ebook img

Arousal, Activation, and Effort in the Control of Attention PDF

35 Pages·2010·1.19 MB·English
by  
Save to my drive
Quick download
Download
Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.

Preview Arousal, Activation, and Effort in the Control of Attention

Psydowf.icoJReview 1975 Yo. 82, No.2, 116-149 Arousal, Activation, and Effort in the Control of Attention Karl H. Pribram Stanford University AND Diane McGuinness University College, London, and the Hatfield Polytechnic, Hatfield, England PIYC"/lkolR~ 1975, Vol. 8l, No. l, IHI-149 Arousal, Activation, and Effort in the Control of Attention Karl H. Pribram Diane McGuinness Stanford University University College, London, and the Hatfield Polytechnic, Hatfield, England This review attempts to organize a range of neuropsychological and psycho physiological data On attention. Three separate, but interacting, neural sys tems are distinguished: One controls arousal, which is defined in terms of phasic physiological responses to input. The arousal control circuits center on the amygdala. A second system controls activation, which is defined in terms of tonic physiological readiness to respond. The readiness circuits center on the basal ganglia of the forebrain. A third system is discerned which coordinates arousal and activation. This coordinating activity is defined as demanding effort. Its cin;uitry centers on the hippocampus. When arousal, activation, and effort are involved in problem solving, at least two further distinctions can be made. During categorizing, arousal precedes activation; during reasoning, activation precedes arousal. Finally, the review addresses the Question of whether effort in problem solving is to be attributed solely to peripheral muscular factors or whether, in fact, direct monitoring of changes in brain organization (changes in set, attitude, etc.) can be productive of measurable indicators of effort. In the mid 1960s,R. J. Douglasand K. H. sensory events (orienting, vigilance, and Pribram presented a series of experiments habituation) and (b) the invariant (cate detailing the effects of hippocampal lesions gorizing), or the variable but computable on problem-solving behavior. The results of (reasoning), pairing of the outcome of re these experiments were accounted for by re sponse (reinforcement) to sensory events. course to the concept of experiencing a An assessmentofthe data derived from these change in awareness which was interpreted paradigms (in approximately 200 experi as indicating the involvement of "attention." ments) has led us to identify three basic at A continuing interest in problems of atten tentional control processes: One regulates tion has been reflected not only in the work arousal resulting from input; a second con reported from our laboratory (a dozen and a trols the preparatory activation of response half papers) but also in that of many others mechanisms; and a third operates to co (see reviews by Mostofsky, 1970; Horn and ordinate arousal and activation, an operation Hinde, 1970; and Kahneman, 1973). Re that demands effort. The first two sections search has largely been directed to two gen of this review will delineate these attentional eral paradigms defined by the following op control systems; the last section will deal pri erations: (a) recording the occurrence of marily with higher order corticalattentional physiological or behavioral responses against controls that operate during categorizing and a background of monotonous repetition of reasoning. We wish to express our gratitude to Muriel REFLEX ATTENTION, REPRESENTATION, AND Bagshaw for additional data analysis and for al THE CONTROL OF AROUSAL lowing us to present her unpublished work in this Arousal is said to occur when an input manuscript, and to Linda Heider and Barbara change produces a measurable incrementing Honegger for their patient help. The research involved was supported by National Institute of of a physiological (e.g., single unit record Mental Health Grant MH-12970-08 and National ing of neural potentials; galvanic skin re Institute of Mental Health Career Award MH sponse) or behavioral (e.g., response ampli 15214-13 to the first author. tude of a spinal reflex; frequency of a loco Requests for reprints should be sent to Karl H. Pribram, Departmentof Psychology, Stanford Uni motor response) indicator over a baseline. versity, Stanford, California 94305. The types of input change that produce 116 THE CONTROL OF ATTENTION 