2021
DOI: 10.1002/elsa.202100145
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ISFET‐based ion sensors with photopolymerizable membranes

Abstract: This minireview summarizes the information on the development and application of ion-sensitive field-effect transistors (ISFETs) with UV-cured polyurethane ion-selective membranes. Among the advantages of photopolymerizable polymer membranes in comparison with traditional poly(vinyl chloride) are excellent adhesion to a solid sensor surface and very fast curing time. Moreover, processes of membrane deposition and curing are compatible with ISFETs fabrication technology which is important for sensors mass produ… Show more

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Cited by 4 publications
(6 citation statements)
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“…By mimicking the in‐line K + recognition of the KcsA potassium channel, our hexyl‐modified monolithic G‐quadruplex produced a K + ‐selective ion flux across the freestanding ion‐impermeable lipid bilayer without water leakage; despite the same valency, Li + and Cl − were less favored than K + , exhibiting P Li / P K = 0.214 and P Cl / P K = 0.004, respectively. Compared to conventional valinomycin‐embedded polymeric membranes (30–100 µm in thickness), [ 32 ] our K + ‐selective membrane, which can be integrated into the OJID, is ultrathin (≈4 nm), highly K + ‐selective, and even non‐cytotoxic. Moreover, the neuron‐like ion‐to‐ion signal transduction of the OJID (10 mm × 10 mm × 1 mm) allowed the direct conversion of K + effluxes into amplified ionic currents (up to 20× amplification ratio), differentiating our ionic device from conventional potentiometric ion recorders that require mediation of electrical potential changes.…”
Section: Discussionmentioning
confidence: 99%
“…By mimicking the in‐line K + recognition of the KcsA potassium channel, our hexyl‐modified monolithic G‐quadruplex produced a K + ‐selective ion flux across the freestanding ion‐impermeable lipid bilayer without water leakage; despite the same valency, Li + and Cl − were less favored than K + , exhibiting P Li / P K = 0.214 and P Cl / P K = 0.004, respectively. Compared to conventional valinomycin‐embedded polymeric membranes (30–100 µm in thickness), [ 32 ] our K + ‐selective membrane, which can be integrated into the OJID, is ultrathin (≈4 nm), highly K + ‐selective, and even non‐cytotoxic. Moreover, the neuron‐like ion‐to‐ion signal transduction of the OJID (10 mm × 10 mm × 1 mm) allowed the direct conversion of K + effluxes into amplified ionic currents (up to 20× amplification ratio), differentiating our ionic device from conventional potentiometric ion recorders that require mediation of electrical potential changes.…”
Section: Discussionmentioning
confidence: 99%
“…Figure 4 reports the comparison of the membrane potential recorded in the experiments in [39] and the simulation results sampled at the Interface 1 (see Fig. 3.a), versus [ClO − 4 ] in 1 The NE equation in Fig. 3.b is…”
Section: B Comparison With Experimental Datamentioning
confidence: 99%
“…Here, a stable interface with gate oxide is needed [1] to make sure that the potential changes at the ISM/electrolyte interface (function of the ionic concentrations) modify the gate voltage of the FET, V g′ , that is:…”
Section: B Ism-based Isfetsmentioning
confidence: 99%
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