Shelley FJ Wickham
Shelley FJ Wickham
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Zitiert von
Zitiert von
A DNA-based molecular motor that can navigate a network of tracks
SFJ Wickham, J Bath, Y Katsuda, M Endo, K Hidaka, H Sugiyama, ...
Nature nanotechnology 7 (3), 169-173, 2012
Direct observation of stepwise movement of a synthetic molecular transporter
SFJ Wickham, M Endo, Y Katsuda, K Hidaka, J Bath, H Sugiyama, ...
Nature nanotechnology 6 (3), 166-169, 2011
Addressing the instability of DNA nanostructures in tissue culture
J Hahn, SFJ Wickham, WM Shih, SD Perrault
ACS nano 8 (9), 8765-8775, 2014
Routing of individual polymers in designed patterns
JB Knudsen, L Liu, AL Bank Kodal, M Madsen, Q Li, J Song, ...
Nature nanotechnology 10 (10), 892-898, 2015
The chiral structure of porous chitin within the wing-scales of Callophrys rubi
GE Schröder-Turk, S Wickham, H Averdunk, F Brink, JDF Gerald, ...
Journal of structural biology 174 (2), 290-295, 2011
Iridescence from photonic crystals and its suppression in butterfly scales
L Poladian, S Wickham, K Lee, MCJ Large
Journal of the Royal Society Interface 6 (suppl_2), S233-S242, 2009
A programmable DNA origami nanospring that reveals force-induced adjacent binding of myosin VI heads
M Iwaki, SF Wickham, K Ikezaki, T Yanagida, WM Shih
Nature communications 7 (1), 13715, 2016
Exaggeration and suppression of iridescence: the evolution of two-dimensional butterfly structural colours
S Wickham, MCJ Large, L Poladian, LS Jermiin
Journal of the Royal Society Interface 3 (6), 99-109, 2006
Complex multicomponent patterns rendered on a 3D DNA-barrel pegboard
SFJ Wickham, A Auer, J Min, N Ponnuswamy, JB Woehrstein, F Schueder, ...
Nature communications 11 (1), 5768, 2020
Switchable DNA-origami nanostructures that respond to their environment and their applications
JK Daljit Singh, MT Luu, A Abbas, SFJ Wickham
Biophysical reviews 10 (5), 1283-1293, 2018
The fusion of lipid and DNA nanotechnology
E Darley, JKD Singh, NA Surace, SFJ Wickham, MAB Baker
Genes 10 (12), 1001, 2019
Insights from nature: Optical biomimetics
MCJ Large, S Wickham, J Hayes, L Poladian
Physica B: Condensed Matter 394 (2), 229-232, 2007
Binding of DNA origami to lipids: maximizing yield and switching via strand displacement
JKD Singh, E Darley, P Ridone, JP Gaston, A Abbas, SFJ Wickham, ...
Nucleic acids research 49 (19), 10835-10850, 2021
Minimizing cholesterol-induced aggregation of membrane-interacting DNA origami nanostructures
JK Daljit Singh, MT Luu, JF Berengut, A Abbas, MAB Baker, SFJ Wickham
Membranes 11 (12), 950, 2021
Iridescence from photonic crystals and its suppression in butterfly scales. JR Soc. Interface 6
L Poladian, S Wickham, K Lee, MCJ Large
S233–S242.(doi: 10.1098/rsif. 2008.0353. focus). Link, ISI, 2009
DNA origami: a substrate for the study of molecular motors
S Wickham
University of Oxford, 2011
ACS Nano 2014, 8, 8765–8775
J Hahn, SFJ Wickham, WM Shih, SD Perrault
of 15, 12, 0
Control of iridescence in natural photonic structures: The case of butterfly scales
S Wickham, L Poladian, MCJ Large, P Vukusic
Optical Biomimetics, 147-176e, 2012
Exploring Artificial Nucleic Acid Mimicking Peptide Nanofibers
SIS Hendrikse, N Todorova, H Soleimaninejad, P Charchar, MA Sani, ...
Chemistry of Materials 35 (11), 4355-4365, 2023
Plasma Activation of Microplates Optimized for One-Step Reagent-Free Immobilization of DNA and Protein
K Coffi Dit Gleize, CTH Tran, A Waterhouse, MMM Bilek, SFJ Wickham
Langmuir 39 (1), 343-356, 2022
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