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Microfluidic Diagnostics

Overview of attention for book
Cover of 'Microfluidic Diagnostics'

Table of Contents

  1. Altmetric Badge
    Book Overview
  2. Altmetric Badge
    Chapter 1 Present Technology and Future Trends in Point-of-Care Microfluidic Diagnostics.
  3. Altmetric Badge
    Chapter 2 Teaching Microfluidic Diagnostics Using Jell-O ® Chips
  4. Altmetric Badge
    Chapter 3 Fundamentals of Microfluidics for High School Students with No Prior Knowledge of Fluid Mechanics
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    Chapter 4 Measuring Microchannel Electroosmotic Mobility and Zeta Potential by the Current Monitoring Method
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    Chapter 5 Overview of the Microfluidic Diagnostics Commercial Landscape
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    Chapter 6 Practical Aspects of the Preparation and Filing of Patent Applications
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    Chapter 7 Introduction to In Vitro Diagnostic Device Regulatory Requirements
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    Chapter 8 Microfluidic Device Fabrication by Thermoplastic Hot-Embossing
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    Chapter 9 Introduction to Glass Microstructuring Techniques
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    Chapter 10 Glass Microstructure Capping and Bonding Techniques
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    Chapter 11 Rapid Prototyping of PDMS Devices Using SU-8 Lithography
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    Chapter 12 Microfluidic Interface Technology Based on Stereolithography for Glass-Based Lab-on-a-Chips
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    Chapter 13 Three-Dimensional, Paper-Based Microfluidic Devices Containing Internal Timers for Running Time-Based Diagnostic Assays
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    Chapter 14 Thread Based Devices for Low-Cost Diagnostics
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    Chapter 15 Droplet-Based Microfluidics
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    Chapter 16 Droplet-Based Microfluidics for Binding Assays and Kinetics Based on FRET
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    Chapter 17 Surface Treatments for Microfluidic Biocompatibility
  19. Altmetric Badge
    Chapter 18 Superhydrophobicity for Antifouling Microfluidic Surfaces
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    Chapter 19 The Application of Microfluidic Devices for Viral Diagnosis in Developing Countries
  21. Altmetric Badge
    Chapter 20 Applications of Microfluidics for Molecular Diagnostics
  22. Altmetric Badge
    Chapter 21 Quantitative Heterogeneous Immunoassays in Protein Modified Polydimethylsiloxane Microfluidic Channels for Rapid Detection of Disease Biomarkers
  23. Altmetric Badge
    Chapter 22 Breast Cancer Diagnostics Using Microfluidic Multiplexed Immunohistochemistry
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    Chapter 23 Charged-Coupled Device (CCD) Detectors for Lab-on-a Chip (LOC) Optical Analysis
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    Chapter 24 Multilayer microfluidic poly(ethylene glycol) diacrylate hydrogels.
  26. Altmetric Badge
    Chapter 25 Purification of DNA/RNA in a Microfluidic Device
  27. Altmetric Badge
    Chapter 26 Agarose Droplet Microfluidics for Highly Parallel and Efficient Single Molecule Emulsion PCR
  28. Altmetric Badge
    Chapter 27 Integrated Fluidic Circuits (IFCs) for Digital PCR.
  29. Altmetric Badge
    Chapter 28 microFIND ® Approach to Fluorescent in Situ Hybridization (FISH)
  30. Altmetric Badge
    Chapter 29 An ELISA Lab-on-a-Chip (ELISA-LOC)
  31. Altmetric Badge
    Chapter 30 Multiplexed Surface Plasmon Resonance Imaging for Protein Biomarker Analysis
  32. Altmetric Badge
    Chapter 31 Surface Acoustic Wave (SAW) Biosensors: Coupling of Sensing Layers and Measurement.
  33. Altmetric Badge
    Chapter 32 Microchip UV Absorbance Detection Applied to Isoelectric Focusing of Proteins
Attention for Chapter 31: Surface Acoustic Wave (SAW) Biosensors: Coupling of Sensing Layers and Measurement.
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Chapter title
Surface Acoustic Wave (SAW) Biosensors: Coupling of Sensing Layers and Measurement.
Chapter number 31
Book title
Microfluidic Diagnostics
Published in
Methods in molecular biology, January 2013
DOI 10.1007/978-1-62703-134-9_31
Pubmed ID
23329462
Book ISBNs
978-1-62703-133-2, 978-1-62703-134-9
Authors

Länge K, Gruhl FJ, Rapp M, Kerstin Länge, Friederike J. Gruhl, Michael Rapp

Abstract

Surface acoustic wave (SAW) devices based on horizontally polarized surface shear waves enable direct and label-free detection of proteins in real time. Signal response changes result mainly from mass increase and viscoelasticity changes on the device surface. With an appropriate sensor configuration all types of binding reactions can be detected by determining resonant frequency changes of an oscillator. To create a biosensor, SAW devices have to be coated with a sensing layer binding specifically to the analyte. Intermediate hydrogel layers used within the coating have been proven to be very suitable to easily immobilize capture molecules or ligands corresponding to the analyte. However, aside from mass increase due to analyte binding, the SAW signal response in a subsequent binding experiment strongly depends on the morphology of the sensing layer, as this may lead to different relative changes of viscoelasticity. Bearing these points in mind, we present two basic biosensor coating procedures, one with immobilized capture molecule and a second with immobilized ligand, allowing reliable SAW biosensor signal responses in subsequent binding assays.

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Mendeley readers

Mendeley readers

The data shown below were compiled from readership statistics for 26 Mendeley readers of this research output. Click here to see the associated Mendeley record.

Geographical breakdown

Country Count As %
Unknown 26 100%

Demographic breakdown

Readers by professional status Count As %
Researcher 7 27%
Student > Ph. D. Student 4 15%
Professor 2 8%
Student > Master 2 8%
Student > Doctoral Student 1 4%
Other 4 15%
Unknown 6 23%
Readers by discipline Count As %
Agricultural and Biological Sciences 6 23%
Engineering 4 15%
Unspecified 2 8%
Business, Management and Accounting 1 4%
Physics and Astronomy 1 4%
Other 3 12%
Unknown 9 35%
Attention Score in Context

Attention Score in Context

This research output has an Altmetric Attention Score of 1. This is our high-level measure of the quality and quantity of online attention that it has received. This Attention Score, as well as the ranking and number of research outputs shown below, was calculated when the research output was last mentioned on 12 June 2013.
All research outputs
#20,194,368
of 22,711,645 outputs
Outputs from Methods in molecular biology
#9,851
of 13,079 outputs
Outputs of similar age
#252,474
of 285,358 outputs
Outputs of similar age from Methods in molecular biology
#305
of 349 outputs
Altmetric has tracked 22,711,645 research outputs across all sources so far. This one is in the 1st percentile – i.e., 1% of other outputs scored the same or lower than it.
So far Altmetric has tracked 13,079 research outputs from this source. They receive a mean Attention Score of 3.3. This one is in the 1st percentile – i.e., 1% of its peers scored the same or lower than it.
Older research outputs will score higher simply because they've had more time to accumulate mentions. To account for age we can compare this Altmetric Attention Score to the 285,358 tracked outputs that were published within six weeks on either side of this one in any source. This one is in the 1st percentile – i.e., 1% of its contemporaries scored the same or lower than it.
We're also able to compare this research output to 349 others from the same source and published within six weeks on either side of this one. This one is in the 1st percentile – i.e., 1% of its contemporaries scored the same or lower than it.

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