117 arousal have been studied extensively and ability of neural tissue as a consequence of have been labeled by Berlyne (1969) as col experience seized on the habituation of an lative variables. These include sudden initial neural or behavioral arousal reaction changes in intensity to which the organism as an extremely simple test paradigm that is unaccustomed, changes in the timing of suited this purpose. Although these efforts inputs, and changes in the ground in which and results have been reviewed by Horn and a stimulus figure appears, in particular when Hinde (1970), we will highlight certain is input is scarce, surprising, complex, and sues that are relevant to this presenetation. novel. Such collative characteristics also An approach initiated by Spencer and define the concept "information" as it is used Thompson (see Groves and Thompson, in the study of communication systems (see 1970) involved recording from the spinal e.g., Brillouin, 1962); thus it is possible to cord and illustrated that neither sensory af treat organisms subject to arousal as "in ferents nor motor efferents accounted for formation processing systems," where input habituation of spinal reflex behavior. Fur is matched against some residual in the or ther, Thompson discerned two primary sys ganism of his past experience, or some com tems, two classes of neurons; those that re petence (Miller, Galanter, &Pribram, 1960; sponded more slowly and incremented for Pribram, 1971). Without such matching, relatively long periods before decrementing, there could be no novelty or information nor and those that rapidly decremented their ac even a measure of change in intensity. tivity with repetition of the stimulus. The This knowledge has led to behavioral re incrementing "monitoring," "sameness," or search which has been addressed to such is "arousal" neurons lie more ventrally and sues as adaptation level (Helson, 1964), medially in the region of the origin of the expectancy (Bruner, 1957) and the develop visceroautonomic outflow, while the decre ment of "neuronal models" (Sokolov 1960, menting neurons lie, for the most part, in the 1963), while neuroscientists were able to dorsal horn of the spinal cord. Convergence demonstrate the occurrence of a permanent of these two systems of neurons was as or semipermanent modifiability of neural tis sumed to account for the activity of a third sue (see Pribram and Broadbent, 1970; population of ("novelty") neurons whose Horn and Hinde, 1970). response characteristics were identical to those demonstrated by the reflex: arousal Neural Modifiability reaction, habituation, and dishabituation. Sharpless and Jasper's (1956) and Soko Thompson's parallel processing model of lov's (1963) classical studies paved the way arousal, habituation and dishabituation, for an analysis of the requisites for produc shared by many other investigators (e.g., ing behavioral and physiological arousal re Horn, 1970; Segundo &Bell, 1970; Spencer spomes. Especially significant was the im & April, 1970) is simpler than Sokolov's as plication of information processing systems it depends only on spatial summation of by Sokolov's findings (1963) that any arousal and decrementing. No "neuronal change in a repetitively presented stimulus model" of the input is developed, only a configuratioil would elicit responses even decrementing to repetition and an "arousal" when that change was a shortening of the proportional to the strength of the input. sensory input or the lowering of its intensity. The model does not account for Sokolov's Sokolov concluded that the organism's sensi findings that in the intact organism dis tivity was not just a measure of its threshold habituation occurs when stimulus duration is but rather that sensitivity was a function of shortenedor stimulus intensity is diminished. a match between input and some competence, These phenomena imply a hierarchical pro a neuronal "model," or a patterned memory cess involvingstorageand subsequent match trace developed in the br~in as a representa ingof input to store. Horn (Horn &Hinde. tion of the experienced stimulus configura 1970) has developed a scheme whereby such tion. Any mismatch produces orienting. a hierarchical process can be realized without Many investigators concerned with modifi- any unnecessary assumptions that go beyond 118 KARL H. PRIBRAM AND DIANE MCGUINNESS the data obtained by practically everyone; pIe auditory, visual, or cutaneous stimuli in namely that