Kyushu University Academic Staff Educational and Research Activities Database
List of Presentations
MAMI NODA Last modified date:2019.06.21

Associate Professor / Laboratory of Pathophysiology / Department of Pharmaceutical Health Care and Sciences / Faculty of Pharmaceutical Sciences


Presentations
1. Mami Noda, How to prevent age-related neurological disorders:
Importance of hormone balance and easy life style habit
, First Purple Mountain International Health Conference in Nanjing, 2019.06.
2. Mami Noda, Cellular mechanisms of neuropsychiatric symptoms induced by thyroid dysfunction, Baikal Neuroscience Meeting-2019, 2019.06.
3. Mami Noda, Gastrointestinal hormone-related effects of molecular hydrogen in neuroprotection., 2nd ISHMB (International Society for Hydrogen Medicine and Biology) , 2019.05.
4. Mami Noda, Cellular mechanisms of neuropsychiatric symptoms induced by thyroidism in mouse model, VII INTERNATIONAL SYMPOSIUM “INTERACTION OF THE NERVOUS AND IMMUNE SYSTEMS IN HEALTH AND DISEASE”, 2019.05.
5. Mami Noda, Sex- and age-dependent effects of thyroiditis on microglia and brain function, FAOPS 2019 , 2019.03, [URL].
6. Mami Noda. Tetsushi Niiyama, Cellular mechanism of neuropsychiatric symptom induced by thyroid dysfunction, International Conference on Biology and Medical Science (ICBMS, 2019.02.
7. Tetushi Niiyama, Kosuke Aoi, Mami Noda, Changes in glial morphology in the brain and animal behavior in hypothyroidism model mice, International Conference on Biology and Medical Sciences (ICBMS 2019), 2019.02.
8. Mami Noda, Microenvironment and immune evasion in the brain metastasis of lung cancer., Cold Spring Harbor Asia - Novel Insights into Glia Function and Dysfunction, 2018.12.
9. Mami Noda, Sex- and age-dependent effect of thyroid hormone on brain function and possible cross talk with the effect of Hsub>2, 2018.11.
10. Mami Noda, True and false: Effects of H2 in health and disease, 2018.11.
11. Mami Noda, Neuroprotective effects of molecular hydrogen: immunohistochemical studies., IV International Scientific conference on «POSTGENOMIC TECHNOLOGIES: FROM THEORY TO PRACTICE», 2018.10.
12. Mami Noda, Protective and preventive effects of molecular hydrogen against neurodegenerative disorders., The 1st International Conference on Hydrogen Medicine and Biology, 2018.10.
13. Mami Noda, Neuroprotective effects of molecular hydrogen and involvement of stomach-brain interaction, 2018.10.
14. Mami Noda, Glial biology and basic and clinical study using a new medical gas, molecular hydrogen (H2), in neurological diseases., AMED-RSF Workshop For the development of collaboration between the two countries in clinical neurosciences , 2018.09.
15. Mami Noda, Neuron-glia interaction and sex-dependent animal behaviors in thyroid dysfunction, Mini-symposium at Slovenian Academy of Sciences and Arts, 2018.08.
16. Mami Noda, Yusaku Yoshioka, Tetsuhi Niiyama, Sex-dependent effects of hypothyroidism in glial morphology and animal behavior, FENS(The Federation of European Neuroscience Societies), 2018.07, Thyroid hormones (THs) are essential for the development and function of the central nervous system (CNS). In the CNS, circulating thyroxine (T4) crosses blood-brain barrier via specific transporters and is taken up to astrocytes, becomes L-tri-iodothyronine (3, 3’, 5–triiodothyronine; T3), an active form of TH, by type 2 de-iodinase (D2). T3 is released to the brain parenchyma from astrocytes (glioendocrine system). In adult CNS, both hypo- and hyper-thyroidism, the prevalence in female being >10 times higher than that in male, may affect psychological condition, for example depression, and potentially increase the risk of cognitive impairment and neurodegeneration including Alzheimer’s disease (AD). We previously reported that non-genomic effects of T3 on microglial functions and its signaling (Mori Y. et al., Glia 63, 906–920, 2015) and sex- and age-dependent effects of THs on glial morphology in the mouse brains of hyperthyroidism (Noda M. Front. Cell. Neurosci. 9:194, 2015; Noda M. et al., OM&P. 2, 85-92, 2016). Here we report that hypothyroidism also induces sex-dependent changes in glial morphology and animal behavior. These results may help to understand physiological and/or pathophysiological functions of THs in the CNS and how hypothyroidism affect behavioral and psychological conditions in sex-dependent manner. Acknowledgement; We appreciate technical help by Research Support Center (Graduate School of Medical Sciences, Kyushu University)..
