Publications

原著論文

[82]  DiRienzo, N. and Aonuma H. (2017 accepted) Individual differences are consistent across changes in mating status and mediated by biogenic amines. Behav. Ecol. Sociobiol.

[81]  Shiratori C., Suzuki N., Momohara Y., Shiraishi K., Aonuma H., and Toshiki Nagayama. (2017 accepted) Cyclic AMP-regulated opposing and parallel effects of serotonin and dopamine on phototaxis in the Marmorkrebs (marbled crayfish). Europ. J. Neurosci.

[80]  Aonuma H., Kaneda M., Hatakeyama D., Watanabe T., Lukowiak K. and Ito E. (2017) Weak involvement of octopamine in aversive taste learning in a snail. Neurobiol. Learn. Mem. 141: 189-198.

[79]  Matsuzaka Y., Sato E., Kano T., Aonuma H. and Ishiguro A. (2017) Non-centralized and functionally localized nervous system of ophiuroids: evidence from topical anesthetic experiments, Biol. Open, 6 : 425-438 .

[78] Shimoji H., Aonuma H., Miura T., Tuji K., Sasaki K. and Okada Y. (2017) Queen contact and among-worker interactions dually suppress worker brain dopamine as a potential regulator of reproduction in an ant, Behavioral Ecology and Sociobiology, 71(35) (2017)

[77] Aonuma H., Kaneda M., Hatakeyama D.,  Watanabe T., Lukowiak K. and Ito E. (2016) Relationship between the grades of a learned aversive-feeding response and the dopamine contents in Lymnaea, Biology Open, 5(12) : 1869-1873 (2016)

[76] Matsuo, R. Tanaka M., Fukuta R., Kobayashi S., Aonuma H. and Matsuo Y. (2016) Octopaminergic system in the central nervous system of the terrestrial slug, J. Comp. Neurol. 524 : 3849-3864 (2016).

[75] Ishikawa Y., Aonuma H., Sasaki K. and Miura T. (2016) Tyraminergic and octopaminergic modulation of defensive behaviour in termite soldier. PLoS ONE.

[74]  Ohkawara, K. and Aonuma H. (2016) Changes in the levels of biogenic amines associated with aggressive behavior of queen in the social parasite ant Vollenhovia nipponica. Insectes Sociaux. doi:10.1007/s00040-016-0461-7.

[73] Newland P.L., al Ghamdi M., Sharkh S., Aonuma H. and Jackson C.W. (2015) Exposure to static electric fields leads to changes in biogenic amine levels in the brains of Drosophila. Proc. Roy. Soc. B., doi: 10.1098/rspb.2015.1198.

[72]  Alessi A.M., O'Connor V., Aonuma H. and  Newland P.L. (2014) Dopaminergic modulation of phase reversal in desert locusts. Front. Behav. Neurosci. 8:371, doi: 10.3389/fnbeh.2014.00371.

[71] Kawabata K., Aonuma H., Takahashi S., Hosoda K. and Xue J. (2014) Image-based pose estimation for analyzing cricket-robot interaction behavior. J. Signal Process. 118(3): 135-141.

[70] Okada R., Ikeno H., Kimura T., Ohashi M., Aonuma H. and Ito E. (2014) Error in the honeybee waggle dance improves foraging flexibility. Sci. Rep. 4: 4175, DOI:10.1038/srep04175

[69] Watanabe T. and Aonuma H. (2014) Tissue-specific promoter usage and diverse splicing variants of the found in neurons; an ancestral Hu/ELAV-like RNA binding protein gene of insects, in a direct developing-insect Gryllus bimaculatus. Insect Mol. Biol., 23(1): 26-41.

[68] Kawabata K., Aonuma H., Hosoda K. and Xue J. (2013) Active interaction utilizing micro mobile robot and on-line data gathering for experiments in cricket pheromone behavior. J. Robot. Auton. Syst. 61: 1529-1538. 

[67]  Yano S., Watanabe T., Aonuma H. and Asama H. (2013). Pitchfork bifurcation in a receptor theory-based model of the serotonergic system. Mol. BioSyst. 9: 2079-2084. doi:10.1039/c3mb25033d.

[66]  Sakura M. and Aonuma H. (2013) Aggressive behavior in the antennectomized male cricket Gryllus bimaculatus. J. Exp. Biol. 216 (12): 2221-2228.

[65]  Watanabe T., Sadamoto H. and Aonuma H. (2013) Molecular basis of the dopaminergic system in the cricket Gryllus bimaculatus. Invert. Neurosci., 13: 107-123.

[64]  Kawabata K., Aonuma H., Hosoda K. and Xue J. (2013) A system for automated interaction with the cricket utilizing a micro mobile robot. J. Robot. Mech., 25(2): 333-339.

[63]  Aonuma H. and Watanabe T. (2012) Changes in the content of brain biogenic amine associated with early colony establishment in the queen of the ant, Formica japonica. PLoS ONE 7(8): e43377.doi:10.1371/journal.pone.0043377.

[62] Ito E., Otsuka E., Hama N., Aonuma H., Okada R., Hatakeyama D., Fujito Y. and Kobayashi S. (2012) Memory trace in feeding neural circuit underlying conditioned taste aversion in Lymnaea. PLoS ONE 7(8): e43151. doi:10.1371/journal.pone.0043151 

[61] Yoritsune A. and Aonuma H. (2012 online published) The anatomical pathways for antennal sensory information in the central nervous system of the cricket, Gryllus bimaculatus. Invert. Neurosci.doi:10.1007/s10158-012-0137-6

[60]  Fukumitsu Y., Irie K., Satho T., Aonuma H., Dieng H., Ahmad A.H., Nakashima Y., Mishima K., Kashige N., Miake F. (2012 online published) Elevation of dopamine level reduces host-seeking activity in the adult female mosquito Aedes albopictus. Parasite Vector 5:92 doi:10.1186/1756-3305-5-92

[59] Okada R., Akamatsu T., Iwata K., Ikeno H., Kimura T., Ohashi M., Aonuma H., and Ito E. (2012) Waggle dance effect: dancing in autumn reduces the weight loss of a honeybee colony. J. Exp. Biol. 215: 1633-1641. 

[58] Okada R., Ikeno H., Kimuta T., Ohashi M., Aonuma H. and Ito E. (2012) Mathematical analysis of the honeybee waggle dance. Act. Biol. Hung., 63 (suppl. 2.8): 75-79.

[57] Sakura M., Watanabe T. and Aonuma H. (2012) Aggressive behavior of the white-eye mutant crickets Gryllus bimaculatus. Act. Biol. Hung., 63 (suppl. 2.7): 69-74. 

[56] Aonuma H. and Watanabe T. (2012) Octopaminergic system in the brain controls aggressive motivation in the ant, Formica japonica. Act. Biol. Hung., 63 (suppl. 2.5): 63-68.

[55] Watanabe T. and Aonuma H. (2012) Identification and expression analyses of a novel serotonin receptor gene, 5-HT2β, in the field cricket Gryllus bimaculatus. Act. Biol. Hung., 63 (suppl. 2.6): 58-62.

[54] Yano S., Ikemoto Y., Aonuma H. and Asama H. (2012) Forgetting curve derived by serotonin hypothesis in cricket, Gryllus bimaculatus. Robot. Auton. Syst. 60: 722-728

[53] Kawabata K., Fujii T., Aonuma H., Suzuki T., Ashikaga M., Ota J. and Asama H. (2012) A neuro-modulation model of behavior selection in the fighting behavior of male crickets. Robot. Auton. Syst. 60: 707-713.