the decrementing observed is the absence of hypothalamic stimulation. due to self-generated synaptic depressionand Since these physiological changes are the not to the development of inhibition (inhibi same as those observed in all orienting re tory postsynaptic potentials characterized in sponses, the defense reaction could therefore intracellular recordings by hyperpolariza be considered in part as due to an increase tion). of arousal. . This does not mean, of course, that inhibi Sensory'SJ1stems and the Neuronal Model tion fails to occur in many systems. The sensory and motor pathways are replete with There is ample evidence that a host of circuits that lead to both lateral (i.e., neigh other brain mechanisms are involved in the borhood) and self-inhibition. As we shall orienting reaction. Electrical brain record see shortly, habituation becomes organized ing, both with macro- and with, microelec into patterns in these pathways whether by trodes, shows that initial desynchronization the mechanisms proposed by Horn or by the and increase in neuronal discharge occurs in action of inhibitory circuits, or both. a large number of neural systems. One of the characteristics of familiarization con Core Brain Arousal System sequent on repetition of a stimulus is the The rostral extension into the mesen progressive restriction of these sites (John, cephalic brain stem of a column of medially 1967;John & Killam, 1960). Paradoxically, placed cells accountsfor the well documented however, this restriction involves primarily arousal effects ofstimulationsofthe reticular the sites where arousal neurons are located formation (see Lindsley, 1961, and Magoun, and does not encompass either sensory path 1958 for review). Less well known is the ways or the primary sensory projection sys fact that such effects are obtained even more tems where responses continue to be re rostrally in the diencephalon in a continua corded in the habituated organism. These, tion of this neuron system into the hypo therefore, became prime candidates for the thalamus. locus of comparison of the input stimulus The contribution of hypothalamic viscero configuration with the neuronal model regis autonomic mechanisms to the reflexive as tered earlier through habituation. pects of the orienting reaction has been To determine where the detailed compari noted by Feldman and Waller (1962). The sons necessary to the Sokolovian model of episodes of fighting and fleeing that are pro habituation and orienting might occur, duced by electrical or chemical stimulation Grandstaff and Pribram (1972) studied the to the so-called "defense" region of the hy possibility that Thompson's results pertained pothalamus can be related to the orienting only to spinal cord and perhaps lower brain reaction. Abrahams and Hilton 0958) and stem mechanisms but that at more rostral Abrahams, Hilton, and Zbrozyna (1964) stations of the sensory projection systems, found that. in attempting to produce a de patterns of change rather than simple dec fense response by stimulation of the hypo rementing were produced during habitua thalamus, at first, a much lower degree of tion. Surprisingly, this study showed the arousal occurred, indicatedby pupildilatation Thompson model to hold at the collicular and and postural alerting. Only when the level of thalamic levels: electrical responses recorded stimulation was increased and maintained for from the lateral geniculate nucleus as well as a few seconds did hissing, snarling, running, those from the retina and superior colliculus and piloerection occur. In the later study, (also obtained with microelectrodes by Horn alerting behaviors were measured in greater and Hill, 1966; and by Bures and Buresova. detail, and during mild stimulation the 1970) in intact monkeys subjected to repeti authors observed changes in pupil dilation, tive visualstimulationuniformly decremented head movement, pricking the ears, respira to repetitive monotonous stimulation, and tion, and blood flow. These same changes enhanced responses occurred only when a were also recorded during responses to sim- change in stimulation was initiated. Soko- THE CONTROL OF ATTENTION 119 lov's model was saved, however, by the re ing mechanism that relies on an initial simul sults obtained from recordings of the activ taneous parallel processing stage, a problem ity of visual cortex. Here, habituation which will be considered in the section on produced no uniform decrementing-some