17. Mami Noda, Kyota Fujita, Margaret A. Hamner, Bruce R. Ransom, PROTECTIVE EFFECTS OF MOLECULAR HYDROGEN AGAINST ISCHEMIC INJURY, 5th European Section meeting of the International Academy of Cardiovascular Sciences (IACS-ES); Advances ın cardıovascular research: from basic mechanisms to therapeutic strategies, 2018.05.
18. Mami Noda., Neuron-glia interaction and sex-dependent animal behaviors in a mouse model of hyperthyroidism., Symposium of Neuro-Glial Interaction, 2018.04.
19. 野田 百美、小林 亜衣, ニコチンはα7アセチルコリン受容体を介してミクログリアのプロトンチャネル活性化を抑制する, 第95回日本生理学会大会, 2018.03.
20. Mami Noda, Miki Yamamoto, Soichi Takiguchi, Mechanism of immune evasion in a mouse model of brain metastasis of lung cancer, 第95回日本生理学会大会, 2018.03.
21. Mami Noda, Possible influence of Orexin in the brain via microglial functional changes., 13th International Symposium on VIP, PACAP, and Related Peptides, 2017.12.
22. Mami Noda, Neuroprotective effects of molecular hydrogen and involvement of stomach-brain interaction, Krasnoyarsk State University Lecture, 2017.11.
23. Mami Noda, Oxidative stress-resistant effects of molecular hydrogen in a mouse model of Parkinson’s disease., "The Molecular Hydrogen 10th Year Anniversary Conference", 2017.09.
24. Mami Noda, Thyroid hormone-regulated neuron-glia interaction in young adult mice and their sex-dependent behavior., MDC seminar, 2017.08.
25. Mami Noda, Neuroprotective and oxidative stress-resistant effects of molecular hydrogen in a mouse model of Parkinson’s disease., University College London (UCL) seminar, 2017.07.
26. Mami Noda, Yusaku Yoshioka, Yosuke Kitahara, Akinori Nishi. , Sex-dependent effect of thyroid hormone in glial-neuronal interaction and animal behavior. , XIII European meeting on glial cells in health and disease. , 2017.07.
27. Mami Noda, Yusuke Yoshii, Taikai Inoue, Yusaku Iwasaki, Toshihiko Yada, Yusaku Nakabeppu. , Complexity of stomach-brain interaction induced by molecular hydrogen in Parkinson’s disease model mice (パーキンソン病モデルマウスにおける分子状水素の複雑な胃―脳連関), 第40回日本神経科学大会(Neuro2017), 2017.07.
28. Mami Noda, Glioendocrine system and neurological dysfunctions., Mediterranean Neuroscience Society 6th Conference 2017, 2017.06.
29. Mami Noda, NEUROPROTECTION BY MOLECULAR HYDROGEN IN PARKINSON’S DISEASE. , VI INTERNATIONAL SYMPOSIUM “INTERACTION OF THE NERVOUS AND IMMUNE SYSTEMS IN HEALTH AND DISEASE”, 2017.06.
30. Mami Noda, Yusaku Yoshioka, Yosuke Kitahara, Akinori Nishi., Thyroid hormone and glioendocrine system in neurological and psychiatric dysfunctions., Cold Spring Harbor Asia - Novel Insights into Glia Function and Dysfunction, 2016.12.
31. Mami Noda, Effects of thyroid hormones in neuron-glia interaction and their sex- and age-dependency., Russian Pathophysiology Society, 2016.12.