[52] Mizuno T., Sakura M., Ashikaga M., Aonuma H., Chiba R. and Ota J. (2012) Model of a sensory-behavioral relation mechanism for aggressive behavior of crickets. Robot. Auton. Syst. 60: 700-706.

[51] Sakura M., Okada R. and Aonuma H. (2011) Evidence for instantaneous e-vector detection in the honeybee using an associative learning paradigm. Proc. Roy. Soc. B., 279: 535-542.

[50] Watanabe T., Sadamoto H. and Aonuma H. (2011) Identification and expression analysis of the genes involved inserotonin biosynthesis and transduction in the field cricket Gryllus bimaculatus. Insect Mol. Biol. 20(5): 619-635.

[49] FunatoT., Nara M., Kurabayashi D., Ashikaga M. and Aonuma H.  (2011) A model for groupsize-dependent behaviour decision in insect using an oscillator network. J. Exp. Biol.214: 2426-2434.

[48] Katsumata A., Yamaoka R. and Aonuma H.(2011) Social interactionsinfluence dopamine andoctopamine homeostasis in the brain of the ant, Formica japonica. J. Exp. Biol.214: 1707-1713.

[47] Guerra R.D., Aonuma H., Hosoda K. and Asada M. (2010) Semi-automatic behavior analysisusing robot/insect mixed society and video tracking. J. Neurosci. Methods.191: 138-144.

[46] Guerra R.D., Aonuma H., Hosoda K. and Asada M. (2010) Behavior change of crickets in a robot-mixed society. J.Rob. Mech. 22(4): 526-531.

[45] Okada R., Ikeno H., Ohashi M., KimuraT.,Aonuma H. and Ito E. (2010)Markov model of honeybee social behavior. Information.13:1115-1113

[44] Ashikaga M.,Sakura M., Kikuchi M., Hiraguchi T., Chiba R., Aonuma H. and Ota J. (2009)Establishment of social status without individual discrimination in the cricket. AdvancedRobotics. 23: 563-578.

[43] Aonuma H., Kitamura Y., Niwa K., Ogawa H. and Oka K. (2008) Nitric oxide-cGMP signaling in the local circuit of the cricket abdominal nervous system. Neuroscience.157: 749-761.

[42] Okada R., Ikeno H., Aonuma H. and Ito E. (2008) Biological insights into robotics: Honeybee foraging behavior by waggle dance. Advanced Robotics. 22(15): 1665-1681.

[41] Ishikawa Y.,Aonuma H. and Miura T. (2008) Soldier-specific modification of the mandibular motor neurons in termites. PLoS ONE3 (7) e2617: 1-8.

[40] Funato T., Kurabayashi D., Nara M. and Aonuma H. (2008) Switching mechanism of sensor-motor coordination through oscillator network model. IEEE Trans. Systems, Man and Cybernetics - Part B. 38 (3):764-770.

[39] Yono O. and Aonuma H. (2008) Cholinergic neurotransmission from mechanosensoryafferents to giant interneurons in the terminal abdominal ganglion of the cricket. Gryllus bimaculatus. Zool. Sci. 25: 517-525.

[38] Sakura M., Hiraguchi T., Ohkawara K., and Aonuma H. (2008) The Compartment structuresof the antennal lobe in the ant Aphaenogaster smythiesi japonica. Acta Biol. Hung. 59: 183-187.

[37] Okada R., Ikeno H., Sasayama N., Aonuma H., Kurabayashi D., and Ito E. (2008) The dance ofthe honeybee: how do they dance to transfer the food information effectively? Acta Biol. Hung. 59:157-162.

[36] Hatakeyama D., Aonuma H., Ito E. and Elekes K. (2007) Localization of glutamate-likeimmunoreactive neurons in the central and peripheral nervous system of the adult anddeveloping pond snail, Lymnaea stagnalis L. Biol. Bull., 213: 172-186.

[35] Ashikaga M., Kikuchi M., Hiraguchi T., Sakura M., Aonuma H. and Ota J. (2007) Foraging task of multiple mobile robots in a dynamic environment using adaptive behavior in crickets. J. Robot. Mech., 19(4): 446-473.

[34] Kawabata K., Fujiki T., Ikemoto Y., Aonuma H. and Asama H. (2007) A neuromodulation model for adaptive behavior selection of the cricket. J. Robot. Mech., 19(4): 388-394.

[33] Tsuji E., Aonuma H., Yokohari F. and Nishikawa M. (2007) Serotonin-immunoreactiveneurons in the antennal sensory system of the brain in the carpenter ant, Camponotus japonicus. Zool. Sci., 24, 836-849

[32] Iwasaki M., Nishino H., Antonia D. and Aonuma H. (2007) Effects of NO/cGMP signalling onthe behavioural change in subordinate male crickets,Gryllus bimaculatus. Zool. Sci., 24: 860-868

[31] Ott S. R., Aonuma H., Newland P.L. and Elphick M.R. (2007) Nitric oxide synthase in crayfishwalking leg ganglia: segmental differences in chemo-tactile centers argue against a generic rolein sensory integration. J. Comp. Neurol., 501: 381-399.

[30] Watanabe T., Kikuchi M., Hatakeyama D., Shiga T., Yamamoto T., Aonuma H., Takahata M.,Suzuki N. and Ito E. (2007). Gaseous neuromodulator-related genes expressed in the brain of honeybee Apis mellifera. Develop. Neurobiol., 67: 456-473.

[29] Matsumoto Y., Unoki S., Aonuma H. and Mizunami M. (2006) Nitric oxide-cGMP signaling is critical for cAMP-dependent long-term memory formation. Learn. Mem., 13(1): 35-44.

[28] Wagatsuma A., Azami S., Sakura M., Hatakeyama D., Aonuma H. and Ito E. (2006). De novo synthesis of CREB in a presynaptic neuron is required for synaptic enhancement involved in memory consolidation. J. Neurosci. Res., 84: 954-960.

[27] Delago A. and Aonuma H. (2006). Experience based agonistic behavior in female crickets, Gryllus bimaculatus. Zool. Sci. 23: 775-783.

[26] Iwasaki M., Delago A., Nishino H. and Aonuma H. (2006). Effects of previous experiences on the agonistic behaviour of male crickets Gryllus bimaculatus. Zool. Sci., 23: 863-872.

[25] Niwa K., Sakai J., Karino T., Aonuma H., Watanabe T., Ohyama T., Inanami O. and KuwabaraM. (2006) Reactive oxygen species mediate shear stress-induced fluid-phase endocytosis invascular endothelial cells. Free Radical Res., 40 (2): 167-174.

[24] Nagamoto J., Aonuma H. and Hisada M. (2005) Discrimination of conspecific individuals via cuticular pheromones by males of the cricket Gryllus bimaculatus. Zool. Sci., 22: 1079-1088.

[23] Seki Y., Aonuma H. and Kanzaki R. (2005) Pheromone processing center in the protocerebrum of Bombyx mori revealed by nitric oxide-induced anti-cGMP immunocytochemistry. J. Comp. Neurol., 481: 340-351.