categorizing. Here we first outline the records invariably and reliably showed an in neural systems involved in the arousal and crementing of activity, while others decre activation that leads to desynchronization of mented (over each of many days of record the patternedneuronal model. ing) and still others showed no reliable Amygdala Circuits changes. A patterned habituation response occurred, and dishabituation to a change in There is evidence for the involvement of stimulation disrupted this pattern. the amygdala and related frontal cortical Patterned changes in cortical rhythmicity structures in the attentional control of the also occur. Thus patterning of electrical core brain arousal systems. This evidence brain activity is not limited to abrupt poten delineates two reciprocally acting circuits, tials evoked by the stimulus. Earlier studies one facilitatory andthe other inhibitory, both have been reviewed byJ.Mackworth (1969). converging on hypothalamic structures re More recently it was shown that during lated to arousal. Such reciprocal innervation habituation, changes occur in both latency allows sensitive modulation (tuning) of the (increase) and duration (decrease) of de arousal mechanism. synchronization when baseline activity is in In pursuing the question of which brain the 10 Hz alpha frequency range (Bagshaw systems are involved in orienting and habitu & Benzies, 1968; Grandstaff & Pribram, ation, we first replicated and showed some 1972). More complex frequency analysis of of the limits over which the Sokolov results the ongoing cortical activity of limited areas held (Koepke & Pribram, 1966, 1967). of the visual cortex (Grandstaff &Pribram, Whenadapting the techniques to the monkey 1972) has shown that a decrease in power with habituation in 8-10, 37-50, and 72-80 Hz frequency ranges occurs when the ampli tude of the evoked potential decreases. By 0---0 N contrast, in those electrode placements where so Jrt••••••_ H 0·.··...········0IT the amplitude of the evoked response in g······..·······OAH creases, an increase in power in the alpha and other critical ranges is obtained. These patterns ofchangedo notoccurat subcortical 60 loci (optic nerve and lateral geniculate nu AVG c1eus) but are limited to recordings made PERCENT from the visual cortex, supporting the con GSR clusion that patterning of neuroelectric ac 40 tivity, an indication of the construction of a "neuronal model," is primarily the function of a cortital information processing com 20 petency. The occurrence of a patterned response at the cortex suggests that each of the cor tical sitescan beconsidered separate informa tion processing channels, which is consonant Z 3 4 10TRIAL BLOCKS with the anatomy of these systems. Neisser (1967), Kahneman (1973), and Lindsay FIGURE1. Curvesforoverallpercentageofgalvanic (1970) have thoroughly reviewed the be skin response (GSR) tothe first 50presentationsof anirregularlypresented2-sectone. (Abbreviations: havioral evidence for considering the sensory N=unoperated group; H =hippocampectornized channels to be primarily parallel processing group; IT=control group; AM=amygdalectom systems, or at least some form of multiplex- ized group.) 120 KARL H. PRIBRAM AND DIANE MCGUINNESS 80,...--'!:P----...l'l.-----r---, parallel behavioral orienting. In many in stances the opposite was observed. Resections of dorsolateral frontal cortex always abolish the visceroautonomic com ponents of orienting (Kimble, Bagshaw, & 60 Pribram, 1965; Luria & Homskaya, 1970; w Luria, Pribram, & Homskaya, 1964), while oCzi) amygdala, resections produce a bimodal dis ll; tribution. Electrodermal responses during w IX: orienting (Figures 1 and 2; Bagshaw & g; 6 HIPPOCAMPECTOMY 40 oCONTROL Benzies, 1968; Bagshaw, Kimble, & Pri Cl 1/l. • AMYGDALECTOMY bram, 1965) are reduced in amplitude and z « amount for most subjects. However, certain w :E subjects show an increas~number and am plitude of response (see Figure 3 and Table 20 i). Tonic heart ,rate is paradoxically ele vated (see below), but all phasic heart rate responses areabolished (Bagshaw& Benzies, 1968; Pribram, Reitz, McNeil, & Spevack, OL-_...L... L..- ....l.._---J 1974). 1-7 8-14 15-21 Thus, reciprocal systems appear to be in TRIALSOF2-SECPURE TONE volved-one apparently relates to the dorso lateral frontal cortex since resections of this FIGURE 2. Curves for a more detailed analysis of the first 21 trials (split into 7-trial blocks) or structure im'ariably eliminate visceral-auto percentage of galvanic skin response (GSR) to a nomic orienting responses. The other, op- 2-sec tone for the amygdalectomized, hippocampec tomized, and unoperated monkeys. (See also Table 1.) ~\ ........ 