Improving the binding efficiency of quartz crystal microbalance biosensors by applying the electrothermal effect

Huang, Yao-Hung; Chang, Jeng‐Shian; Chao, Sheng D.; Wu, Kuang‐Chong; Huang, Long-Sun

doi:10.1063/1.4898633

Cited by 11 publications

(4 citation statements)

References 48 publications

(52 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This section discusses QCM calibration and explains all artifacts produced as a result of the experimental procedure. When one face of the quartz crystal resonator is in contact with a liquid, the change in frequency (Δ F ) can be expressed by eq , − where ρ q is the density of quartz crystal (2.648 g·cm –3 ), μ q is the shear modulus of quartz (2.947 × 10 11 g·cm –1 ·s –2 ), f 0 is the frequency of the loaded crystal, A is the piezoelectrically active crystal area (given by the manufacturer as 0.1 cm 2 ), Δ m is the change in mass, η L is the viscosity of the liquid, and ρ L is the density of the liquid. From eq , the resonant frequency can be disturbed by either a change in surface mass (caused by film deposition or decay), a change in viscosity of the liquid or a change in density of the liquid.…”

Section: Resultsmentioning

confidence: 99%

Low-Fouling Characteristics of Ultrathin Zwitterionic Cysteine SAMs

et al. 2018

View full text Add to dashboard Cite

Surface fouling remains an exigent issue for many biological implants. Unwanted solutes adsorb to reduce device efficiency and hasten degradation while increasing the risks of microbial colonization and adverse inflammatory response. To address unwanted fouling in modern implants in vivo, surface modification with antifouling polymers has become indispensable. Recently, zwitterionic self-assembled monolayers, which contain two or more charged functional groups but are electrostatically neutral and form highly hydrated surfaces, have been the focus of many antifouling coatings. Reports using various compositions of zwitterionic polymer brushes have demonstrated ultralow fouling in the ng/cm range. These coatings, however, are thick and can hinder the target application of biological devices. Here, we report an ultrathin (8.52 Å) antifouling self-assembled monolayer composed of cysteine that is amenable to facile fabrication. The antifouling characteristics of the zwitterionic surfaces were evaluated against bovine serum albumin, fibrinogen, and human blood in real time using quartz crystal microbalance and surface plasmon resonance imaging. Compared to untreated gold surfaces, the ultrathin cysteine coating reduced the adsorption of bovine serum albumin by 95% (43 ng/cm adsorbed) after 3 h and 90% reduction after 24 h. Similarly, the cysteine self-assembled monolayer reduced the adsorption of fibrinogen as well as human blood by >90%. The surfaces were further characterized using scanning electron microscopy: protein-enhanced adsorption and cellular adsorption in human blood was found on untreated surfaces but not on the cysteine SAM-protected surfaces. These findings suggest that surfaces can be functionalized with an ultrathin layer of cysteine to resist the adsorption of key proteins, with performance comparable to zwitterionic polymer brushes. As such, cysteine surface coatings are a promising methodology to improve the long-term utility of biological devices.

show abstract

Section: Resultsmentioning

confidence: 99%

Low-Fouling Characteristics of Ultrathin Zwitterionic Cysteine SAMs

et al. 2018

View full text Add to dashboard Cite

show abstract

“…The AC electrothermal effect (ACET) was implicated in different biological technologies (Salari and Thompson 2018;Gao and Li 2019;Selmi et al 2015Selmi et al , 2016aSelmi et al , b, 2017Sin et al 2010;Huang and Chang 2013). It is well known that the ACET effect is more efficient at high frequencies (above 100 kHz), and when having a solution with an electrical conductivity σ that exceeds the value of 0.002 S/m (Huang et al 2014). Under these conditions, both experimental and numerical studies on the heterogeneous binding assays biotin/streptavidin have been achieved by Feldman et al (2007).…”

Section: Introductionmentioning

confidence: 99%

Enhancement of COVID-19 detection time by means of electrothermal force

Kaziz

Saad

Bouzid

et al. 2021

Microfluid Nanofluid

View full text Add to dashboard Cite

The rapid spread and quick transmission of the new ongoing pandemic coronavirus disease 2019 has urged the scientific community to looking for strong technology to understand its pathogenicity, transmission, and infectivity, which helps in the development of effective vaccines and therapies. Furthermore, there was a great effort to improve the performance of biosensors so that they can detect the pathogenic virus quickly, in reliable and precise way. In this context, we propose a numerical simulation to highlight the important role of the design parameters that can significantly improve the performance of the biosensor, in particular the sensitivity as well as the detection limit. Applied alternating current electrothermal (ACET) force can generate swirling patterns in the fluid within the microfluidic channel, which improve the transport of target molecule toward the reaction surface and, thus, enhance the response time of the biosensor. In this work, the ACET effect on the SARS-CoV-2 S protein binding reaction kinetics and on the detection time of the biosensor was analyzed. Appropriate choice of electrodes location on the walls of the microchannel and suitable values of the dissociation and association rates of the binding reaction, while maintaining the same affinity, with and without ACET effect, are also, discussed to enhance the total performance of the biosensor and reduce its response time. The two-dimensional equations system is solved by the finite element approach. The best performance of the biosensor is obtained in the case where the response time decreased by 61% with AC applying voltage.

show abstract

“…The AC electrothermal effect (ACET) was massively involved in the last decade of research on different biological technologies [22][23][24][25][26][27][28][29]. The ACET effect is effective at high frequencies (larger than 100 kHz) in a solution having a large electrical conductivity σ (greater than 0.002 S/m) [30]. Feldman et al [21] performed experimental and numerical investigations.…”

Section: Introductionmentioning

confidence: 99%

AC Electroosmosis Effect on Microfluidic Heterogeneous Immunoassay Efficiency

Selmi

Belmabrouk

2020

Micromachines

View full text Add to dashboard Cite

A heterogeneous immunoassay is an efficient biomedical test. It aims to detect the presence of an analyte or to measure its concentration. It has many applications, such as manipulating particles and separating cancer cells from blood. The enhanced performance of immunosensors comes down to capturing more antigens with greater efficiency by antibodies in a short time. In this work, we report an efficient investigation of the effects of alternating current (AC) electrokinetic forces such as AC electroosmosis (ACEO), which arise when the fluid absorbs energy from an applied electric field, on the kinetics of the antigen–antibody binding in a flow system. The force can produce swirling structures in the fluid and, thus, improve the transport of the analyte toward the reaction surface of the immunosensor device. A numerical simulation is adequate for this purpose and may provide valuable information. The convection–diffusion phenomenon is coupled with the first-order Langmuir model. The governing equations are solved using the finite element method (FEM). The impact of AC electroosmosis on the binding reaction kinetics, the fluid flow stream modification, the analyte concentration diffusion, and the detection time of the biosensor under AC electroosmosis are analyzed.

show abstract

Improving the binding efficiency of quartz crystal microbalance biosensors by applying the electrothermal effect

Cited by 11 publications

References 48 publications

Low-Fouling Characteristics of Ultrathin Zwitterionic Cysteine SAMs

Low-Fouling Characteristics of Ultrathin Zwitterionic Cysteine SAMs

Enhancement of COVID-19 detection time by means of electrothermal force

AC Electroosmosis Effect on Microfluidic Heterogeneous Immunoassay Efficiency

Contact Info

Product

Resources

About