32. Mami Noda, Neuroprotective effects of molecular hydrogen and involvement of stomach-brain interaction., A programme of workshop: «The results and perspectives of common investigations of Kyushu University (Fukuoka, Japan) and FSBSI «IEM», Saint-Petersburg, Russia, 2016.12.
33. Jiadai Liu, Satoko Naoe, Taishi Jodoi, Miki Yamamoto, Soichi Takiguchi, Mami Noda. , Interaction between glia cells and lung cancer cells in the progression of brain metastases., Cold Spring Harbor Asia - Novel Insights into Glia Function and Dysfunction, 2016.12.
34. Mami Noda, The latest research trends of hydrogen in Japan - Neuroprotective effects of molecular hydrogen and involvement of stomach-brain interaction., 2016 Korea International Symposium on Hydrogen, 2016.11.
35. Mami Noda, Ai Kobayashi. , Neuroprotective effect of nicotine by inhibition of microglial proton currents via α7 nAChR. , Society for Neuroscience, 46th Annual Meeting., 2016.11.
36. Mami Noda, Yusaku Yoshioka, Yosuke Kitahara, Takahide Shuto, Keisuke Ohta, Kei-ichiro Nakamura, Akinori Nishi, An increase in dendritic spine density in the hippocampus and alterations of sex-dependent animal behaviors in a mouse model of hyperthyroidism. , Society for Neuroscience, 47th Annual Meeting. , 2016.11.
37. MAMI NODA, Ai Kobayashi, Nicotine-induced inhibition of activated microglia and neuroprotection., The 13th Korea-Japan Joint Symposium of Brain Sciences, and Cardiac and Smooth Muscle Sciences, 2016.08.
38. MAMI NODA, Yusaku Yoshioka, Effects of thyroid hormones in neuron-glia interaction., Volga Neuroscience 2016, 2016.07.
39. Mami Noda, Chieri Higashi, Ayaka Fukuo, Jiadai Liu, Neuroprotective effect of molecular hydrogen on ischemic injury in diabetic model mice. , 第39回日本神経科学大会, 2016.07.
40. MAMI NODA, Physiology of microglia., Guangxi University of Chinese Medicine Seminar , 2016.07, [URL].
41. MAMI NODA, Neuroprotective effects of molecular hydrogen; Innovation by a new medical gas, Guangxi University of Chinese Medicine, Seminar in Hospital , 2016.07, [URL].
42. MAMI NODA, Chieri Higashi, Jiadai Liu, Neuroprotective effect of molecular hydrogen in diabetic mouse model., 10th FENS Forum of Neuroscience, 2016.07.
43. MAMI NODA, Glia-endocrine system and neurological disorders., 22nd Scientific Conference, Society on NeuroImmune Pharmacology (SNIP), 2016.04.
44. MAMI NODA, Session 1. Perception, Cognifive, Motor Control and Social Behavior (group discussion), International workshop on “the future of primate neuroscience”., 2016.03.
45. MAMI NODA, Yusuke Yoshii, Taikai Inoue, Multiple Effects of Molecular Hydrogen and its Distinct Mechanism., 6th International Society of Radiation Neurology (ISRN) Conference, 2016.02.
46. MAMI NODA, Possible interaction of thyroid hormones and polyamines in microglia., “Glial Interactions and Brain Experiments” International CaribeGLIA-6 Symposium., 2016.01.
47. MAMI NODA, Jiadai Liu, Yusuke Yoshii, Yusaku Yoshioka, Impact of thyroid hormone on glial function and morphology., Society for Neuroscience, 45th Annual Meeting. , 2015.10.
48. Jiadai Liu, Satoko Naoe, Taishi Jodoi, Soichi Takiguchi, Haruo Iguchi, MAMI NODA, Jiadai Liu, Satoko Naoe, Taishi Jodoi, Soichi Takiguchi, Haruo Iguchi, Mami Noda. Interaction between glia cells and lung cancer cells in microenvironment of brain metastases. (Wuzhen, China, 2015.09.20-23(22)) 6th FAONS: Congress & the 11th Biennial Conference of CNS, 6th FAONS: Congress & the 11th Biennial Conference of CNS, 2015.09.