0 AMYGDALECTOMY ",'" \ (Responders) ...... \ • AMYGDALECTOMY_ we found, contrary to expectation, that le 0'"" "(Non-responders, sions of the mediobasal, frontolimbic fore \6 HIPPOCAMPECTOM \ brain, and not of the convexity of the cere o INFEROTEMPORAL \ CORTEXABLATlON \ bral mantle, had a dramatic effect on mea o CONTROL \\ J sures of orienting (Bagshaw, Kimble, & \ \ Pribram, 1965; Kimble, Bagshaw, & Pri bram, 1965). \ I Amygdalectomy results in a failure of ~J behavioral habituation, producing an ever recurring locomotor orienting reaction (Bag .... 0:J ~ ~I shaw & Benzies, 1968; Schwartzbaum, Wil son, & Morrissette, 1961). Such hyper reactivity is also produced by lesions of the ........ ........ orbital surface of the frontal lobe (Mettler ....... & McLardy, 1948; Ruch & Shenkin, 1943; ol.-_~ ~"'. _ Wall &Davis, 1951) which has been shown 1-7 8-14 15-21 to be a part of a larger orbitofrontal-insular TRIALOF2SECPURETONE temporal-polar-amygdala system (Kaada, FIGCRE 3. Group mean amplitude for galvanic Pribram, &Epstein, 1949). When an analy skin response (GSR) to tone on the first 21 trials sis of the visceroautonomic components of showing the bimodal distribution of the amygdal ectomized monkeys when compared with normal the orienting response was carried out on (control) and with two other brain-Iesioned groups frontal and amygdalectomized'monkeys, it of monkeys: inferotemporal cortex resection and was expected that these components would hippocampectomy. ~-~--------------.,....--- THE CONTROL OF ATTENTION 121 TABLE 1 AMOUNT AND AMPLITUDE OF GALVANICSKIN RESPONSES OVER TRIAL BLOCKSFORSUBJECTS Response Amplitude (%) (kD) Group Trials Trials Trials Trials Trials Trials 1-7 8-14 15-21 1-7 8-14 15-21 0:> Xorrnal (14) 63 54 43 3.0 2.9 3.2 Hippocarnpectomy (7) 710 700 62 5.90 5.80 3.5 Arnygdalectorny (6) Hyperresponsive (2) 90· 50 40 11.40 4.30 1.9 Hyporesponsive (4) 150 000 00· 2.0 I - - No/e. "umberofsubjectsineachgroupappearinparenthesesfollowingthegroup. •p <.05. posite in function, is most likely related to input from locations near the visceroauto the orbitofrontal cortex which has been nomic regulating mechanisms. This is borne shown to be the rostral pole of an extensive out both by the results of electrical stimula inhibitory pathway (Kaada, Pribram, &Ep tions of the hypothalamus (noted above), stein, 1949; Pribram, 1961; Sauerland & the amygdala (Gastaut, 1953, 1954), andre Clemente, 1973; Skinner & Lindsley, 1973; lated cortical areas (Wi1cott, in press). Wall & Davis, 1951). These data relate Thus, not only can the visceroautonomic to the early descriptions of the behavior of components of orienting be sharply distin amygdalectomized animals (Pribram &Bag guished from the somatomotor components, shaw, 1953) which focused on the fact that but their role in the orienting mechanism ap while the majority were tame, unresponsive pears to be primary. to threat, and nonaggressive, the opposite The fact that the two amygdala systems finding was also occasionally observed (e.g., are reciprocal, one facilitating, the other Rosvold, Mirsky, & Pribram, 1954), and inhibiting arousal, suggests a controlling, more recent behavioral studies by Ursin and modulating mechanism and is in accord with Kaada (1960) using restricted lesions and evidence on other control functions of the electrical stimulations have confirmed the amygdala and related structures. Injections stiggestion that at least two more or less of carbachol into the appropriate hypo reciprocal systems can be identified in the thalamic site will initiate drinking; such in amygdala. jections into the amygdala have no effect unless the animal is already drinking, in Attentiol1al Control of the Arousal System which case the amount of drinking becomes The presence of reciprocal systems sug proportional to the amount of carbachol in gests the existence of a locus upon which jected in an exquisitely accurate relationship they converge, a locus which, from anatom (Russell, Singer,Flanagan, Stone, & Rus ical considerations (Pribram & Kruger, sell, 1968). The fr011toamgydala influence 1954), is most likely to be found in the can be conceived as a finely tuned determi hypothalamic regions of the brain stem. nant controlling visceroautonomic arousal This suggestion