Antioxidant Therapy in Oxidative Stress-Induced Neurodegenerative Diseases: Role of Nanoparticle-Based Drug Delivery Systems in Clinical Translation
Abstract
:1. Introduction
1.1. Endogenous and Exogenous Sources of Free Radicals
1.2. Free Radicals: A Double Edge Sword
2. Oxidative Stress and Neurodegenerative Diseases
2.1. Progressive Neurodegenerative Diseases
2.1.1. Alzheimer’s Disease (AD)
2.1.2. Parkinson’s Disease (PD)
2.1.3. Amyotrophic Lateral Sclerosis (ALS)
2.2. Injury-Induced Oxidative Stress
2.2.1. Stroke
2.2.2. Spinal Cord Injury (SCI)
2.2.3. Peripheral Nerve Injury (PNI)
3. Antioxidants
3.1. Endogenous Antioxidants
3.1.1. Antioxidant Enzymes
3.1.2. Antioxidant Non-Enzymes
3.2. Exogenous Antioxidants
3.3. Synthetic Antioxidants
4. Preclinical Studies with Antioxidant Agents
4.1. Antioxidant-Based Therapy in Neurodegenerative Diseases
4.2. Antioxidant-Based Therapy in Neurological Injury
4.3. Clinical Trials with Antioxidants
4.4. Drug Delivery Challenges
- Low permeability to the CNS: The presence of a physiological barrier such as the BBB or spinal–blood barrier (SBB) restricts the accessibility of antioxidant compounds to the CNS and hence could not achieve a prolonged therapeutic dose to impart an antioxidant effect in chronic neurodegenerative diseases [280]. In certain pathological conditions, the BBB/SBB may be compromised due to inflammation or injury (e.g., stroke and spinal cord injury) but still may not be able to achieve the desired dose for a prolonged period due to transient and limited permeability of the BBB/SBB, giving a narrow time window for delivery of therapeutics [281].
- Low bioavailability: Most antioxidants are given orally, and they are insoluble or unstable in a gastric environment that could result in low bioavailability to provide high systemic levels for transport to the CNS at effective doses [282,283]. Antioxidant compounds that are administered via systemic routes have short half-lives [284], which could also limit their transport to the CNS.
- Low catalytic activity: High doses of antioxidant compounds are needed to detoxify the effect of free radicals, which could not be given to humans because of the dose-limiting toxicity [285]. Noncatalytic antioxidant becomes ineffective, once these molecules interact with free radicals [286], and hence, maintaining high antioxidant levels in the target tissue to counteract free radicals that are formed over a period of time in chronic conditions could be challenging.
- Toxicity: Due to toxicity concerns, human doses could have been significantly lower than those used in animal model studies. This could also constrain the duration of treatment necessary to see the beneficial outcome in clinical trials [287].
- Oxidative stress target and other factors: Although oxidative stress is considered as the driving force behind neurodegenerative diseases, there could be other cofounding pathological factors in humans that may not have been targeted solely by antioxidants [288,289]. In addition, the question raised is also how close animal models are to human pathology [290].
5. Antioxidant-Based Nanotherapy
Antioxidant Enzymes
6. Concluding Remarks/Future Perspective
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Abbreviations
ALA | α-Lipoic acid |
ALSFRSr | Amyotrophic Lateral Sclerosis Functional Rating Scale Revised |
APP | Amyloid Precursor Protein |
ARE | Antioxidant Response Element |
BBB | Blood-Brain Barrier |
CAT | Catalase |
CNS | Central Nervous System |
CoQ10 | Coenzyme Q10 |
EGCG | Epigallocatechin Gallates |
ETC | Electron Transport Chain |
GSH | Glutathione |
GST | Glutathione S-Transferase |
GPx | Glutathione Peroxidases |
GR | Glutathione Reductase |
HO-1 | Heme Oxygenase 1 |
4-HNE | 4-Hydroxynonenal |
KEAP1 | Kelch-like ECH-Associated Protein 1 |
LDL | Low-Density Lipoproteins |
LPO | Lipid Peroxidation |
MCAO | Middle Cerebral Artery Occlusion |
MDA | Malondialdehyde |
MMP | Matrix Metalloproteinases |
NF-κB | Nuclear Factor Kappa B |
NFTs | Neurofibrillary Tangles |
Nrf2 | Nuclear Factor Erythroid 2-Related Factor 2 |
NQO1 | NADPH Quinine Oxidoreductase 1 |
PLGA | Poly(Lactic-co-Glycolic Acid) |
PNS | Peripheral Nervous System |
RA | Retinoic Acid |
ROS | Reactive Oxygen Species |
RNS | Reactive Nitrogen Species |
SIRT-1 | Sirtuin 1 |
SOD | Superoxide Dismutase |
TAC | Total Antioxidant Capacity |
UPDRS | Unified Parkinson’s Disease Rating Scale |
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Antioxidants | Route | Disease Patients | Dosage | Follow Up Period | No. of Patients | Outcome | References |
---|---|---|---|---|---|---|---|
