about
Animal models of chronic pain: Advances and challenges for clinical translation.Analgesia induced by the epigenetic drug, L-acetylcarnitine, outlasts the end of treatment in mouse models of chronic inflammatory and neuropathic pain.Hyperbaric oxygen treatment attenuates neuropathic pain by elevating autophagy flux via inhibiting mTOR pathway.The Emotional Brain as a Predictor and Amplifier of Chronic PainThe thalamo-cortical complex network correlates of chronic pain.Role of Epigenetics in Biology and Human Diseases.Recent advances in understanding neuropathic pain: glia, sex differences, and epigenetics.Pain as a disease: an overview.Emerging Treatments for Neuropathic Pain.Selective repression of gene expression in neuropathic pain by the neuron-restrictive silencing factor/repressor element-1 silencing transcription (NRSF/REST).Neuroprotection as a Potential Therapeutic Perspective in Neurodegenerative Diseases: Focus on Antiepileptic Drugs.Drugging the pain epigenome.Exercise-induced hypoalgesia: potential mechanisms in animal models of neuropathic pain.Correlation Between DNA Methylation of TRPA1 and Chronic Pain States in Human Whole Blood Cells.[EXPRESS] Threshold Effect of G9a/Glp on Peripheral Nerve Injury Induced Hypersensitivity.Pain vulnerability and DNA methyltransferase 3a involved in the affective dimension of chronic painEpigenetic regulation of spinal cord gene expression contributes to enhanced postoperative pain and analgesic tolerance subsequent to continuous opioid exposure.Autophagy: Can It be a New Experimental Research Method of Neuropathic Pain?Neuronal activity modifies the chromatin accessibility landscape in the adult brain.Challenges in translational drug research in neuropathic and inflammatory pain: the prerequisites for a new paradigm.Potential mechanisms of microRNA-141-3p to alleviate chronic inflammatory pain by downregulation of downstream target gene HMGB1: in vitro and in vivo studies.Chronic Pain After Traumatic Brain Injury: Pathophysiology and Pain Mechanisms.Headache in Resource-Limited Settings.miRNAs: Important Targets for Oral Cancer Pain Research.Chronic postsurgical pain: is there a possible genetic link?Reward Circuitry Plasticity in Pain Perception and Modulation.The analgesic effects of triptolide in the bone cancer pain rats via inhibiting the upregulation of HDACs in spinal glial cells.To Treat or Not to Treat: The Effects of Pain on Experimental Parameters.Influence of new societal factors on neovascular age-related macular degeneration outcomes.5-Hydroxymethylcytosine (5hmC) and Ten-eleven translocation 1-3 (TET1-3) proteins in the dorsal root ganglia of mouse: Expression and dynamic regulation in neuropathic pain.miR-183 cluster scales mechanical pain sensitivity by regulating basal and neuropathic pain genes.Identification of FAM173B as a protein methyltransferase promoting chronic pain.Macrophage migration inhibitory factor mediates peripheral nerve injury-induced hypersensitivity by curbing dopaminergic descending inhibition.EZH2 regulates spinal neuroinflammation in rats with neuropathic pain.Changes in the expression of IL-6-Mediated MicroRNAs in the dorsal root ganglion under neuropathic pain in mice.Subliminal (latent) processing of pain and its evolution to conscious awareness.Epigenetic Modifications Associated to Neuroinflammation and Neuropathic Pain After Neural Trauma.A bright future? Optogenetics in the periphery for pain research and therapy
