刊期:双月刊
主管单位:四川省科学技术协会
主办单位:四川省动物学会/成都大熊猫繁育研究基金会/四川省野生动植物保护协会/四川大学
地址:四川省成都市武侯区望江路29号四川大学生命科学学院内
邮编:610064
电话:028-85410485; 15881112385
传真:028-85410485
E-Mail:scdwzz@vip.163.com & scdwzz001@163.com
刊号:ISSN 1000-7083
        CN 51-1193/Q
国内发行代号:
国际发行代号:
发行范围:国内外公开发布
定价:50元/册
定价:300元/年

您所在位置:首页->过刊浏览->2018年第37卷第3期

基于事件相关电位P300的动物认知研究进展
Research Development of Animal Cognition Based on P300
张小琴1, 鲜雪梅1, 方光战2*
点击:173次 下载:0次
DOI:
作者单位:1. 阿坝师范学院资源与环境学院, 四川汶川 623002;
2. 中国科学院成都生物研究所两栖爬行动物研究室, 成都 610041
中文关键字:事件相关电位;P300;类P300;动物认知
英文关键字:event-related potential; P300; like-P300; animal cognition
中文摘要:P300是事件相关电位中被广泛用于研究正常人、患者和动物认知加工及其脑机制的重要电生理指标。本文就其起源、影响因素和动物类P300的研究进展进行了综述,详细论述了各动物在视觉、听觉和触觉等不同模态下的类P300的主要结论,及P300在人类和动物之间的异同,并分析了导致差异的原因。最后对研究的不足之处提出了可能的解决方案,并对基于P300的动物认知研究方向进行了展望。
英文摘要:P300 is an important and widely used electrophysiological index to study cognitive processing and the underlying neural mechanisms in normal people, patients and non-human animals. In this paper, previous studies were reviewed concerning the origin of P300, influencing factors on P300, like-P300 acquired from non-human animals especially in visual, auditory and tactile modalities. Moreover, the similarity and specificity of P300 between humans and non-human animals was compared and the possible causes resulting in these differences were discussed. Finally, some protocols for studies on animal cognition based on P300 and the possible prospects in the future was proposed.
2018,37(3): 351-359 收稿日期:2017-12-11
DOI:10.11984/j.issn.1000-7083.20170390
分类号:Q955
基金项目:国家自然科学基金项目(31672305,31372217);四川省教育厅项目(18ZB0003)
作者简介:张小琴,女,硕士,讲师,研究方向:动物声音通讯及其神经机理,E-mail:qingerzx1982@163.com
*通讯作者:方光战,E-mail:fanggz@cib.ac.cn
参考文献:
魏景汉, 罗跃嘉. 2010. 事件相关电位原理与技术[M]. 北京:科学出版社:52-55.
Allen JJB. 2002. The role of psychophysicology in clinical assessment:ERPs in the evaluation of memory[J]. Psychophysiology, 39(3):261-280.
Arnone B, Pompili A, Tavares MC, et al. 2011. Sex-related memory recall and talkativeness for emotional stimuli[J]. Frontiers in Behavioral Neuroscience, 5:52.
Arthur DL, Starr A. 1984. Task-relevant late positive component of the auditory event-related potential in monkeys resembles P300 in humans[J]. Science, 223(4632):186-188.
Barceló F, Rubia FJ. 1998. Non-frontal P3b-like activity evoked by the Wisconsin Card Sorting Test[J]. Neuroreport, 9(4):747-751.
Calcus A, Deltenre P, Hoonhorst I, et al. 2014. MMN and P300 are both modulated by the featured/featureless nature of deviant stimuli[J]. Clinical Neurophysiology, 126(9):1727-1734.
Dien J, Spencer KM, Donchin E. 2004. Parsing the late positive complex:mental chronometry and the ERP components that inhabit the neighborhood of the P300[J]. Psychophysiology, 41(5):665-678.
Duncan CC, Barry RJ, Connolly JF, et al. 2009. Event-related potentials in clinical research:guidelines for eliciting, recording, and quantifying mismatch negativity, P300, and N400[J]. Clinical Neurophysiology, 120(11):1883-1908.
Ehlers CL, Desikan A, Wills DN. 2014. Event-related potential responses to the acute and chronic effects of alcohol in adolescent and adult Wistar rats[J]. Alcoholism Clinical and Experimental Research, 38(3):749-759.
