Neural Regeneration Research (Jan 2015)
Autologous nerve graft repair of different degrees of sciatic nerve defect: stress and displacement at the anastomosis in a three-dimensional fnite element simulation model
- Cheng-dong Piao,
- Kun Yang,
- Peng Li,
- Min Luo
Affiliations
- Cheng-dong Piao
- Kun Yang
- Peng Li
- Min Luo
- DOI
- https://doi.org/10.4103/1673-5374.156986
- Journal volume & issue
-
Vol. 10,
no. 5
pp. 804 – 807
Abstract
In the repair of peripheral nerve injury using autologous or synthetic nerve grafting, the magnitude of tensile forces at the anastomosis affects its response to physiological stress and the ultimate success of the treatment. One-dimensional stretching is commonly used to measure changes in tensile stress and strain however, the accuracy of this simple method is limited. Therefore, in the present study, we established three-dimensional finite element models of sciatic nerve defects repaired by autologous nerve grafts. Using PRO E 5.0 finite element simulation software, we calculated the maximum stress and displacement of an anastomosis under a 5 N load in 10-, 20-, 30-, 40-mm long autologous nerve grafts. We found that maximum displacement increased with graft length, consistent with specimen force. These findings indicate that three-dimensional finite element simulation is a feasible method for analyzing stress and displacement at the anastomosis after autologous nerve grafting.
Keywords
- active zone stability
- Drosophila
- neuromuscular junction
- dephosphorylation
- Liprin-α
- Syd-1
- PP2A
- GSK-3ß
- living scaffolds
- neural tissue engineering
- cell transplant
- biomaterials
- regeneration
- neurotrauma
- neurodegeneration
- axon pathfinding
- cell migration
- injury
- plasticity
- neurodegenerative disease
- brain
- therapy
- neuron
- microglia
- neural progenitor
- tissue engineering
- neuroregeneration
- repair
- central nervous system
- biomaterial
- regenerative medicine
- nanotechnology
- spinal cord injury
- axonal regeneration
- exosome
- extracellular vesicle
- microRNA
- microvesicle
- nerve gap
- neurite outgrowth
- peripheral nerve injury
- Schwann cell
- stem cell
- hemodynamic phases
- cerebral subarachnoid hemorrhage
- metabolic crises
- nerve regeneration
- hypoxic-ischemic brain damage
- ginsenoside Rg1
- neural stem cells
- cell transplantation
- cell differentiation
- cognition
- nerve reconstruction
- neural regeneration
- nerve regeneration
- brain injury
- neuroimaging
- functional magnetic resonance imaging
- regional homogeneity
- apoplexy
- subacute
- ischemia
- participants
- healthy
- volunteers
- brain activity
- NSFC grants
- neural regeneration
- nerve regeneration
- brain injury
- neuroprotection
- cerebral ischemia/reperfusion injury
- lateral intracerebroventricular injection
- Apelin-13
- nerve apoptosis
- Bcl-2
- caspase-3
- NSFC grants
- neural regeneration
- nerve regeneration
- fractalkine
- CX3 chemokine receptor 1
- neuronal maturation
- dendrites
- doublecortin
- synaptic maturation
- newborn neurons
- neural regeneration
- nerve regeneration
- neurodegenerative diseases
- Alzheimer′s disease
- transgenic animal models
- mice
- epimedium herb
- milkvetch root
- kudzuvine root
- divalent metal transporter 1
- ferroportin 1
- neural regeneration
- nerve regeneration
- microRNA-124
- neurogenesis
- neuronal survival
- Huntington′s disease
- SRY-related HMG box transcription factor 9
- brain-derived neurotrophic factor
- peroxisome proliferator-activated receptor gamma coactivator 1-alpha
- mutant huntingtin
- nerve regeneration
- Ras/Raf/Erk1/2 signaling pathway
- spinal cord injury
- apoptosis
- repair
- regulation
- inhibition
- neural regeneration
- nerve regeneration
- neurogenic bladder
- bibliometric analysis
- Web of Science database
- visualization analysis
- CiteSpace III
- citation analysis
- neural regeneration
- nerve regeneration
- sciatic nerve injury
- autologous nerve grafting
- epineurial suturing
- three-dimensional finite element models
- load
- stress
- displacement
- neural regeneration
