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Journal articles on the topic 'Biosensing'

Author: Grafiati
Published: 4 June 2021
Last updated: 25 January 2025

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1

Howell, Noura, John Chuang, Abigail De Kosnik, Greg Niemeyer, and Kimiko Ryokai. "Emotional Biosensing." Proceedings of the ACM on Human-Computer Interaction 2, CSCW (November 2018): 1–25. http://dx.doi.org/10.1145/3274338.

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2

Mejía-Salazar, J. R., and Osvaldo N. Oliveira. "Plasmonic Biosensing." Chemical Reviews 118, no. 20 (September 24, 2018): 10617–25. http://dx.doi.org/10.1021/acs.chemrev.8b00359.

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3

Fink, Dietmar, Gerardo Munoz Hernandez, Jiri Vacik, and Lital Alfonta. "Pulsed Biosensing." IEEE Sensors Journal 11, no. 4 (April 2011): 1084–87. http://dx.doi.org/10.1109/jsen.2010.2073461.

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4

Curtin, Kathrine, Bethany J. Fike, Brandi Binkley, Toktam Godary, and Peng Li. "Recent Advances in Digital Biosensing Technology." Biosensors 12, no. 9 (August 23, 2022): 673. http://dx.doi.org/10.3390/bios12090673.

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Digital biosensing assays demonstrate remarkable advantages over conventional biosensing systems because of their ability to achieve single-molecule detection and absolute quantification. Unlike traditional low-abundance biomarking screening, digital-based biosensing systems reduce sample volumes significantly to the fL-nL level, which vastly reduces overall reagent consumption, improves reaction time and throughput, and enables high sensitivity and single target detection. This review presents the current technology for compartmentalizing reactions and their applications in detecting proteins and nucleic acids. We also analyze existing challenges and future opportunities associated with digital biosensing and research opportunities for developing integrated digital biosensing systems.
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5

Wu, Jiyun, and Qiuyao Wu. "The Review of Biosensor and its Application in the Diagnosis of COVID-19." E3S Web of Conferences 290 (2021): 03028. http://dx.doi.org/10.1051/e3sconf/202129003028.

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The objective of this article is to summarize the available technologies for biosensing applications in COVID-19. The article is divided into three parts, an introduction to biosensing technologies, applications of mainstream biosensing technologies and a review of biosensing applications in COVID-19. The introduction of biosensors presents the history of inventing the biosensing technology, which refers to the ISFET. The resonant biosensor with the example of MEMS. the principle of optical biosensor, and the thermal biosensor. In the second part, the main use of biosensing techniques, it was discussed the field of the food industry, environmental monitoring, and the medical industry. In the part of biosensor application in COVID-19, it was mentioned that the technique of POCT, the use of RT-LAMP-NBS in the early detection in China, and the use in gRT-PCR for the detection of the DNA code to determine the presence of pathogen of COVLD-19 in the human body.
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6

Ullah, Najeeb, Tracy Ann Bruce-Tagoe, George Adu Asamoah, and Michael K. Danquah. "Multimodal Biosensing of Foodborne Pathogens." International Journal of Molecular Sciences 25, no. 11 (May 29, 2024): 5959. http://dx.doi.org/10.3390/ijms25115959.

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Microbial foodborne pathogens present significant challenges to public health and the food industry, requiring rapid and accurate detection methods to prevent infections and ensure food safety. Conventional single biosensing techniques often exhibit limitations in terms of sensitivity, specificity, and rapidity. In response, there has been a growing interest in multimodal biosensing approaches that combine multiple sensing techniques to enhance the efficacy, accuracy, and precision in detecting these pathogens. This review investigates the current state of multimodal biosensing technologies and their potential applications within the food industry. Various multimodal biosensing platforms, such as opto-electrochemical, optical nanomaterial, multiple nanomaterial-based systems, hybrid biosensing microfluidics, and microfabrication techniques are discussed. The review provides an in-depth analysis of the advantages, challenges, and future prospects of multimodal biosensing for foodborne pathogens, emphasizing its transformative potential for food safety and public health. This comprehensive analysis aims to contribute to the development of innovative strategies for combating foodborne infections and ensuring the reliability of the global food supply chain.
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7

Zhang, Wu, Jiahan Lin, Zhengxin Yuan, Yanxiao Lin, Wenli Shang, Lip Ket Chin, and Meng Zhang. "Terahertz Metamaterials for Biosensing Applications: A Review." Biosensors 14, no. 1 (December 21, 2023): 3. http://dx.doi.org/10.3390/bios14010003.

