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Previous Article | Next Article
Volume 16, Number 9, Issue of May 1, 1996 pp. 3082-3088
Copyright ©1996 Society for NeuroscienceCovert Orienting of Attention in the Rat and the Role of Striatal Dopamine
Nick M. Ward and Verity J. Brown School of Psychology, University of St. Andrews, St. Andrews KY16 9JU, United Kingdom
ABSTRACT
Attention can be directed to a location in the absence of overt signs of orienting, a phenomenon termed ``covert orienting.'' The ability to orient attention covertly has been well documented in humans, but recent progress has been made with the operational definition of the processes involved in covert orienting. Reaction times to visual targets are quickened when attention is drawn to the location of the subsequent target, and processes such as disengagement, maintenance, and movement of attention can be dissociated by using this method. The possible involvement of striatal dopamine in covert orienting is disputed, with conflicting reports of deficits in covert orienting in patients with Parkinson's disease. To examine the significance of dopamine in the striatum in attentional processes, a test of covert orienting, analogous to that used in humans, was devised for the rat. Unilateral dopamine-depleting lesions of the striatum resulted in increases in mean reaction times contralateral to the side of the lesion, but reaction times did not change differentially as a function of the requirements to maintain, disengage, or shift attention. These findings add additional support to the hypothesis that the deficit that appears as hemineglect observed after striatal damage reflects a motor impairment rather than damage in neural systems underlying mechanisms for directing attention.
Key words: striatum; dopamine; rat; covert orienting; attention; Parkinson's disease
INTRODUCTION
The appearance of a visual target is often associated with the movement of the head and eyes to foveate the attended target; however, shifts of attention can occur in the absence of such overt orienting (Ericksen and Hoffman, 1972; Jonides, 1981). Posner (1980)
Measuring covert shifts in attention, in the absence of overt orienting, has been possible in primates (Petersen et al., 1987
Posner et al. (1984)
The dopaminergic antagonist droperidol causes a reduction in the validity effect (Clark et al., 1989
MATERIALS AND METHODS
Animals. Twenty, pair-housed Lister hooded rats (supplied by in-house breeding program, School of Psychology, University of St. Andrews) were used during the study. The rats were maintained on a 12 hr light/dark cycle with free access to water and a restricted diet of 15-20 gm of sucrose pellets and standard laboratory chow per day (weight range, 215-280 gm at the start and 373-432 gm at completion of the study).The guidelines laid out in the Principles of Laboratory Animal Care (National Institutes of Health, Publication No. 86-23, revised 1985) and the requirements of the United Kingdom Animals (Scientific Procedures) Act, 1986, were adhered to throughout the study.
Apparatus. The test apparatus was a nine-hole box (Paul Fray, Cambridge, UK), which has been described in detail previously (Brown and Robbins, 1989
Training regimen. The rats were placed on the restricted diet 24 hr before the commencement of training. Training began with habituation to the test apparatus for 1 hr, with standard laboratory food pellets placed in the hopper.
In the first training program, the rat pushed the panel door open to receive a food pellet. During this training, a light in the food hopper was activated with each panel press. Once a rat was able to gain 100 pellets in 15 min (typically, within two 30 min training sessions), it progressed to the next stage of training.
In the next stage of training, the central hole was uncapped. To receive a pellet, the rat now had to place its nose in the central hole, in response to the hole light coming on, and maintain it there for a brief delay, after which the hopper light came on and a food pellet reward was delivered into the food hopper. Premature withdrawal from the central hole resulted in the house light in the chamber switching off for a ``time-out'' punishment and no food reward; after 1 sec, the house light and the light in the food hopper were activated. To initiate a new trial, the rat pushed open the panel door of the food hopper. After 5 d of this training, the rats were able to wait for delays of 400 msec, at which point they progressed to the testing paradigm.
Testing paradigm. Figure 1 illustrates the order of trial events. The three central holes in the chamber were uncapped, and the rat was required to poke its nose into the central hole. After 100 msec, the cue was presented. The cue was the brief (100 msec) dim illumination of the bulb in the hole to the left or right of the central hole. After a variable delay of up to 800 msec from the onset of the cue, the target was presented. The target was the bright illumination, for 150 msec, of the bulb in one of the holes adjacent to the central hole. To complete the trial, the rat withdrew from the central hole and moved to the location of the target. The cue light indicated the side of the subsequent target on 80% of the trials (valid cue). The remaining 20% of trials were invalid cues, in which the cue light appeared on the opposite side of the target. The order of valid and invalid trials and the variable delays between cue and target lights were randomized. The variable delays preceding the target light were increased gradually until they were 200, 400, 600, and 800 msec. Each testing session lasted until completion of 120 correct trials or for 30 min.