[22] Sadamoto H., Sato H., Kobayashi S., Murakami J., Aonuma H., Ando H., Fujito Y., Hamano K.,Awaji M., Lukowiak K., Urano A. and Ito E. (2004) CREB in the pond snail Lymnaea stagnalis:Cloning, gene expression and function in identifiable neurons of the central nervous system. J.Neurobiol., 58(4): 455-466.

[21] Nagayama T., Kimura K., Araki M., Aonuma H. and Newland P.L. (2004) Distribution of glutamatergic immunoreactive neurons in the terminal abdominal ganglion of the crayfish, J.Comp. Neurol., 474(1): 123-135.

[20] Schuppe H., Araki M., Aonuma H., Nagayama T. and Newland P.L. (2004) Effects of nitric oxide on proprioceptive signaling. Zool. Sci., 21(1): 1-5.

[19] Aonuma H. and Niwa K. (2004) Nitric oxide regulates the levels of cGMP accumulation in the cricket brain. Act. Biol. Hung., 55(1-4): 65-70.

[18] Aonuma H. (2002) Distribution of NO-induced cGMP-like immunoreactive neurones in the abdominal nervous system of the crayfish, Procambarus clarkii. Zool. Sci., 19: 969-979.

[17] Aonuma H. and Newland P.L. (2002) Synaptic inputs onto spiking local interneurons in crayfish are depressed by nitric oxide. J. Neurobiol., 52: 144-155.

[16] Fujie S., Aonuma H., Ito I., Gelperin A. and Ito E. (2002) The nitric oxide/cyclic GMP pathway in olfactory processing system of the terrestrial slug Limax marginatus. Zool. Sci., 19: 15-26.

[15] Schuppe H., Aonuma H. and Newland P.L. (2001) Distribution of NADPH-diaphorase- positive ascending interneurones in the crayfish terminal abdominal ganglion. Cell Tissue Res., 305: 135-146.

[14] Schuppe H., Aonuma H. and Newland P.L. (2001) NADPH-diaphorase histochemistry in the terminal abdominal ganglion of the crayfish. Cell Tissue Res., 303: 289-299.

[13] Aonuma H. and Newland P.L. (2001) Opposing actions of nitric oxide on synaptic inputs of identified interneurones in the central nervous system of the crayfish. J. Exp. Biol., 204: 1319-1332.

[12] Aonuma H., Nagayama T. and Takahata M. (2000) Modulatory effect of nitric oxide on the synaptic depression of the crayfish neuro-muscular system. J. Exp. Biol., 203: 3595-3602.

[11] Aonuma H. and Nagayama T. (1999) GABAergic and non-GABAergic spiking interneurones of local and intersegmental groups in the crayfish terminal abdominal ganglion. J. Comp. Neurol.,410(4): 677-688.

[10] Aonuma H., Nagao T., Nagayama T. and Takahata M. (1999) Modulatory effects of amino acids upon the neuromuscular transmission in the crayfish fast flexor muscle. J. Exp. Zool., 283: 531-540.

[9] Aonuma H., Newland P.L. and Nagayama T. (1999) Processing of proprioceptive signals by ascending interneurones in the terminal abdominal ganglion of the crayfish. J. Exp. Biol., 202:2975-2984.

[8] Aonuma H., Nagayama T. and Takahata M. (1998) L-glutamate as an excitatory transmitter of motor giant neurons in the crayfish Procambarus clarkii. J. Crust. Biol., 18: 243-252.

[7] Nagayama T., Aonuma H. and Newland P.L. (1997) Convergent chemical and electricalsynaptic inputs from proprioceptive afferents onto an identified intersegmental interneuron in the crayfish. J. Neurophysiol., 77: 2826-2830.

[6] Nagayama T., Namba H. and Aonuma H. (1997) Distribution of GABAergic premotor nonspikinglocal interneurones in the terminal ganglion of the crayfish. J. Comp. Neurol., 389: 139-148.

[5] Newland P.L., Aonuma H. and Nagayama T. (1997) Monosynaptic excitation of lateral giant fibers by proprioceptive afferents in the crayfish. J. Comp. Physiol., 181: 103-109.

[4] Aonuma H., Nagayama T. and Takahata M. (1996) Distribution of autofluorescent cell bodies in the nervous system of the crayfish. J. Exp. Zool., 275: 406-412.

[3] Nagayama T., Aonuma H. and Miyata H. (1996) GABA-like immunoreactivity of an identified nonspiking local interneurone in the crayfish terminal abdominal ganglion. J. Exp. Biol., 199(11):2447-2450.

[2] Newland P.L., Aonuma H., Sato M. and Nagayama T. (1996) Presynaptic inhibition of exteroceptive afferents by proprioceptive afferents in the terminal abdominal ganglion of the crayfish. J. Neurophysiol., 76: 1047-1058.

[1] Aonuma H., Nagayama T. and Hisada M. (1994) Output effect of identified ascending interneurons upon the abdominal postural system in the crayfish Procambarus clarkii (Girard). Zool. Sci., 11: 191-202.


学術論文(日本語)

[6] 高橋悟,奥田泰丈,川端邦明,青沼仁志,佐藤雄隆,岩田健司 (2016) クロコオロギの行動解析に向けた動画像計測手法 (英語表題:Method of dynamic image measurement for analyzing of cricket behavior).  J. Signal Processing「信号処理」. 20 (2): 65-74.

[5]  小林充,片岡崇,青沼仁志,柴田洋一 (2015) ヨトウガの性フェロモンに対する触角電位応答. (英語表題:Response of the bioelectric potential within antenna of Mamestra Brassicae against sex pheromone). 農業食料工学誌, 77(3): 179-185.

[4] 古橋一憲, 北川善政, 赤坂司, 亘理文夫, 青沼仁志 (2013) ヒト上皮3次元培養組織モデルを用いた生体材料‐軟組織間の封鎖性評価.北海道外科雑誌,58(1) 87-88.

[3] 川端 邦明,藤井 喬,鈴木 剛,青沼 仁志,太田 順,淺間 一 (2012) 相互作用効果ダイナミクスを持つ行動切り替えモデルによるマルチ・エージェント掃引作業 (英語表題:Sweeping task of multiple mobile agents by utilizing behavior selection model with interaction-based efficacy dynamics) 機械学会論文集78(792): 3028-3032.

[2] 舩戸徹郎,倉林大輔,奈良維仁,青沼仁志 (2007) 振動子網を用いた行動遷移メカニズムの考察. 物性研究, Vol. 87, No. 4, pp. 579-582. 

[1] 中山 由佳子,河原 剛一,青沼 仁志,山内 芳子,中島 崇行,鉢呂 健 (2004) 培養心筋細胞内Ca2+振動の細胞間同期とそのメカニズムの解析,電子情報通信学会技術研究報告,2: 41-44.


解説・総説・著書等

[22]  Sakai R., Shimizu M., Aonuma H. and Hosoda K. (2015) Visualizing wakes in swimming locomotion of Xenopus-Noid by using PIV. in Biomimetic and Biohybrid Systems. (Eds: Wilson S.P., Verschure P. F.M.J., Mura A. and Prescott T.J.) Springer pp. 97-100.

[21]  Aonuma H., Sakura M. and Kurabayasi D. (2015) Memory mediated by internal state: memory of lost suppresses motivation of fight in the cricket. in Memory Consolidation. (Eds: Sakakibara M. and Ito E) Nova Science Publisher. pp38-52.

