Interactions of silica nanoparticles with therapeutics for oxidative stress attenuation in neurons

Oxidative stress plays a major role in many disease pathologies, notably in the central nervous system (CNS). For instance, after initial spinal cord injury, the injury site tends to increase during a secondary chemical injury process based on oxidative stress from necrotic cells and the inflammatory response. Prevention of this secondary chemical injury would represent a major advance in the treatment of people with spinal cord injuries. Few therapeutics are useful in combating such stress in the CNS due to side effects, low efficacy, or half-life. Mesoporous silica nanoparticles show promise for delivering therapeutics based on the formation of a porous network during synthesis. Ideally, they increase the circulation time of loaded therapeutics to increase the half-life while reducing overall concentrations to avoid side effects. The current study explored the use of silica nanoparticles for therapeutic delivery of anti-oxidants, in particular, the neutralization of acrolein which can lead to extensive tissue damage due to its ability to generate more and more copies of itself when it interacts with normal tissue. Both an FDA-approved therapeutic, hydralazine, and natural product, epigallocatechin gallate, were explored as antioxidants for acrolein with nanoparticles for increased efficacy and stability in neuronal cell cultures. Not only were the nanoparticles explored in neuronal cells, but also in a co-cultured in vitro model with microglial cells to study potential immune responses to near-infrared (NIRF)-labeled nanoparticles and uptake. Studies included nanoparticle toxicity, uptake, and therapeutic response using fluorescence-based techniques with both dormant and activated immune microglia co-cultured with neuronal cells.

[1]  I. Fidler,et al.  Nitric oxide-mediated tumoricidal activity of murine microglial cells. , 2010, Translational oncology.

[2]  Takuro Niidome,et al.  PEG-modified gold nanorods with a stealth character for in vivo applications. , 2006, Journal of controlled release : official journal of the Controlled Release Society.

[3]  R. Shi,et al.  Anti-acrolein treatment improves behavioral outcome and alleviates myelin damage in experimental autoimmune enchephalomyelitis mouse , 2011, Neuroscience.

[4]  Chi-Tang Ho,et al.  Trapping effects of green and black tea extracts on peroxidation-derived carbonyl substances of seal blubber oil. , 2009, Journal of agricultural and food chemistry.

[5]  Libang Feng,et al.  Preparation of poly(ethylene glycol)-grafted silica nanoparticles using a facile esterification condensation method , 2009 .

[6]  Riyi Shi,et al.  Functionalized mesoporous silica nanoparticle-based drug delivery system to rescue acrolein-mediated cell death. , 2008, Nanomedicine.

[7]  Weihong Tan,et al.  Surface modification of silica nanoparticles to reduce aggregation and nonspecific binding. , 2006, Langmuir : the ACS journal of surfaces and colloids.

[8]  R. Shi,et al.  Accumulation of Acrolein–Protein Adducts after Traumatic Spinal Cord Injury , 2005, Neurochemical Research.

[9]  B. Pessac,et al.  A spontaneously immortalized mouse microglial cell line expressing CD4. , 1996, Brain research. Developmental brain research.

[10]  R. Shi,et al.  Neuroprotection from secondary injury by polyethylene glycol requires its internalization , 2007, Journal of Experimental Biology.

[11]  A. Nègre-Salvayre,et al.  Carbonyl scavenger and antiatherogenic effects of hydrazine derivatives. , 2008, Free radical biology & medicine.

[12]  P. Couvreur,et al.  Stealth PEGylated polycyanoacrylate nanoparticles for intravenous administration and splenic targeting. , 1999, Journal of controlled release : official journal of the Controlled Release Society.

[13]  D. Petersen,et al.  Protein adduct-trapping by hydrazinophthalazine drugs: mechanisms of cytoprotection against acrolein-mediated toxicity. , 2004, Molecular pharmacology.

[14]  T. Barder,et al.  Controlled Growth of Monodisperse Silica Spheres in the Micron Size Range , 2017 .

[15]  Zhenkun Zhang,et al.  Synthesis of poly(ethylene glycol) (PEG)-grafted colloidal silica particles with improved stability in aqueous solvents. , 2007, Journal of colloid and interface science.

[16]  Jianlin Shi,et al.  The effect of PEGylation of mesoporous silica nanoparticles on nonspecific binding of serum proteins and cellular responses. , 2010, Biomaterials.

[17]  Raoul Kopelman,et al.  Room-temperature preparation and characterization of poly (ethylene glycol)-coated silica nanoparticles for biomedical applications. , 2003, Journal of biomedical materials research. Part A.

[18]  S. Scheff,et al.  Protective effect of Pycnogenol in human neuroblastoma SH-SY5Y cells following acrolein-induced cytotoxicity. , 2008, Free radical biology & medicine.

[19]  K. Suk,et al.  Anti-inflammatory effects of catechols in lipopolysaccharide-stimulated microglia cells: inhibition of microglial neurotoxicity. , 2008, European journal of pharmacology.