Imaging of 3D Engineered Tissues
Lead Research Organisation:
University of Sheffield
Department Name: Materials Science and Engineering
Abstract
Abstracts are not currently available in GtR for all funded research. This is normally because the abstract was not required at the time of proposal submission, but may be because it included sensitive information such as personal details.
Technical Summary
The current proposal outlines research themes on tissue engineering at Sheffield University where a laser scanning confocal microscope with META multichannel confocal detection is requested (with the potential for multiphoton upgrade in the future). The model is for a confocal system to be located in the new interdisciplinary Kroto Research Institute at Sheffield University. This facility will have a suite of GMP accredited clean rooms to enable tissue engineered construct formation under sterile conditions for clinical use. Multidisciplinary research laboratories located immediately next to the clean rooms will support core research and further development of reconstructed tissues. Location of an on-site confocal microscope in the research laboratories will therefore enable the in-depth study of cells in synthetic scaffolds across a number of research programmes. Confocal microscopy is a leading-edge technology and a powerful research tool, enabling the capture of unrivalled high resolution of cells within 3 dimensional constructs as well as in-depth penetration of specimens tagged with very specific fluorophores. This leading edge technology is now becoming a method of choice for the dynamic imaging of cells, tissues and biological systems not otherwise possible by other optical systems. Such a technology is essential for driving the research of our team, understanding a range of interconnected problems spanning the life sciences-engineering interface. Each member of our team has programmes that rely heavily on the need for high resolution microscopy which presently is only partially met by existing fluorescence systems. META confocal technology advances the quality of imaging and flexibility of analysis by such a high degree over standard fluorescence that it is now the new benchmark from visualising cells in vitro or in 3 dimension structures in vivo. It therefore has wide applicability in biology, chemistry and engineering and this is represented by our team of applicants. A central imaging facility will also be essential for maintaining research of an internationally competitive standard and will act as a potent catalyst for attracting high quality collaborations with investigators in the UK and abroad.
Publications
Bell J
(2011)
The use of plasma polymerised acrylic acid and maleic anhydride for neuronal cell engineering
in European Cells and Materials
Chunthapong J
(2011)
Development of a tissue-engineered skin model for detecting irritants
in European Cells and Materials
Murray-Dunning C
(2011)
Three-dimensional alignment of schwann cells using hydrolysable microfiber scaffolds: strategies for peripheral nerve repair.
in Methods in molecular biology (Clifton, N.J.)
Melissinaki V
(2011)
Direct laser writing of 3D scaffolds for neural tissue engineering applications.
in Biofabrication
Kaewkhaw R
(2011)
Adipose-derived stem cells (ASCs) for peripheral nerve repair
in European Cells and Materials
Kaewkhaw R
(2011)
Adipose-derived stem cells for peripheral nerve repair
in European Cells and Materials
Daud MF
(2012)
An aligned 3D neuronal-glial co-culture model for peripheral nerve studies.
in Biomaterials
Kaewkhaw R
(2012)
Integrated culture and purification of rat Schwann cells from freshly isolated adult tissue.
in Nature protocols
Chau DY
(2013)
The development of a 3D immunocompetent model of human skin.
in Biofabrication
Paviolo C
(2013)
Laser exposure of gold nanorods can increase neuronal cell outgrowth.
in Biotechnology and bioengineering
Paviolo C
(2014)
Laser exposure of gold nanorods can induce intracellular calcium transients.
in Journal of biophotonics
Baggaley E
(2014)
Dinuclear ruthenium(II) complexes as two-photon, time-resolved emission microscopy probes for cellular DNA.
in Angewandte Chemie (International ed. in English)
Alépée N
(2014)
State-of-the-art of 3D cultures (organs-on-a-chip) in safety testing and pathophysiology
in ALTEX
Hopper AP
(2014)
Amine functionalized nanodiamond promotes cellular adhesion, proliferation and neurite outgrowth.
in Biomedical materials (Bristol, England)
Zilic L
(2015)
An anatomical study of porcine peripheral nerve and its potential use in nerve tissue engineering.
in Journal of anatomy
Lizarraga-Valderrama L
(2015)
Nerve tissue engineering using blends of poly(3-hydroxyalkanoates) for peripheral nerve regeneration
in Engineering in Life Sciences
Pateman CJ
(2015)
Nerve guides manufactured from photocurable polymers to aid peripheral nerve repair.
in Biomaterials
Plenderleith RA
(2015)
Arginine-glycine-aspartic acid functional branched semi-interpenetrating hydrogels.
in Soft matter
Hopper AP
(2016)
Photochemically modified diamond-like carbon surfaces for neural interfaces.
in Materials science & engineering. C, Materials for biological applications
Description | The grant allowed the purchase of a versatile imaging system for conducting work on 3D in vitro cells/tissues. The major outcome has been the discovery of several methods for imaging a breadth of cells and scaffolds in 3D as a alternative to using animals. |
Exploitation Route | The grant has supported a tremendous breadth of outputs - not just those I am personally associated with (immediate outputs herein), but those of many other groups. These outputs have been documented on the webpage cited above and here - (https://www.sheffield.ac.uk/kroto/confocal). These findings may be taken forward by devising new methods for further reducing animal research, new methods for SMEs to develop new implants, through to new bioreactors for such methods. |
Sectors | Healthcare |
URL | https://www.sheffield.ac.uk/kroto/confocal |
Description | This was an equipment grant for imaging 3D engineered tissues. It has led to a breadth of research represented in several outputs. Parallel findings have arisen including: 1. Design of commercial bioreactors in collaboration with SMEs 2. Design of methods for orthopaedic implants in collaboration with SMEs using 3D in vitro methods. |
First Year Of Impact | 2014 |
Sector | Healthcare |
Impact Types | Economic |