Andrew E Rodda
Overview
Explore the profile of Andrew E Rodda including associated specialties, affiliations and a list of published articles.
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11
Citations
137
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Recent Articles
1.
Tria A, Dharma A, Spiegel L, Rodda A, Allada A, Sluka P, et al.
Cardiovasc Eng Technol
. 2024 Dec;
PMID: 39707135
Purpose: A triple lumen iteration of the novel photo-angioplasty drug eluting balloon catheter (DEBc) Lumi-Solve may be compromised by guidewire shadow (GWS)-mediated attenuation of balloon surface drug activation. The current...
2.
Parker B, Rhodes D, OBrien C, Rodda A, Cameron N
Acta Biomater
. 2021 Sep;
135:64-86.
PMID: 34492374
Commercial nerve guidance conduits (NGCs) for repair of peripheral nerve discontinuities are of little use in gaps larger than 30 mm, and for smaller gaps they often fail to compete...
3.
Zhu C, Rodda A, Truong V, Shi Y, Zhou K, Haynes J, et al.
ACS Biomater Sci Eng
. 2021 Jan;
4(7):2494-2504.
PMID: 33435113
Myocardial tissue engineering is a promising therapy for myocardial infarction recovery. The success of myocardial tissue engineering is likely to rely on the combination of cardiomyocytes, prosurvival regulatory signals, and...
4.
Rodda A, Ercole F, Glattauer V, Nisbet D, Healy K, Dove A, et al.
J Mater Chem B
. 2020 Apr;
4(45):7314-7322.
PMID: 32263733
While polycaprolactone (PCL) and similar polyesters are commonly used as degradable scaffold materials in tissue engineering and related applications, non-specific adsorption of environmental proteins typically precludes any control over the...
5.
Rodda A, Parker B, Spencer A, Corrie S
ACS Sens
. 2018 Feb;
3(3):540-560.
PMID: 29441780
Liquid biopsies that analyze circulating tumor DNA (ctDNA) hold great promise in the guidance of clinical treatment for various cancers. However, the innate characteristics of ctDNA make it a difficult...
6.
Rodda A, Ercole F, Glattauer V, Gardiner J, Nisbet D, Healy K, et al.
Biomacromolecules
. 2015 May;
16(7):2109-18.
PMID: 26020464
While electrospun fibers are of interest as scaffolds for tissue engineering applications, nonspecific surface interactions such as protein adsorption often prevent researchers from controlling the exact interactions between cells and...
7.
Rodda A, Ercole F, Nisbet D, Forsythe J, Meagher L
Macromol Biosci
. 2015 Feb;
15(6):799-811.
PMID: 25689676
Poly(oligo(ethylene glycol) methacrylate) (pOEGMA) brushes were grafted via surface-initiated atom transfer radical polymerization (SI-ATRP) from a poly(styrene-co-vinylbenzyl chloride) macroinitiator. While bromoisobutyryl initiator groups are most commonly used for this purpose,...
8.
Kelly R, Rodda A, Dickinson A, Mahmud A, Nefzger C, Lee W, et al.
Stem Cells
. 2013 Jan;
31(4):703-16.
PMID: 23307500
Mitochondrial DNA haplotypes are associated with various phenotypes, such as altered susceptibility to disease, environmental adaptations, and aging. Accumulating evidence suggests that mitochondrial DNA is essential for cell differentiation and...
9.
Nisbet D, Rodda A, Horne M, Forsythe J, Finkelstein D
Tissue Eng Part A
. 2010 Apr;
16(9):2833-42.
PMID: 20408769
To develop neural tissue engineering strategies that are useful for repairing damaged neural pathways in the central nervous system, it is essential to control and optimise neurone and neurite interactions...
10.
Nisbet D, Rodda A, Horne M, Forsythe J, Finkelstein D
Biomaterials
. 2009 Jun;
30(27):4573-80.
PMID: 19500836
Assessment of axonal infiltration and guidance within neural tissue engineering scaffolds, along with the characterisation of the inflammatory response, is critical in determining these scaffolds' potential for facilitating neural repair....