Neuroprotective Effects of Functionalized Hydrophilic Carbon Clusters: Targeted Therapy of Traumatic Brain Injury in an Open Blast Rat Model

Traumatic brain injury (TBI) causes multiple cerebrovascular disruptions and oxidative stress. These pathological mechanisms are often accompanied by serious impairment of cerebral blood flow autoregulation and neuronal and glial degeneration. Background/Objectives: Multiple biochemical cascades are...

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Published in:Biomedicines 2024-12, Vol.12 (12), p.2832
Main Authors: Padmanabhan, Parasuraman, Lu, Jia, Ng, Kian Chye, Srinivasan, Dinesh Kumar, Sundramurthy, Kumar, Nilewski, Lizanne Greer, Sikkema, William K. A, Tour, James M, Kent, Thomas A, Gulyás, Balázs, Carlstedt-Duke, Jan
Format: Article
Language:English
Subjects:
Antioxidants
biologically compatible carbon-based nanoclusters
Blood flow
Blood-brain barrier
Brain
Brain damage
Carbon
Cerebral blood flow
Dentate gyrus
Explosions
Hydrogen peroxide
Hypotension
Hypoxia
Immunohistochemistry
Injuries
Laboratory animals
Medical research
Nanoparticles
Neurodegeneration
Neuromodulation
Neuronal-glial interactions
Neurons
Neuroprotection
Nitric-oxide synthase
open blast rat TBI model
Oxidative stress
Parenchyma
poly-ethylene-glycol-functionalized hydrophilic carbon clusters (PEG-HCCs)
Reactive oxygen species
Superoxide
Traumatic brain injury
traumatic brain injury (TBI)
Veterans
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Summary:Traumatic brain injury (TBI) causes multiple cerebrovascular disruptions and oxidative stress. These pathological mechanisms are often accompanied by serious impairment of cerebral blood flow autoregulation and neuronal and glial degeneration. Background/Objectives: Multiple biochemical cascades are triggered by brain damage, resulting in reactive oxygen species production alongside blood loss and hypoxia. However, most currently available early antioxidant therapies lack capacity and hence sufficient efficacy against TBI. The aim of this study was to test a novel catalytic antioxidant nanoparticle to alleviate the damage occurring in blast TBI. Methods: TBI was elicited in an open blast rat model, in which the rats were exposed to the effects of an explosive blast. Key events of the post-traumatic chain in the brain parenchyma were studied using immunohistochemistry. The application of a newly developed biologically compatible catalytic superoxide dismutase mimetic carbon-based nanocluster, a poly-ethylene-glycol-functionalized hydrophilic carbon cluster (PEG-HCC), was tested post-blast to modulate the components of the TBI process. Results: The PEG-HCC was shown to significantly ameliorate neuronal loss in the brain cortex, the dentate gyrus, and hippocampus when administered shortly after the blast. There was also a significant increase in endothelial activity to repair blood–brain barrier damage as well as the modulation of microglial and astrocyte activity and an increase in inducible NO synthase in the cortex. Conclusions: We have demonstrated qualitatively and quantitatively that the previously demonstrated antioxidant properties of PEG-HCCs have a neuroprotective effect after traumatic brain injury following an explosive blast, acting at multiple levels of the pathological chain of events elicited by TBI.
ISSN:2227-9059
2227-9059
DOI:10.3390/biomedicines12122832