Evgeniy Mervinetsky scite author profile

Zinc and copper are essential metal ions for numerous biological processes. Their levels are tightly maintained in all body organs. Impairment of the Zn2+ to Cu2+ ratio in serum was found to correlate with many disease states, including immunological and inflammatory disorders. Oxytocin (OT) is a neuropeptide, and its activity is modulated by zinc and copper ion binding. Harnessing the intrinsic properties of OT is one of the attractive ways to develop valuable metal ion sensors. Here, we report for the first time an OT-based metal ion sensor prepared by immobilizing the neuropeptide onto a glassy carbon electrode. The developed impedimetric biosensor was ultrasensitive to Zn2+ and Cu2+ ions at physiological pH and not to other biologically relevant ions. Interestingly, the electrochemical impedance signal of two hemicircle systems was recorded after the attachment of OT to the surface. These two semicircles suggest two capacitive regions that result from two different domains in the OT monolayer. Moreover, the change in the charge-transfer resistance of either Zn2+ or Cu2+ was not similar in response to binding. This suggests that the metal-dependent conformational changes of OT can be translated to distinct impedimetric data. Selective masking of Zn2+ and Cu2+ was used to allow for the simultaneous determination of zinc to copper ions ratio by the OT sensor. The OT sensor was able to distinguish between healthy control and multiple sclerosis patients diluted sera samples by determining the Zn/Cu ratio similar to the state-of-the-art techniques. The OT sensor presented herein is likely to have numerous applications in biomedical research and pave the way to other types of neuropeptide-derived sensors.

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Copper Induced Conformational Changes of Tripeptide Monolayer Based Impedimetric Biosensor

Mervinetsky

Alshanski

Hamo

et al. 2017

Sci Rep

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Copper ions play a major role in biological processes. Abnormal Cu2+ ions concentrations are associated with various diseases, hence, can be used as diagnostic target. Monitoring copper ion is currently performed by non-portable, expensive and complicated to use equipment. We present a label free and a highly sensitive electrochemical ion-detecting biosensor based on a Gly-Gly-His tripeptide layer that chelate with Cu2+ ions. The proposed sensing mechanism is that the chelation results in conformational changes in the peptide that forms a denser insulating layer that prevents RedOx species transfer to the surface. This chelation event was monitored using various electrochemical methods and surface chemistry analysis and supported by theoretical calculations. We propose a highly sensitive ion-detection biosensor that can detect Cu2+ ions in the pM range with high SNR parameter.

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Sulfation Patterns of Saccharides and Heavy Metal Ion Binding

Alshanski

Blaszkiewicz

Mervinetsky

et al. 2019

Chemistry A European J

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Sulfated saccharides are an essentialp art of extracellularm atrices, and they are involvedi nalarge number of interactions. Sulfated saccharide matricesi no rganismsa ccumulate heavy metal ions in addition to othere ssentialm etal ions. Accumulation of heavy metal ions alters the function of the organisms and cells, resulting in severea nd irreversible damage. The effect of the sulfation pattern of saccharides on heavym etal binding preferences is enigmatic because the accessibility to structurally definedsulfated sac-charides is limited and because standard analytical techniquescannot be used to quantify these interactions.Wedeveloped an ew strategy that combines enzymatic and chemicals ynthesis with surfacec hemistry and label-free electrochemical sensing to study the interactions between well-defined sulfated saccharides and heavy metal ions. By using these tools we showedt hat the sulfation pattern of hyaluronic acid governs their heavy metal ions binding preferences.

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Molecular and Ionic Dipole Effects on the Electronic Properties of Si-/SiO₂-Grafted Alkylamine Monolayers

Gankin

Sfez

Mervinetsky

et al. 2017

ACS Appl. Mater. Interfaces

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In this work, we demonstrate the tunability of electronic properties of Si/SiO substrates by molecular and ionic surface modifications. The changes in the electronic properties such as the work function (WF) and electron affinity were experimentally measured by the contact potential difference technique and theoretically supported by density functional theory calculations. We attribute these molecular electronic effects mainly to the variations of molecular and surface dipoles of the ionic and neutral species. We have previously shown that for the alkylhalide monolayers, changing the tail group from Cl to I decreased the WF of the substrate. Here, we report on the opposite trend of WF changes, that is, the increase of the WF, obtained by using the anions of these halides from Cl to I. This trend was observed on self-assembled alkylammonium halide (-NH X, where X = Cl, Br, or I) monolayer-modified substrates. The monolayer's formation was supported by ellipsometry measurements, X-ray photoelectron spectroscopy, and atomic force microscopy. Comparison of the theoretical and experimental data suggests that the ionic surface dipole depends mainly on the polarizability and the position of the counter halide anion along with the organization and packaging of the layer. The described ionic modification can be easily used for facile tailoring and design of the electronic properties Si/SiO substrates for various device applications.

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Electrochemical biosensing platform based on complex biantennary N-glycan for detecting enzymatic sialylation processes

Alshanski

Sukhran

Mervinetsky

et al. 2021

Biosensors and Bioelectronics

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