as machine learning where large amounts of pristine data are a prerequisite.
KW - high-lifetime
KW - low-noise
KW - million events
KW - nanopores
KW - ultra-stable
UR - http://www.scopus.com/inward/record.url?scp=85151692768&partnerID=8YFLogxK
U2 - 10.1002/smll.202300198
DO - 10.1002/smll.202300198
M3 - Article
SN - 1613-6810
VL - 19
JO - Small
JF - Small
IS - 29
M1 - 2300198
ER -