参考文献
[1]Arce F,Novick I,Mandelblat-cerf Y,et al.Combined adaptiveness of specific motor cortical ensembles underlies learning[J].J Neurosci,2010,30(15):5415-5525.
[2]Asanuma H,Rosén I.Topographical organization of cortical efferent zones projecting to distal forelimb muscles in the monkey[J].Exp Brain Res,1972,14(3):243-256.
[3]Ashe J,Georgopoulos AP.Movement parameters and neural activity in motor cortex and area[J].Cereb Cortex,1994,4(6):590-600.
[4]Caminiti R,Johnson PB,Urbana A.Making arm movements within different parts of space:dynamic aspects in the primate motor cortex[J].J Neurosci,1990,10(7):2039-2058.
[5]Carmena JM,Lebedev MA,Crist RE,et al.Learning to control a brain-machine interface for reaching and grasping by primates[J].PLoS Biol,2003,1(2):193-208.
[6]Cheney PD,Fetz EE.Functional classes of primate corticomotoneuronal cells and their relation to active force[J].J Neurophysiol,1980,44(4):773-791.
[7]Cheney PD,Fetz EE.Comparable patterns of muscle facilitation evoked by individual corticomotoneuronal(CM)cells and by single intracorticalmicrostimuli in primates:evidence of functional groups of CM cells[J].J Neurophysiol,1985,53(3):786-804.
[8]Cheney PD,Fetz EE,Palmer SS.Patterns of facilitation and suppression of antagonist forelimb muscles from motor cortex sites in the awake monkey[J].J Neurophysiol,1985,53(3):805-820.
[9]Evarts EV.Relation of pyramidal tract activity to force exerted during voluntary movement[J].J Neurophysiol,1968,31(1):14-27.
[10]Evarts EV,Fromm C,Kröller J,et al.Motor cortex and control of finely graded forces[J].J Neurophysiol,1983,49(5):1199-1215.
[11]Fetz EE,Cheney PD.Postspike facilitation of forelimb muscle activity by primate corticomotoneuronal cells[J].J Neurophysiol,1980,44(4):751-772.
[12]Fetz EE,Finocchio DV.Correlations between activity of motor cortex neurons and arm muscles during operantly conditioned response patterns[J].Exp Brain Res,1975,23(3):217-240.
[13]Georgopoulos AP,Ashe J,Smyrnis N,et al.The motor cortex and the coding of force[J].Science,1992,256(5064):1692-1695.
[14]Georgopoulos AP,Caminiti R,Kalaska JF,et al.Spatial coding of movement:A hypothesis concerning the coding of movement direction by motor cortical populations[J].Exp Brain Res Suppl,1983,49(7):327-336.
[15]Georgopoulos AP,Kalaska JF,Caminiti R,et al.On the relations between the direction of two-dimensional arm movements and cell discharge in primate motor cortex[J].J Neurosci,1982,2(11):1527-1537.
[16]Georgopoulos AP,Merchant H,Naselaris T,et al.Mapping of the preferred direction in the motor cortex[J].Proceedings of the National Academy of Sciences USA,2007,104(26):11068-11072.
[17]Gribble PL,Scott SH.Overlap of internal models in motor cortex for mechanical loads during reaching[J].Nature,2002,417(6892):938-941.
[18]Griffin DM,Hudson HM,Belhaj-SaïfA,et al.Stability of output effects from motor cortex to forelimb muscles in primates[J].J Neurosci,2009,29(6):1915-1927.
[19]Griffin DM,Hudson HM,Belhaj-Saïf A,et al.Do corticomotoneuronal cells predict target muscle EMG activity?[J].J Neurophysiol,2008,99(3):1169-1186.
[20]He SQ,Dum RP,Strick PL.Topographic organization of corticospinal projections from the frontal lobe:motor areas on the lateral surface of the hemisphere[J].J Neurosci,1993,13(3):952-980.
[21]HochbergLR,Serruya MD,Friehs GM,et al.Neuronal ensemble control of prosthetic devices by a human with tetraplegia[J].Nature,2006,442(7099):164-171.
