Towards in vitro molecular diagnostics using nanostructures

Kurkina, Tetiana; Balasubramanian, Kannan

doi:10.1007/s00018-011-0855-7

Cited by 28 publications

(11 citation statements)

References 151 publications

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“… 16 − 25 On the basis of current trends in the development of nanoISFET-based sensor platforms and bioassays, it is suggested that label-free detection approaches may soon provide breakthroughs in the field of in vitro diagnostics (IVD) and compete against otherwise tedious and expensive bioanalytical methods involving preamplification of analytes, for example, polymerase chain reactions (PCRs) and enzyme-linked immunosorbent assays (ELISAs). 3 , 26 − 30 …”

Section: Introductionmentioning

confidence: 99%

On the Use of Scalable NanoISFET Arrays of Silicon with Highly Reproducible Sensor Performance for Biosensor Applications

et al. 2016

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As a prerequisite to the development of real label-free bioassay applications, a high-throughput top–down nanofabrication process is carried out with a combination of nanoimprint lithography, anisotropic wet-etching, and photolithography methods realizing nanoISFET arrays that are then analyzed for identical sensor characteristics. Here, a newly designed array-based sensor chip exhibits 32 high aspect ratio silicon nanowires (SiNWs) laid out in parallel with 8 unit groups that are connected to a very highly doped, Π-shaped common source and individual drain contacts. Intricately designed contact lines exert equal feed-line resistances and capacitances to homogenize the sensor response as well as to minimize parasitic transport effects and to render easy integration of a fluidic layer on top. The scalable nanofabrication process as outlined in this article casts out a total of 2496 nanowires (NWs) on a 4 inch p-type silicon-on-insulator (SOI) wafer, yielding 78 sensor chips based on nanoISFET arrays. The sensor platform exhibiting high-performance transistor characteristics in buffer solutions is thoroughly characterized using state-of-the-art surface and electrical measurement techniques. Deploying a pH sensor in liquid buffers after high-quality gas-phase silanization, nanoISEFT arrays demonstrate typical pH sensor behavior with sensitivity as high as 43 ± 3 mV·pH–1 and a device-to-device variation of 7% at the wafer scale. Demonstration of a high-density sensor platform with uniform characteristics such as nanoISFET arrays of silicon (Si) in a routine and refined nanofabrication process may serve as an ideal solution deployable for real assay-based applications.

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Section: Introductionmentioning

confidence: 99%

On the Use of Scalable NanoISFET Arrays of Silicon with Highly Reproducible Sensor Performance for Biosensor Applications

et al. 2016

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“…Detection of biomolecules is fundamentally important in a number of fields such as environmental analysis, identification of biological threats and in medical diagnosis. Among all these application areas, modern molecular diagnostics has been the driving force for the extensive research on nanoscale biosensors . The current trend in the domain of medical sciences is to investigate the molecular basis of various diseases rather than attempt just a symptomatic treatment .…”

Section: Introductionmentioning

confidence: 99%

25th Anniversary Article: Label‐Free Electrical Biodetection Using Carbon Nanostructures

Balasubramanian

Kern

2014

Advanced Materials

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Nanostructures are promising candidates for use as active materials for the detection of chemical and biological species, mainly due to the high surface-to-volume ratio and the unique physical properties arising at the nanoscale. Among the various nanostructures, materials comprised of sp(2) -carbon enjoy a unique position due to the possibility to readily prepare them in various dimensions ranging from 0D, through 1D to 2D. This review focuses on the use of 1D (carbon nanotubes) and 2D (graphene) carbon nanostructures for the detection of biologically relevant molecules. A key advantage is the possibility to perform the sensing operation without the use of any labels or complex reaction schemes. Along this spirit, various strategies reported for the label-free electrical detection of biomolecules using carbon nanostructures are discussed. With their promise for ultimate sensitivity and the capability to attain high selectivity through controlled chemical functionalization, carbon-based nanobiosensors are expected to open avenues to novel diagnostic tools as well as to obtain new fundamental insight into biomolecular interactions down to the single molecule level.

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“…Since the synthesis of the first carbon nanostructures, such as fullerene C 60 (0D) [27] and CNTs (1D) [28] (Figure 2), there has been a tremendous effort for understanding the properties of these nanomaterials and for exploring the broad range of applications in which they can be used. Carbon-based nanomaterials (CNMs) have created a great deal of interest in various applications such as optical imaging [29], drug and gene delivery [30], and nanotherapeutics [31,32] due to their excellent mechanical, optical and electrical Review of In Vitro Toxicity of Nanoparticles and Nanorods-Part 2 http://dx.doi.org/10.5772/intechopen.78616…”

Section: Carbon Nanostructuresmentioning

confidence: 99%

Review of In Vitro Toxicity of Nanoparticles and Nanorods—Part 2

Perez¹,

Alsharif²,

Martínez-Banderas³

et al. 2018

Cytotoxicity

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The specific use of engineered nanostructures in biomedical applications has become very attractive, due to their ability to interface and target specific cells and tissues to execute their functions. Additionally, there is continuous progress in research on new nanostructures with unique optical, magnetic, catalytic and electrochemical properties that can be exploited for therapeutic or diagnostic methods. On the other hand, as nanostructures become widely used in many different applications, the unspecific exposure of humans to them is also unavoidable. Therefore, studying and understanding the toxicity of such materials are of increasing importance. Previously published reviews regarding the toxicological effects of nanostructures focus mostly on the cytotoxicity of nanoparticles and their internalization, activated signaling pathways and cellular response. Here, the most recent studies on the invitro cytotoxicity of NPs, nanowires and nanorods for biomedical applications are reviewed and divided into two parts. The first part considers nonmagnetic metallic and magnetic nanostructures, while, the second part covers carbon structures and semiconductors. The factors influencing the toxicity of these nanostructures are elaborated to help elucidate the effects of these nanomaterials on cells, which is a prerequisite for their safe clinical use.

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Towards in vitro molecular diagnostics using nanostructures

Cited by 28 publications

References 151 publications

On the Use of Scalable NanoISFET Arrays of Silicon with Highly Reproducible Sensor Performance for Biosensor Applications

On the Use of Scalable NanoISFET Arrays of Silicon with Highly Reproducible Sensor Performance for Biosensor Applications

25th Anniversary Article: Label‐Free Electrical Biodetection Using Carbon Nanostructures

Review of In Vitro Toxicity of Nanoparticles and Nanorods—Part 2

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