Silicon Nanowire Arrays for Label-Free Detection of DNA

Gao, Zhiqiang; Agarwal, Ajay; Trigg, A. D.; Singh, Navab; Fang, Cheng; Tung, Chih-Hang; Fan, Yi; Buddharaju, K.D.; Kong, Jinming

doi:10.1021/ac061808q

Cited by 414 publications

(331 citation statements)

References 33 publications

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“…It is defined as a group of metabolic diseases where ultimately the body's pancreas does not produce enough insulin or does not properly respond to insulin produced, resulting in high blood sugar levels over a prolonged period. Glucose meters and other POC devices utilize an assortment of methods for detecting and monitoring biomarkers including electrochemical [16][17][18][19][20], magnetic [21][22][23][24][25][26][27][28][29][30], optical [31][32][33][34], label-free spectroscopic analysis [35][36][37][38][39][40][41][42][43], colorimetric [44][45][46][47][48][49], and plasmonic nanoparticle based sensors [50][51][52]. Generally, electrochemical detection uses potentiometric, amperometric, and impedimetric measurements in conjunction with electroactive tags or free flowing electroactive analytes [17][18][19][20] [15,53,54] are examples of electrochemical and colorimet...…”

Section: Current Commercial Poc Technologiesmentioning

confidence: 99%

Surface enhanced Raman spectroscopy (SERS) for in vitro diagnostic testing at the point of care

et al. 2017

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Point-of-care (POC) device development is a growing field that aims to develop low-cost, rapid, sensitive in-vitro diagnostic testing platforms that are portable, selfcontained, and can be used anywhere -from modern clinics to remote and low resource areas. In this review, surface enhanced Raman spectroscopy (SERS) is discussed as a solution to facilitating the translation of bioanalytical sensing to the POC. The potential for SERS to meet the widely accepted "ASSURED" (Affordable, Sensitive, Specific, Userfriendly, Rapid, Equipment-free, and Deliverable) criterion provided by the World Health Organization is discussed based on recent advances in SERS in vitro assay development. As SERS provides attractive characteristics for multiplexed sensing at low concentration limits with a high degree of specificity, it holds great promise for enhancing current efforts in rapid diagnostic testing. In outlining the progression of SERS techniques over the past years combined with recent developments in smart nanomaterials, high-throughput microfluidics, and low-cost paper diagnostics, an extensive number of new possibilities show potential for translating SERS biosensors to the POC.

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Section: Current Commercial Poc Technologiesmentioning

confidence: 99%

Surface enhanced Raman spectroscopy (SERS) for in vitro diagnostic testing at the point of care

et al. 2017

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“…Top-down micro-and nano-fabrication of nanostructure devices utilize well-known processes such as electron-beam nanolithography followed by dry etching [7], silicon wire thinning via repeated surface oxidation and HF etching processes [12,13] and anisotropic timed etching of silicon structures to nanoscale feature sizes [14]. These top-down techniques involve high processing costs/complexity, low yields associated with e-beam lithography and focused ion beam (FIB), and significant variability across etched devices due to etching non-uniformity across the wafer and its high sensitivity to processing conditions.…”

Section: Motivationmentioning

confidence: 99%

Contact detection for nanomanipulation in a scanning electron microscope

2012

Ultramicroscopy

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A major difficulty in the fabrication of nanostructure based electronics is the lack of effective processes capable of precisely arranging nanostructures into predefined positions. Top-down approaches introduce increased complexity and a high cost for practical industrial use, while bottom-up approaches are probabilistic in nature and do not provide precise control of nanostructure properties (i.e., number, diameter), which influence device performance.Alternatively, nanomanipulation promises specificity, precision and programmed motion and its automation may facilitate the large-scale fabrication of nanostructure based devices.This study focuses on the development of an automated contact detection algorithm which positions an end-effector in contact with a target surface without the need for additional equipment, devices or sensors. We demonstrate this algorithm as an enabling feature for automated nano-FET biosensor construction with precise control over nanowire parameters thereby reducing device-to-device variability and also potentially allowing us to optimize individual device performance.iii

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“…In addition, SiNW-FETs can perform rapid, ultrasensitive, and multiplexed detection of the desired targets independent of any labels (Patolsky et al 2006a, Gao et al 2007). In the past decade, this nanobiosensor has been widely used to detect a variety of molecule binding events with sensitivities below picomolar concentrations (Gao et al 2011(Gao et al , 2012(Gao et al , 2013.…”

Section: Introductionmentioning

confidence: 99%

Silicon nanowire-transistor biosensor for study of molecule-molecule interactions

Yang

Zhang

2014

Reviews in Analytical Chemistry

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Abstract:Monitoring the molecular recognition, binding, and disassociation between probe and target is important in medical diagnostics and drug screening, because such a wealth of information can be used to identify the pathogenic species and new therapeutic candidates. Nanoelectronic biosensors based on silicon nanowire field-effect transistors (SiNW-FETs) have recently attracted tremendous attention as a promising tool in the investigation of biomolecular interactions due to their capability of ultrasensitive, selective, real-time, and label-free detection. Herein, we summarize the recent advances in label-free analysis of molecule-molecule interactions using SiNWFETs, with a discussion and emphasis on small molecule-biomolecule interaction, biomolecule-biomolecule interactions (including carbohydrate-protein interaction, protein-protein or antigen-antibody binding, and nucleic acid-nucleic acid hybridization), and protein-virus interaction. Such molecular recognitions offer a basis of biosensing and the dynamics assay of biomolecular association or dissociation. Compared to the conventional technologies, SiNW-FETs hold great promise to monitor molecule-molecule interactions with higher sensitivity and selectivity. Finally, several prospects concerning the future development of SiNW-FET biosensor are discussed.

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Silicon Nanowire Arrays for Label-Free Detection of DNA

Cited by 414 publications

References 33 publications

Surface enhanced Raman spectroscopy (SERS) for in vitro diagnostic testing at the point of care

Surface enhanced Raman spectroscopy (SERS) for in vitro diagnostic testing at the point of care

Contact detection for nanomanipulation in a scanning electron microscope

Silicon nanowire-transistor biosensor for study of molecule-molecule interactions

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