[22]Hoffman DS,Strick PL.Effects of a primary motor cortex lesion on step-tracking movements of the wrist[J].J Neurophysiol,1995,73(2):891-895.
[23]Humphrey DR,Schmidt EM,Thompson WD.Predicting measures of motor performance from multiple cortical spike trains[J].Science,1970,170(3959):758-762.
[24]Humphrey DR,Tan ji J.What features of voluntary motor control are encoded in the neuronal discharge of different cortical areas?[C].In:DR Humphrey,H-J Freund(eds).Motor Control:Concepts and Issues.New York:Wiley,1991.413-443.
[25]Jackson A,Mavoori J,Fetz EE.Correlations between the same motor cortex cells and arm muscles during a trained task,free behavior,and natural sleep in the macaque monkey[J].J Neurophysiol,2007,97(1):360-374.
[26]Jacobs KM,Donoghue JP.Reshaping the cortical motor map by unmasking latent intracortical connections[J].Science,1991,251(4996):944-947.
[27]Kakei S,Hoffman DS,Strick PL.Muscle and movement representations in the primary motor cortex[J].Science,1991,285(5436):2136-2139.
[28]Kalaska JF,Cohen DA,Hyde ML,et al.A comparison of movement direction-related versus load directionrelated activity in primate motor cortex,using a two-dimensional reaching task[J].J Neurosci,1989,9(6):2080-2102.
[29]Lawrence DG,Kuypers HG.The functional organization of the motor system in the monkey.I.The effects of bilateral pyramidal lesions[J].Brain,1968,91(1):1-14.
[30]Lemon RN.Functional Properties of monkey motor cortex neurones receiving afferent input from the hand and fingers[J].J Physiol,1981,311:497-519.
[31]Li CS,Padoa-Schioppa C,Bizzi E.Neuronal correlates of motor performance and motor learning in the primary motor cortex of monkeys adapting to an external forcefield[J].Neuron,2001,30(2):593-607.
[32]Maier MA,Bennett KM,Hepp-Reymond MC,et al.Contribution of the monkey corticomotoneuronal system to the control of force in precision grip[J].J Neurophysiol,1993,69(3):772-785.
[33]Mckiernan BJ,Marcario JK,Kerrer JH,et al.Correlations between corticomotoneuronal(CM)cell postspike effects and cell-target muscle covariation[J].J Neurophysiol,2000,83(1):99-115.
[34]Moran DW,Schwartz AB.Motor cortical activity during drawing movements:population representation during spiral tracing[J].J Neurophysiol,1999,82(5):2693-2704.
[35]Morrow MM,Jordan LR,Miller LE.Direct comparison of the task-dependent discharge of M1 in hand space and muscle space[J].J Neurophysiol,2007,97(2):1786-1798.
[36]Muir RB,Lemon RN.Corticospinal neurons with a special role in precision grip[J].Brain Res,1983,261(2):312-316.
[37]Murphy JT,Kwan MC,Mackay WA,et al.Spatial organization of precentral cortex in awake primates.Ⅲ.Input-output coupling[J].J Neurophysiol,1978,41(5):1132-1139.
[38]Musallam S,Corneil BD,Greger B,et al.Cognitive control signals for neural prosthetics[J].Science,2004,305(5681):258-262.
[39]Nudo RJ,Milliken GW,Jenkins WM,et al.Use-dependent alterations of movement representations in primary motor cortex of adult squirrel monkeys[J].J Neurosci,1996,16(2):785-807.
[40]Li C-SR,Padoa-Schioppa C,Bizzi E.Neuronal correlates of motor performance and motor learning in the primary motor cortex of monkeys adapting to an external force field[J].Neuron,2001,30(2):593-607.
[41]Padoa-Schioppa C,Li CS,Bizzi E.Neuronal activity in the supplementary motor area of monkeys adapting to anew dynamic environment[J].J Neurophysiol,2004,91(1):449-473.
[42]Paninski L,Fellows MR,Hatsopoulos NG,et al.Spatiotemporal tuning of motor cortical neurons for hand position and velocity[J].J Neurophysiol,2004,91(1):515-532.
