Nanomaterials enhanced surface plasmon resonance for biological and chemical sensing applications

The main challenge for all electrical, mechanical and optical sensors is to detect low molecular weight (less than 400 Da) chemical and biological analytes under extremely dilute conditions. Surface plasmon resonance sensors are the most commonly used optical sensors due to their unique ability for...

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Published inChemical Society reviews Vol. 43; no. 1; pp. 3426 - 3452
Main Authors Zeng, Shuwen, Baillargeat, Dominique, Ho, Ho-Pui, Yong, Ken-Tye
Format Journal Article
LanguageEnglish
Published England 21.05.2014
Subjects
Biological
biomarkers
Biosensing Techniques
chemical species
disease diagnosis
Equipment Design
food quality
latex
Magnetic resonance
magnetism
molecular weight
Nanomaterials
Nanoparticles
Nanostructure
Nanostructures
Optical sensors
Plasmons
quality control
Sensors
sensors (equipment)
Surface Plasmon Resonance
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Abstract The main challenge for all electrical, mechanical and optical sensors is to detect low molecular weight (less than 400 Da) chemical and biological analytes under extremely dilute conditions. Surface plasmon resonance sensors are the most commonly used optical sensors due to their unique ability for real-time monitoring the molecular binding events. However, their sensitivities are insufficient to detect trace amounts of small molecular weight molecules such as cancer biomarkers, hormones, antibiotics, insecticides, and explosive materials which are respectively important for early-stage disease diagnosis, food quality control, environmental monitoring, and homeland security protection. With the rapid development of nanotechnology in the past few years, nanomaterials-enhanced surface plasmon resonance sensors have been developed and used as effective tools to sense hard-to-detect molecules within the concentration range between pmol and amol. In this review article, we reviewed and discussed the latest trend and challenges in engineering and applications of nanomaterials-enhanced surface plasmon resonance sensors ( e.g. , metallic nanoparticles, magnetic nanoparticles, carbon-based nanomaterials, latex nanoparticles and liposome nanoparticles) for detecting "hard-to-identify" biological and chemical analytes. Such information will be viable in terms of providing a useful platform for designing future ultrasensitive plasmonic nanosensors. A comprehensive review of nanomaterials-based enhanced surface plasmon resonance sensing of chemical and biological analytes is presented.
AbstractList The main challenge for all electrical, mechanical and optical sensors is to detect low molecular weight (less than 400 Da) chemical and biological analytes under extremely dilute conditions. Surface plasmon resonance sensors are the most commonly used optical sensors due to their unique ability for real-time monitoring the molecular binding events. However, their sensitivities are insufficient to detect trace amounts of small molecular weight molecules such as cancer biomarkers, hormones, antibiotics, insecticides, and explosive materials which are respectively important for early-stage disease diagnosis, food quality control, environmental monitoring, and homeland security protection. With the rapid development of nanotechnology in the past few years, nanomaterials-enhanced surface plasmon resonance sensors have been developed and used as effective tools to sense hard-to-detect molecules within the concentration range between pmol and amol. In this review article, we reviewed and discussed the latest trend and challenges in engineering and applications of nanomaterials-enhanced surface plasmon resonance sensors (e.g., metallic nanoparticles, magnetic nanoparticles, carbon-based nanomaterials, latex nanoparticles and liposome nanoparticles) for detecting "hard-to-identify" biological and chemical analytes. Such information will be viable in terms of providing a useful platform for designing future ultrasensitive plasmonic nanosensors.
The main challenge for all electrical, mechanical and optical sensors is to detect low molecular weight (less than 400 Da) chemical and biological analytes under extremely dilute conditions. Surface plasmon resonance sensors are the most commonly used optical sensors due to their unique ability for real-time monitoring the molecular binding events. However, their sensitivities are insufficient to detect trace amounts of small molecular weight molecules such as cancer biomarkers, hormones, antibiotics, insecticides, and explosive materials which are respectively important for early-stage disease diagnosis, food quality control, environmental monitoring, and homeland security protection. With the rapid development of nanotechnology in the past few years, nanomaterials-enhanced surface plasmon resonance sensors have been developed and used as effective tools to sense hard-to-detect molecules within the concentration range between pmol and amol. In this review article, we reviewed and discussed the latest trend and challenges in engineering and applications of nanomaterials-enhanced surface plasmon resonance sensors ( e.g. , metallic nanoparticles, magnetic nanoparticles, carbon-based nanomaterials, latex nanoparticles and liposome nanoparticles) for detecting "hard-to-identify" biological and chemical analytes. Such information will be viable in terms of providing a useful platform for designing future ultrasensitive plasmonic nanosensors. A comprehensive review of nanomaterials-based enhanced surface plasmon resonance sensing of chemical and biological analytes is presented.
