Observing Single Nanoparticle Collisions at an Ultramicroelectrode by Electrocatalytic Amplification

Xiao, Xiaoyin; Bard, Allen J.

doi:10.1021/ja072344w

Cited by 638 publications

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“…Second, the frequency of collision can be calculated theoretically by assuming a diffusionlimited flux of particles to the electrode surface and experimentally by counting the number of collision events over time. The frequency of collision based on diffusion (28), f D, theoretical , is given by f D,theoretical = 4DCr e N A , [1] where N A is Avogadro's number, r e is the radius of the electrode, C is the concentration of colloid in solution, and D is the diffusion coefficient of the particular particle. The concentrations of the MCMV and MHV-68 (a virus used for negative control in gaining specificity with the primary antibody) were determined using nanoparticle tracking analysis (NTA), which tracks individual particles and determines a size distribution based on the diffusion coefficient using the random walk model.…”

Section: Significancementioning

confidence: 99%

“…By observing the collisions of small particles, there is the possibility that information can be deduced that is not available in ensemble measurements. The electrochemical study of single collision events has been applied to a wide range of hard nanoparticles (NPs), which include metal, metal oxide, and organic NPs [platinum (1), silver (2), gold (3), nickel (4), copper (5), iridium oxide (6), cerium oxide (7), titanium oxide (8), silicon oxide (9), indigo (10), polystyrene (11), and relatively large aggregates of fullerene (12)]. Recently, collisions of soft particles have been investigated, such as toluene droplets (13) and liposomes (14).…”

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confidence: 99%

“…The interested reader can consult the references for a discussion on each of the techniques used to observe stochastic events electrochemically: blocking (9, 13), electrocatalytic amplification (1), open circuit potential (16), droplet blocking/reactor (13,14), and ECL (15,17,18). The simplest and most reproducible method of observing collisions is a technique termed blocking, which is so named because particles, which are brought to the electrode by a diffusion-limited flux and/or electrophoretic migration, irreversibly adsorb (1) to the electrode surface, blocking the flux of redox active species.…”

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confidence: 99%

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Electrochemical detection of a single cytomegalovirus at an ultramicroelectrode and its antibody anchoring

Dick

Hilterbrand

Boika

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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We report observations of stochastic collisions of murine cytomegalovirus (MCMV) on ultramicroelectrodes (UMEs), extending the observation of discrete collision events on UMEs to biologically relevant analytes. Adsorption of an antibody specific for a virion surface glycoprotein allowed differentiation of MCMV from MCMV bound by antibody from the collision frequency decrease and current magnitudes in the electrochemical collision experiments, which shows the efficacy of the method to size viral samples. To add selectivity to the technique, interactions between MCMV, a glycoprotein-specific primary antibody to MCMV, and polystyrene bead "anchors," which were functionalized with a secondary antibody specific to the Fc region of the primary antibody, were used to affect virus mobility. Bead aggregation was observed, and the extent of aggregation was measured using the electrochemical collision technique. Scanning electron microscopy and optical microscopy further supported aggregate shape and extent of aggregation with and without MCMV. This work extends the field of collisions to biologically relevant antigens and provides a novel foundation upon which qualitative sensor technology might be built for selective detection of viruses and other biologically relevant analytes.collisions | cytomegalovirus | electrochemistry | murine cytomegalovirus | virus O ver the past decade, the study of discrete collision events on ultramicroelectrodes (UMEs) has gained attention due to the interest in understanding stochastic phenomena by electrochemistry. By observing the collisions of small particles, there is the possibility that information can be deduced that is not available in ensemble measurements. The electrochemical study of single collision events has been applied to a wide range of hard nanoparticles (NPs), which include metal, metal oxide, and organic NPs [platinum (1), silver (2), gold (3), nickel (4), copper (5), iridium oxide (6), cerium oxide (7), titanium oxide (8), silicon oxide (9), indigo (10), polystyrene (11), and relatively large aggregates of fullerene (12)]. Recently, collisions of soft particles have been investigated, such as toluene droplets (13) and liposomes (14). Also, collisions of toluene and tri-n-propylamine droplets were observed simultaneously by both electrochemical and electrogenerated chemiluminescent (ECL) measurements (15).Similarly, a variety of techniques have been developed to observe these collision events. The interested reader can consult the references for a discussion on each of the techniques used to observe stochastic events electrochemically: blocking (9, 13), electrocatalytic amplification (1), open circuit potential (16), droplet blocking/reactor (13,14), and ECL (15,17,18). The simplest and most reproducible method of observing collisions is a technique termed blocking, which is so named because particles, which are brought to the electrode by a diffusion-limited flux and/or electrophoretic migration, irreversibly adsorb (1) to the electrode surface, blocking the flux of red...

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Section: Significancementioning

confidence: 99%

mentioning

confidence: 99%

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Electrochemical detection of a single cytomegalovirus at an ultramicroelectrode and its antibody anchoring

Dick

Hilterbrand

Boika

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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150

132

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“…1,[5][6][7][8][9][10][11][12][13] However, as the vast majority of investigations have employed a large number of particles in a catalytic ensemble, the information obtained is limited due to unavoidable variations in NP size, shape and local environment. 14 Efforts to circumvent this limitation have been made by shifting to single particle measurements, [15][16][17][18][19][20] but such studies are rather challenging. 21 In general, single particle experiments fall into one of two categories.…”

mentioning

confidence: 99%

“…First, a single NP can be deposited on an electrode with a small surface area, either through electrodeposition 15,16 or through collision of a colloidal NP in solution with the electrode. 17 Valuable insights can be obtained, but such studies preclude an understanding of ensemble behavior and are limited in the range of electrode supports and environments that can be investigated. Second, attempts have been made to study NP ensembles at a single particle level by scanning probe techniques, such as scanning tunneling microscopy 19 and scanning electrochemical microscopy.…”

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confidence: 99%

Visualizing Zeptomole (Electro)Catalysis at Single Nanoparticles within an Ensemble

et al. 2011

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Analytical Nanotoxicology

Caballero-Díaz

2016

Encyclopedia of Analytical Chemistry

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The inclusion of engineered nanoparticles (NPs) in a large number of consumer products and their potential use for medical purposes leads to an urgent need for designing and establishing toxicity assessment protocols that allow for obtaining information on potential harmful effects of NPs at cellular and organism levels (in vitro and in vivo experiments, respectively). For defining the toxicological profile of NPs, exhaustive characterization studies are firstly needed in order to correlate the observed biological response with well‐characterized NPs. This article summarizes the key aspects about NP characterization to be considered in any toxicological study. Characterized NPs are then assayed by in vitro toxicity screening tests based on cell culture systems, existing numerous available testing platforms whose choice depends on the cellular effect to be analyzed. For further corroboration of the effects reported on cell lines, in vivo experiments are finally conducted on experimental animals where investigation about pharmacokinetics provides a better understanding on biological behavior of NPs, creating more realistic scenarios for risk assessment. This article describes the most commonly used analytical strategies for in vitro and in vivo nanotoxicity assessment. A final section is also included for setting the reader in a context on challenges and future prospects in nanotoxicity.

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Observing Single Nanoparticle Collisions at an Ultramicroelectrode by Electrocatalytic Amplification

Cited by 638 publications

References 17 publications

Electrochemical detection of a single cytomegalovirus at an ultramicroelectrode and its antibody anchoring

Electrochemical detection of a single cytomegalovirus at an ultramicroelectrode and its antibody anchoring

Visualizing Zeptomole (Electro)Catalysis at Single Nanoparticles within an Ensemble

Analytical Nanotoxicology

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