[43]Park MC,Belhaj- Saïf A,Cheney PD.Properties of primary motor cortex output to forelimb muscles in rhesus macaques[J].J Neurophysiol,2004,92(5):2968-2984.
[44]Park MC,Belhaj-Saïf A,Gordon M,et al.Consistent features in the forelimb representation of primary motor cortex in rhesus macaques[J].J Neurosci,2001,21(8):2784-2792.
[45]Paz R,Boraud T,Natan C,et al.Preparatory activity in motor cortex reflects learning of local visuomotor skills[J].Nat Neurosci,2003,6(8):882-890.
[46]Rathelot JA,Strick PL.Muscle representation in the macaque motor cortex:an anatomical perspective[J].Proceedings of the National Academy of Sciences USA,2006,103(21):8257-8262.
[47]Rioult-Pedotti MS,Friedman D,Hess G,et al.Strengthening of horizontal cortical connections following skill learning[J].Nat Neurosci,1998,1(3):230-234.
[48]Rosén I,Asanuma H.Peripheral afferent inputs to the forelimb area of the monkey motor cortex:input-output relations[J].Exp Brain Res,1972,14(3):257-273.
[49]Sanes JN,Suner S,Lando JF,et al.Rapid reorganization of adult rat motor cortex somatic representation patterns after motor nerve injury[J].Proceedings of the National Academy of Sciences USA,1988,85(6):2003-2007.
[50]Schwartz AB.Motor cortical activity during drawing movements:population representation during sinusoidal tracing[J].J Neurophysiol,1993,70(1):28-36.
[51]Schwartz AB,Kettner RE,Georgopoulos AP.Primate motor cortex and free arm movements to visual targets in three-dimensional space.I.Relations between single cell discharge and direction of movement[J].J Neurosci,1988,8(8):2928-2937.
[52]Scott SH,Kalaska JF.Reaching movements with similar hand paths but different arm orientations.I Activity of individual cells in motor cortex[J].J Neurophysiol,1997,77(2):826-852.
[53]Sergio LE,Kalaska JF.Systematic changes in motor cortex cell activity with arm posture during directional isometric force generation[J].J Neurophysiol,2003,89(1):212-228.
[54]Sergio LE,Hamel-Pâquet C,Kalaska JF.Motor cortex neural correlates of output kinematics and kinetics during isometric-force and arm-reaching tasks[J].J Neurophysiol,2005,94(4):2353-2378.
[55]Shen L,Alexander GE.Neural correlates of a spatial sensory-to-motor transformation in primary motor cortex[J].J Neurophysiol,1997,77(3):1171-1194.
[56]Shinoda Y,Yokota J,Futami T.Divergent projections of individual corticospinal axons to motoneurons of multiple muscles in the monkey[J].NeurosciLett,1981,23(1):7-12.
[57]Smith AM,Hepp-Reymond MC,Wyss UR.Relation of activity in precentral cortical neurons to force and rate of force change during isometric contractions of finger muscles[J].Exp Brain Res,1975,23(3):315-332.
[58]Thach WT.Correlation of neural discharge with pattern and force of muscular activity,joint position,and direction of intended next arm movement in motor cortex and cerebellum[J].J Neurophysiol,1978,41(3):654-676.
[59]Townsend BR,Paninski L,Lemon RN.Linear coding of muscle activity in primary motor cortex and cerebellum[J].J Neurophysiol,2006,96(5):2578-2592.
[60]Velliste M,Perel S,Spalding MC,et al.Cortical control of a prosthetic arm for self-feeding[J].Nature,2008,453(7198):1098-1101.
[61]Wise SP,Moody SL,Blomstrom KJ,et al.Changes in motor cortical activity during visuomotor adaptation[J].Exp Brain Res,1998,121(3):285-299.
[62]AjemianR,Green A,Bullock D,et al.Assessing the function or motor cortex:single-neuron models of how neural response is modulated by limb biomechanics[J].Neuron,2008,58(3):414-428.