49. MAMI NODA, Thyroid hormone and glial cells in health and disease. , UOEH (University of Occupational and Environmental Health) Workshop 2015, 2015.09.
50. MAMI NODA, Thyroid dysfunction and glial cells: possible contribution to neurological dysfunctions. , The 3rd Asian Clinical Congress (ACC3) in Tokyo., 2015.09.
51. MAMI NODA, Sex- and age-dependent effect of thyroid hormone on microglia and possible influence on neurodegenerative diseases., The Joint Meeting of the Federation of European Physiological Societies (FEPS) and the Baltic Physiological Societies. , 2015.08.
52. MAMI NODA, Changes in microglial response to glutamate and thyroid hormone in neurodegeneration , 25th ISN (International Society for Neurochemistry) Binneal Meeting., 2015.08.
53. MAMI NODA, Thyroid hormones in glioendocrine system in health and disease., Satellite Meeting in conjunction with the 25th ISN Binneal Meeting – Cairns 2015-, 2015.08.
54. MAMI NODA, Kyota Fujita, Margaret A. Hamner, Yusaku Nakabeppu, Bruce R. Ransom, Protective effects of molecular hydrogen against ischemic injury. In theme “From Basic to Clinical Aspects of Neurology”. , The National Congress of Indonesia Neurological Association VIII and Internationa Symposium, 2015.08.
55. 野田 百美, Mami Noda. Functional change in microglia induced by thyroid dysfunction. Sympoisum (S210a) “Basic and psychological research on microglia” , 第38回日本神経科学大会 (Neuro2015) , 2015.07.
56. MAMI NODA, Microglial dysfunction and neuronal damage in neurodegeneration., International Meeting "Molecular Neurodegeneration - News and Views in Molecular Neuroscience in Health and Disease". , 2015.07.
57. MAMI NODA, Takuma Yoshimura, Liu Jiadai, Yusuke Yoshii, Glioendocrine system of thyroid hormone and its effect on microglia. , XII European Meeting on Glial Cells in Health and Disease (EuroGLIA 2015), 2015.07.
58. MAMI NODA, Jiadai Liu, Yusuke Yoshii, Yusaku Yoshioka, Glioendocrine system and the involvement in neurological dysfunctions. , Cold Spring Harbor Asia - Novel Insights into Glia Function and Dysfunction, 2015.05.
59. MAMI NODA, Taishi Jodoi, Takuma Yoshimura, Soichi Takiguchi, Haruo Iguchi, Glia-tumor interaction in microenvironment of brain metastases. , 第120回日本解剖学会総会・全国学術集会、第92回日本生理学会大会 合同大会, 2015.03.
60. Fumiya Suematsu, Yuichiro Kojima, Haruhiro Higashida, MAMI NODA, Expression and interaction between CD38 and TRPM2 in microglia., 第120回日本解剖学会総会・全国学術集会、第92回日本生理学会大会 合同大会, 2015.03.
61. MAMI NODA, Yuki Mori, Takuma Yoshimura, Liu Jiadai, Yusuke Yoshii, Sex- and age-dependent effects of thyroid hormones on microglial functions. , Gordon Research Conferences-Glial Biology: Functional Interactions Among Glia & Neurons., 2015.03.
62. MAMI NODA, Neuron-glia interaction via thyroid hormone: An example of glioendocrine system. Neuroglia pathology from basic research to clinical practice., グリアの基礎・臨床研究に関するミニシンポジウム, 2015.02.
63. MAMI NODA, Effects of thyroid hormone in microglial function and their signaling. , The 12th Korea-Japan Joint Symposium of Brain Sciences, Cardiac and Smooth Muscle Sciences., 2015.01.
64. MAMI NODA, Yuichiro Kojima, Fumiya Suematsu, Expression of CD38 and its interaction with TRPM2 in microglia. , International Symposium: CD38-NAD Asian 3 countries Meeting Part II, 2014.11.