Curcumin | Oral | AD ALS | 1.5 g/d 100 mg/d | 6 months 9 months | 34 42 | Reduced cognitive deterioration Slowdown in disease progression | [251,252] |
Resveratrol | Oral | AD | 1 g/d | 52 weeks | 119 | Decreased Aβ1–40 and MMP-9 levels in CSF Slowed cognitive decline | [253] |
GSH | Intranasal | PD | 300 mg/d or 600 mg/d thrice 100 mg/d or 200 mg/d thrice | 3 months | 30 45 | Safety and tolerability No significant differences between groups No effect on motor function | [256,257] |
CoQ10 | Oral | PD PD ALS | 400, 800, 1200, and 2400 mg/d 1200 mg/d or 2400 mg/d 1800 mg/d and 2700 mg/d | 10 weeks 16 months 9 months | 16 600 105 | Improved UPDRS, Reduced F2-isoprostanes No therapeutic benefit Decreased ALSFRSr No significant differences between groups at high dose | [258,259,260] |
Ginkgo biloba | Oral | AD | 120 mg/d twice | 8 years | 3069 | No improvement in cognition | [261] |
Edaravone (FDA Approved in 2017) | Intravenous | ALS | 60 mg/d | 24 Weeks | 137 | Decreased ALSFRSr | [262,263] |
Lipoic acid and, Omega-3 fatty acids | Oral | AD | 600 mg/d 675 mg docosahexaenoic acid (DHA) 975 mg eicosapentaenoic acid (EPA) | 12 months | 39 | Slowed cognitive and functional decline | [268] |
Vitamin E and, Memantine | Oral | AD | 2000 IU/d20 mg/d | 5 years | 613 | Slower functional deterioration in Vitamin E group | [269] |
Vitamin E, Vitamin C, ALA, and CoQ | Oral | AD | 800 IU/d 500 mg/d 900 mg/d 400 mg/d thrice | 16 weeks | 78 | No effect on amyloid or tau pathology biomarkers | [270] |
Omega-3 fatty acids and, Vitamin E | Oral | PD | 1000 mg 400 IU | 12 weeks | 60 | Improved UPDRS, TAC and GSH | [271] |
Nanocurcumin and, Riluzole | Oral | ALS | 80 mg/d 50 mg/d twice | 12 months | 54 | Safety and tolerability Increased survival probability of ALS patients | [272] |
Curcumin Formulation (Longvida) Solid-Lipid Curcumin | Oral | AD Control | 2000 mg–3000 mg/d 400 mg/d | 9 months 4 weeks | 26 60 | Not provided Improved cognition and mood | [273,274] |
Antioxidants | Route | Disease Patients | Dosage | Follow Up Period | No. of Patients | Outcome | References |
---|---|---|---|---|---|---|---|
Resveratrol | Oral/ Infusion | Stroke | 2.5 mg/kg | 0–2 h of stroke onset | 312 | Decreased MMP-9 and MMP-2 levels | [253,254] |
EGCG | Intravenous/ oral/ infusion | Stroke | 500 mg | 0–5 h of stroke onset | 371 | Decreased MMP-9 and MMP-2 levels | [255] |
Edaravone | Intravenous | Stroke | 30 mg 60 mg | 6 months 12–24 h of stroke onset | 40163 | Effective recovery Decreased MMP-9 levels | [264,265] |
Edaravone Dexborneol | Intravenous | Stroke Intracerebral Hemorrhage | 12.5 mg, 37.5 mg or 62.5 mg every 12 h for 14 days 37.5 mg every 12 h for 14 days | 3 months NA | 385390 (estimated) | Safe and well tolerated No Recruitment | [266,267] |
Nanoparticle-loaded Edaravone | Intravenous | Cerebral Hemorrhage | 25 mg | 3 weeks | 120 | Reduced edema Improved neurological function Reduced interleukin and tumor necrosis factor | [275] |
Ginkgo biloba and, Aspirin | Oral | Stroke | 450 mg 100 mg | 6 months | 348 | Alleviated cognitive and neurological impairment | [276] |
Omega-3 pill Vegetation Protein Powder InflanNox (curcumin) capsuleAnti-oxidant Network capsule Chlorella tablet | Oral | SCI | 500 mg/d EPA, 250 mg/d DHA, thrice 45 g/d 400 mg/d thrice 615 mg/d twice 1000 mg/d, 6 times | 3 months | 20 | Improvement in behavior Modification in neuroactive compounds Reduction in IL-1β | [277] |
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Ashok, A.; Andrabi, S.S.; Mansoor, S.; Kuang, Y.; Kwon, B.K.; Labhasetwar, V. Antioxidant Therapy in Oxidative Stress-Induced Neurodegenerative Diseases: Role of Nanoparticle-Based Drug Delivery Systems in Clinical Translation. Antioxidants 2022, 11, 408. https://doi.org/10.3390/antiox11020408
Ashok A, Andrabi SS, Mansoor S, Kuang Y, Kwon BK, Labhasetwar V. Antioxidant Therapy in Oxidative Stress-Induced Neurodegenerative Diseases: Role of Nanoparticle-Based Drug Delivery Systems in Clinical Translation. Antioxidants. 2022; 11(2):408. https://doi.org/10.3390/antiox11020408
Chicago/Turabian StyleAshok, Anushruti, Syed Suhail Andrabi, Saffar Mansoor, Youzhi Kuang, Brian K. Kwon, and Vinod Labhasetwar. 2022. "Antioxidant Therapy in Oxidative Stress-Induced Neurodegenerative Diseases: Role of Nanoparticle-Based Drug Delivery Systems in Clinical Translation" Antioxidants 11, no. 2: 408. https://doi.org/10.3390/antiox11020408
APA StyleAshok, A., Andrabi, S. S., Mansoor, S., Kuang, Y., Kwon, B. K., & Labhasetwar, V. (2022). Antioxidant Therapy in Oxidative Stress-Induced Neurodegenerative Diseases: Role of Nanoparticle-Based Drug Delivery Systems in Clinical Translation. Antioxidants, 11(2), 408. https://doi.org/10.3390/antiox11020408