[63]BuchER,Brasted PJ,Wise SP.Comparison of population activity in dorsal premotor cortex and putamen during the learning of arbitrary visuomotormappings[J].Exp Brain Res,2006,169(1):69-84.
[64]Cattaneo L,Fabbri-Destro M,Boria S,et al.Impairment of actions chains in autism and its possible role in intention understanding[J].ProcNatlAcadSci USA,2007,104(45):17825-17830.
[65]Cisek P,CrammondDJ,Kalaska JF.Neural activity in primary motor and dorsal premotor cortex in reaching tasks with the contralateral versus ipsilateralarm[J].J Neurophysiol,2003,89(2):922-942.
[66]CisekP,Kalaska JE.Neural correlates of reaching decisions in dorsal premotor cortex:specification of multiple direction choices and final selection of action[J].Neuron,2005,45(5):801-814.
[67]Cisek P,Kalaska JF.Neural correlates of mental rehearsal in dorsal premotor cortex[J].Nature,2004,431(7011):993-996.
[68]Cramond DJ,Kalaska JF.Prior information in motor and premotor cortex:activity in the delay period and effect on pre-movement activity[J].J Neurophysiol,2000,84(2):986-1005.
[69]Cui H,Andersen RA.Posterior parietal cortex encodes autonomously selected motor plans[J].Neuron,2007,56(3):552-559.
[70]Deecke L,Scheid P,Kornhuber HH.Distribution of readiness potential,pre-motion positivity,and motor potential of the human cerebral cortex preceding voluntary finger movements[J].Exp Brain Res,1967,7(2):158-168.
[71]Duhamel JR,Bremmer F,Hamed SB,et al.Spatial invariance of visual receptive fields in parietal cortex neurons[J].Nature,1997,389(6653):845-848.
[72]Duhamel JR,Colby CL,Goldberg ME.Ventral intraparietal area of the macaque:congruent visual and somatic response properties[J].J Neurophysiol,1998,79(1):126-136.
[73]Fattori P,Kutz DF,Breveglieri R,et al.Spatial tuning of reaching activity in the medial parieto-occipital cortex (area V6A)of macaque monkey[J].Eur I Neurosci,2005,22(4):956-972.
[74]Fogassi L,Ferrari PF,Gesierich B,et al.Parietal lobe:from action organization to intention understanding[J].Science,2005,308(5722):662-667.
[75]Fogassi L,Gallese V,Fadiga L,et al.Coding of peripersonal space in inferior premotor cortex (area F4)[J].J Neurophysiol,1996,76(1):141-157.
[76]Gallese V,Fadiga L,Fogassi L,et al.Action recognition in the premotor cortex[J].Brain,1996,119(2):593-609.
[77]Graziano MSA,Yap GS,Gross CG.Coding of visual space by premotor neurons[J].Science,1994,266(5187):1054-1057.
[78]Tsai CG,Chen CC,Chou TL,et al.Neural mechanisms involved in the oral representation of percussion music:An fMRI study[J].Brain and cognition,2010,74(2):123-131.
[79]Hoshi E,Tanji J.Differential involvement of neurons In the dorsal and ventral premotor cortex during processing of visual signals for action planning[J].J Neurophysiol,2006,95(6):3596-3616.
[80]Hoshi E,Tanji J.Differential roles of neuronal activity in the supplementary and presupplementary motor areas:from information retrieval to motor planning and execution[J].J Neurophysiol,2004,92(6):3482-3499.
[81]Jeannerod M,Arbib MA,Rizzolatti G,et al.Grasping objects:the cortical mechanisms of visuomotor transformation [J].Trends Neurosci,1995,18(7):314-320.
[82]Jeannerod M,Decety J.Mental motor imagery:a window into the representational stages of action[J].CurrOpinNeurobiol,1995,5(6):727-732.
[83]Kakei S.Hoffman DS,Strick PL.Direction of action is represented in the ventral premotor cortex[J].Nat Neurose,2001,4(10):1020-1025.
[84]Kalaska JE,Crammond DJ.Deciding not to go:neuronal correlates of response selection in a GO/NOGO task in primate premotor and parietal cortex[J].Cereb Cortex,1995,5(5):410-428.
