Glioblastoma multiforme (GBM) is an incurable form of brain cancer with a very poor prognosis. Because of its highly invasive nature, it is impossible to remove all tumor cells during surgical resection, making relapse inevitable. Further research into the regulatory mechanism underpinning GBM pathogenesis is therefore warranted, and over the past decade, there has been an increased focus on the functional role of microRNA (miRNA). This systematic review aims to present a comprehensive overview of all the available literature on the expression profiles and function of miRNA in GBM. Here, we have reviewed 163 papers and identified 253 upregulated, 95 downregulated, and 17 disputed miRNAs with respect to expression levels; 85 % of these miRNAs have not yet been functionally characterized. A focus in this study has been 26 interesting miRNAs involved in the mesenchymal mode of migration and invasion, demonstrating the importance of miRNAs in the context of the cellular niche. Both oncogenic and tumor-suppressive miRNAs were found to affect target genes involved in cell migration, cytoskeletal rearrangement, invasiveness, and angiogenesis. Clearly, the distinct functional properties of these miRNAs need further investigation and might hold a great potential in future molecular therapies targeting GBM.Electronic supplementary materialThe online version of this article (doi:10.1007/s12035-012-8349-7) contains supplementary material, which is available to authorized users.
This study elucidates the potential of L-menthol as a counter-irritant to secondary neurogenic inflammation and provides evidence of an intricate interplay between cold receptors TRPA1 and TRPM8, warranting further investigation of the neural coding of cold pain perception.
Background: Cold allodynia and cold hyperalgesia are both elusive features of neuropathic pain, particularly in patients with various polyneuropathies. Numerous studies have suggested that topical application of L-menthol causes temporary cold hypersensitivity and thus acts as a proxy for associated symptoms. This review summarizes studies on L-menthol-induced nociception, cold allodynia and cold hyperalgesia in vitro, in animals and in humans. Methods: A comprehensive literature search was performed using the PubMed and Google Scholar databases until February 2013. Obtained manuscripts were reviewed for relevancy and reference lists of the retrieved articles were cross-checked for additional important studies. Solely the literature regarding topical application of L-menthol in humans was attained systematically. Of the total identified studies (96), 10 met the inclusion criteria being controlled studies applying L-menthol at a concentration of ≥30%. Results: The extracted data are meticulously compared and presented with emphasis on clarity and transparency. In seven animal studies, cold allodynia or hyperalgesia was successfully established utilizing various methods. Eight studies in healthy volunteers unanimously reported a significant increase in cold pain threshold, representing cold allodynia and increased supra-threshold cold pain sensitivity, thus demonstrating cold hyperalgesia. Conclusions: Topical high-concentration L-menthol consistently induces cold hypersensitivity in animals and humans, thus constituting a predictable surrogate model of cold allodynia and hyperalgesia. Understanding translational features of this model and its underlying mechanisms could be valuable in preclinical and human phases of drug development and in improving current treatment of patients with polyneuropathy.
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