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Mechanical regulation of vascular growth and tissue regeneration in vivo
Joel D. Boerckel
, Brent A. Uhrig
, Nick J. Willett
, Nathaniel Huebsch
, Robert E. Guldberg
Department of Biomedical Engineering
Institute of Clinical and Translational Sciences (ICTS)
Center of Regenerative Medicine
Research output
:
Contribution to journal
›
Article
›
peer-review
196
Scopus citations
Overview
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Keyphrases
Neovascular
100%
Tissue Regeneration
100%
Vascular Tissue
100%
Vascular Growth
100%
Mechanical Regulation
100%
Bone Formation
40%
Vascular Remodeling
40%
Histology
20%
Angiogenesis
20%
Highly Sensitive
20%
Bone Damage
20%
Mechanical Loading
20%
Rat Model
20%
Microvascular Invasion
20%
Functional Tissue
20%
Collateral Vessels
20%
Engineered Tissue
20%
Vascular Reactivity
20%
Vascular Density
20%
Matrix Deformation
20%
Network Formation
20%
Wound Healing Process
20%
Large Vessel
20%
Small Vessels
20%
Contrast-enhanced Computed Tomography
20%
Bone Regeneration
20%
Network Remodeling
20%
Vessel Formation
20%
Functional Load
20%
Mechanosensitivity
20%
Biomechanical Stimulation
20%
Matrix Effect
20%
Degree of Anisotropy
20%
Mechanical Condition
20%
Vascular Network Formation
20%
Large Bone Defects
20%
Fixation Plate
20%
Bone Defect Regeneration
20%
Vascular Connectivity
20%
Stiffened Plate
20%
Medicine and Dentistry
Tissue Regeneration
100%
Ossification
66%
X-Ray Microtomography
33%
In Vitro
33%
Angiogenesis
33%
Bone Injury
33%
Vascular Remodeling
33%
Vascular Network
33%
Blood Vessel Reactivity
33%
Wound Healing
33%
Bone Defect
33%
Engineered Tissue
33%
Bone Regeneration
33%
Immunology and Microbiology
Tissue Regeneration
100%
Ossification
66%
Angiogenesis
33%
Rat Model
33%
Micro-Computed Tomography
33%
Blood Vessel Reactivity
33%
Wound Healing
33%
Anisotropy
33%
Bone Regeneration
33%
Engineered Tissue
33%
In Vitro
33%
Biochemistry, Genetics and Molecular Biology
Tissue Regeneration
100%
Ossification
66%
Angiogenesis
33%
Micro-Computed Tomography
33%
Rat Model
33%
Blood Vessel Reactivity
33%
Wound Healing
33%
Anisotropy
33%
Bone Regeneration
33%
Mechanosensitivity
33%