[85]Libet B.Mind Time:The Temporal Factor in Consciousness[M].Cambridge,MA:Harvard Univ Press,2004,255-256.
[86]Luppino G,Matelli M,Camarda RM,et al.Multiple representations of body movements in mesial area 6 and the adjacent cingulate cortex:an intracorticalmicrostimulation study in the macaque monkey[J].J Comp Neurol,1991,311(4):463-482.
[87]Massion J.Movement,posture and equilibrium:interaction and coordination[J].ProgNeurobiol,1992,38(1):35-56.
[88]Mitz AR,Godschalk M,Wise SP.Learning-dependent neuronal activity in the premotor cortex:activity during the acquisition of conditional motor associations[J].J Neurosci,1991,11(6):1855-1872.
[89]Murata A,Fadiga L,Fogassi L,et al.Object representation in the ventral premotor cortex (area F5)of the monkey[J].J Neurophysiol,1997,78(4):2226-2230.
[90]Murata A,Gallese V,Luppino G,et al.Selectivity for the shape,size,and orientation of objects for grasping in neurons of monkey parietal area AIP[J].J Neurophysiol,2000,83(5):2580-2601.
[91]Nakayama Y,Yamagata T,Tanji J,et al.Transformation of a virtual action plan into a motor plan in the premotor cortex[J].J Neurosci,2008,28(41):10287-10297.
[92]Ochia T,Muchiake H,Tanji J.Involvement of the ventral premotor cortex in controlling image motion of the hand during performance of a target-capturing task[J].Cereb Cortex,2005,15(7):929-937.
[93]Rizzolatti G,Camarda R,Fogassi L,et al.Functional organization of inferior area 6 in the macaque monkey.Ⅱ.Area F5 and the control of distal movement[J].Exp Brain Res,1988,71(3):491-507.
[94]Rizzolatti G,Gentilucci M,Camarda RM,et al.Neurons related to reaching-grasping arm movements in the rostral part of area 6 (area 6abeta)[J].Exp Brain Res,1990,82(2):337-350.
[95]Rizzolatti G,Fadiga L,Gallese V,et al.Premotor cortex and the recognition of motor actions[J].Brain Res Cogn Brain Res,1996,3(2):131-141.
[96]Romo R,Hernández A,Zainos A.Neuronal correlates of a perceptual decision in ventral premotor cortex[J].Neuron,2004,41(1):165-173.
[97]Sakata H,Taira M,Murata A,et al.Neural mechanism of visual guidance of hand action in the parietal cortex of the monkey[J].Cereb Cortex,1995,5(5):429-438.
[98]Schieber MH,Hibbard LS.How somatotopic is the motor cortex hand area?[J].Science,1993,261(5120):489-492.
[99]Wallis JD,Miller EK.From rule to response:neuronal processes in the premotor and prefrontal cortex[J].J Neurophysiol,2003,90(3):1790-1806.
[100]Yamagata T,Nakayama Y,Tanji J,et al.Processing of visual signals for direct specification of motor targets and for conceptual representation of action targets in the dorsal and ventral premotor cortex[J].J Neurophysiol,2009,102(6):3280-3294.
[101]Adam A,De Luca CJ.Firing rates of motor units in human vastus lateralis muscle during fatiguing isometric contractions[J].Journal of Applied Physiology,2005,99(1):268-280.
[102]Al-Mulla M R,Sepulveda F,Colley M.A review of non-invasive techniques to detect and predict localised muscle fatigue[J].Sensors,2011,11(4):3545-3594.
[103]Ament W,Bonga G J J,Hof A L,et al.Electromyogram median power frequency in dynamic exercise at medium exercise intensities[J].European Journal of Applied Physiology and Occupational Physiology,1996,74(1-2):180-186.
[104]Anmuth C J,Goldberg G,Mayer N H.Fractal dimension of electromyographic signals recorded with surface electrodes during isometric contractions is linearly correlated with muscle activation[J].Muscle &Nerve,1994,17(8):953-954.