P2860
Q30249165-DB682CBE-1D1E-45B3-9DE5-645AF2C5AB98Q33610537-FB8C5628-6C2D-4F38-ACDB-C80EB19B1803Q33733301-ED73A520-6F4B-4972-8271-5A39038EFC60Q37046049-E71AD692-03CF-40B1-A516-2C17F498B81CQ37336074-7C8DB424-8757-473E-8256-ED2E0B19CD22Q37358791-A382F365-BDAE-48EA-88B4-9DB086B37071Q37577709-D8103BC0-459B-41F3-8F96-5C4D97F708EEQ38598917-6A7F71F5-4717-4A16-B666-CE8EAE753086Q38623570-7592BB67-43DD-4D7B-BFF4-46446459E86BQ38672415-E1E531E4-A129-43E5-AA45-FF382E6F5B7FQ38684428-0D5AEE4B-3C93-4C6F-8C83-2E592076A2DBQ38761806-238E33A6-6964-4548-8043-782FD8E19594Q38916284-7C750778-EF00-41C5-825F-795C939DD491Q40019648-4C044027-A290-4BA5-90D3-44C3CB296B6CQ41588359-B6605CBE-B108-4970-8D06-C7D7FF0146FBQ41591615-6A7BC43A-29F9-486D-9E3D-B32517958565Q41990673-1A16118A-A7E9-4E75-B016-8CDFA35C078CQ42114474-B629B014-D419-4B23-A052-8454704F2901Q42319910-E834D8F2-6DAB-490B-B515-276BB225F497Q42359116-D431D888-940B-42E8-83D2-8A828150DE2EQ45867059-A4EA5F71-DD6F-47B4-B810-16B104D4DBF7Q45992958-A8C5130E-784B-4E28-BA76-33FC474E39D6Q46550998-1FFBFB0B-CCE2-43A5-A9FF-6021168C24B8Q46902619-7A4221A9-70D1-4288-895B-083631C92423Q47102507-977C0E33-60BA-44FC-A7E6-9B69C3ED2A61Q47131724-8D96C37F-24FF-4A15-A39C-7B7A1B89D05EQ47138089-EA540E61-C14C-4199-ACBF-8C7A7751A638Q47280904-FE72EDBC-6174-4B0D-8231-A490E98C9EA2Q47550896-B3AFE1FF-CC63-42B3-82A9-25A8ABE01C1EQ48145892-C72246D7-80B6-4761-A874-4BA824EC59A0Q48340825-B653DECA-762F-4367-9AAE-1BDBE5CF4D49Q50000807-AA053C9B-3D7D-4707-B9BD-EADB1C8F79E3Q52367517-C6C91124-61BA-4E35-B2E1-16DD337308D0Q52709080-03BAAF7A-73AC-4B5D-ABD1-29A75E751BA9Q53187793-4D60377F-2CC9-47D5-8569-35A7D314C2ABQ55253332-86BB602F-94B6-4D5A-A7A4-6F5B7C3B147CQ55260556-BAC5A55B-662A-4368-826A-1015B86D898FQ57165754-98A8E69D-B83B-4920-9218-C497CCD14F99
P2860
description
2015 nî lūn-bûn
@nan
2015 թուականի Ապրիլին հրատարակուած գիտական յօդուած
@hyw
2015 թվականի ապրիլին հրատարակված գիտական հոդված
@hy
2015年の論文
@ja
2015年論文
@yue
2015年論文
@zh-hant
2015年論文
@zh-hk
2015年論文
@zh-mo
2015年論文
@zh-tw
2015年论文
@wuu
name
Epigenetic mechanisms of chronic pain
@ast
Epigenetic mechanisms of chronic pain
@en
Epigenetic mechanisms of chronic pain
@nl
type
label
Epigenetic mechanisms of chronic pain
@ast
Epigenetic mechanisms of chronic pain
@en
Epigenetic mechanisms of chronic pain
@nl
prefLabel
Epigenetic mechanisms of chronic pain
@ast
Epigenetic mechanisms of chronic pain
@en
Epigenetic mechanisms of chronic pain
@nl
P2093
P2860
P3181
P1476
Epigenetic mechanisms of chronic pain
@en
P2093
Daigo Ikegami
Giannina Descalzi
Minoru Narita
Venetia Zachariou
P2860
P304
P3181
P356
10.1016/J.TINS.2015.02.001
P407
P577
2015-04-01T00:00:00Z