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In recent decades, THz metamaterials have emerged as a promising technology for biosensing by extracting useful information (composition, structure and dynamics) of biological samples from the interaction between the THz wave and the biological samples. Advantages of biosensing with THz metamaterials include label-free and non-invasive detection with high sensitivity. In this review, we first summarize different THz sensing principles modulated by the metamaterial for bio-analyte detection. Then, we compare various resonance modes induced in the THz range for biosensing enhancement. In addition, non-conventional materials used in the THz metamaterial to improve the biosensing performance are evaluated. We categorize and review different types of bio-analyte detection using THz metamaterials. Finally, we discuss the future perspective of THz metamaterial in biosensing.
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8

Kumar, Ravinder, Somvir ., Surender Singh, and Kulwant . "A Review on application of Nanoscience for Biosensing." International Journal of Engineering Research 3, no. 4 (April 1, 2014): 279–85. http://dx.doi.org/10.17950/ijer/v3s4/423.

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9

Han, Xue, Kun Liu, and Changsen Sun. "Plasmonics for Biosensing." Materials 12, no. 9 (April 30, 2019): 1411. http://dx.doi.org/10.3390/ma12091411.

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Techniques based on plasmonic resonance can provide label-free, signal enhanced, and real-time sensing means for bioparticles and bioprocesses at the molecular level. With the development in nanofabrication and material science, plasmonics based on synthesized nanoparticles and manufactured nano-patterns in thin films have been prosperously explored. In this short review, resonance modes, materials, and hybrid functions by simultaneously using electrical conductivity for plasmonic biosensing techniques are exclusively reviewed for designs containing nanovoids in thin films. This type of plasmonic biosensors provide prominent potential to achieve integrated lab-on-a-chip which is capable of transporting and detecting minute of multiple bio-analytes with extremely high sensitivity, selectivity, multi-channel and dynamic monitoring for the next generation of point-of-care devices.
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10

McConnell, Erin M., Ioana Cozma, Quanbing Mou, John D. Brennan, Yi Lu, and Yingfu Li. "Biosensing with DNAzymes." Chemical Society Reviews 50, no. 16 (2021): 8954–94. http://dx.doi.org/10.1039/d1cs00240f.

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This article provides a comprehensive review of biosensing with DNAzymes, providing an overview of different sensing applications while highlighting major progress and seminal contributions to the field of portable biosensor devices and point-of-care diagnostics.
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11

Yan, Xiaodong, Hai-Feng Ji, and Thomas Thundat. "Microcantilever (MCL) Biosensing." Current Analytical Chemistry 2, no. 3 (July 1, 2006): 297–307. http://dx.doi.org/10.2174/157341106777698251.

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12

Telford, Mark. "Biosensing, biocidal ‘nanocarpets’." Materials Today 7, no. 12 (December 2004): 10. http://dx.doi.org/10.1016/s1369-7021(04)00611-x.

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13

Pumera, Martin. "Graphene in biosensing." Materials Today 14, no. 7-8 (July 2011): 308–15. http://dx.doi.org/10.1016/s1369-7021(11)70160-2.

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14

Scheggi, A. M., and A. G. Mignani. "Optical fiber biosensing." Optics News 15, no. 11 (November 1, 1989): 28. http://dx.doi.org/10.1364/on.15.11.000028.

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15

Qi, Honglan, and Chengxiao Zhang. "Electrogenerated Chemiluminescence Biosensing." Analytical Chemistry 92, no. 1 (December 2, 2019): 524–34. http://dx.doi.org/10.1021/acs.analchem.9b03425.

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16

Marquette, Christophe A., and Loïc J. Blum. "Electro-chemiluminescent biosensing." Analytical and Bioanalytical Chemistry 390, no. 1 (October 2, 2007): 155–68. http://dx.doi.org/10.1007/s00216-007-1631-2.

