Sensitive and Specific Detection of Estrogens Featuring Doped Silicon Nanowire Arrays

Duan, Wenqi; Zhi, Hui; Keefe, Daniel W.; Gao, Bingtao; Lefèvre, Grégory; Toor, Fatima

doi:10.1021/acsomega.1c00210

Cited by 5 publications

(4 citation statements)

References 54 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The sensing platform included a second MTF electrode capped with a control aptamer, which did not react with the target, to provide a baseline and correction to drifts due to interferences. 163 Finally, field-effect transistor (FET) biosensors based on nanomaterials such as silicon nanowires 164 and graphene 165 have the potential of rapid and label-free detection of a wide range of biomarkers. Indeed, FET biosensors detect changes in the charge distribution at the surface of the transistor when biomolecules bind to the biorecognition elements on the gate electrode or the transistor channel.…”

Section: Further Applications In Biosensingmentioning

confidence: 99%

“…Finally, field-effect transistor (FET) biosensors based on nanomaterials such as silicon nanowires and graphene have the potential of rapid and label-free detection of a wide range of biomarkers. Indeed, FET biosensors detect changes in the charge distribution at the surface of the transistor when biomolecules bind to the biorecognition elements on the gate electrode or the transistor channel .…”

Section: Further Applications In Biosensingmentioning

confidence: 99%

See 1 more Smart Citation

Ordered Mesoporous Electrodes for Sensing Applications

et al. 2023

View full text Add to dashboard Cite

Electrochemical sensors have become increasingly relevant in fields such as medicine, environmental monitoring, and industrial process control. Selectivity, specificity, sensitivity, signal reproducibility, and robustness are among the most important challenges for their development, especially when the target compound is present in low concentrations or in complex analytical matrices. In this context, electrode modification with Mesoporous Thin Films (MTFs) has aroused great interest in the past years. MTFs present high surface area, uniform pore distribution, and tunable pore size. Furthermore, they offer a wide variety of electrochemical signal modulation possibilities through molecular sieving, electrostatic or steric exclusion, and preconcentration effects which are due to mesopore confinement and surface functionalization. In order to fully exploit these advantages, it is central to develop reproducible routes for sensitive, selective, and robust MTF-modified electrodes. In addition, it is necessary to understand the complex mass and charge transport processes that take place through the film (particularly in the mesopores, pore surfaces, and interfaces) and on the electrode in order to design future intelligent and adaptive sensors. We present here an overview of MTFs applied to electrochemical sensing, in which we address their fabrication methods and the transport processes that are critical to the electrode response. We also summarize the current applications in biosensing and electroanalysis, as well as the challenges and opportunities brought by integrating MTF synthesis with electrode microfabrication, which is critical when moving from laboratory work to in situ sensing in the field of interest.

show abstract

Section: Further Applications In Biosensingmentioning

confidence: 99%

Section: Further Applications In Biosensingmentioning

confidence: 99%

Ordered Mesoporous Electrodes for Sensing Applications

et al. 2023

View full text Add to dashboard Cite

show abstract

“…An additional leverage to control Si NSs is their agglomeration. Si NS bundling is of paramount relevance in many applications, from antireflective layers in photovoltaic cells to sensors , and from electronics to thermoelectric devices. , Concerning thermoelectrics, tip agglomeration introduces additional electrical contact resistances that are noxious to the device efficiency . Factors affecting tip bundling were then analyzed to either reduce or enhance its extent.…”

Section: Introductionmentioning

confidence: 99%

Self-Sustained Quasi-1D Silicon Nanostructures for Thermoelectric Applications

Giulio,

Puccio,

Magagna

et al. 2023

ACS Appl. Electron. Mater.

