Treatment of hind limb ischemia using angiogenic peptide nanofibers
Treatment of hind limb ischemia using angiogenic peptide nanofibers
For a proangiogenic therapy to be successful, it must promote the development of mature vasculature for rapid reperfusion of ischemic tissue. Whole growth factor, stem cell, and gene therapies have yet to achieve the clinical success needed to become FDA-approved revascularization therapies. Herein, we characterize a biodegradable peptide-based scaffold engineered to mimic VEGF and self-assemble into a nanofibrous, thixotropic hydrogel, SLanc. We found that this injectable hydrogel was rapidly infiltrated by host cells and could be degraded while promoting the generation of neovessels. In mice with induced hind limb ischemia, this synthetic peptide scaffold promoted angiogenesis and ischemic tissue recovery, as shown by Doppler-quantified limb perfusion and a treadmill endurance test. Thirteen-month-old mice showed significant recovery within 7 days of treatment. Biodistribution studies in healthy mice showed that the hydrogel is safe when administered intramuscularly, subcutaneously, or intravenously. These preclinical studies help establish the efficacy of this treatment for peripheral artery disease due to diminished microvascular perfusion, a necessary step before clinical translation. This peptide-based approach eliminates the need for cell transplantation or viral gene transfection (therapies currently being assessed in clinical trials) and could be a more effective regenerative medicine approach to microvascular tissue engineering.
113-119
Kumar, Vivek A.
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Liu, Qi
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Wickremasinghe, Navindee C.
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Shi, Siyu
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Cornwright, Toya T.
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Deng, Yuxiao
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Azares, Alon
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Moore, Amanda N.
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Acevedo-Jake, Amanda M.
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Agudo, Noel R.
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Pan, Su
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Woodside, Darren G.
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Vanderslice, Peter
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Willerson, James T.
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Dixon, Richard A.
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Hartgerink, Jeffrey D.
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1 August 2016
Kumar, Vivek A.
44b39eed-933f-4f9a-9c0e-303b40dc1805
Liu, Qi
45fc5929-6172-48d4-95b8-fdc94baedefe
Wickremasinghe, Navindee C.
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Shi, Siyu
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Cornwright, Toya T.
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Deng, Yuxiao
2124fb13-c9d6-4051-9fc0-cc2bc3c14770
Azares, Alon
be401c2a-c7a8-420d-8d1b-208b59dc5cc3
Moore, Amanda N.
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Acevedo-Jake, Amanda M.
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Agudo, Noel R.
8de65a11-e48e-413b-8d19-44d3b6dd4db2
Pan, Su
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Woodside, Darren G.
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Vanderslice, Peter
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Willerson, James T.
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Dixon, Richard A.
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Hartgerink, Jeffrey D.
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Kumar, Vivek A., Liu, Qi, Wickremasinghe, Navindee C., Shi, Siyu, Cornwright, Toya T., Deng, Yuxiao, Azares, Alon, Moore, Amanda N., Acevedo-Jake, Amanda M., Agudo, Noel R., Pan, Su, Woodside, Darren G., Vanderslice, Peter, Willerson, James T., Dixon, Richard A. and Hartgerink, Jeffrey D.
(2016)
Treatment of hind limb ischemia using angiogenic peptide nanofibers.
Biomaterials, 98, .
(doi:10.1016/j.biomaterials.2016.04.032).
Abstract
For a proangiogenic therapy to be successful, it must promote the development of mature vasculature for rapid reperfusion of ischemic tissue. Whole growth factor, stem cell, and gene therapies have yet to achieve the clinical success needed to become FDA-approved revascularization therapies. Herein, we characterize a biodegradable peptide-based scaffold engineered to mimic VEGF and self-assemble into a nanofibrous, thixotropic hydrogel, SLanc. We found that this injectable hydrogel was rapidly infiltrated by host cells and could be degraded while promoting the generation of neovessels. In mice with induced hind limb ischemia, this synthetic peptide scaffold promoted angiogenesis and ischemic tissue recovery, as shown by Doppler-quantified limb perfusion and a treadmill endurance test. Thirteen-month-old mice showed significant recovery within 7 days of treatment. Biodistribution studies in healthy mice showed that the hydrogel is safe when administered intramuscularly, subcutaneously, or intravenously. These preclinical studies help establish the efficacy of this treatment for peripheral artery disease due to diminished microvascular perfusion, a necessary step before clinical translation. This peptide-based approach eliminates the need for cell transplantation or viral gene transfection (therapies currently being assessed in clinical trials) and could be a more effective regenerative medicine approach to microvascular tissue engineering.
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Accepted/In Press date: 19 April 2016
e-pub ahead of print date: 26 April 2016
Published date: 1 August 2016
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Local EPrints ID: 434656
URI: http://eprints.soton.ac.uk/id/eprint/434656
ISSN: 0142-9612
PURE UUID: 6844491b-955c-46fe-8302-7c502d499127
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Date deposited: 04 Oct 2019 16:30
Last modified: 16 Mar 2024 04:22
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Contributors
Author:
Vivek A. Kumar
Author:
Qi Liu
Author:
Navindee C. Wickremasinghe
Author:
Siyu Shi
Author:
Toya T. Cornwright
Author:
Yuxiao Deng
Author:
Alon Azares
Author:
Amanda N. Moore
Author:
Amanda M. Acevedo-Jake
Author:
Noel R. Agudo
Author:
Su Pan
Author:
Darren G. Woodside
Author:
Peter Vanderslice
Author:
James T. Willerson
Author:
Richard A. Dixon
Author:
Jeffrey D. Hartgerink
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