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17

Ron, Eliora Z. "Biosensing environmental pollution." Current Opinion in Biotechnology 18, no. 3 (June 2007): 252–56. http://dx.doi.org/10.1016/j.copbio.2007.05.005.

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18

Lei, Jianping, and Huangxian Ju. "Nanotubes in biosensing." Wiley Interdisciplinary Reviews: Nanomedicine and Nanobiotechnology 2, no. 5 (August 16, 2010): 496–509. http://dx.doi.org/10.1002/wnan.94.

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19

Marchisio, Mario Andrea, and Fabian Rudolf. "Synthetic biosensing systems." International Journal of Biochemistry & Cell Biology 43, no. 3 (March 2011): 310–19. http://dx.doi.org/10.1016/j.biocel.2010.11.012.

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20

Bellassai, Noemi, Roberta D’Agata, and Giuseppe Spoto. "Novel nucleic acid origami structures and conventional molecular beacon–based platforms: a comparison in biosensing applications." Analytical and Bioanalytical Chemistry 413, no. 24 (April 6, 2021): 6063–77. http://dx.doi.org/10.1007/s00216-021-03309-4.

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AbstractNucleic acid nanotechnology designs and develops synthetic nucleic acid strands to fabricate nanosized functional systems. Structural properties and the conformational polymorphism of nucleic acid sequences are inherent characteristics that make nucleic acid nanostructures attractive systems in biosensing. This review critically discusses recent advances in biosensing derived from molecular beacon and DNA origami structures. Molecular beacons belong to a conventional class of nucleic acid structures used in biosensing, whereas DNA origami nanostructures are fabricated by fully exploiting possibilities offered by nucleic acid nanotechnology. We present nucleic acid scaffolds divided into conventional hairpin molecular beacons and DNA origami, and discuss some relevant examples by focusing on peculiar aspects exploited in biosensing applications. We also critically evaluate analytical uses of the synthetic nucleic acid structures in biosensing to point out similarities and differences between traditional hairpin nucleic acid sequences and DNA origami. Graphical abstract
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21

Kim, Youngsun, John Gonzales, and Yuebing Zheng. "Optical Biosensing: Sensitivity‐Enhancing Strategies in Optical Biosensing (Small 4/2021)." Small 17, no. 4 (January 2021): 2170016. http://dx.doi.org/10.1002/smll.202170016.

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22

Flynn, Connor D., and Dingran Chang. "Artificial Intelligence in Point-of-Care Biosensing: Challenges and Opportunities." Diagnostics 14, no. 11 (May 25, 2024): 1100. http://dx.doi.org/10.3390/diagnostics14111100.

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The integration of artificial intelligence (AI) into point-of-care (POC) biosensing has the potential to revolutionize diagnostic methodologies by offering rapid, accurate, and accessible health assessment directly at the patient level. This review paper explores the transformative impact of AI technologies on POC biosensing, emphasizing recent computational advancements, ongoing challenges, and future prospects in the field. We provide an overview of core biosensing technologies and their use at the POC, highlighting ongoing issues and challenges that may be solved with AI. We follow with an overview of AI methodologies that can be applied to biosensing, including machine learning algorithms, neural networks, and data processing frameworks that facilitate real-time analytical decision-making. We explore the applications of AI at each stage of the biosensor development process, highlighting the diverse opportunities beyond simple data analysis procedures. We include a thorough analysis of outstanding challenges in the field of AI-assisted biosensing, focusing on the technical and ethical challenges regarding the widespread adoption of these technologies, such as data security, algorithmic bias, and regulatory compliance. Through this review, we aim to emphasize the role of AI in advancing POC biosensing and inform researchers, clinicians, and policymakers about the potential of these technologies in reshaping global healthcare landscapes.
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23

Mancera Zapata, Diana Lorena, and Eden Morales Narváez. "A biosensing platform based on graphene oxide and photoluminescent probes: advantages and perspectives." Mundo Nano. Revista Interdisciplinaria en Nanociencias y Nanotecnología 16, no. 31 (June 1, 2023): 1e—12e. http://dx.doi.org/10.22201/ceiich.24485691e.2023.31.69798.