is supported by microelec initiated by the hypothalamic mechanism trode evidence at the spinal cord level during orienting. It is as if in the absence (Groves & Thompson, 1970) which indi of the frontoamygdala systems, the animal cates that the origin of the desynchronizing would fail to control his drinking behavior: mechanisnl'leading to orienting may be lo Once)5tarted he would drink under circum calized to the medial parts of the spinal cord stances in which others would stop. This is where the visceroautonomic outflow orig exactly what happens-and more. Both eat inates. The neurons that respond during ing' and drinking are controlled in this orienting are likely to have derived their fashion-not only their cessation but also 121 KARL H. PRIBRA~I .\XD DI.\XE :\IcGlT,XE:-S 100...-----------------, re~pon~t'sw movt'mellts or !() "hock. \\hen .. thre"hold for shock "'as measured. iront:!1 lobectomized ~Grueninger .\: Grncninger. 1973) and nonresponsive am)'gcialenomized / ............................~ subjects. ,,"ere found to have. if anything-. ;.." ........•....~ greater sensitivity (see Figure 4'). Specifi .0' o . cally. these mc'nkeys frequently t'roduced a ~ maximal number aed amplitude of re:-ponse::: ~40 /::....-------- •""- to intensities that produced very little or no :i: :0 '~ reaction in normal subjects. ~ ::20 : This leaves 1:0 doubt that the peripheral response mechanism remains intact. ~either ol-- a change in sensory sensitivity.. nor an al :--~--:--..J o J·4 4·a a·, '·4 4·.1 0 tered peripheral response mechanism can ac d. SHO<l count for the effects of frontal and 3m)'gdala ......AM lesions on the orienting reaction. The crit -N ical influence exerted by these forebrain 6Or----------------, structures appears to relate to arousal in -- duced registration of input effecting changes • ,.........•.. in the organization of central mechanisms. ~40 ........................... Certain changes relate to the finding that .•.. despite reactivity to shock. the amygdalec • .::.:20 tomized and frontally lesioned subjects have = fewer "spontaneous gah"anic skin responses" : during the shock sessions, suggesting an al .,.1.2 tered base le\'el. So far. we have referred .1-.4 .4'" 1.2·1.6 lJI·2.0 .A. SHOCI to phasic changes in the initial period of (,bsen-ation. "'hich often reach asymptote FIGL"RE4. Top: Curyes oj percentage of galvanic \\"ithin three to five stimulus presentations. skin response generated by three runs of stimuli in ascending and descending intensity (in map) by However. while behm"ioral and some elec the amygdaleclOmized (A~{) and control (X) trocortical responses appear to be normal groups. Bottom: A finer breakdown oj stimulus during orienting, after frontal and amygdala yalues from .I to 1.0 rnA. pooled ascending and lesions (Bagshaw& Benzies. 1968;Schwartz descending yalues. (From "Effect oj Amygdalec· Lawn et a!.. 1961) the background Ine] of tomy on Stimulus Threshold of the Monkey" by M. H. Bagshaw and J. D. Pribram, Experimental these respoll5es is lo\\"er than for controls. Nrwalop.\'. )963. 20. 197-202. Copyright 1968 by For example, ear flickir.g is practically ab Academic Press. Reprinted by permission.) sent during interstimulus internls (Bag sha,,' & Benzies. 1968). and while electro their initiation (Fuller, Rosvold, & Pribram, myographic respnnses (lCCUr with normal 1957). latency. the amplitude of these resp0nses is uJnsiderabh" reduced (Pribram, Reitz. ~Ic­ SCIIsitivity and Registratioll Xeil. & 5p~vack. 1974). The question arises as to the significance .-\ccompanying the reduction in baseline of for the orienting reaction of the "isceroauto phasic responses. a striking tonic psycho nomic components per se. The absence of physiological effect followed amygdalectomy. visceroautonomic reactivity during orienting This was the finding of a paradoxically ele could result simply from lowering the sensi yated basal heart rate (Bagshaw & Benzies, tivity of the organism to stimulation. How 1%.>:t: Pribram et a!.. 1974). The paradox ever.resectior.soffrontal cortex (Grueninger. has been clarified by experimental results Kimble. Grueninger, & Levine. 1965) or of (,btained by Elliott" (Elliott, Bankart. & the amygdala (Bagshaw and Coppock. 1968; Light. 1970) in which he found that novel !