Ehlers CL, Kaneko WM, Robledo P, et al. 1994. Long-latency event-related potentials in rats:effects of task and stimulus paramenters[J]. Neuroscience, 62(3):759-769.
Elliott TM, Kelley DB. 2007. Male discrimination of receptive and unreceptive female calls by temporal features[J]. Journal of Experimental Biology, 210(Pt 16):2836-2842.
Euser AS, Arends LR, Evans BE, et al. 2012. The P300event-related brain potential as a neurobiological endophenotype for substance use disorders:a meta-analytic investigation[J]. Neuroscience & Biobehavioral Reviews, 36(1):572-603.
Fang GZ, Yang P, Xue F, et al. 2015. Sound classification and call discrimination are decoded in order as revealed by event-related potential components in frogs[J]. Brain Behavior Evolution, 86(3-4):232-245.
Friedman D, Cycowicz YM, Gaeta H. 2001. The novelty P3:an event-related brain potential (ERP) sign of the brain's evaluation of novelty[J]. Neuroscience & Biobehavioral Reviews, 25(4):355-373.
Ghilardi MF, Marx MS, Onofrj MC, et al. 1987. Scalp distribution of pattern visual evoked potentials in normal and hemianopic monkeys[J]. Physiology & Behavior, 41:297-302.
Glaser E, Mendrek A, Germain M, et al. 2012. Sex differences in memory of emotional images:a behavioral and electrophysiological investigation[J]. International Journal of Psychophysiology, 85(1):17-26.
Glover A, Ghilardi MF, Bodis-Wollner I, et al. 1991. Visual ‘cognitive’ evoked potentials in the behaving monkey[J]. Electroencephalography Clinical Neurophysiology, 90(1):65-72.
Grupe M, Grunnet M, Laursen B, et al. 2014. Neuropharmacological modulation of the P3-like event-related potential in a rat two-tone auditory discrimination task with modafinil and NS9283, a positive allosteric modulator of alpha4 beta2 nAChRs[J]. Neuropharmacology, 79:444-455.
Halgren E, Marinkovic K, Chauvel P. 1998. Generators of the late cognitive potentials in auditory and visual oddball tasks[J]. Electroencephalography and Clinical Neurophysiology, 106(2):156-164.
Halgren E, Squires N, Wilson C, et al. 1980. Endogenous potentials generated in the human hippocampal formation and amygdala by infrequent events[J]. Science, 210(4471):803-805.
Harrison J, Buchwald J, Kaga K. 1986. Cat P300 present after primary auditory cortex ablation[J]. Electroencephalography & Clinical Neurophysiology, 63(2):180-187.
Harrison JB, Dickerson LW, Song S, et al. 1990. Cat-P300 present after association cortex ablation[J]. Brain Research Bulletin, 24(4):551-560.
Hattori M, Onoda K, Sakata S. 2010. Identification of rat P3-like processes in the anterior cingulate cortex and hippocampus[J]. Neuroscience Letters, 472(1):43-46.
Hermens DF, Ward PB, Hodge M, et al. 2010. Impaired MMN/P3a complex in first-episode psychosis:cognitive and psychosocial associations[J]. Progress in Neuro-Psychopharmacology & Biological Psychiatry, 34(6):822-829.
Huster RJ, Westerhausen R, Herrmann CS. 2011. Sex differences in cognitive control are associated with midcingulate and callosal morphology[J]. Brain Structure & Function, 215(3-4):225-235.
Imada A. 2013. Analysis of rat event related potentials in frontal and parietal lobes as a possible neural correlate of attention in passive Oddball and active Go/No-Go paradigms[D]. Massachusetts:Wellesley College:11-20.
Isreal JB, Chesney GL, Wickens CD, et al. 1980. P300 and tracking difficulty:evidence for multiple resources in dual-task performance[J]. Psychophysiology, 17(3):259-273.
Johnson RJ. 1989a. Auditory and visual P300s in temproal lobectomy patients-evidence for modailtiy-dependent generators[J]. Psychophysiology, 26(6):633-650.
Johnson RJ. 1989b. Developmental evidence for modality-dependent P300 generators:a normative study[J]. Psychophysiology, 26(6):651-667.