65. 野田 百美, Kaoru Beppu, Rolf Sprengel, Dysfunction of AMPA-type glutamate receptors in microglia may cause neurodegeneration. (in Symposium “Revealing the prominent role of neuroglia in neurodegeneration” ), Joint Meeting of the Federation of European Phusiological Societies (FEPS) and the Hungarian Physiological Society, 2014.08.
66. MAMI NODA, Possible role of microglial dysfunction in neurodegenative disorders. , INTERNATIONAL CONGRESS ON NEUROSCIENCE , 2014.06.
67. MAMI NODA, Protective effect of new medical gas against Parkinson’s disease. , INTERNATIONAL CONGRESS ON NEUROSCIENCE , 2014.06.
68. MAMI NODA, Protective Role of Microglia and its Mechanism under Stroke: Na+/Ca2+Exchange-Dependent Microglial Migration, (Symposium “Transporters in Glial Cells as New Therapeutic Targets”) , ASPET (American Society for Pharnacology and Experimental Therapeutics) Annual Meeting at Experimental Biology (EB) 2014., 2014.04.
69. MAMI NODA, Akio Matsumoto, Megumi Yamafuji, Tomoko Tachibana, Yusaku Nakabeppu, Haruaki Nakaya, Stomach-brain interaction induced by oral ‘hydrogen water’ in Parkinson’s disease model animal. , Akio Matsumoto, Megumi Yamafuji, Tomoko Tachibana, Yusaku Nakabeppu, Haruaki Nakaya., 2014.04.
70. MAMI NODA, Expression of CD38 in Different Cell Types in the Hypothalamus and Pituitary., 2014 Jeju CD38 and NAD meeting. , 2014.02.
71. MAMI NODA, Functional role for neuropeptides and their signaling cascades in microglial migration (Sympoium: Neuropeptide Signaling in Cellular Interactions: Toward Future Therapeutics), Society for Neuroscience, 43rd Annual Meeting., 2013.11.
72. MAMI NODA, Therapeutic approach to neurodegenerative diseases by medical gases. , FENS Featured Regional Meeting, 2013.09.
73. MAMI NODA, A new target in the treatment for neuropathic pain induced by nerve injury., The 11thKorea-Japan Joint Symposium of Brain Sciences,and Cardiac and Smooth Muscle Sciences , 2013.09.
74. MAMI NODA, Importance of oligodendrocytes in oxidative stress-resistance in white matter ischemic injury., EuroGlia2013, 2013.07.
75. MAMI NODA, CCL-1 in the spinal cord contributes to neuropathic pain induced by nerve injury., EuroGlia2013, 2013.07.
76. MAMI NODA, Peripheral poly I:C-induced neuroinflammatioin: role of Toll-like receptor 3 (TLR3) in microglia., EuroGlia2013, 2013.07.
77. MAMI NODA, Possible contribution of dysfunction of AMPA-type glutamate receptor in microglia under pathological conditions., eduGLIA, final meeting., 2013.07.
78. 野田 百美, New resistance mechanism of Hydrogen water against oxidative stress in Parkinson’s disease model mice, 第36回日本神経科学大会・第56回日本神経化学会大会・第23回日本神経回路学会, 2013.06.
79. 野田 百美, New resistance mechanism of Hydrogen water against oxidative stress in Parkinson’s disease model mice, 第36回日本神経科学大会・第56回日本神経化学会大会・第23回日本神経回路学会, 2013.06.
80. 野田 百美, “Neuroprotection and slow aging induced by oxidative stress-resistant signaling driven by medical gas”., 第36回日本神経科学大会・第56回日本神経化学会大会・第23回日本神経回路学会大会 , 2013.06.
81. MAMI NODA, ROLE OF OLIGODENDROCYTES IN THE PROTECTIVE EFFECTS OF MOLECULAR HYDROGEN AGAINST WHITE MATTER ISCHEMIC INJURY. , ISN (International Society for Neurochemistry, American Society for Neurochemistry) 24th Biennial Joint Meeting, Glial Sattelite , 2013.04.
82. MAMI NODA, Protective effects of molecular hydrogen against ischemic injury, Trans-Pacific Workshop on Stroke 2012. , 2012.10.