[20]  Sakai R., Shimizu M., Aonuma H. and Hosoda K. (2014) Swimming Locomotion of Xenopus Laevis Robot. in Biomimetic and Biohybrid Systems, Lecture Notes in Computer Science Volume 8608, 2014, Springer International Publishing: 420-422.

[19] 青沼 仁志 (2014) モデル構築とロボット実装による昆虫の適応行動を創り出すからくりの理解,日本画像学会誌 特集 “Advanced Technology”. 53(3): 207-215.

[18] 青沼 仁志 (2011) 特集 II.新たな臨床・研究発展に向けて-異分野との連携をさぐる- コオロギの世界から発達障害・社交障害をみる. 精神科(科学評論社)18(5): 353-541

[17]  青沼仁志,太田順  (2010)  シリーズ移動知.第4巻:社会適応-発現機構と機能障害.第1章:生物の社会適応機能の解明に向けて.第2章:行動選択-コオロギは集団内でどのように振る舞うか?(太田順・青沼仁志 共編)オーム社pp. 1-72.

[16] 青沼仁志  (2009) シリーズ「動物の多様な生き方」.第4巻「動物は何を考えているか?:学習と記憶の比較生物学」第6章:昆虫の記憶・学習と神経可塑性.(曽我部正博編)共立出版

[15] 青沼仁志,佐倉 緑 (2009)  身近な動物を使った学実験.コオロギの交尾行動と喧嘩行動の観察. (鈴木範男編)三共出版

[14] 青沼仁志  (2008) 昆虫ミメティクス-昆虫の設計に学ぶ.第4章:コントローラー 第3節昆虫の適応的行動選択.(監修 下澤楯夫 針山孝彦)pp. 445-455エヌ・ティー・エス企画

[13] Ota J., Aonuma H., Asama H., Kawabata K and Ashikaga M., (2008) Modeling of adaptive mechanism in crickets by means of constructive approach, Workshops/Tutorials Proceedings of the 2008 IEEE/RSJ International Conference on Intelligent Robots and Systems, Workshop: Mobiligence: Adaptive Motor Function through Dynamic Interactions among the Body, Brain and Environment, 54-59

[12] Ikeno H., Kanzaki R., Aonuma H., Takahata M., Mizunami M., Yasuyama K., Matsui N., Yokohari F. and Usui S. (2008) Development of invertebrate brain platform: Management of research resources for invertebrate neuroscience and neuroethology. inProceedings of 14thInternational Conference on Neural Information Processing 2007: Part II, LNCS 4985, (Eds.Ishikawa M. et al.) Springer-Verlag Berlin Heidelberg. pp.905-914

[11] 青沼仁志,長尾隆司,太田 順,川端邦明,浅間一 (2007) 社会的適応行動の動的モデリングと工学応用―コオロギの喧嘩行動を対象として―,計測と制御 特集号「移動知:生物の社会適応機能の解明とその工学的応用 46 (12) 903-909.

[10] 淺間 一,青沼仁志,太田 順,千葉 龍介 (2007) 移動知と社会適応,計測と制御 特集号「移動知:生物の社会適応機能の解明とその工学的応用」46 (12) 885-886.

[9] 岡田 龍一,池野 英利,青沼仁志,倉林 大輔,伊藤 悦朗 (2007) 社会的適応行動から学ぶ情報共有システムの構築 -ミツバチの8の字ダンスを対象として-,計測と制御 特集号「移動知:生物の社会適応機能の解明とその工学的応用」46 (12) 916-921.

[8] 淺間 一,神崎 亮平,青沼仁志,三浦 徹,倉林 大輔,太田 順 (2007) 座談会:生物の社会適応機能の解明その工学的応用,計測と制御 特集号「移動知:生物の社会適応機能の解明とその工学的応用」46 (12) 951-957.

[7] 舩戸徹郎,倉林大輔,奈良維仁,青沼仁志 (2007)振動子網を用いた行動遷移メカニズムの考察.物性研究, Vol. 87, No. 4, pp. 579-582.

[6] 青沼仁志 (2006)第21章 COE成果本 基礎編 IV-3個体のバイオサイエンス.昆虫の適応行動の発現機構から学ぶナノとバイオの融合. Pp. 287-306.北大出版会

[5] 青沼仁志 (2005)昆虫に見る行動の動的選択機構.計測と制御, 44(9): 621-627.

[4] 青沼仁志 (2005)昆虫の行動決定にかかわる神経機構.日本ロボット学会誌, 23(1): 6-10.

[3] Aonuma H. and Newland P.L. (2001) The action of nitric oxide and cGMP on intersegmental interneurones in the crayfish terminal abdominal ganglion. in The Crustacean Nervous System (Ed. Wiese K.), Springer-Verlag Berlin Heidelberg. pp. 305-312.

[2] Newland P.L., Nagayama T. and Aonuma H. (2000) The role of proprioceptive signals in the crayfish escape circuit. Zool. Sci., 17: 1185-1195.

[1] Nagayama T., Namba H. and Aonuma H. (1994) Morphological and physiological bases of crayfish local circuit neurons. Histol.Histopathol., 9: 791-805


国際会議の発表でProceedingとして出版された論文 (査読あり)

[25] Kawabata K., Aonuma H., Hosoda K., Sugimoto Y. and Xue J. (2014) Experimental study on robotic interactions to the cricket. Proceedings of IEEE ROBIO.

[24] Kobayashi M., Kataoka T., Aonuma H., Al-Mallahi A. A. and Shibata Y. (2013) Obsering electro-antennogram response of Mamestra brassicae against sex pheromone, Bio-Robotics (IFAC2013), 1(1): 223-226. 

[23] Kawabata K., Aonuma H., Hosoda K., Xue J., (2013) Controlled interaction with the cricket based on on-line pose estimation of mobile robot. Proc. IEEE Intern. Conf. Robot. Biomim., pp.1347-1352.

[22] Okuda Y., Takahashi S., Kawabata K., Aonuma A., Iwata K. and Satoh Y. (2013) Vision-based tracking for ecology analysis of the cricket. Proceedings of the 1st Int. Symp. Computing and Networking - Across Practical Development and Theoretical Research – (CANDAR’13). 

[21] Okuda Y., Takahashi S., Kawabata K., Aonuma A., Iwata K. and Satoh Y. (2013) Behavior observation method for the cricket. Proc. 2013 IEEE Int. Conf. TENCON 546.

[20] Kano T., Suzuki S., Sato E., Aonuma H. and Ishiguro A. (2013) Toward realization of resilient locomotion: Lessons from the locomotion of arm-amputated ophiuroids. The 6th Int. Symp. on Adaptive Motion in Animals and Machines. pp. 98-101.

[19] Aonuma H., Guerra R.S., Asada M. and Hosoda K. (2011) Manipulation of aggressive behavior of the cricket using a small robot. The 5th Int. Symp. Adaptive Motion in Animals and Machines, 99-100. 

[18] Kawabata K., Aonuma H., Hosoda K. and Xue J. (2012) Development of a Cricket Interaction System utilizing Mobile Robot for Behavioral Data Collection, Proc. 2012 IEEE Int. Conf. Robotics and Biomimetics, pp1615-1620.