\1cXeil, 1972) do not abolish galvanic skin input had little effect on tonic heart rate or THE CONTROL OF ATTENTION 123 had an effect (deceleratory) opposite to ex visceroautonomic responses. By way of its pectations. However, response factors and diffuse connections,thissystem is responsible incentive factors (reinforcing consequences) for the more ubiquitous "arousal" responses hadstrongacceleratingeffects. Thus,arousal, recorded throughout the brain concomitant though it may produce a brief initial phasic with orienting. Forebrain control over this acceleration (Obrist, Wood, &Perez-Reyes, corebrain arousal system ~s exerted by re 1965), leads more often to tonic heart rate ciprocal facilitatory and inhibitory circuits deceleration, which is indicative ofactivation, centered on the amygdala. These circuits a process detailed in the next section. In control the onset and duration of neural short, the monkeys with absent arousal reac arousal much as they control the onset and tions are consistent in showing an elevated duration of visceroautonomic and appetitive tonic heart rate. As Elliott's data indicate, responses. and as will be detailed in the last section Our interpretation of the relationship be of this article, elevated tonic heart rate is tween the lack ofvisceroautonomic responses manifest \\'hen the situation demands "ef to orienting and the failure to habituate be fort" on the part of the organism. haviorally has been to suggest that a defi The effects of amygdalectomy can be in ciency is produced in the more ubiquitous terpreted as follows: Because the specific central mechanism by which organisms "reg controls on arousal are removed, behavioral ister" input.. When such failure in registra arousal fails to lead to the registration of the tion occurs, the organism's nervous system situation by altering the neuronal model but is temporarily swamped by the arousing in results in nonspecific defensive "effort" to put and reacts defensively to shut out all cope with the situation. This defense reac further input and thus leads to automatisms. tion is characterized by an attempt to shut This interpretation fits the clinical picture off further input (see Pribram, 1969), and of the amnestic states (deja vu and jamais is reflected in an elevated heart rate and vu) and the automatisms occurring during other changes indicative of a lack of readi psychomotor seizures produced by epileptic ness to respond meaningfully to the input. lesions in the region ofthe amygdala. There Thus "effort" is manifest in the absence of is also considerable congruity between this readiness. This interpretation is borne out interpretation and those of Mednick and by the results of an experiment in which in Schulsinger (1968) and ofVenables (Gruze fant kittens were raised in isolation. When lier &Venables. 1972) in their report of two examined at the age of 6 months their classes (galvanic skin responders and non visceroautonomic and endocrine reactivity in responders) of patients diagnosed as schizo orienting experiments was essentially similar phrenic. However, the interpretation also to that of amygdalectomized subjects: They suffers from the difficulties that plague un had not learned to cope with situations and derstanding of these clinical syndromes: thus showed. the "defensive" syndrome sug How do disturbances of registration in im gestive of considerable "effort" (Konrad & "mediate awareness influence subsequent re Bagshaw, 1,970). trieval? This will be discussed further in the following sections. Summary Studies relating brain function and the VIGILANT ATTENTION. EFFORT, AND THE orienting reaction to sensory input have CONTROL OF ACTIVATION pointed to the presence of a system of The interaction between behaving organ neurons responding to the amount 'of input isms and their environment is not one-sided. to them by maintaining or incrementing The organism is not just a switchboard for their activity. This core system of neurons incoming stimulation. Rather, the essence extends from the spinal cord through the of behaving organisms is that they are spon brainstem reticular formation, including hy taneously active, generating changes in the pothalamic sites. and lies in close proximity environment often by way of highly pro to those responsible for the engenderment of grammed, that is, serially ordered, responses 124 KARL H. PRIBRAM AND DrANE McGurr.;!'ESS (Miller, Galanter, & Pribram, 1960; Pri minute-long changes in heart rate and "en bram, 1960b, 1962, 1963, 1971). These or during" changes in background level. We :ganizationsof behavior must involve the con shall call both of these "tonic" in the present struction