83. MAMI NODA, The relationship between CCL-1 and neuron/glia in the neuropathic pain model., Trans-Pacific Workshop on Stroke 2012., 2012.10.
84. MAMI NODA, Plasmalogen attenuate systemic lipopolysaccharide-induced neuroinflammation and β-amyloid protein in adult mice. , Society for Neuroscience, 42nd Annual Meeting, 2012.10.
85. MAMI NODA, Microglia-derived IL-1β is involved in poly I:C-induced fatigue., Society for Neuroscience, 42nd Annual Meeting,, 2012.10.
86. MAMI NODA, The relationship between CCL-1 and neuron/glia in the neuropathic pain model, Society for Neuroscience, 42nd Annual Meeting, 2012.10.
87. MAMI NODA, Bruce R. Ransom, Molecular hydrogen protects against central nervous system white matter ischemic injury., Society for Neuroscience, 42nd Annual Meeting, 2012.10.
88. MAMI NODA, Oral Epithelial Cells are Osmo-sensitive and regulate epithelial barrier via TRPV4. , Society for Neuroscience, 42nd Annual Meeting, 2012.10.
89. MAMI NODA, Role of glial cells in oxidative stress resistance in neurodegenerative diseases., MNS 2012: 4th CONFERENCE OF THE MEDITERRANEAN NEUROSCIENCE SOCIETY, 2012.09.
90. MAMI NODA, Metastatic lung cancer cells promote microglial phagocytosis and proliferation, APSN-JNS合同神経化学会, 2012.09.
91. MAMI NODA, Physiological properties of microglia: possible role of microglia in mouse hypothalamus and pituitary, 2012.09.
92. 直江 智子, 山藤 芽実, 藤田 慶大, 毛利 優希, 秋元 望, 上土井 太志, 井口 東郎, 野田 百美, Interaction between glial cells and metastatic lung cancer cells in the brain, Kyushu University-Pusan University Joint Seminar・第11回システム創薬リサーチコア研究会 ・第10回薬学研究院若手研究者セミナー , 2012.09.
93. Mechanism of neuroprotective effects of molecular hydrogen in Parkinson's model mice.
94. Effects of thyroid hormone on microglial function.
95. Mechanism of the effect of thyroid hormone on microglial function.
96. Effects of CCL-1 on neuropathic pain.
97. 野田 百美, Mechanism of protective effects of molecular hydrogen against oxidative damage., 2012.06.