Fig. 1. A schematic representation of the covert orienting paradigm in the nine-hole box. At the rear of each hole is a light. In the central hole, the light provides the signal to start a trial. The cue and target are the dim and bright illumination, respectively, of the bulb in the left or right hole. Responses are recorded by nose pokes into the holes, which are monitored by photoelectric cells. Eighty percent of trials consisted of a cue presented on the same side as the subsequent target (valid cue); 20% of trials consisted of the cue presented on the side opposite the subsequent target (invalid cue).
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Definition of measures. The time between target light onset and withdrawal from the central hole was recorded as reaction time. The time taken to reach the target hole after withdrawal from the central hole was recorded as movement time.
For the period before and 100 msec after the target light onset, the rat had to keep its nose in the central hole; failure to do so resulted in 1 sec of darkness in the chamber (``time-out'') and no food reward and was recorded as an early error. Responding with a nose poke in the hole opposite the target light was also punished with a time-out, was unrewarded, and was recorded as an incorrect response. A movement time >2000 msec also resulted in a time-out and no food reward and was recorded as a late error. In trials that were otherwise correct, reaction times >1500 msec also were classified as late errors for subsequent analysis, but the trial was rewarded and advanced nevertheless. After a time-out, the trial was repeated until it had been completed successfully.
Collection of behavioral data. Once all the rats had reached the performance criterion of 120 correct trials within 30 min, presurgical data were collected over 5 d for 10 test sessions (~1200 trials). On completion of the collection of presurgical data, the rats were assigned to receive a unilateral intrastriatal infusion of the neurotoxin 6-hydroxydopamine (6-OHDA) (Sigma, Poole, UK). The side that was lesioned was determined by presurgical task performance. If there was an asymmetry in performance, the side contralateral to the strongest validity effect was lesioned (n = 10). Where there was no asymmetry, the side of lesion was assigned randomly. After 2 weeks of recovery from surgery, the rats were tested for 3 weeks. A total of ~3900 correct trials were collected for each rat over this period.
Hypothesis. By using a unilateral model, each rat served as its own control: reaction times for contralateral responses were compared with ipsilateral responses. It is possible to make predictions about the pattern of reaction times expected with different deficits; on the basis of previous neuropsychological studies, many of these are already associated with particular anatomical regions. Table 1 shows the pattern of reaction time change predicted for a unilateral lesion resulting in a given psychological impairment and the anatomical region most likely to be involved. The final two hypotheses are of greatest interest in the current experiment. It is possible that striatal dopamine might play a role in the maintenance of attention (Wright et al., 1990
Table 1. The pattern of reaction-time deficits changes after a unilateral lesion that would result from different hypothetical deficits
Deficit Anatomical region Contralateral valid Contralateral invalid Ipsilateral valid Ipsilateral invalid Disengagement of attention Posterior parietal cortexa,b Movement of attention Superior colliculusc,d,e Engagement of attention Lateral pulvinar of the thalamusf,g Maintenance of attention Striatal dopamineh Response deficit Striatumi,j,k These attentional deficits have been associated with different brain regions in the neuropsychological literature. Of most interest in the present study are the final two rows. (a Posner et al., 1984 Increase in reaction time;
decrease in reaction time;
no change in reaction time.