The main challenge for all electrical, mechanical and optical sensors is to detect low molecular weight (less than 400 Da) chemical and biological analytes under extremely dilute conditions. Surface plasmon resonance sensors are the most commonly used optical sensors due to their unique ability for real-time monitoring the molecular binding events. However, their sensitivities are insufficient to detect trace amounts of small molecular weight molecules such as cancer biomarkers, hormones, antibiotics, insecticides, and explosive materials which are respectively important for early-stage disease diagnosis, food quality control, environmental monitoring, and homeland security protection. With the rapid development of nanotechnology in the past few years, nanomaterials-enhanced surface plasmon resonance sensors have been developed and used as effective tools to sense hard-to-detect molecules within the concentration range between pmol and amol. In this review article, we reviewed and discussed the latest trend and challenges in engineering and applications of nanomaterials-enhanced surface plasmon resonance sensors (e.g., metallic nanoparticles, magnetic nanoparticles, carbon-based nanomaterials, latex nanoparticles and liposome nanoparticles) for detecting "hard-to-identify" biological and chemical analytes. Such information will be viable in terms of providing a useful platform for designing future ultrasensitive plasmonic nanosensors.The main challenge for all electrical, mechanical and optical sensors is to detect low molecular weight (less than 400 Da) chemical and biological analytes under extremely dilute conditions. Surface plasmon resonance sensors are the most commonly used optical sensors due to their unique ability for real-time monitoring the molecular binding events. However, their sensitivities are insufficient to detect trace amounts of small molecular weight molecules such as cancer biomarkers, hormones, antibiotics, insecticides, and explosive materials which are respectively important for early-stage disease diagnosis, food quality control, environmental monitoring, and homeland security protection. With the rapid development of nanotechnology in the past few years, nanomaterials-enhanced surface plasmon resonance sensors have been developed and used as effective tools to sense hard-to-detect molecules within the concentration range between pmol and amol. In this review article, we reviewed and discussed the latest trend and challenges in engineering and applications of nanomaterials-enhanced surface plasmon resonance sensors (e.g., metallic nanoparticles, magnetic nanoparticles, carbon-based nanomaterials, latex nanoparticles and liposome nanoparticles) for detecting "hard-to-identify" biological and chemical analytes. Such information will be viable in terms of providing a useful platform for designing future ultrasensitive plasmonic nanosensors.
Author Yong, Ken-Tye
Zeng, Shuwen
Ho, Ho-Pui
Baillargeat, Dominique
AuthorAffiliation Research Techno Plaza
School of Electrical and Electronic Engineering
Novitas
Nanoelectronics Centre Of Excellence
Department of Electronic Engineering
Nanyang Technological University
The Chinese University of Hong Kong
UMI 3288
CINTRA CNRS/NTU/THALES
AuthorAffiliation_xml – name: The Chinese University of Hong Kong
– name: Department of Electronic Engineering
– name: Research Techno Plaza
– name: Nanoelectronics Centre Of Excellence
– name: UMI 3288
– name: School of Electrical and Electronic Engineering
– name: CINTRA CNRS/NTU/THALES
– name: Nanyang Technological University
– name: Novitas
Author_xml – sequence: 1
  givenname: Shuwen
  surname: Zeng
  fullname: Zeng, Shuwen
– sequence: 2
  givenname: Dominique
  surname: Baillargeat
  fullname: Baillargeat, Dominique
– sequence: 3
  givenname: Ho-Pui
  surname: Ho
  fullname: Ho, Ho-Pui
– sequence: 4
  givenname: Ken-Tye
  surname: Yong
  fullname: Yong, Ken-Tye
BackLink https://www.ncbi.nlm.nih.gov/pubmed/24549396$$D View this record in MEDLINE/PubMed
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Riskin (c3cs60479a-(cit92)/*[position()=1]) 2011; 83
Zhang (c3cs60479a-(cit163)/*[position()=1]) 2013; 3
Zhao (c3cs60479a-(cit46)/*[position()=1]) 2013; 257
Lishko (c3cs60479a-(cit108)/*[position()=1]) 2011; 471
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Snippet The main challenge for all electrical, mechanical and optical sensors is to detect low molecular weight (less than 400 Da) chemical and biological analytes...
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SubjectTerms Biological
biomarkers
Biosensing Techniques
chemical species
disease diagnosis
Equipment Design
food quality
latex
Magnetic resonance
magnetism
molecular weight
Nanomaterials
Nanoparticles
Nanostructure
Nanostructures
Optical sensors
Plasmons
quality control
Sensors
sensors (equipment)
Surface Plasmon Resonance
Title Nanomaterials enhanced surface plasmon resonance for biological and chemical sensing applications
URI https://www.ncbi.nlm.nih.gov/pubmed/24549396
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