98. Interaction between CCL-1 and neuroglia in neuropathic pain.
99. Effects of active form of thyroid hormone on microglial function.
100. Purine2012, [URL].
101. Symposium “Physical Aspect of Medical Science”.
102. Mami Noda1, Satoko Naoe1, Yuki Mohri1, Masataka Ifuku2, Toshihiko Katafuchi, [URL].
103. Effects of thyroid hormone on microglial function.
104. The 10th Japan-Korea Joint Symposium on Brain, Cardiac and Smooth Muscles.
105. Effects of pre-treatment of hydrogen on Parkinson's disease and ischemia model aminals.
106. International Workshop in UOEH 2012.
107. Recovery of oxidative damage by medical gases.
108. The Israel Society for Neuroscience 20th Annual meeting: Israel-Japan Joint Sympoium, [URL].
109. Hydrogen confers resistance to neuronal loss on dopaminergic neurons in mice model of Parkinson’s disease, [URL].
110. Mechanism of inhibition of ATP response in microglia.
111. Minocycline attenuates poly I:C-induced impairment of learning behavior in rats..
112. Effects of thyroid hormone on microglial functions.
113. Bradykinin-, but not ATP- and galanin-induced microglial migration, depends on calcium influx through NCX. , [URL].
114. Neuroprotective effect of hydrogen in Parkinson's disease model mice, [URL].
115. The molecular neurobiology of anti-oxidative stress induced by hydrogen., [URL].
116. Neurotransmitter regulation of microglial motility and phagocytosis.
117. Nicotine inhibits activation of microglial proton currents via interactions with α7 acetylcholine receptors.
118. The relationship between CCL-1 and neuron/glia in the neuropathic pain model..
119. The relationship between CCL-1 and neurons/glial-cells in the neuropathic pain model. , [URL].
120. Relationship between CCL-1 and neuroglia in the development of neuropathic pain.
121. Neuropeptide Receptors in Microglia and their Function..
122. Microenvironment of metastasized tumor cells in the brain. .
123. Neuroprotective effects of hydrogen on MPTP-induced neurotoxicity.
124. Polyriboinosinic : polyribocytidylic acid (PolyI:C)-induced chronic fatigue.
125. Effects of thyroid hormone on microgilal function.
126. Role of GluR2 Subunit of AMPA-type of Glutamate Receptor in Microglia .
127. Brain metastasis of lung cancer and microenvironment in the brain.
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128. Interaction between lung cancer cells and glial cells in brain metastasis..
129. Glutamate receptors in microglia and their loss of function in pathologic conditions. .
130. Activation of microglia is important in polyinosinic-polycytidylic acid (poly I:C)-induced fatigue.
131. Immunologically induced fatigue and glial cells..
132. Role of GluA2 (GluR-B) subunits of AMPA type of glutamate receptor in microglia. .
133. Activation of microglia is important in polyinosinic-polycytidylic acid (poly I:C)-induced fatigue. .
134. Physiological role of GluR2 subunits of AMPA type of Glutamate Receptor in Microglia and pathophysiological implication. .
135. Chemotactic cytokine ligand-1 (CCL-1) contributes to neuropathic pain in mice. .
136. Protective effect of hydrogen on neurodegeneration.
137. Effect of nicotine on proton channel in microglia.
138. Interaction between chemotactic cytokine ligand-1 (CCL-1) and chronic pain.
139. Molecular hydrogen as medical gas; anti-oxidant and ROS-resistant effects in the nervous system..
140. Chemotactic cytokine ligand-1 (CCL-1) contributes to neuropathic pain in mice. .
141. Involvement of glial cells in the development of fatigue.
142. Neuroprotective role of hydrogen on MPTP-induced neurotoxiciy.
143. Gas mediator hydrogen as a tool for protection of Parkinson's disease..
144. Involvement of chemotactic cytokine ligand-1 (CCL-1) in induction of chronic pain and neuron-glia interaction.
145. Hydrogen gas has protective effects on animal model of Parkinson's disease. .
146. Role of microglia in chronic fatigue.
147. Involvement of chemotactic cytokine ligand-1(CCL-1) in neuropathic pain.
148. Effects of hydrogen on Parkinson's disease model animal.
149. Functional role of GluR2 in AMPA-type of glutamate receptor in microglia.
150. Molecular hydrogen as antioxidant: Expectation and improvement of "Medical hydrogen".
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151. Molecular and genetic analyses of neurodegeneration
神経変性疾患の治療薬および予防薬の分子・遺伝子レベルにおける評価法.
152. Function of AMPA-type of glutamate receptors in microglia.
153. Different cellular mechanisms in microglial migration induced by ATP and neuropeptides.
154. Bradykinin-induced incrase in microglial motility and chemotaxisis due to the activation of B1 receptors and Na/Ca exchange system.
155. Oppsite effect of glial cells in the brain metastasis of lung cancer cells.
156. Mechanism of assembling of the brain immune cells to lesion sites.
157. Bradykinin-induced increase in microglial motillity and chemotaxis via Na/Ca exange system.
158. Neuroprotective role of kinin via glial cells in the central nervous system
Mami Noda, Kenjiro Sasaki, Toshihiro Seike, Masataka Ifuku, Bing Wang, Keiji Wada.
159. Neurotensin receptor type-1 impair the LTP gated by dopamine D2 receptor in the basolateral amygdala
Taiju Amano, Etsuko Wada, Mami Noda, Keiji Wada, Masayuki Sekiguchi
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160. Interaction of cancer cells with glial cells in microenvironment of brain metastasis..
161. Deficient of neurotensin receptor type-1 (NTR1) facilitates LTP in basolateral amygdala.
162. Bradykinin-induced microglial migration mediated by B1-type of bradykinin receptors depends on Ca2+ influx via reverse mode of Na+/Ca2+ exchanger.