View full text Add to dashboard Cite

Silicon (Si) nanowires have garnered significant interest for their potential applications in Si-based thermoelectrics, primarily due to their low thermal conductivity. While there are several methods to obtain Si nanowires, their density has been a limiting factor, resulting in a low power density that can be achieved by thermoelectric generators. To address this limitation, metal-assisted chemical etching (MACE) has been developed, enabling the creation of high-density nanopillar “forests”. This technique overcomes the previous density constraints. However, Si nanopillars protrude from a bulk Si wafer, which adds its thermal and electric resistivity to those of nanopillars, ultimately reducing the overall power density that can be attained. In this paper, we demonstrate how precise control of pre- and post-MACE processing allows for the creation of fully self-sustained quasi-1D Si nanostructures. We additionally demonstrate that pre-MACE Si processing does not control nanopillar bundling; rather, it primarily determines their shape. This outcome is attributed to the formation of gas nanobubbles during the initial steps of MACE.

show abstract

“…However, these techniques are time-consuming and complex, involving sample pretreatment, expensive equipment, and well-trained personnel. Recently, sensors have been designed using aptamer-based analytical methods for the detection of E2, such as electrochemical, colorimetric, fluorescent, photoelectrochemical aptasensors, and vertically oriented silicon nanowire (vSiNW) [14][15][16][17][18][19][20][21][22][23]. These sensors detect the concentration of E2 by determining E2 binding using a DNA aptamer bonded to a gold nanoparticle, 3-aminopropyltriethoxysilane (APTES), gold thin film, RhoB, and TiO 2 -BiVO 4 , and then measuring the current (I), wavelength (λ), absorbance (A), and fluorescence intensity (F).…”

Section: Introductionmentioning

confidence: 99%

Sensing High 17β-Estradiol Concentrations Using a Planar Microwave Sensor Integrated with a Microfluidic Channel

2023

View full text Add to dashboard Cite

The global issue of pollution caused by endocrine-disrupting chemicals (EDCs) has been gaining increasing attention. Among the EDCs of environmental concern, 17β-estradiol (E2) can produce the strongest estrogenic effects when it enters the organism exogenously through various routes and has the potential to cause harm, including malfunctions of the endocrine system and development of growth and reproductive disorders in humans and animals. Additionally, in humans, supraphysiological levels of E2 have been associated with a range of E2-dependent disorders and cancers. To ensure environmental safety and prevent potential risks of E2 to human and animal health, it is crucial to develop rapid, sensitive, low cost and simple approaches for detecting E2 contamination in the environment. A planar microwave sensor for E2 sensing is presented based on the integration of a microstrip transmission line (TL) loaded with a Peano fractal geometry with a narrow slot complementary split-ring resonator (PF-NSCSRR) and a microfluidic channel. The proposed technique offers a wide linear range for detecting E2, ranging from 0.001 to 10 mM, and can achieve high sensitivity with small sample volumes and simple operation methods. The proposed microwave sensor was validated through simulations and empirical measurements within a frequency range of 0.5–3.5 GHz. The E2 solution was delivered to the sensitive area of the sensor device via a microfluidic polydimethylsiloxane (PDMS) channel with an area of 2.7 mm2 and sample value of 1.37 µL and measured by a proposed sensor. The injection of E2 into the channel resulted in changes in the transmission coefficient (S21) and resonance frequency (Fr), which can be used as an indicator of E2 levels in solution. The maximum quality factor of 114.89 and the maximum sensitivity based on S21 and Fr at a concentration of 0.01 mM were 1746.98 dB/mM and 40 GHz/mM, respectively. Upon comparing the proposed sensor with the original Peano fractal geometry with complementary split-ring (PF-CSRR) sensors without a narrow slot, several parameters were evaluated, including sensitivity, quality factor, operating frequency, active area, and sample volume. The results showed that the proposed sensor exhibited an increased sensitivity of 6.08% and had a 40.72% higher quality factor, while the operating frequency, active area, and sample volume showed decreases of 1.71%, 25%, and 28.27%, respectively. The materials under tests (MUTs) were analyzed and categorized into groups using principal component analysis (PCA) with a K-mean clustering algorithm. The proposed E2 sensor has a compact size and simple structure that can be easily fabricated with low-cost materials. With the small sample volume requirement, fast measurement with a wide dynamic range, and a simple protocol, this proposed sensor can also be applied to measure high E2 levels in environmental, human, and animal samples.

show abstract

Sensitive and Specific Detection of Estrogens Featuring Doped Silicon Nanowire Arrays

Cited by 5 publications

References 54 publications

Ordered Mesoporous Electrodes for Sensing Applications

Ordered Mesoporous Electrodes for Sensing Applications

Self-Sustained Quasi-1D Silicon Nanostructures for Thermoelectric Applications

Sensing High 17β-Estradiol Concentrations Using a Planar Microwave Sensor Integrated with a Microfluidic Channel

Contact Info

Product

Resources

About