[17] Kawabata K., Aonuma H., Hosoda K. and Xue J. (2012) Real-Time Visual Tracking for Cricket - Micro Robot Interaction Experiment, Proc. 2012 Int. Symp. Nonlinear Theory and its Applications, pp122-125.

[16] Watanabe T. and Aonuma H. (2011) Molecular aspects of the serotonergic system in the cricket CNS: implication in the adaptive modulation of behavior. The 5th Int. Symp. on Adaptive Motion in Animals and Machines, 57-58.

[15] AonumaH.,Ota J., Kawabata K., Kurabayashi D., Kanzaki R.and Asama H. (2009) Understanding social adaptive functions in animals,The 3rd International Symposium on Mobiligence, 3: 74-78.

[14]Kawabata K., Fujii T.,Aonuma H., Suzuki T., AshikagaM., Ota J. and Asama H. (2009) A neuro-modulation model of behavior selection in the fighting behavior of male crickets,The 3rd International Symposiumon Mobiligence, 3: 271-276.

[13]Yano S., Ikemoto Y.,AonumaH.and Asama H. (2009) Forgetting curve derived by serotonin hypothesis in cricket,Gryllus bimaculatus,The3rd International Symposium on Mobiligence, 3: 324-327.

[12]Sakura M., Kikuchi M. andAonuma H.(2009) Role of nitric oxide and octopamine in the aggressive behavior of the cricket,The 3rd International Symposium on Mobiligence, 3: 328-331.

[11]Mizuno T., Sakura M., Ashikaga M.,Aonuma H., Chiba R. and Ota J. (2009)Modeling of the effects of multi-modal inputs on the aggressive behavior using handicapped crickets,The 3rd International Symposium on Mobiligence, 3:332-337.

[10] Funato T., Nara M., Kurabayashi D. and Aonuma H. (2007) Development of structure-mediated behaviour selector using oscillator network. IEEE Int. Conf. Robotics and Biomimetics,1206/1211.

[9] Aonuma H., Sakura M., Kikuchi M., Hiraguchi T., Ashikaga M., Ota J., Kawabata K., Fujiki T., Ikemoto Y. and Asama H. (2007) Social experience dependent behavior selection in the cricket- from neuroethological approach to modeling -. Proc. International Symp. Mobiligence, 2: 16-19

[8] Sakura M., Yoritsune A. and Aonuma H. (2007) Fighting experiences modulate aggressive and avoidance behaviors in crickets against male cuticular substances. Proc. International Symp.Mobiligence, 2: 243-246

[7] Ashikaga M., Kikuchi M., Hiraguchi T., Sakura M., Aonuma H. and Ota J. (2007) Modeling of socially adaptive behavior in crickets. Proc. International Symp. Mobiligence, 2: 191-194

[6] Kikuchi M. and Aonuma H. (2007) Distributions of aminergic and nitric oxidergic neurons.Proc. International Symp. Mobiligence, 2: 239-242

[5] Yoritsune A. and Aonuma H. (2007) 3-D atlas of the cricket antennal lobe. Proc.International Symp. Mobiligence, 2: 187-190

[4] Kawabata K., Fujiki T., Ashikaga M., Ota J., Aonuma H. and Asama H. (2007) A study on neural circuit model of insects for adaptive behavior selection - Verification of action selection modeling multi-individual environments -, Proc. International Symp. Mobiligence, 2: 187-190.

[3] Funato T., Kurabayashi D., Nara M., Aonuma H. (2007) Development o Structure-mediatedBehavior Selector Using Oscillator Network. Proc. IEEE Int. Conf. Robotics and Biomimetics.1206-1211.

[2] Aonuma H., Iwasaki M. and Niwa K. (2004) Role of NO signaling in switching mechanisms in the nervous system of insect. Proc. SICE Ann. Conf., 2477-2482, CD-ROM. ISBN 4-907764-22-7.

[1] Aonuma H., Newland P.L. and Nagayama T. (1998) Identified interneurones in the escape generating network of crayfish receive excitatory proprioceptive inputs, J. Physiol., 513P: 104P.




国際会議の発表でProceedingとして出版された論文 (査読なし)

[30] Aonuma H. (2012) Social isolation regulates task dependent interspecific aggression in the ant, Formica japonica. Front. Behav. Neurosci. Conference Abstract: The 10th Int. Cong. of Neuroethology. doi: 10.3389/conf.fnbeh.2012.27.00180

[29] Watanabe T., Aonuma H. (2012) Molecular basis of the biogenic amine system in the field cricket Gryllus bimaculatus. Front. Behav. Neurosci. Conference Abstract: The 10th Int. Cong. of Neuroethology. doi: 10.3389/conf.fnbeh.2012.27.00178

[28]Kazawa T., Namiki S., Takashima A., Haupt S.S., Siga S., Ai H., Aonuma H., Takahata M., Kanzaki K., Ikeno H. and Usui S. From Bombyx neuron database to Invetebrate brain platform - toward a virtual invertebrate neuroscience lab. Front. Neurosci., doi: 10.3389/conf.fnins.2010.13.00113

[27] Ota J.,Aonuma H.and Asama H. (2009) Mobiligence: Emergence ofAdaptive Motor Function through Interaction among the Body, Brain andEnvironment,Workshops/Tutorials Proceedings of the 2009 IEEE/RSJInternational Conference on Intelligent Robots and Systems, Workshop:Mobiligence: Adaptive Motor Function through Dynamic Interactions among theBody, Brain and Environment, IEEE, 3-9.

[26] AonumaH.,Sakura M., Ota J. and Asama H. (2009) Social Adaptive Functions in Animals-Learning from Insect Social Behaviors-,Workshops/Tutorials Proceedings of the 2009 IEEE/RSJ International Conference on Intelligent Robots and Systems,Workshop: Mobiligence: Adaptive Motor Function through Dynamic Interactionsamong the Body, Brain and Environment, IEEE, 10-15.

[25] Kawabata K.,Aonuma H., Ota J. and Asama H. (2009) Modeling of Neuromodulation for Behavior Selection of the Cricket : Synthetic Neuroethology,Workshops/Tutorials Proceedings of the 2009 IEEE/RSJInternational Conference on Intelligent Robots and Systems, Workshop: Mobiligence: Adaptive Motor Function through Dynamic Interactions among theBody, Brain and Environment, IEEE, 16-21.

[24] Guerra R.D.,Aonuma H., Hoshoda K. and Asada M. (2009) Using Micro-robotsas a Tool for Insect Behavior Studies,Workshops/Tutorials Proceedings of the 2009 IEEE/RSJ International Conference on Intelligent Robots and Systems,Workshop: Mobiligence: Adaptive Motor Function through Dynamic Interactions among the Body, Brain and Environment, IEEE : 39-44.

[23] Ota J.,Aonuma H., Asama H., Kawabata K and Ashikaga M., (2008)Modeling of adaptive mechanism in crickets by means of constructive approach,Workshops/Tutorials Proceedings of the 2008 IEEE/RSJ International Conferenceon Intelligent Robots and Systems, Workshop: Mobiligence: Adaptive MotorFunction through Dynamic Interactions among the Body, Brain and Environment, 54-59.