Johnson RJ. 1993. On the neural generators of the P300 component of the event-related potential[J]. Psychophysiology, 30(1):90-97.
Joos K, Gilles A, Van de Heyning, et al. 2014. From sensation to percept:the neural signature of auditory event-related potentials[J]. Neuroscience & Biobehavioral Reviews, 42(5):148-156.
Jun J, Porjesz B, Begleiter H, et al. 1999. P300:the similarities and differences in the Scalp distribution of visual and auditory modality[J]. Brain Topography, 11:315-327.
Knight RT. 1997. Distributed cortical network for visual attention[J]. Journal of Cognitive Neuroscience, 9(1):75-91.
Lindín M, Zurrón M, Díaz F. 2005. Stimulus intensity effects on P300 amplitude across repetitions of a standard auditory oddball task[J]. Biological Psychology, 69(3):375-385.
Luck SJ. 2005. An introduction to the event-related potential technique[M]. Cambridge, Massachusetts:MIT Press:229-235.
Miltner W, Johnson JR, Braun C, et al. 1989. Somatosensory event-related potentials to painful and non-painful stimuli:effects of attention[J]. Pain, 38(3):303-312.
Nieuwenhuis S, Aston-Jones G, Cohen JD. 2005. Decision making, the P3, and the locus coeruleus-norepinephrine system[J]. Psychological Bulletin, 131(4):510-532.
O'connor TA, Starr A. 1985. Intracranial potentials correlated with an event-related potential, P300, in the cat[J]. Brain Research, 339(1):27-38.
O'Neill J, Halgren E, Marinkovic K, et al. 2000. Effects of muscarinic and adrenergic agonism on auditory P300 in the macaque[J]. Physiology & Behavior, 70(1-2):163-170.
Paller KA, Zolamorgan S, Squire LR, et al. 1988. P3-like brain waves in normal monkeys and in monkeys with medial temporal lesions[J]. Behavioral Neuroscience, 102(5):714-725.
Patel SH, Azzam PN. 2005. Characterization of N200 and P300:selected studies of the event-related potential[J]. International Journal of Medical Sciences, 2(4):147-154.
Picton TW, Stuss DT, Champagne SC, et al. 1984. The effects of age on human event-related potentials[J]. Psychophysiology, 21(3):312-326.
Pineda JA, Swick D. 1992. Visual P3-like potentials in squirrel monkey:effects of a noradrenergic agonist[J]. Brain Research Bulletin, 28(3):485-491.
Pineda JA, Westerfield M. 1993. Monkey P3 in an "oddball" paradigm:pharmacological support for multiple neural sources[J]. Brain Research Bulletin, 31(6):689-696.
Polich J, Criado JR. 2006. Neuropsychology and neuropharmacology of P3a and P3b[J]. International Journal of Psychophysiology, 60(2):172-185.
Polich J, Kok A. 1995. Cognitive and biological determinants of P300:an integrative review[J]. Biological Psychology, 41(2):103-146.
Polich J. 1987. Task difficulty, probability, and inter-stimulus interval as determinants of P300 from auditory stimuli[J]. Electroencephalography & Clinical Neurophysiology, 68(4):311-320.
Polich J. 2003. Theoretical overview of P3a and P3b[M]//Polich J. Detection of change:event-related potential and fMRI findings. Boston:Kluwer Academic Press:83-98.
Polich J. 2007. Updating P300:an integrative theory of P3a and P3b[J]. Clinical Neurophysiology, 118(10):2128-2148.
Posner MI. 1980. Orienting of attention[J]. Quarterly Journal of Experimental Psychology, 32(1):3-25.
Sambeth A, Maes JH, van Luijtelaar G, et al. 2003. Auditory event-related potentials in humans and rats:effects of task manipulation[J]. Psychophysiology, 40(1):60-68.
Slawecki CJ, Thomas JD, Riley EP, et al. 2000. Neonatal nicotine exposure alters hippocampal EEG and event-related potentials (ERPs) in rats[J]. Pharmacology Biochemistry & Behavior, 65(4):711-718.
Snyder E, Hillyard SA, Galambos R. 1980. Similarities and differences among the P3 waves to detected signals in three modalities[J]. Psychophysiology, 17(2):112-122.
Snyder EW, Beck EC, Dustman RE. 1979. Visual evoked potentials in monkeys[J]. Electroencephalography & Clinical Neurophysiology, 47(4):430-440.
