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Virus-Derived Nanoparticles for Advanced Technologies

Overview of attention for book
Virus-Derived Nanoparticles for Advanced Technologies
Springer New York

Table of Contents

  1. Altmetric Badge
    Book Overview
  2. Altmetric Badge
    Chapter 1 Production of Mosaic Turnip Crinkle Virus-Like Particles Derived by Coinfiltration of Wild-Type and Modified Forms of Virus Coat Protein in Plants
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    Chapter 2 Isolation and Characterization of Two Distinct Types of Unmodified Spherical Plant Sobemovirus-Like Particles for Diagnostic and Technical Uses
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    Chapter 3 RNA-Directed Assembly of Tobacco Mosaic Virus (TMV)-Like Carriers with Tunable Fractions of Differently Addressable Coat Proteins
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    Chapter 4 Fabrication of Tobacco Mosaic Virus-Like Nanorods for Peptide Display
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    Chapter 5 In Planta Production of Fluorescent Filamentous Plant Virus-Based Nanoparticles
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    Chapter 6 Self-Assembling Plant-Derived Vaccines Against Papillomaviruses
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    Chapter 7 Recombinant Expression of Tandem-HBc Virus-Like Particles (VLPs)
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    Chapter 8 Production and Application of Insect Virus-Based VLPs
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    Chapter 9 Nanomanufacture of Free-Standing, Porous, Janus-Type Films of Polymer–Plant Virus Nanoparticle Arrays
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    Chapter 10 Self-Assembly of Rod-Like Bionanoparticles at Interfaces and in Solution
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    Chapter 11 Bottom-Up Assembly of TMV-Based Nucleoprotein Architectures on Solid Supports
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    Chapter 12 Internal Deposition of Cobalt Metal and Iron Oxide Within CPMV eVLPs
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    Chapter 13 Plant Virus-Based Nanoparticles for the Delivery of Agronomic Compounds as a Suspension Concentrate
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    Chapter 14 Nanowires and Nanoparticle Chains Inside Tubular Viral Templates
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    Chapter 15 In Vitro-Reassembled Plant Virus-Like Particles of Hibiscus Chlorotic Ringspot Virus (HCRSV) as Nano-Protein Cages for Drugs
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    Chapter 16 CCMV-Based Enzymatic Nanoreactors
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    Chapter 17 Protocol for Efficient Cell-Free Synthesis of Cowpea Chlorotic Mottle Virus-Like Particles Containing Heterologous RNAs
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    Chapter 18 Packaging DNA Origami into Viral Protein Cages
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    Chapter 19 In Vitro Assembly of Virus-Derived Designer Shells Around Inorganic Nanoparticles
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    Chapter 20 In Vivo Packaging of Protein Cargo Inside of Virus-Like Particle P22
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    Chapter 21 Encapsulation of Negatively Charged Cargo in MS2 Viral Capsids
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    Chapter 22 Delivering Cargo: Plant-Based Production of Bluetongue Virus Core-Like and Virus-Like Particles Containing Fluorescent Proteins
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    Chapter 23 Bioinspired Silica Mineralization on Viral Templates
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    Chapter 24 Propagation and Isolation of Tobacco Mosaic Virus That Surface Displays Metal Binding and Reducing Peptides for Generation of Gold Nanoparticles
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    Chapter 25 TMV-Templated Formation of Metal and Polymer Nanotubes
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    Chapter 26 Semiconducting Hybrid Layer Fabrication Scaffolded by Virus Shells
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    Chapter 27 Dual Functionalization of Rod-Shaped Viruses on Single Coat Protein Subunits
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    Chapter 28 Drug-Loaded Plant-Virus Based Nanoparticles for Cancer Drug Delivery
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    Chapter 29 Construction of Artificial Enzymes on a Virus Surface
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    Chapter 30 Redox-Immunofunctionalized Potyvirus Nanoparticles for High-Resolution Imaging by AFM-SECM Correlative Microscopy
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    Chapter 31 Presenting Peptides at the Surface of Potyviruses In Planta
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    Chapter 32 Engineering of M13 Bacteriophage for Development of Tissue Engineering Materials
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    Chapter 33 Displaying Whole-Chain Proteins on Hepatitis B Virus Capsid-Like Particles
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    Chapter 34 Dual-Functionalized Virus–Gold Nanoparticle Clusters for Biosensing
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    Chapter 35 TMV-Based Adapter Templates for Enhanced Enzyme Loading in Biosensor Applications
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    Chapter 36 Integrated Methods to Manufacture Hydrogel Microparticles Containing Viral–Metal Nanocomplexes with High Catalytic Activity
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    Chapter 37 Integrated Methods to Manufacture Hydrogel Microparticles with High Protein Conjugation Capacity and Binding Kinetics via Viral Nanotemplate Display
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    Chapter 38 Interactions Between Plant Viral Nanoparticles (VNPs) and Blood Plasma Proteins, and Their Impact on the VNP In Vivo Fates
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    Chapter 39 Fabrication of Plant Virus-Based Thin Films to Modulate the Osteogenic Differentiation of Mesenchymal Stem Cells
  41. Altmetric Badge
    Chapter 40 Dual Surface Modification of Genome-Free MS2 Capsids for Delivery Applications
  42. Altmetric Badge
    Chapter 41 Virus-Based Cancer Therapeutics for Targeted Photodynamic Therapy
Attention for Chapter 18: Packaging DNA Origami into Viral Protein Cages
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About this Attention Score