[105]Arabadzhiev T I,Dimitrov V G,Dimitrova N A,et al.Interpretation of EMG integral or RMS and estimates of "neuromuscular efficiency" can be misleading in fatiguing contraction[J].J Electromyogr Kinesiol,2010,20(2):223-232.
[106]Arendt-Nielsen L,Mills K R.Muscle fibre conduction velocity,mean power frequency,mean EMG voltage and force during submaximal fatiguing contractions of human quadriceps[J].European Journal of Applied Physiology and Occupational Physiology,1988,58(1-2):20-25.
[107]Arendt-Nielsen L,Sinkjær T.Quantification of human dynamic muscle fatigue by electromyography and kinematic profiles[J].Journal of Electromyography &Kinesiology,1991,1(1):1-8.
[108]Baker A J,Kostov K G,Miller R G,et al.Slow force recovery after long-duration exercise:metabolic and activation factors in muscle fatigue[J].Journal of Applied Physiology,1993,74(5):2294-2300.
[109]Barry BK,Enoka RM.The neurobiology of muscle fatigue:15 years later[J].Integrative &Comparative Biology,2007,47(4):465-473.
[110]Whittaker RG.The fundamentals of electromyography[J].Pract Neurol.2012,12(3):187-194.
[111]Bigland-Ritchie B,Donovan E F,Roussos C S.Conduction velocity and EMG power spectrum changes in fatigue of sustained maximal efforts[J].Journal of Applied Physiology,1981,51(5):1300-1305.
[112]Bigland-Ritchie B,Johansson R,Lippold O C,et al.Changes in motoneurone firing rates during sustained maximal voluntary contractions[J].J.Physiol.(Lond.),1983,340:335-346.
[113]B.Bigland-Ritchie,Woods J J.Changes in muscle contractile properties and neural control during human muscular fatigue[J].Muscle &Nerve,1984,7(9):691-699.
[114]Bonato P,Cheng M S,Gonzalez-Cueto J,et al.EMG-based measures of fatigue during a repetitive squat exercise[J].IEEEEng Med Biol Mag,2001,20(6):133-143.
[115]Bonato P,Gagliati G,Knaflitz M.Analysis of myoelectric signals recorded during dynamic contractions[J].IEEE Eng Med Biol Mag,1996,15(6):102-111.
[116]Bonato P,Roy S H,Knaflitz M,et al.Time-frequency parameters of the surface myoelectric signal for assessing muscle fatigue during cyclic dynamic contractions[J].IEEE Eng Med Biol Mag,2001,48(7):745-753.
[117]Boyas S,A.Guével.Neuromuscular fatigue in healthy muscle:underlying factors and adaptation mechanisms[J].Ann Phys Rehabil Med,2011,54(2):88-108.
[118]Cairns S P,Knicker A J,Thompson M W,et al.Evaluation of models used to study neuromuscular fatigue[J].Exercise &Sport Sciences Reviews,2005,33(1):9-16.
[119]Chaffin D B.Localized muscle fatigue-definition and measurement[J].Journal of Occupational and Environmental Medicine,1973,15(4):346-354.
[120]Cheng,A.J.Fatigue and recovery of power and isometric torque following isotonic knee extensions[J].Journal of Applied Physiology,2005,99(4):1446-1452.
[121]Cifrek M,Medved V,Tonkovi S,et al.Surface EMG based muscle fatigue evaluation in biomechanics[J].Clinical Biomechanics,2009,24(4):327-340.
[122]Dideriksen J L,Farina D,Baekgaard M,et al.An integrative model of motor unit activity during sustained submaximal contractions[J].Journal of Applied Physiology,2010,108(6):1550-1562.
[123]Dideriksen JL,Farina D,Enoka RM.Influence of fatigue on the simulated relation between the amplitude of the surface electromyogram and muscle force[J].Philos Trans A Math Phys Eng Sci,2010,368(1920):2765-2781.
[124]Dimitrov G V,Arabadzhiev T I,Mileva K N,et al.Muscle fatigue during dynamic contractions assessed by new spectral indices[J].Med Sci Sports Exerc,2006,38(11):1971-1979.