Soltani M, Knight RT. 2000. Neural origins of the P300[J]. Critical Reviews in Neurobiology, 14(3-4):199-224.
Sommer W, Matt J. 2010. Awareness of P300-related cognitive processes:a signal detection approach[J]. Psychophysiology, 27(5):575-585.
Sutton S, Braren M, Zubin J, et al. 1965. Evoked potential correlates of stimulus uncertainty[J]. Science,150:1187-1188.
Swick D, Pineda JA, Foote SL. 1994a. Effects of systemic clonidine on auditory event-related potentials in squirrel monkeys[J]. Brain Research Bulletin, 33(1):79-86.
Swick D, Pineda JA, Schacher S, et al. 1994b. Locus coeruleus neuronal activity in awake monkeys:relationship to auditory P300-like potentials and spontaneous EEG[J]. Experimental Brain Research, 101(1):86-92.
Tsolaki A, Kosmidou V, Hadjileontiadis L, et al. 2015. Brain source localization of MMN, P300 and N400:aging and gender differences[J]. Brain Research, 1603:32-49.
Twomey DM, Murphy PR, Kelly SP, et al. 2015. The classic P300 encodes a build-to-threshold decision variable[J]. European Journal of Neuroscience, 42(1):1636-1643.
Uther M, Jansen DHJ, Huotilainen M, et al. 2003. Mismatch negativity indexes auditory temporal resolution:evidence from event-related potential (ERP) and event-related field (ERF) recordings[J]. Brain Research Cognitive Brain Research, 17(3):685-691.
van Dinteren R, Arns M, Jongsma ML, et al. 2014. Combined frontal and parietal P300 amplitudes indicate compensated cognitive processing across the lifespan[J]. Frontiers in Aging Neuroscience, 6(6):294.
Wang F, He Y, Pan J, et al. 2015. A novel audiovisual brain-computer interface and its application in awareness detection[J]. Scientific Reports, 5:9962.
Wang Y, Kawai Y, Nakashima K. 1999. Rabbit P300-like potential depends on cortical muscarinic receptor activation[J]. Neuroscience, 89(2):423-427.Wang Y, Nakashima K, Shiraishi Y, et al. 1997. P300-like potential disappears in rabbits with lesions in the nucleus basalis of Meynert[J]. Experimental Brain Research, 114(2):288-292.
Wang Y, Shiraishi Y, Kawai Y, et al. 1998. Cortical anesthesia reduced the amplitude of local P300 event-related potential in rabbits by auditory oddball paradigm[J]. Neuroscience Letters, 244:25-28.
Woods DL, Ridgway SH, Bullock TH. 1986. Middle-and long-latency auditory event-related potentials in dolphins[M]//Schusterman JR, Thomas JA, Wood FG. Dolphin cognition and behavior:a comparative perspective. London:Lawrence Erlbaum Associates:61-77.
Wronka E, Kaiser J, Coenen AM. 2012. Neural generators of the auditory evoked potential components P3a and P3b[J]. Acta Neurobiologiae Experimentalis, 72(1):51-64.
Yamaguchi S, Knight RT. 1991a. Age effects on the P300 to novel somatosensory stimuli[J]. Electroencephalography & Clinical Neurophysiology, 78(4):297-301.
Yamaguchi S, Knight RT. 1991b. P300 generation by novel somatosensory stimuli[J]. Electroencephalography & Clinical Neurophysiology, 78(1):50-55.
Zola-Morgan S, Squire LR, Mishkin M. 1982. The neuroanatomy of amnesia:amygdala-hippocampus versus temporal stem[J]. Science, 218(4579):1337-1339.
读者评论

      读者ID: 密码:   
我要评论:
国内统一连续出版物号:51-1193/Q |国际标准出版物号:1000-7083
主管单位:四川省科学技术协会  主办单位:四川省动物学会/成都大熊猫繁育研究基金会/四川省野生动植物保护协会/四川大学
开户银行:中国工商银行四川分行营业部东大支行(工行成都东大支行营业室)  帐户名:四川省动物学会  帐号:4402 2980 0900 0012 596
版权所有©2018四川动物》编辑部 蜀ICP备08107403号-3
您是本站第6558322名访问者

川公网安备 51010702000173号