[22] Aonuma H. (2007) NO/cGMP system and biogenic amine system in antagonistic behavior in the cricket. Comp. Biochem. Physiol., 148A (Sup. 1): S33

[21] Kurabayashi D., Aonuma H., Funato T., Fujiki T., Ashikaga M., Ota J. and Asama H. (2007)Artificial model for behavior switching by using network transition through neuromodulation effect. Comp. Biochem. Physiol., 148A (Sup. 1): S32

[20] Kitamura Y., Aonuma H., Oka K. and Ogawa H. (2006) Acetylcholine enhances nitric oxideproduction in the terminal abdominal ganglion of the cricket, Gryllus bimaculatus. Society for Neuroscience, 2006 (351): 16/X11.

[19] Suzuki M., Kimura T., Ogawa H., Aonuma H., Kitamura Y., Hotta K. and Oka K. (2006)Peripheral nervous plexuses control squid chromatophore organs. Society for Neuroscience2006 (353): 4/W5.

[18] Aonuma H., Iwasaki M., Katagiri C. and Delago A. (2005) Role of NO/cGMP signaling during formation of social hierarchy in the cricket, Neuroforum, CD-ROM (ISSN 0947-0875): 248B.

[17] Ott S.R., Aonuma H., Newland P.L. and Elphick M.R. (2005) Analysis of nitric oxide synthase expression in the thoracic nerve cord of crayfish. Neuroforum, CD-ROM (ISSN 0947-0875):266B.

[16] Hatakeyama D., Ito E., Aonuma H. and Elekes K. (2005) Distribution of glutamate-like immunoreactive neurons in the adult and developing nervous system of gastropod molluscs (Lymnaea stagnalis L.). Clin. Neurosci., 58 (S1): 39.

[15] Elekes K., Hatakeyama D., Aonuma H. and Ito E. (2005) Distribution of putative glutamatergic neurons in the adult and developing nervous system of the snail Lymnaea stagnali (L.). Societyfor Neuroscience, (31): 10.

[14] Kitamura Y., Aonuma H., Oka K. and Ogawa H. (2005) Nitric oxide production in the terminal abdominal ganglion of the cricket, Gryllus bimaculatus. Society for Neuroscience, (296): 11.

[13] Kitamura Y., Aonuma H., Mizutani K., Ogawa H. and Oka K. (2004) Effect of NO-cGMP signaling in non-asociative learning of the earthworm, Eisenia fetida. Society for Neuroscience,(730): 8.

[12] Aonuma H. and Iwasaki M. (2004) NO/cGMP signaling regulates short-term memory in the cricket. Nitric Oxide-Biol. Chem., 11(1): 107.

[11] Kitamura Y., Aonuma H., Niwa K., Mizutani K., Ogawa H. and Oka K. (2004) NO-cGMP signaling in non-associative learning of the earthworm. Nitric Oxide-Biol. Chem., 11(1): 106-107.

[10] Kitamura Y., Hashii H., Mizutani K., Aonuma H. and Oka K. (2003) Effect of NO-cGMP signaling on neural activity of the ventral nerve cord of the earthworm, Eisenia fetida. Societyfor Neuroscience, (270): 3.

[9] Aonuma H., Matsumoto Y., Ott S.R., Elphick M.R., Mizunami M. and Shimozawa T. (2002) NO-cGMP signaling mediates medium-term memory in the cricket. 3rd Forum of EuropeanNeuroscience, FENS 2002: p124.

[8] Ott S.R., Aonuma H., Newland P.L. and Elphick M.R. (2001) NADPH diaphorase in invertebrate nervous systems: new techniques and a note of caution. Goettingen Neurobiology Report vol. II:719.

[7] Aonuma H. and Newland P.L. (2000) Modulatory effects of nitric oxide on intersegmental ascending interneurones in the terminal ganglion of the crayfish. Euro. J. Neurosci., 12 Sup(11): p34.

[6] Schuppe H., Aonuma H. and Newland P.L. (2000) NADPH-diaphorase histochemistry in the terminal ganglion of the crayfish. Europ. J. Neurosci., 12 Sup (11): p34.

[5] Aonuma H., Newland P. L. and Nagayama T. (1999) Processing of proprioceptive in formation by identified ascending interneurones in the crayfish. Goettingen Neurobiology Report: p204.

[4] Newland P.L., Aonuma H. and Nagayama T. (1997) Proprioceptive excitation of interneurones in the escape generating network of crayfish. Goettingen Neurobiology Report: p252.

[3] Nwland P.L., Aonuma H., Sato M. and Nagayama T. (1995) Inhibition of primary afferents in the terminal abdominal ganglion of crayfish. Goettingen Neurobiology Report: p238.

[2] Newland P.L., Sato M., Aonuma H. and Nagayama T. (1995) Presynaptic inhibition of water motion sensitive afferents by proprioceptive afferents in the terminal abdominal ganglion of crayfish. Nervous Systems and Behavior: p233.

[1] Aonuma H., Nagayama T. and Takahata M. (1995) Distribution of autofluorescent cell bodies in the central nervous system of the crayfish. Nervous Systems and Behavior: pp460.




国内学会での講演論文集等 

[32] 青沼 仁志 (2014) 個体間相互作用から学ぶコトミメティクス-昆虫の個体間相互作用によって変容する内部状態-,第26回自律分散システムシンポジウム資料,14SY0001 : 147-150.

[31] 杉本 靖博, 青沼 仁志, 川端 邦明, 大須賀 公一 (2014) 個体間相互作用から学ぶコトミメティクス-ロボット間相互作用による内部状態の変化を用いた位置同定法の再解釈-,第26回自律分散システムシンポジウム資料,14SY0001 : 151-152.

[30] 川端 邦明, 青沼 仁志, 杉本 靖博, 細田 耕, 薛 建儒(2014) 個体間相互作用から学ぶコトミメティクス-昆虫-ロボット相互作用系による行動実験-,第26回自律分散システムシンポジウム資料,14SY0001 : 153-156.

[29] 佐藤 英毅, 加納 剛史, 青沼 仁志, 松坂 義哉, 石黒 章夫 (2014) クモヒトデの腕間協調メカニズムの数理モデル,第26回自律分散システムシンポジウム資料,14SY0001 : 177-182.

[28] 青沼 仁志 (2014) 自律分散-創発-移動知-コトミメティクス,生物学のこれまでとこれから,第26回自律分散システムシンポジウム資料,14SY0001 : 287-288.

[27] 加納 剛史, 大須賀 公一, 小林 亮, 青沼 仁志, 石川 将人, 杉本 靖博, 大脇 大, 石黒 章夫 (2014) 「個性」を持つ粒子集団が創り出す動的秩序~人間社会における交友関係を採り上げた事例研究~,第26回自律分散システムシンポジウム資料,14SY0001 : 244-248.

[26] 矢野 史朗, 渡邊 崇之, 青沼 仁志, 淺間 一(2014) 受容体理論による縫線核セロトニン神経のモデル化と解析,第26回自律分散システムシンポジウム資料,14SY0001 : 289-292.

[25] 清水 正宏,青沼 仁志,細田 耕 (2013) アフリカツメガエルの腓腹筋を駆動源とする1自由度拮抗筋アーム,第25回自律分散システムシンポジウム資料,13SY0001 : 109-112.

[24] 川端 邦明,青沼 仁志,薛 建儒 クロコオロギ-ロボット間相互作用による実時間行動選択機構の理解-相互作用実験および行動データ収集系の構築-,第24 回自律分散システム・シンポジウム資料, pp103-108, 2012.