of neuronal models in at least two review, though it is possible that the shorter 'ways: (a) control of the somatomotor sys~ changes are related to activation while more tem which effects the responses and (b) enduring leyels of heart rate reflect effort.) feedback from the outcomes (reinforcing The CNV was originally proposed to re consequences) of the behavior. Sherrington flect an e.,"pectancy developed when a specific (1955),in discussing central representations, response was contingent on mvaiting the sec framed the issue in terms of whether the ond of two stimuli. This would suggest that organism is intending to do something about the CNV reflects another central event in the stimulus variables in the situation. In dicating that an input is about to be matched a review of the evidence Germana (1968, to the organism's neuronal model., However, 1969) suggested that an'y central representa other workers suggested that the negative tion or "neuronal model" must include such 6hift in potential reflects intended motor ac "demand" characteristics. Thus he proposes tivity (e.g., Kornhuber & Deecke, 1965; that Pavlov's "What is it?" reaction (which Vaughan, Costa, & Ritter, 1968). Still we have called "arousal," the registration of others (Weinberg, 1972; Donchin, Ger input in awareness) may not occur unless brandt, Leifer, & Tucker, 1972) demon there is also a "What's to be done?" reac strated that a CNV occurs whether or not tion. As we shall see, our analysis would an overt motor or even a discriminative re suggest that both reactions occur and that sponse is required, provided some set or ex they can be distinguished: registering input, pectancy is built into the situation. Such indicating "What is it?", and vigilant readi sets do, of course, demand postural motor ness signaling"What'stobedone?" Strictly readiness. Weinberg (1972), for instance, behavioral analyses have led to a similar dis has shown that in man the CNV continues sociation. The early studies of Lawrence until feedback from the consequences of re I (1949. 1950) and the more recent work of inforcement of the response occurs, and sim Broadbent and Gregory (reviewed by Broad ilar evidence has been obtained in monkeys bent, 1971) are perhaps the best known in (Pribram, Spinelli, &Kamback, 1967). In terms of independent manipulations of stim a review of the CNV literature, Tecce ulus set and of response set. (1972) suggests that three types of negative potentials interact depending upon the de Contingent Negative Variation mands of the experiment: (a) CNV due to and Activation expectant attentional processes; (b) the mo The simplest situation which demands that tor readiness potential signaling intention to responses become serially organized is one act; and (c) more or less "spontaneous" in which two successive input signals are shifts whose occurrence cannot yet be at separated by an interval. The first input tributed to specific task situations. Thisclas signals the organism to become ready to sification though consonant with results from make a response to the second which deter a series of studies (Donchin. Otto. Ger mines the outcome. A large body of data brandt, &Pribram, 1971, 1973) does not in has been gathered in this situation, using dicate the full diversity of the CNV. Re slow changes in brain electrical activity such cordings were made from several cortical as the contingent negative variation (CNV) locations under a variety of vigilance condi (Walter, Cooper, Aldridge, McCallum, & tions. These studies showed that sites which 'Winter, 1964) and tonic changes in heart produced transcortical negative variations rate. Lacey and Lacey (1970) have estab (TNVs) depended upon the type of vigilance lished a correlation between the amplitude task. Thus, frontal TNVsare recorded only of CKV and heart rate deceleration. (]. 1. early in a task and when the task is changed; Laceyand B. C. Lacey, 1974,and Malmoand motor negative potentials are recorded only Belanger, 1967, distinguish between their 1- in anticipation of the necessity to make an

Description:
(Kaada,. Pribram, & Epstein, 1949). When an analy- sis of the visceroautonomic components of the orienting response was carried out on frontal and Kaada (1960) using restricted lesions and electrical stimulations have confirmed .. (Walter, Cooper, Aldridge, McCallum, &. 'Winter, 1964) and tonic
See more

The list of books you might like

Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.