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Biosensing systems are powerful biotechnological tools which are widely applied in medical and environmental settings. Herein, we provide an overview of a recently developed optical biosensing system based on the quenching abilities of graphene oxide and fluorescent bioprobes. This biosensing platform has been demonstrated to be a fast, cost-effective and reliable nanophotonic technology. In particular, it has been exploited to detect relevant analytes in real matrixes, including prostate specific E. coli and COVID-19 antibodies. Besides, this technology enabled the detection of sialidase in clinical samples to determine bacterial vaginosis. This biosensing system has recently been used to determine relevant information on the kinetics of proteins involved in the biorecognition process, everything performed in real-time and in a single step.
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24

P.Sangeetha, P. Sangeetha, and Dr A. Vimala Juliet. "Biosensing by Cantilever Resonator for Disease Causing Pathogen Detection." Indian Journal of Applied Research 4, no. 3 (October 1, 2011): 174–75. http://dx.doi.org/10.15373/2249555x/mar2014/51.

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25

Abdelhamid, Mohamed A. A., Mi-Ran Ki, and Seung Pil Pack. "Biominerals and Bioinspired Materials in Biosensing: Recent Advancements and Applications." International Journal of Molecular Sciences 25, no. 9 (April 25, 2024): 4678. http://dx.doi.org/10.3390/ijms25094678.

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Inspired by nature’s remarkable ability to form intricate minerals, researchers have unlocked transformative strategies for creating next-generation biosensors with exceptional sensitivity, selectivity, and biocompatibility. By mimicking how organisms orchestrate mineral growth, biomimetic and bioinspired materials are significantly impacting biosensor design. Engineered bioinspired materials offer distinct advantages over their natural counterparts, boasting superior tunability, precise controllability, and the ability to integrate specific functionalities for enhanced sensing capabilities. This remarkable versatility enables the construction of various biosensing platforms, including optical sensors, electrochemical sensors, magnetic biosensors, and nucleic acid detection platforms, for diverse applications. Additionally, bioinspired materials facilitate the development of smartphone-assisted biosensing platforms, offering user-friendly and portable diagnostic tools for point-of-care applications. This review comprehensively explores the utilization of naturally occurring and engineered biominerals and materials for diverse biosensing applications. We highlight the fabrication and design strategies that tailor their functionalities to address specific biosensing needs. This in-depth exploration underscores the transformative potential of biominerals and materials in revolutionizing biosensing, paving the way for advancements in healthcare, environmental monitoring, and other critical fields.
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26

Soleymani, Leyla, Sudip Saha, Amanda Victorious, Sadman Sakib, and Igor Zhitomirsky. "(Invited) Development of New Strategies for Bringing Photoelectrochemical Biosensing to the Point-of-Need." ECS Meeting Abstracts MA2022-01, no. 53 (July 7, 2022): 2178. http://dx.doi.org/10.1149/ma2022-01532178mtgabs.

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Photoelectrochemistry combines light excitation with electrochemical readout for lowering the bias voltage needed for performing electrochemical reactions. As a result, when used in biosensing, photoelectrochemical signal readout reduces the background signals, lowering the limit-of-detection of such biosensors. To enable photoelectrochemical (PEC) signal readout to be applied to point-of-need biosensing, we have taken a three tiered approach focused on improving the understanding of signal transduction in PEC Biosensing, developing label-free assays, and creating handheld readout platforms. In this work, we developed a system using DNA as a nano-ruler to control the distance between plasmonic nanoparticles and PEC electrodes. This system was used to rationally-design PEC material systems for signal-on biosensing. Using this materials architecture, we developed a signal-on biosensor without target labeling for detecting DNA hybridization. This assay uses sequential DNA hybridization to generate a PEC signal. First, the DNA target is captured on probe-modified photoelectrodes. This is followed by hybridization of the unbound probes with DNA strands modified with plasmonic labels. The plasmonic label modulates the PEC signal, increasing the measured PEC current at low target concentrations. To enable biosensing at the point-of-need, we also developed a handheld PEC reader. The integration of plasmonic nanoparticles with PEC electrodes, label-free DNA assays, and handheld PEC readout paves the way toward bringing point-of-need PEC Biosensing.
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27

Ng, Keng Wooi, and S. Moein Moghimi. "Skin Biosensing and Bioanalysis: what the Future Holds." Precision Nanomedicine 1, no. 2 (July 26, 2018): 124–27. http://dx.doi.org/10.33218/prnano1(2).180709.1.