[23] 矢野 史朗,渡邊 崇之,佐倉 緑,青沼 仁志,淺間 一(2011)セロトニン仮説に基づく行動修飾機構を持つ競争的エージェントの社会相互作用 ,第23回自律分散システム・シンポジウム資料,計測自動制御学会,11 SY 002 : 190-193. 

[22] ゲーハ ダ シルバ ロドリゴ,青沼 仁志,細田 耕,浅田 稔 (2011) Combining EMG Recording and Robust Tracking for Insect/Robot Mixed Society,第23回自律分散システム・シンポジウム資料,計測自動制御学会,11 SY 002 : 23-26.

[21] 藤井喬,川端邦明,青沼仁志,佐倉緑,鈴木剛,太田順,淺間一(2010)クロコオロギの行動選択機構のモデリングに関する研究 ~触角からの感覚入力感受性による群行動の変容についての考察~,第22回自律分散シンポジウムム・シンポジウム予稿集,10SY0002: 213-218.

[20] 矢野史朗,池本有助,青沼仁志,淺間一(2010) 空間構造を考慮したコオロギの闘争行動モデルと個体順位の空間的分布に関する考察,第22回自律分散シンポジウムム・シンポジウム予稿集,10SY0002: 219-222.

[19] 藤井喬,川端邦明,青沼仁志,鈴木剛,足利昌俊,太田順,淺間一(2009)クロコオロギの行動選択機構のモデリングに関する研究―内部状態レベルによる行動選択に関する考察−,ロボティクス・メカトロニクス講演会'09講演論文集, 2A1-B10.

[18] 青沼仁志,佐倉緑,足利昌俊,藤木智久,藤井喬,川端邦明,太田順,淺間一(2008) 昆虫の社会的経験にもとづく行動選択のモデル化,第18回インテリジェント・システム.シンポジウム講演論文集,08 SY 0010, 305-310 (CD)

[17] 川端 邦明,藤木 智久,青沼 仁志,淺間 一 (2007) 適応的行動選択を実現する昆虫の神経回路モデルに関する研究 ?闘争行動の開始・終了に関するモデルの提案?,ロボティクス・メカトロニクス講演会'07講演論文集, 1A1-A09.

[16] 川端 邦明,太田 順,青沼 仁志,淺間 一 (2007) コオロギ社会適応行動の神経機構モデリング,第25回日本ロボット学会学術講演会予稿集, 1F14.

[15] 矢野 史朗,池本 有助, 青沼 仁志, 淺間 一 (2007) コオロギの適応的行動選択を実現する動的制御機構のモデリング, 第13回創発システム・シンポジウム, 165-166.

[14] 足利 昌俊,菊地 美香,平口 鉄太郎,佐倉 緑,青沼 仁志,太田 順 (2007) コオロギ群における社会的行動選択のモデル化,第17回インテリジェント・システム・シンポジウム講演論文集, 191/196.

[13] 舩戸 徹郎,奈良 維仁,A. D’Angelo,E. Pagello,倉林 大輔,青沼 仁志 (2007) 結合振動子による行動選択回路の実装と行動評価,第25回日本ロボット学会学術講演会予稿集, 1D16.

[12] 倉林 大輔,舩戸 徹郎,奈良 維仁,青沼 仁志 振動子網を用いた行動切替メカニズムの実現,計測自動制御学会制御部門大会, 2N4-5

[11] 足利 昌俊,菊地 美香,平口 鉄太郎,佐倉 緑,青沼 仁志,太田 順 (2007) コオロギ群における社会的行動選択のモデル化,第13回創発システム・シンポジウム「創発夏の学校」 公演資料集, 119-122.

[10] 足利 昌俊,菊地 美香,平口 鉄太郎,佐倉 緑,青沼 仁志,太田 順 (2007) コオロギ群における社会的行動のモデル化,第17回インテリジェント・システム・シンポジウム(FANシン ポジウム) 公演論文集, 191-196.

[9] 頼経 篤史,佐倉 緑,青沼 仁志 (2006) クロコオロギの社会的経験による攻撃行動と回避行動の切り換え,第7回(社)計測自動制御学会・システムインテグレーション部門・講演論文集, 06 SY0013: 874-875.

[8] 足利 昌俊,平口 鉄太郎,佐倉 緑,菊地 美香,青沼 仁志,太田 順 (2006) コオロギ群の喧嘩行動をモデルとした動的環境下における移動ロボット群の採餌作業,第7回(社)計測自動制御学会・システムインテグレーション部門・講演論文集, 06 SY 0013: 876-877.

[7] 藤木 智久,足利 昌俊,川端 邦明,太田 順,青沼 仁志,淺間 一 (2006) 適応的行動選択を実現する昆虫の神経回路モデルに関する研究 -複数個体環境下における行動選択モデルの検証- ,第7回(社)計測自動制御学会・システムインテグレーション部門・講演論文集, 06 SY 0013: 878-879.

[6] 足利 昌俊,菊地 美香,平口 鉄太郎,佐倉 緑,青沼 仁志,太田 順 (2006)コオロギ群の喧嘩行動を規範とした移動ロボット群の探餌行動,第16回インテリジェント・システム・シンポジウム講演論文集, 17-22.

[5] 藤木 智久,川端 邦明,池本 有助,青沼 仁志,淺間 一 (2006) 昆虫の適応的行動選択を実現する神経回路モデルに関する研究-NO/cGMPカスケードによる適応的行動選択のモデル化-.第16回インテリジェント・システム・シンポジウム講演論文集, 23-28.

[4] 足利 昌俊,平口 鉄太郎,佐倉 緑,青沼 仁志,太田 順 (2006) コオロギ集団における多様的振るまいのモデル化, 自律分散シンポジウム資料, 06SY0001: 189-194.

[3] 浅間 一,矢野 雅文,土屋 和雄,伊藤 宏司,高草木 薫,神崎 亮平,青沼 仁志,太田 順,石黒章夫 (2004) 移動知発現のシステム原理(生物学と工学の相互連携), 第16回自律分散システム・シンポジウム資料, 04SY0001: 1-4.

[2] 青沼 仁志,岩崎 正純 (2004) 昆虫の行動制御機構にかかわる一酸化窒素カスケードの役割,第16回自律分散システム・シンポジウム資料, 04SY0001: 41-46.

[1] 中山 由佳子,河原 剛一,青沼 仁志,山内 芳子,中島 崇行,鉢呂 健 (2004) 培養心筋細胞内Ca2+振動の細胞間同期とそのメカニズムの解析. 電子情報通信学会技術研究報告, 62: 41-44.



