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    Article Cited by others

INVITED REVIEW

Neurotrophic factors: from neurodevelopmental regulators to novel therapies for Parkinson's disease

Hegarty Shane V, O«SQ»Keeffe Gerard W, Sullivan Aideen M

Year : 2014| Volume: 9| Issue : 19 | Page no: 1708-1711

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[Pubmed]  [Google Scholar] [DOI]
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[Pubmed]  [Google Scholar] [DOI]
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5 Stigmasterol upregulates immediate early genes and promotes neuronal cytoarchitecture in primary hippocampal neurons as revealed by transcriptome analysis
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17 Gdf-15 deficiency does not alter vulnerability of nigrostriatal dopaminergic system in MPTP-intoxicated mice
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