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Wearable skin biosensors have important applications in health monitoring, medical treatment and theranostics. There has been a rapid growth in the development of novel biosensing and bioanalytical techniques in recent years, much of it underpinned by recent advancements in nanotechnology. As the two related disciplines continue to co-evolve, we take a timely look at some notable developments in skin biosensing/bioanalysis, scan the horizon for emerging nanotechnologies, and discuss how they may influence the future of biosensing/bioanalysis in the skin.
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28

Yang, Yun Jun, and Zhong Feng Gao. "Bio-inspired Superwettable Surface for the Detection of Cancer Biomarker: A Mini Review." Technology in Cancer Research & Treatment 21 (January 2022): 153303382211106. http://dx.doi.org/10.1177/15330338221110670.

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Inspired by nature, superwettable material-based biosensors have aroused wide interests due to their potential in cancer biomarker detection. This mini review mainly summarized the superwettable materials as novel biosensing substrates for the development of evaporation-induced enrichment-based signal amplification and visual biosensing method. Biosensing applications based on the superhydrophobic surfaces, superwettable micropatterned surfaces, and slippery lubricant-infused porous surfaces for various cancer biomarker detections were described in detail. Finally, an insight of remaining challenges and perspectives of superwettable biosensor is proposed.
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29

Ye, Shun, Shilun Feng, Liang Huang, and Shengtai Bian. "Recent Progress in Wearable Biosensors: From Healthcare Monitoring to Sports Analytics." Biosensors 10, no. 12 (December 15, 2020): 205. http://dx.doi.org/10.3390/bios10120205.

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Recent advances in lab-on-a-chip technology establish solid foundations for wearable biosensors. These newly emerging wearable biosensors are capable of non-invasive, continuous monitoring by miniaturization of electronics and integration with microfluidics. The advent of flexible electronics, biochemical sensors, soft microfluidics, and pain-free microneedles have created new generations of wearable biosensors that explore brand-new avenues to interface with the human epidermis for monitoring physiological status. However, these devices are relatively underexplored for sports monitoring and analytics, which may be largely facilitated by the recent emergence of wearable biosensors characterized by real-time, non-invasive, and non-irritating sensing capacities. Here, we present a systematic review of wearable biosensing technologies with a focus on materials and fabrication strategies, sampling modalities, sensing modalities, as well as key analytes and wearable biosensing platforms for healthcare and sports monitoring with an emphasis on sweat and interstitial fluid biosensing. This review concludes with a summary of unresolved challenges and opportunities for future researchers interested in these technologies. With an in-depth understanding of the state-of-the-art wearable biosensing technologies, wearable biosensors for sports analytics would have a significant impact on the rapidly growing field—microfluidics for biosensing.
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30

MO, YANG, and TAN FEI. "NANOPOROUS MEMBRANE FOR BIOSENSING APPLICATIONS." Nano LIFE 02, no. 01 (March 2012): 1230003. http://dx.doi.org/10.1142/s1793984411000323.

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Synthetic nanoporous membranes have been used in numerous biosensing applications, such as glucose detection, nucleic acid detection, bacteria detection, and cell-based sensing. The increased surface affinity area and enhanced output sensing signals make the nanoporous membranes increasingly attractive as biosensing platforms. Surface modification techniques can be used to improve surface properties for realizable bioanalyte immobilization, conjugation, and detection. Combined with realizable detection techniques such as electrochemical and optical detection methods, nanoporous membrane–based biosensors have advantages, including rapid response, high sensitivity, and low cost. In this paper, an overview of nanoporous membranes for biosensing application is given. Types of nanoporous membranes including polymer membranes, inorganic membranes, membranes with nanopores fabricated using nanolithography, and nanotube-based membranes are introduced. The fabrication techniques of nanoporous membranes are also discussed. The key requirements of nanoporous membranes for biosensing applications include surface functionality for bioanalyte immobilization, biocompatibility, mechanical and chemical stability, and anti-biofouling capability. The recent advances and development of nanoporous membrane–based biosensors are discussed, especially for the sensing mechanism and surface functionalization strategies. Finally, the challenges and future development of nanoporous membrane for biosensing applications are discussed.
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31