Surgery. The rats were pretreated with an intraperitoneal injection of the monoamine oxidase inhibitor pargyline (50 mg/kg in warm sterile 0.9% saline; Sigma) before surgery to enhance the efficacy of 6-OHDA (Breese and Traylor, 1971
Histology. On completion of postsurgical testing, the rats were killed humanely by intraperitoneal administration of Euthatal (1.0 ml/kg, pentobarbitone sodium BP 200 mg/ml). The rats were perfused transcardially with phosphate buffer for 2 min at a rate of 10 ml per min, followed by 4% paraformaldehyde in phosphate buffer for 20 min at the same rate. The brains then were removed carefully and placed into a 20% sucrose/4% paraformaldehyde phosphate buffer solution until processed. Serial coronal sections 50 µm thick were cut using a freezing microtome, and two adjacent sections every 400 µm were taken for staining with cresyl violet and immunohistochemistry for tyrosine hydroxylase. Tyrosine hydroxylase activity was used as an indirect measure of dopamine depletion in the striatum. To establish the area of tyrosine hydroxylase depletion, the side of lesion was compared with the unlesioned side. Ten sections, at 400 µm intervals, were examined between approximately bregma +1.4 mm and
Data analysis. Raw data were processed to extract mean reaction times, error-type frequency, and reaction-time distributions for each rat. Accuracy of performance was assessed as the proportion of correct responses as a function of all trials (correct and all error responses). Each type of error also was examined separately as a percentage of all trials.
Mean reaction time, percentage correct, and percentage of errors by type were analyzed by repeated measures ANOVA using the variables surgery, validity, side, and delay. When appropriate, additional investigations of significant interactions were conducted using post hoc Newman-Keuls comparisons.
Probability density distributions (Silverman, 1986
RESULTS
Histological results
Tyrosine hydroxylase depletion was not evident in the striatum of one rat, and therefore this rat was excluded from subsequent analysis. In the remaining rats (n = 19), the percentage area of tyrosine hydroxylase depletion in the striatum ranged from 19% to 91% (mean 54%). Figure 2 shows tissue sections stained for tyrosine hydroxylase from the cases with the largest and smallest lesions. The depletion was evident in the body of the striatum between bregma +1.4 and
Fig. 2. Digitized coronal sections illustrating the extent of tyrosine hydroxylase depletion in the striatum after an intrastriatal injection of the neurotoxin 6-OHDA. The largest lesion is depicted in the sections on the left (rat 289; total area of dopamine depletion in the striatum is 91%), and the smallest lesion is depicted in the sections on the right (rat 291; total area of dopamine depletion in the striatum is 19%).
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Reaction-time performance
There was a significant validity effect at the shortest two delays (200 and 400 msec) of 61 and 38 msec, regardless of side of response (validity by delay: F(3,54) = 10.63, p < 0.0001). The validity effect was not significant at the longer delays of 600 and 800 msec.Figure 3 illustrates the effects of the unilateral striatal dopamine depletion on reaction time. There was no change in the magnitude of the validity effect after surgery (surgery by side by validity: F(1,18) = 0.64, NS; surgery by validity: F(1,18) = 1.6, NS). The mean reaction time, however, increased by an average of 73 msec for all responses initiated contralateral to the side of lesion. Ipsilateral reaction times, by contrast, were faster postoperatively, with a decrease in the mean of 54 msec (surgery by side: F(1,18) = 12.45, p < 0.01).
Fig. 3. Mean ± SEM (n = 19) of reaction times before and after surgery for validly and invalidly cued trials to each side. Presurgical reaction times are plotted with respect to the side of the subsequent lesion. Mean reaction time was lengthened for contralateral responses postsurgery. Reaction times were longer after invalid as compared with valid cues, and this pattern did not change after unilateral dopamine depletion in the striatum.
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To test whether there was a relationship between size of the contralateral reaction-time deficit and lesion size, a one-way ANOVA was performed, dividing the group according to lesion size. The reaction-time deficit was greater in the rats with lesion volumes >50% (n = 9) compared with those with lesion volumes <50% (F(1,17) = 6.1, p < 0.05).
Figure 4 shows the probability of a response as a function of reaction time. Although there was an increase in mean contralateral reaction time, the average modal reaction time did not change after surgery, remaining at 175 msec. The reaction-time distribution for contralateral responses postsurgery, however, displays a downward shift in the probability of a response at the mode. It is apparent that the reason for the significant postsurgery increase in mean reaction time is that the relative frequency of reaction times around the mode has decreased, resulting in the slower reaction times in the tail of distribution increasing the mean. The reaction-time distributions for responses to the ipsilateral side display smaller changes, with both a decrease in the mode (
Fig. 4. The mean probability density distributions pre- and postsurgery are plotted as a function of response side and include both validity conditions and all cue-target delays. The increase in mean reaction time for responses made contralateral to the side of lesion was attributable to a decrease in the probability of responses occurring at the mode rather than a lateral shift in the distribution.
