Exponential Increase in an Ionic Signal: A Dominant Role of the Space Charge Effect on the Outer Surface of Nanochannels

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Surface charge effects in nanoconfines is one of the fundamentals in the ion current rectification (ICR) of nanofluidics, which provides entropic driving force by asymmetric surface charges and causes ion enrichment/depletion by the electrostatic interaction of fixed surface charges. However, the surface charge effect causes a significant electrostatic repulsion in nanoconfines, restricting additional like charge or elaborate chemistry on the highly charged confined surface, which limits ICR manipulation. Here, we use polydopamine (PDA), a nearly universal adhesive, that adheres to the highly positive-charged poly(ethyleneimine) (PEI) gel network in a nanochannel array. PDA enhances the ICR effect from a low rectification ratio of 9.5 to 92.6 by increasing the surface charge and hydrophobicity of the PEI gel network and, meanwhile, shrinking its gap spacing. Theoretical and experimental results demonstrate the determinants of the fixed surface charge in the enrichment/depletion region on ICR properties, which is adjustable by PDA-induced change in a nanoconfined environment. Chemically active PDA brings Au nanoparticles by chloroauric reduction for further hydrophobization and the modification of negative-charged DNA complexes in nanochannels, whereby ICR effects can be manipulated in versatile means. The results describe an adjustable and versatile strategy for adjusting the ICR behaviors of nanofluidics by manipulating local surface charge effects using PDA.

Section: ■ Results and Discussionmentioning

confidence: 98%

Polydopamine-Induced Modification on the Highly Charged Surface of Asymmetric Nanofluidics: A Strategy for Adjustable Ion Current Rectification Properties

Lin

et al. 2022

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“…For a long time, people ignored FE OS , so that its functions were not clear. We carried out research on the precise functional zoning of solid-state nanopores and focused on the role of FE OS in ion gating (Figure c). − By controllably depositing metal layers using an electron-beam evaporation technique, only the one outer surface of the nanopores was modified (Figure a). For example, a thick gold layer was sputtered onto one side of the anodic aluminum oxide nanopore membrane, and the capture probe was immobilized to the outer surface through Au–S chemistry for regulating ion gating after the formation of a self-assembled DNA monolayer .…”

Section: Outer Surface Modified Nanoporesmentioning

confidence: 99%

“…FE OS such as negatively charged DNA causes an exponential increase in an ionic signal by the space charge effect. 16 DNA rolling circle amplification on the outer surface of nanopores achieves single-base mismatch detection of mRNA-21 with a sensitivity of 6 fM. 17 FE OS can effectively improve the ion selectivity and output power of nanopores without increasing the internal resistance.…”

Section: ■ Outer Surface Modified Nanoporesmentioning

confidence: 99%

“…These studies only focus on the functional elements modified on the inner wall (FE IW ) and ignore the role of functional elements modified on the outer surface (FE OS ) in sensing. To distinguish the functions of FE IW and FE OS , we carried out a series of studies on the impact of precise functional zoning of inner wall and outer surface on ion/molecule transport in solid-state nanopores and developed some highly sensitive and specific nanopore-based sensors. − Here, we review the research progress of inner wall and outer surface distinguished solid-state nanopores (Figure ) and discuss the development prospects and challenges. The nanopores discussed in this perspective are a broad concept, including nanochannels, mainly membrane materials such as silicon nitride, , two-dimensional materials, , aluminum oxide, and polymer films .…”

mentioning

confidence: 99%

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Inner Wall and Outer Surface Distinguished Solid-State Nanopores for Sensing

Dai

Zhang

et al. 2022

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Solid-state nanopores, inspired by biological nanopores, have the advantages of good mechanical properties, stability, and easy modification. They have attracted wide attention in the fields of sequencing, sensing, molecular sieving, nanofluidic devices, nanoelectrochemistry, and energy conversion. Because of the ion/molecule transport characteristic of the pore, the research on solid-state nanopores mainly focuses on the functional modification of its inner wall. In recent years, the outer surface of nanopores has also attracted the attention of researchers, and the functional elements on the outer surface have the functions of anti-interference and ionic signal enhancement. In this perspective, we review research progress of inner wall and outer surface distinguished solid-state nanopores, highlight their processing and advantages, summarize their functions and applications in sensing, and give insight into further research.

“…Specific recognition moiety-functionalized solid-state nanofluidic channels have been shown to be selective and sensitive sensors for various analytes. − Steady-state current change with chemical composition, surface charge, wettability, and the diameter of the nanofluidic channel caused by even a single molecule can be efficaciously recorded, endowing nanofluidic sensors with sensitivity down to aM levels. ,− The introduction of various specific recognition moieties including aptamer, phenylboronic acid, antibodies, and functional metal–organic frameworks brings the nanofluidic channel target-specific selectivity. , However, the time-consuming interaction of the recognition moieties and the targets is a great limitation for the application of nanofluidic channel-based sensors in rapid detection. ,− Thus, promoting the kinetics for the interaction between the analyte and the recognition moiety on the nanofluidic channels is the key to overcome the limitation.…”

Section: Introductionmentioning

confidence: 99%

Integrating Ordered Two-Dimensional Covalent Organic Frameworks to Solid-State Nanofluidic Channels for Ultrafast and Sensitive Detection of Mercury

Ran

Yan

2022

Grafting specific recognition moieties onto solid-state nanofluidic channels is a promising way for selective and sensitive sensing of analytes. However, the time-consuming interaction between recognition moieties and analytes is the main hindrance to the application of nanofluidic channel-based sensors in rapid detection. Here, we show the integration of ordered twodimensional covalent organic frameworks (2D COFs) to solid-state nanofluidic channels to achieve rapid, selective, and sensitive detection of contaminants. As a proof of concept, a thiourea-linked 2D COF (JNU-3) as the recognition unit is covalently bonded on the stable artificial anodic aluminum oxide nanochannels