Ganesh, Kalathur Mohan, Seemesh Bhaskar, Vijay Sai Krishna Cheerala, Prajwal Battampara, Roopa Reddy, Sundaresan Chittor Neelakantan, Narendra Reddy, and Sai Sathish Ramamurthy. "Review of Gold Nanoparticles in Surface Plasmon-Coupled Emission Technology: Effect of Shape, Hollow Nanostructures, Nano-Assembly, Metal–Dielectric and Heterometallic Nanohybrids." Nanomaterials 14, no. 1 (January 2, 2024): 111. http://dx.doi.org/10.3390/nano14010111.

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Point-of-care (POC) diagnostic platforms are globally employed in modern smart technologies to detect events or changes in the analyte concentration and provide qualitative and quantitative information in biosensing. Surface plasmon-coupled emission (SPCE) technology has emerged as an effective POC diagnostic tool for developing robust biosensing frameworks. The simplicity, robustness and relevance of the technology has attracted researchers in physical, chemical and biological milieu on account of its unique attributes such as high specificity, sensitivity, low background noise, highly polarized, sharply directional, excellent spectral resolution capabilities. In the past decade, numerous nano-fabrication methods have been developed for augmenting the performance of the conventional SPCE technology. Among them the utility of plasmonic gold nanoparticles (AuNPs) has enabled the demonstration of plethora of reliable biosensing platforms. Here, we review the nano-engineering and biosensing applications of AuNPs based on the shape, hollow morphology, metal–dielectric, nano-assembly and heterometallic nanohybrids under optical as well as biosensing competencies. The current review emphasizes the recent past and evaluates the latest advancements in the field to comprehend the futuristic scope and perspectives of exploiting Au nano-antennas for plasmonic hotspot generation in SPCE technology.
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32

Merkoçi, Arben, Chen-zhong Li, Laura M. Lechuga, and Aydogan Ozcan. "COVID-19 biosensing technologies." Biosensors and Bioelectronics 178 (April 2021): 113046. http://dx.doi.org/10.1016/j.bios.2021.113046.

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33

Sondhi, Palak, Md Helal Uddin Maruf, and Keith J. Stine. "Nanomaterials for Biosensing Lipopolysaccharide." Biosensors 10, no. 1 (December 21, 2019): 2. http://dx.doi.org/10.3390/bios10010002.

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Lipopolysaccharides (LPS) are endotoxins, hazardous and toxic inflammatory stimulators released from the outer membrane of Gram-negative bacteria, and are the major cause of septic shock giving rise to millions of fatal illnesses worldwide. There is an urgent need to identify and detect these molecules selectively and rapidly. Pathogen detection has been done by traditional as well as biosensor-based methods. Nanomaterial based biosensors can assist in achieving these goals and have tremendous potential. The biosensing techniques developed are low-cost, easy to operate, and give a fast response. Due to extremely small size, large surface area, and scope for surface modification, nanomaterials have been used to target various biomolecules, including LPS. The sensing mechanism can be quite complex and involves the transformation of chemical interactions into amplified physical signals. Many different sorts of nanomaterials such as metal nanomaterials, magnetic nanomaterials, quantum dots, and others have been used for biosensing of LPS and have shown attractive results. This review considers the recent developments in the application of nanomaterials in sensing of LPS with emphasis given mainly to electrochemical and optical sensing.
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34

Yuan, Liang, and Lei Liu. "Peptide-based electrochemical biosensing." Sensors and Actuators B: Chemical 344 (October 2021): 130232. http://dx.doi.org/10.1016/j.snb.2021.130232.

