Despite the potential for nanopores to be a platform for high-bandwidth study of single-molecule systems, ionic current measurements through nanopores have been limited in their temporal resolution by noise arising from poorly optimized measurement electronics and large parasitic capacitances in the nanopore membranes. Here, we present a complementary metal-oxide-semiconductor (CMOS) nanopore (CNP) amplifier capable of low noise recordings at an unprecedented 10 MHz bandwidth. When integrated with state-of-the-art solid-state nanopores in silicon nitride membranes, we achieve an SNR of greater than 10 for ssDNA translocations at a measurement bandwidth of 5 MHz, which represents the fastest ion current recordings through nanopores reported to date. We observe transient features in ssDNA translocation events that are as short as 200 ns, which are hidden even at bandwidths as high as 1 MHz. These features offer further insights into the translocation kinetics of molecules entering and exiting the pore. This platform highlights the advantages of high-bandwidth translocation measurements made possible by integrating nanopores and custom-designed electronics.
Accurate
and low-cost analysis of biomolecules is important for
many applications. This work seeks to further improve the measurement
bandwidths achievable with solid-state nanopores, which have emerged
as an important platform for this analysis. We report single-stranded
DNA translocation recordings at a bandwidth of 10 MHz copolymers of
80 (C20A20C20A20), 90
(C30A30C30), and 200 (C50A50C50A50) nucleotides through Si
nanopores with effective diameters of 1.4–2.1 nm and effective
membrane thicknesses 0.5–8.9 nm. By optimizing glass chips
with thin nanopores and by integrating them with custom-designed amplifiers
based on complementary metal-oxide-semiconductor technology, this
work demonstrates detection of translocation events as brief as 100
ns with a signal-to-noise ratio exceeding seven at a measurement bandwidth
of 10 MHz. We also report data robustness and variability across 13
pores of similar size and thickness, yielding a current blockade between
30 and 60% with a mean ionic current blockade (ΔI) of ∼3–9 nA and a characteristic dwell time of ∼2–21
ns per nucleotide. These measurements show that characteristic translocation
rates are at least 10 times faster than previously recorded. We detect
transient intraevent fluctuations, multiple current levels within
translocation events, and variability of DNA translocation event signatures
and durations.
Solid-state membranes are finding use in many applications in nanoelectronics and nanomedicine, from single molecule sensors to water filtration, and yet many of their electronics applications are limited by the relatively high current noise and low bandwidth stemming from the relatively high capacitance (>10 pF) of the membrane chips. To address this problem, we devised an integrated fabrication process to grow and define circular silicon nitride membranes on glass chips that successfully lower the chip capacitance to below 1 pF. We use these devices to demonstrate low-noise, high-bandwidth DNA translocation measurements. We also make use of this versatile, low-capacitance platform to suspend other thin, two-dimensional membrane such as graphene.
Recent work has pushed the noise-limited bandwidths of solid-state nanopore conductance recordings to more than 5 MHz and of ion channel conductance recordings to more than 500 kHz through the use of integrated complementary metal-oxide-semiconductor (CMOS) integrated circuits. Despite the spectral spread of the pulse-like signals that characterize these recordings when a sinusoidal basis is employed, Bessel filters are commonly used to denoise these signals to acceptable signal-to-noise ratios (SNRs) at the cost of losing many of the faster temporal features. Here, we report improvements to the SNR that can be achieved using wavelet denoising instead of Bessel filtering. When combined with state-of-the-art high-bandwidth CMOS recording instrumentation, we can reduce baseline noise levels by over a factor of four compared to a 2.5-MHz Bessel filter while retaining transient properties in the signal comparable to this filter bandwidth. Similarly, for ion channel recordings, we achieve a temporal response better than a 100-kHz Bessel filter with a noise level comparable to that achievable with a 25-kHz Bessel filter. Improvements in SNR can be used to achieve robust statistical analyses of these recordings, which may provide important insights into nanopore translocation dynamics and mechanisms of ion channel function.
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