招待講演

青沼 仁志 (2012年5月) コオロギの闘争行動から理解する社会環境への適応メカニズム,「新学術領域・システム分子行動学」数理シンポジウム,東京大学

Aonuma H. (2012 Mar) Aminergic control of aggressive behavior in the cricket, The 2nd International Conference on the Cricket/ RNAi Symposium for Medicine-Agriculture-Engineering Collaboration Project (Joint Meeting), Tokushima, Japan 

青沼 仁志 (2011年7月)  クロヤマアリFormica japonicaの攻撃性を制御する脳内オ クトパミンの働き―異種昆虫に対する攻撃性は社会的隔離によって リセットされる,第16回北陸社会性昆虫勉強会,富山大学

Aonuma H. (2011 Mar) Fighting experience dependent motivation change in cricket, The 1st International Conference on the Cricket/ RNAi Symposium for Medicine-Agriculture-Engineering Collaboration Project (Joint Meeting), Tokushima, Japan

青沼 仁志 (2011年3月) コオロギの闘争行動と順位形成:神経生理学から行動学へ,第58回日本生態学会,札幌コンベンションセンター,札幌

青沼 仁志 (2010年12月) コオロギの闘争経験に基づいた行動選択と社会適応行動の発現メカニズム,第6回犬山比較社会認知シンポジウム,京都大学霊長類研究所(愛知県犬山)

青沼 仁志 (2010年11月) 個体間相互作用に基づく社会適応行動のモデル化,文部科学省「物質・デバイス領域共同研究拠点」 複雑系数理とその応用に関するシンポジウム,北海道大学電子科学研究所

AonumaH., Ota J., Kawabata K. and Asama H. (2010 Aug) Mobiligence: Synthetic approach for understanding social adaptation, The SICE Annual Conference 2010 (SICE2010), The Grand Hotel, Taipei, Taiwan.

青沼 仁志 (2010年3月) コオロギの社会適応行動の構成論的研究,国立情報研究所・社会的知能発生学研究会・公開シンポジウム.学術総合センター.(東京)

Aonuma H., Ota J., Kawabata K., Kurabayashi D., Kanzaki R. and Asama H. (2009 Nov) Understanding social adaptive functions in animals, The 3rd International Symposium on Mobiligence, Awaji.

OtaJ.,Aonuma H., and Asama H.(2009 Oct) Mobiligence: Emergence of adaptive motor function through interaction among the body, brain and environment,IROS2009: The 2009 IEEE/RSJ International Conference on Intelligent RObots andSystems,St. Louis,MO,U.S.A.

Aonuma H., Sakura M., Ota J. and Asama H.(2009 Oct)Social adaptive functions in animals -Learning from insect social behaviors-,IROS 2009: The 2009 IEEE/RSJ International Conference on Intelligent RObots andSystems,St. Louis,MO,U.S.A.

KawabataK.,Aonuma H., Ota J. and Asama H. (2009 Oct)Modeling of neuromodulation for behavior selection of the cricket: Synthetic neuroethology approach, IROS 2009: The 2009 IEEE/RSJ International Conference on IntelligentRObots and Systems,St.Louis, MO,U.S.A.

Guerra RD.,Aonuma H., Hosoda K. and AsadaM.(2009 Oct)Using micro-robots as a tool for insect behavior studies, IROS 2009: The 2009 IEEE/RSJ InternationalConference on Intelligent RObots and Systems,St. Louis,MO,U.S.A.

Aonuma, H. (2009 Feb) Modelling of experience dependent behavior - Fighting among male crickets. International Conference for Nonlinear Sciences SAPPORO WINTER SCHOOL, Sapporo

Aonuma H. (2008 Sep) Modelling of social interaction dependent behavior selection in the cricket. Workshop on Dynamical Circuits in the Brain, Sapporo, Japan.

Ota J., Aonuma H., Asama H., Kawabata K. and Ashikaga M. (2008 Sep) Multidisciplinary contributions from neuroethology and engineering-Understanding experience dependent behavior selection in crickets. IROS2008: IEEE/RSJ Int'l Conf. on Intelligent Robots and Systems, Acropolis Convention Center, Nice, France.

Aonuma H. (2008 June) Experience dependent behavior selection in the cricket. International Seminar: Evolutionary Studies in Behavioral Neuroscience, Hayama, Japan.

Aonuma H. (2008 June) Synthetic neuroethological approach to understand experience dependent adaptive behavior in the cricket. The 4th International Symposium on Adaptive Motion of Animals and Machines, Cleveland U.S.A.

青沼仁志 (2008年8月) コオロギの振る舞いから学ぶ人間社会, 環境・自然を考える会,(札幌)

青沼仁志 (2008年2月) クロコオロギの社会的適応行動,非線形数理東京フォーラム「人と自然の数理」,東京大学(東京)

Aonuma H. (2007 Aug) NO/cGMP system and biogenic amine system in agonistic behavior in the cricket. The 7th International Congress of Comparative Physiology and Biochemistry, Salvador, Brazil

Aonuma H., Sakura M., Kikuchi M., Hiraguchi T., Ashikaga M., Ota J., Kawabata K., Fujiki T., Ikemoto Y. and Asama H. (2007 Jul) Social experience dependent behavior selection in the cricket -from neuroethological approaches to modeling-. The 2nd International Symposium on Mobiligence, Awaji, Japan

Aonuma H., Kurabayashi D. and Kanzaki R. (2007 Apr) Behaviour switching system based on chemical effects in insect brain, International Workshop on Mobiligence. University of Padova , Italy

Ashikaga M., Kikuchi M., Hiraguchi T., Sakura M., Aonuma H. and Ota J. (2007 Apr) Modeling of Adaptive Mechanism in Crickets and its Application to Robotics. International Workshop on Mobiligence, University of Padova, Italy

青沼仁志,太田 順 (2007年8月) コオロギの社会的経験による行動の発現と切り替え-行動モデルの構築にむけて,日本進化学会第9回 京都大会シンポジウム ,京都大学(京都)

青沼仁志 (2007年5月) 昆虫の記憶,日本機械学会ロボット・メカトロニクス部門主催 チュートリアル「昆虫の脳・個体・社会から探る知能」,秋田メトロポリタンホテル(秋田)

Aonuma H. (2005 Jul) Formation of social hierarchy in the cricket - a role of NO/cGMP cascade in fighting behavior. Neuro2005,Yokohama, Japan

Aonuma H. (2005 Dec) Mechanism whereby animals adapt to society, The 1st International Symposium on Mobiligence, Sapporo, Japan

青沼仁志 (2006年11月) 神経生物学とナノテク.第31回日本比較内分泌学会大会シンポジウム(札幌)

青沼仁志 (2006年6月) コオロギの社会的経験と行動変容.社会的知能発生学研究会(札幌)

青沼仁志 (2006年6月) 社会適応のメカニズム解明にむけた構成論的アプローチ.移動知シンポジウム(洞爺)

Aonuma H. (2004 Dec) Functional role of the NO/cGMP cascade in pheromonal behavior of insects; a lack of NO makes super confident crickets. The 6th RIES-Hokudai Symposium, Sapporo, Japan

Aonuma H. (2004 Jul) Role of NO/cGMP signaling in the pheromonal behavior of the cricket. International Symposium on Chemical Senses and Insect, Kyoto, Japan

青沼仁志 (2004年3月) 昆虫の実時間行動選択機構のシステム的理解.移動知研究会,東北大学電気通信研究所(仙台)

青沼仁志 (2004年1月) 昆虫の行動制御機構にかかわる一酸化窒素カスケードの役割.第16回自律分散システム・シンポジウム(京都)

青沼仁志 (2003年1月) 昆虫の行動切換えの神経機構解明をめざして(昆虫の中枢神経系における一酸化窒素の役割)JST異分野研究フォーラム(高松)

Aonuma H. and Newland P.L. (1999 Jul) The action of nitric oxide and cGMP on intersegmental interneurones in the crayfish terminal abdominal ganglion. Frontier in Crustacean Neurobiology Meeting, Hamburg, Germany

© Hitoshi AONUMA 2017