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35

Parveen, Ariba, and Jai Prakash. "Biosensing Using Liquid Crystals." Resonance 26, no. 9 (September 2021): 1187–96. http://dx.doi.org/10.1007/s12045-021-1221-1.

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36

Banciu, Roberta Maria, Nimet Numan, and Alina Vasilescu. "Optical biosensing of lysozyme." Journal of Molecular Structure 1250 (February 2022): 131639. http://dx.doi.org/10.1016/j.molstruc.2021.131639.

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37

Benabdallah, Gabrielle, and Blair Subbaraman. "Explorations in narrative biosensing." Interactions 29, no. 1 (January 2022): 14–15. http://dx.doi.org/10.1145/3505276.

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38

Melvin, Tracy. "Optical biosensing: future possibilities." Expert Review of Ophthalmology 2, no. 6 (December 2007): 883–87. http://dx.doi.org/10.1586/17469899.2.6.883.

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39

Liu, Kuo-Kang, Ren-Guei Wu, Yun-Ju Chuang, Hwa Seng Khoo, Shih-Hao Huang, and Fan-Gang Tseng. "Microfluidic Systems for Biosensing." Sensors 10, no. 7 (July 9, 2010): 6623–61. http://dx.doi.org/10.3390/s100706623.

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40

Hou, Sichao, Aiying Zhang, and Ming Su. "Nanomaterials for Biosensing Applications." Nanomaterials 6, no. 4 (March 30, 2016): 58. http://dx.doi.org/10.3390/nano6040058.

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41

Razansky, D., P. D. Einziger, and D. Adam. "Cavity Plasmon Resonance Biosensing." IEEE Transactions on Nanotechnology 7, no. 5 (September 2008): 580–85. http://dx.doi.org/10.1109/tnano.2008.926446.

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42

Sorokulova, I., R. Guntupalli, E. Olsen, L. Globa, O. Pustovyy, and V. Vodyanoy. "Lytic Phage in Biosensing." ECS Transactions 58, no. 23 (February 27, 2014): 1–7. http://dx.doi.org/10.1149/05823.0001ecst.

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43

Petrou, P. S., S. E. Kakabakos, and K. Misiakos. "Silicon optocouplers for biosensing." International Journal of Nanotechnology 6, no. 1/2 (2009): 4. http://dx.doi.org/10.1504/ijnt.2009.021704.

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44

DeWitt, Natalie. "Brighter aptamers for biosensing." Nature Biotechnology 18, no. 12 (December 2000): 1233. http://dx.doi.org/10.1038/82317.

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45

Merkoçi, Arben. "Electrochemical biosensing with nanoparticles." FEBS Journal 274, no. 2 (December 20, 2006): 310–16. http://dx.doi.org/10.1111/j.1742-4658.2006.05603.x.

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46

Yousef, Andrew, Soren Jonzzon, Leena Suleiman, Jennifer Arjona, and Jennifer S. Graves. "Biosensing in multiple sclerosis." Expert Review of Medical Devices 14, no. 11 (October 23, 2017): 901–12. http://dx.doi.org/10.1080/17434440.2017.1388162.

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47

Bonanni, Alessandra, Adeline Huiling Loo, and Martin Pumera. "Graphene for impedimetric biosensing." TrAC Trends in Analytical Chemistry 37 (July 2012): 12–21. http://dx.doi.org/10.1016/j.trac.2012.02.011.

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48

de la Escosura-Muñiz, Alfredo, and Arben Merkoçi. "Nanochannels for electrical biosensing." TrAC Trends in Analytical Chemistry 79 (May 2016): 134–50. http://dx.doi.org/10.1016/j.trac.2015.12.003.

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49

Cosnier, Serge, and Michael Holzinger. "Electrosynthesized polymers for biosensing." Chemical Society Reviews 40, no. 5 (2011): 2146. http://dx.doi.org/10.1039/c0cs00090f.

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JACOBY, MITCH. "DIAMOND FILMS FOR BIOSENSING." Chemical & Engineering News 80, no. 48 (December 2, 2002): 14. http://dx.doi.org/10.1021/cen-v080n048.p014.

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