[125]Dimitrova N A,Dimitrov G V.Amplitude-related characteristics of motor unit and M-wave potentials during fatigue.A simulation study using literature data on intracellular potential changes found in vitro[J].J Electromyogr Kinesiol,2002,12(5):339-349.
[126]Eckmann J P,Kamphorst S O,Ruelle D.Recurrence plots of dynamical systems[J].Europhysics Letters (EPL),1987,4(9):973-977.
[127]Edwards RH.Human muscle function and fatigue[J].Ciba Found.Symp,1981,82:1-18.
[128]Farina D.Interpretation of the surface electromyogram in dynamic contractions[J].Exerc Sport Sci Rev,2006,34(3):121-127.
[129]Farina D,Fattorini L,Felici F,et al.Nonlinear surface EMG analysis to detect changes of motor unit conduction velocity and synchronization[J].Journal of Applied Physiology,2002,93(5):1753-1763.
[130]Farina D,Frédéric Leclerc,Arendt-Nielsen L,et al.The change in spatial distribution of upper trapezius muscle activity is correlated to contraction duration[J].J Electromyogr Kinesiol,2008,18(1):16-25.
[131]Farina D,Merletti R,Enoka RM.The extraction of neural strategies from the surface EMG[J].J Appl Physiol,2004,96(4):1486-1495.
[132]Felici F,Rosponi A,Sbriccoli P,et al.Linear and non-linear analysis of surface electromyograms in weightlifters[J].European Journal of Applied Physiology,2001,84(4):337-342.
[133]Fuglevand AJ,Keen DA.Re-evaluation of muscle wisdom in the human adductor pollicis using physiological rates of stimulation[J].J Physiol,2003,549(Pt3):865-875.
[134]Gandevia S C.Spinal and supraspinal factors in human muscle fatigue[J].PhysiolRev,2001,81(4):1725-1789.
[135]Wang G,Ren X M,Li L,et al.Multifractal analysis of surface EMG signals for assessing muscle fatigue during static contractions[J].J Zhejiang Univ Sci A,2007,8(6):910-915.
[136]Gerdle B,Larsson B,Karlsson S.Criterion validation of surface EMG variables as fatigue indicators using peak torque:a study of repetitive maximum isokinetic knee extensions[J].J Electromyogr Kinesiol,2000,10(4):225-232.
[137]Gitter J A,Czerniecki M J.Fractal analysis of the electromyographic interference pattern[J].J Neurosci Methods,1995,58(1-2):103-108.
[138]Gonzalez-Izal M,Falla D,Izquierdo M,et al.Predicting force loss during dynamic fatiguing exercises from non-linear mapping of features of the surface electromyogram[J].J Neurosci Methods,2010,190(2):271-278.
[139]González-Izal M,Malanda A,Navarro-Amézqueta I,et al.EMG spectral indices and muscle power fatigue during dynamic contractions.[J].J Electromyogr Kinesiol,2010,20(2):233-240.
[140]Gonzalez-Izal M,Malanda A,I Rodríguez-Carreño,et al.Linear vs.non-linear mapping of peak power using surface EMG features during dynamic fatiguing contractions[J].J Biomech,2010,43(13):2589-2594.
[141]González-Izal M,Rodríguez-Carreño I,Malanda A,et al.sEMG wavelet-based indices predicts muscle power loss during dynamic contractions[J].J Electromyogr Kinesiol,2010,20(6):1097-1106.
[142]Izquierdo M,González-Izal M,Navarro-Amezqueta I,et al.Effects of strength training on muscle fatigue mapping from surface EMG and blood metabolites[J].Med Sci Sports Exerc,2011,43(2):303-311.
[143]Klimesch W.EEG alpha and theta oscillations reflect cognitive and memory performance:a review and analysis[J].Brain Research Reviews,1999,29(2-3):169-195.
[144]Pascual-Marqui R D,Michel C M,Lehmann D.Low resolution electromagnetic tomography:a new method for localizing electrical activity in the brain [J].International Journal of Psychophysiology,1994,18(1):49-65.