163. Interaction between cancer cells and microenvironment in the brain: the role of astrocytes.
164. The processes of adaptation of microglia in brain trauma and metasitasis..
165. Inhibition of ATP-induced inward current by docosahexaenoic acid in rat nodose ganglion neurons.
166. The mechanism of bradykinin B1 receptor-induced microglial migration and chamotaxis.
167. Kinin-induced microglial migration and anti-inflammatory effects in the central nervous system..
168. Protective effects of kinins via microglia in the brain..
169. Enhancement of amygdala LTP in neurotensin receptor type-1 knockout mice; participation of the dopamine system.
170. A possible role of parkin in neurotransmission; potentiation of P2X receptor channels..
171. Facilitation of glutamate release by antidepressant drugs in rat locus ceruleus..
172. deltaFosB determines resistance to excitotoxicity induced by kainic acid..
173. The role of microglia and astrocytes in brain metastasis of lung-cancer.
174. Bradykinin-induced motility and migration of microglia via B1 receptor.
175. BK-induced migration of microglia.
176. Expression and function of KCNQ channels in microglia.
177. Tricyclic antidepressant desipramine induced glutamate release from presynaptic nerve terminals.
178. A possible role of parkin and ubiquitin carboxy-terminal hydrolase L1 in neurotransmission; potentiation of P2X receptor channels.
179. The role of microglia in brain metastases: a study using the lung-cancer metastatic model.
180. Effects of parkin and alpha-synuclein on P2X receptor-induced responses.
181. Establishment of new animal model for Parkinson's disease using I193M mutant UCHL-1.
182. The role of UCH-L1 in neural differencitaion.
183. Anti-inflammatory effects of BK in microglia..
184. Characters of KCNQ channels in microglia..
185. Effects of non-narcotic antitussives on 5-HT(3)-receptor-mediated currents in acutely isolated rat nodose ganglion neurons..
186. Functional importance of Ca2+-activated K+ channels for bradykinin-induced microglial migration..
187. Tricyclic antidepressnat desipramine facilitated glutamate release from presynaptic nerve terminals..
188. Microglia: a sensor for pathology and immune system in the central nervous system..
189. Activation of Ca2+-dependent K+ channels is essential for bradykinin-induced microglial migration.
190. Physiological and molecular biological characterization of KCNQ channels in neuron and glia..
191. Anti-inflammatory effects of kinins via microglia in the central nervous system..
192. Protein kinase C bound with A-kinase anchoring protein in muscarinic or bradykinin receptor-activated modulation of M-type KCNQ potassium channels..
193. Anti-inflammatory effects of kinins in microglia, an immune cell in the central nervous system..
194. Bradykinin-induced microglial motility and its mechanism.
195. AMPA-type of glutamate receptors in microglia..
196. Potentiation of ATP-induced currents due to the activation of P2X receptors by parkin..
197. Potentiation of ATP-induced currents due to the activation of P2X receptors by parkin..
198. Potentiation of ATP-induced currents due to the activation of P2X receptors by parkin..
199. Potentiation of ATP-induced currents due to the activation of P2X receptors by parkin..
200. Membrane translocation of GluR2 and inhibition of glutamate-induced
inward currents in activated microglia.
201. Cyclic ADP ribose coupled to 5-HT receptors in glial cells.
202. Membrane translocation of GluR2 and inhibition of glutamate-induced
inward currents in activated microglia.
203. Membrane translocation of GluR2 and inhibition of glutamate-induced
inward currents in activated microglia.
204. Excitatory effect of noradrenalin on cardiac parasympathetic neurons..
205. Effects of bradykinin in the brain: the role of microglia.
206. Effects of bradykinin in the brain: the role of microglia.
207. Excitatory effect of noradrenalin on cardiac parasympathetic neurons..
208. Human 5-HT5A receptors and multiple signal transduction pathways.
209. Electrogenic dopamine transporter in PC12 cells.
210. Regulation of P2X receptor by ubiquitin C-terminal hydrolase 1.
211. Regulation of P2X receptor by ubiquitin C-terminal hydrolase 1.