  • Good Attention Score compared to outputs of the same age (71st percentile)
  • High Attention Score compared to outputs of the same age and source (88th percentile)

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Chapter title
Packaging DNA Origami into Viral Protein Cages
Chapter number 18
Book title
Virus-Derived Nanoparticles for Advanced Technologies
Published in
Methods in molecular biology, January 2018
DOI 10.1007/978-1-4939-7808-3_18
Pubmed ID
Book ISBNs
978-1-4939-7806-9, 978-1-4939-7808-3
Authors

Veikko Linko, Joona Mikkilä, Mauri A. Kostiainen, Linko, Veikko, Mikkilä, Joona, Kostiainen, Mauri A.

Abstract

The DNA origami technique is a widely used method to create customized, complex, spatially well-defined two-dimensional (2D) and three-dimensional (3D) DNA nanostructures. These structures have huge potential to serve as smart drug-delivery vehicles and molecular devices in various nanomedical and biotechnological applications. However, so far only little is known about the behavior of these novel structures in living organisms or in cell culture/tissue models. Moreover, enhancing pharmacokinetic bioavailability and transfection properties of such structures still remains a challenge. One intriguing approach to overcome these issues is to coat DNA origami nanostructures with proteins or lipid membranes. Here, we show how cowpea chlorotic mottle virus (CCMV) capsid proteins (CPs) can be used for coating DNA origami nanostructures. We present a method for disassembling native CCMV particles and isolating the pure CP dimers, which can further bind and encapsulate a rectangular DNA origami shape. Owing to the highly programmable nature of DNA origami, packaging of DNA nanostructures into viral protein cages could find imminent uses in enhanced targeting and cellular delivery of various active nano-objects, such as enzymes and drug molecules.

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X Demographics

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Mendeley readers

Mendeley readers

The data shown below were compiled from readership statistics for 10 Mendeley readers of this research output. Click here to see the associated Mendeley record.

Geographical breakdown

Country Count As %
Unknown 10 100%

Demographic breakdown

Readers by professional status Count As %
Student > Ph. D. Student 4 40%
Student > Master 2 20%
Student > Bachelor 1 10%
Unknown 3 30%
Readers by discipline Count As %
Chemical Engineering 2 20%
Biochemistry, Genetics and Molecular Biology 1 10%
Physics and Astronomy 1 10%
Social Sciences 1 10%
Medicine and Dentistry 1 10%
Other 1 10%
Unknown 3 30%
Attention Score in Context

Attention Score in Context

This research output has an Altmetric Attention Score of 5. 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 31 October 2019.
All research outputs
#6,238,832
of 23,088,369 outputs
Outputs from Methods in molecular biology
#1,848
of 13,206 outputs
Outputs of similar age
#125,566
of 442,629 outputs
Outputs of similar age from Methods in molecular biology
#162
of 1,499 outputs
Altmetric has tracked 23,088,369 research outputs across all sources so far. This one has received more attention than most of these and is in the 72nd percentile.
So far Altmetric has tracked 13,206 research outputs from this source. They receive a mean Attention Score of 3.4. This one has done well, scoring higher than 85% of its peers.
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 442,629 tracked outputs that were published within six weeks on either side of this one in any source. This one has gotten more attention than average, scoring higher than 71% of its contemporaries.
We're also able to compare this research output to 1,499 others from the same source and published within six weeks on either side of this one. This one has done well, scoring higher than 88% of its contemporaries.