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The effect of cue validity at delays of 200 and 400 msec (illustrated in Fig. 5) also causes a small downward shift in the probability of a modal reaction time for invalidly as compared with validly cued trials. This pattern is true for both sides and also for both presurgery and postsurgery. In addition, there is a lateral shift in the distribution with the mode increasing from 170 msec for valid trials to 190 msec for the invalid trials. Thus, the significant increase in mean reaction times for invalidly cued trials is attributable to a decreased probability of occurrence of responses at the mode and a slight lengthening of reaction times globally.
Fig. 5. The mean probability distributions for the first two delays, plotted as a function of surgery, response side, and validity. The validity effect results in a change in probability of a response at the mode and also a shift in the distribution. This pattern is independent and additive with the effect of surgery.
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Percentage correct
The percentage correct fell from 72% presurgery to 57% postsurgery for responses to targets contralateral to the side of lesion. This was greater than the fall in percentage correct postsurgery for responses ipsilateral to the side of lesion (from 69% to 62%; surgery by side: F(1,18) = 6.53, p < 0.02). The fall in percentage correct was independent of the validity of the cue, with no significant interactions of surgery with validity (surgery by side by validity: F(1,18) = 0.66, NS; surgery by validity: F(1,18) = 0.34, NS). The percentage correct also fell as a function of increasing delay (F(3,54) = 213.96, p < 0.0001), attributable to an increase in early errors as a function of delay.The significant interaction between surgery and side for percentage correct was investigated further by examining the percentage of early, incorrect, and late errors. Not surprisingly, there were no interactions of surgery with validity and/or side for early errors (surgery by side by validity (F(1,18) = 0.06, NS; surgery by side: F(1,18) = 0.36, NS; surgery by validity: F(1,18) = 0.0003, NS); however, the interaction of surgery and side was also not significant for late (surgery by side: F(1,18) = 1.8, NS) or incorrect (F(1,18) = 1.59, NS) errors. Nevertheless, as is apparent in Figure 6, the origin of the significant surgery by side interaction for overall percentage correct is a cumulative effect of an increase in the percentage of both late and incorrect errors postsurgery for responses to the side contralateral to the lesion.
Fig. 6. Bar graph showing error type as a percentage of all trials. The significant interaction for percentage correct between side and surgery can be attributed to the cumulative effect of an increase in both late and incorrect errors for responses to the contralateral side.
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DISCUSSION
In this study, we have shown that it is possible to measure covert orienting in the rat, thus extending previous demonstrations of covert orienting of attention in humans (Posner, 1980After unilateral striatal dopamine depletion, there was an increase in mean reaction time of responses made to the side contralateral to the lesion (with a corresponding decrease in ipsilateral reaction time), regardless of the validity of the preceding cue. The magnitude of the validity effect did not change after dopamine depletion, which supports the hypothesis that dopamine in the striatum is important for response processes (Table 1) and does not play a role in mechanisms of directed attention.
These results are consistent with and extend the findings of Carli et al. (1989)
The increase in mean reaction time does not cause a lateral shift in the entire reaction-time distribution; rather, there is a decreased probability of responses at the mode of the distribution. This finding, of a decrease in the probability of a response at the mode of the distribution, has been reported previously in Parkinson's disease patients tested with and without L-dopa therapy (Brown et al., 1993
The suggestion that there might be a role for striatal dopamine in covert orienting has support from several sources. In normal subjects, Clark et al. (1989)
FOOTNOTES
Received Nov. 26, 1995; revised Feb. 13, 1996; accepted Feb. 28, 1996.
This research was supported by The Wellcome Trust (Project Grant 040551/z/94) and the Fujisawa Institute of Neuroscience. N.M.W. is the recipient of a Medical Research Council (UK) Collaborative Studentship (G78/4236) with the Fujisawa Institute of Neuroscience, Department of Pharmacology, University of Edinburgh, Edinburgh EH8 9JZ, UK. We thank Dr. J. Phillips for assistance with the behavioral testing, Dr. E. Bowman for helpful discussion, and M. Latimer and the workshop of the School of Psychology for technical support.
Correspondence should be addressed to Dr. Verity J. Brown, School of Psychology, University of St. Andrews, St. Andrews KY16 9JU, UK.
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