[145]Curran D J.Instrumental and separation analysis (Kenner,C.T.)[J].J.neurosci.methods,2004,134(1):21.
[146]Nunez P L,Srinivasan R.Electric fields of the brain:theneurophysics of EEG[J].Physics Today,1982,35(6):59-59.
[147]Pun R Y K,Kleene S J.An estimate of the resting membrane resistance of frog olfactory receptor neurons [J].Journal of Physiology (Oxford),2004,559(2):535-542.
[148]Delorme A,Sejnowski T,Makeig S.Enhanced detection of artifacts in EEG data using higher-order statistics and independent component analysis[J].Neuroimage,2007,34(4):1443-1449.
[149]Ferree T C,Luu P,Russell G S,et al.Scalp electrode impedance,infection risk,and EEG data quality [J].Clinical Neurophysiology,2001,112(3):536-544.
[150]NyboL,Nielsen B.Hyperthermia and central fatigue during prolonged exercise in humans[J].Journal of Applied Physiology,2001,91(3):1055-1060.
[151]OntonJ,Delorme A,Makeig S.Frontal midline EEG dynamics during working memory[J].Neuroimage,2005,27(2):341-356.
[152]Lars N,Bodil N.Perceived exertion is associated with an altered brain activity during exercise with progressive hyperthermia[J].Journal of Applied Physiology,2001,91(5):2017-2023.
[153]Onton J,Westerfield M,Townsend J,et al.Imaging human EEG dynamics using independent component analysis[J].Neuroscience &Biobehavioral Reviews,2006,30(6):808-822.
[154]Vernon D,Egner T,Cooper N,et al.The effect of training distinct neurofeedback protocols on aspects of cognitive performance[J].International Journal of Psychophysiology,2003,47(1):75-85.
[155]Hillman C H,Snook E M,Jerome G J.Acute cardiovascular exercise and executive control function[J].International Journal of Psychophysiology,2003,48(3):307-314.
[156]Stone J V.Independent component analysis:an introduction[J].Trends in Cognitive Sciences,2002,6(2):59-64.
[157]Niedermeyer E.The clinical relevance of EEG interpretation[J].Clin Electroencephalogr.2003;34(3):93-98.
[158]EgnerT,Gruzelier J H.EEG biofeedback of low beta band components:frequency-specific effects on variables of attention and event-related brain potentials[J].Clinical Neurophysiology,2004,115(1):131-139.
[159]PfurtschellerG,Leeb R,Keinrath C,et al.Walking from thought[J].Brain Research,2006,1071(1):145-152.
[160]Castellanos N P,Makarov V A.Recovering EEG brain signals:artifact suppression with wavelet enhanced independent component analysis[J].Journal of Neuroscience Methods,2006,158(2):300-312.
[161]Walsh E,Oakley DA,Halligan PW,et al,Deeley Q.Brain mechanisms for loss of awareness of thought and movement[J].Soc Cogn Affect Neurosci,2017,12(5):793-801.
[162]EgnerT,Gruzelier J.Ecological validity of neurofeedback:modulation of slow wave EEG enhances musical performance[J].Neuroreport,2003,14(9):1221.
[163]Hong-Yan L I,Run-Fang H,Jian-Fen M A,et al.Image enhancement algorithm based on independent component analysis[J].Journal of Projectiles Rockets Missiles &Guidance,2007,27(5):299-302.
[164]EgnerT,Gruzelier J H.Learned self-regulation of EEG frequency components affects attention and eventrelated brain potentials in humans[J].Neuroreport,2001,12(18):4155-4159.
[165]Haufler A J,Spalding T W,Santa Maria D L,et al.Neuro-cognitive activity during a self-paced visuospatial task:comparative EEG profiles in marksmen and novice shooters[J].Biological Psychology,2000,53(2):131-160.
[166]LevanP,Urrestarazu E,Gotman J.A system for automatic artifact removal in ictal scalp EEG based on independent component analysis and Bayesian classification[J].Clinical Neurophysiology,2006,117(4):912-927.