Effects of Drugs on Response Duration Differentiation. V: Differential Effects under Temporal Response Differentiation Schedules

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

This Article

	Abstract
	Full Text (PDF)
	Submit a response
	Alert me when this article is cited
	Alert me when eLetters are posted
	Alert me if a correction is posted
	Citation Map

Services

	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager

Citing Articles

	Citing Articles via HighWire
	Citing Articles via Google Scholar

Google Scholar

	Articles by Mcclure, G. Y.贌.
	Articles by Mcmillan, D. E.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Mcclure, G. Y.贌.
	Articles by Mcmillan, D. E.

Vol. 281, Issue 3, 1357-1367, 1997

Effects of Drugs on Response Duration Differentiation. V: Differential Effects under Temporal Response Differentiation Schedules¹

G. Y. H. Mcclure, G. R. Wenger and D. E. Mcmillan

Department of Pharmacology and Toxicology, University of Arkansas for Medical Sciences, Little Rock, Arkansas

	Abstract

Top Abstract Introduction Methods Results Discussion References

The effects of methamphetamine, phencyclidine and $Delta$ ⁹-tetrahydrocannabinol on responding under temporal response differentiationschedules were studied under three different time requirements.Under the schedules studied, Sprague-Dawley rats were requiredto make a continuous response for at least a minimum time duration,but not more than a maximum. Base-line performance under a temporaldifferentiation schedule usually produces a normal frequency distributionof response durations with the peak at or near the minimum durationrequired for delivery of the reinforcer. These frequencies weresummed to calculate cumulative frequencies that were plotted assigmoidal curves. Under the temporal differentiation 1-1.3 secschedule, methamphetamine increased the frequency of short responsedurations at low doses, whereas high doses produced both longand short response durations, flattening the relative frequencydistribution. Under the temporal differentiation 4-5.2 sec and10-13 sec schedules, methamphetamine produced only short responsedurations, which shifted the relative frequency and cumulativefrequency distribution of response durations leftward. $Delta$ ⁹-Tetrahydrocannabinol had little effect under the temporal differentiation1-1.3 sec and 4-5.2 sec schedules, but it greatly increased therelative frequency of short response durations under the 10-13sec schedule. Phencyclidine produced a similar effect under alltemporal differentiation schedules, increasing the relative frequencyof short response durations. Thus the effect of drugs on timingbehavior under these temporal differentiation schedules not onlydepended on the drug, but also depended on the dose and the timeparameters of the schedule. These data suggest that drugs producemultiple effects on timing behaviors that depend on complex interactionsamong several factors.

	Introduction

Top Abstract Introduction Methods Results Discussion References

Timing behavior is important in many operant schedules, but two reinforcement schedules that are thought to measure timingbehavior directly are TRD and the more well known DRL. Under bothschedules, the temporal dimension of the response is differentiallyreinforced, such that reinforcement can be made contingent uponresponding which is correlated with a minimum and a maximum timevalue of that response or the time between responses (Ferraroand Grilly, 1970; McMillan and Patton, 1965; Sidman, 1955, 1956).Under both schedules, the subject presumably relies on interoceptivecues to regulate behavior. The DRL schedule differs from the TRDin the specifics of the behavioral response. Whereas the animalunder a DRL is reinforced for spacing responses at a specifiedtime duration, under a TRD the animal must emit a continuous responseof specified duration.

The number of drugs that have been studied with subjects performing under TRD schedules is limited. Stimulants, such as MAP,amphetamine, cocaine and caffeine have produced mixed results.Increases in the proportion of responses both too short and toolong in duration to produce a reinforcer have produced flattenedresponse-duration distributions in some studies with MAP and cocaine(Hudzik and McMillan, 1994b; McMillan et al., 1994), whereas amphetamineand caffeine have predominantly produced increases in the proportionof shorter response durations (Schulze and Paule, 1990; Buffaloet al., 1993).

The antipsychotic, chlorpromazine, also has produced equivocal results with long-duration responses predominating in someanimals and short durations in others within the same study (Fergusonand Paule, 1992). Antidepressants have produced unique profilesunder the TRD 1-1.3 sec schedule. Drugs such as imipramine, trazodoneand tranylcypromine increase slightly the proportion of both shortand long response durations, but the most interesting effect isthe production of many long response durations. These long responsedurations greatly exceed the reinforced response durations causinglarge increases in the mean response duration at low doses ofdrugs that have little effect on response rates (Hudzik and McMillan,1994a).

Depressant drugs have produced mixed results. Pentobarbital and morphine flattened the relative frequency distribution ofresponse durations in one study (Hudzik and McMillan, 1994b) becauseof a slight increase in the frequency of both shorter and longerresponse durations. In other studies, these drugs have shown onlyincreases in short response durations (Schulze and Paule, 1991;Ferguson and Paule, 1993). Diazepam was reported to increase theproportion of short response durations (Schulze et al., 1989),whereas in other studies diazepam flattened the distribution ofresponse durations (Hudzik and McMillan, 1994a), an effect similarto pentobarbital and morphine. $Delta$ ⁹-THC increased the relative frequency of shorter response durationsunder some TRD schedules (Schulze et al., 1988), but flattenedthe distribution of response durations under other TRD schedules(Schulze et al., 1988; Hudzik and McMillan, 1994b). PCP, whichhas mixed stimulant-depressant properties, produced only an increasein short response durations that shifted relative frequency distributionsleftward (Hudzik and McMillan, 1994b; McMillan et al., 1994).

These conflicting results raise many questions about timing behavior under TRD schedules. Differences in the species used,the schedule parameters, the drug vehicle, routes of administration,the failure to report relative frequency distributions and otherprocedural aspects make it difficult to systematically comparedrug effects on behavior under TRD schedules.

In an attempt to elucidate the role of the schedule parameters in these reported differences, comparisons of behavior of ratsunder three TRD schedules with different time-duration requirementswere conducted. To determine the effects of drugs on the timingbehavior of animals under these schedules, MAP, PCP and $Delta$ ⁹-THC were selected as representative abused drugs from differentpharmacological classes. Altered time perception has been reportedwith PCP and $Delta$ ⁹-THC, based on human anecdotal reports (Hollister and Gillespie,1970; Tinklenberg et al., 1976; Yesavage et al., 1978), and withMAP by use of animal temporal discrimination studies (Meck andChurch, 1983; Maricq et al., 1981).

	Methods

Top Abstract Introduction Methods Results Discussion References

Subjects. Twelve male, Sprague-Dawley rats were maintained at 80% (285-315 g) of their free-feeding weights by food presented duringthe session and postsession feeding. Water was available at alltimes except during the experimental sessions. Animals were individuallyhoused in suspended stainless steel cages in a colony room (maintainedat 70-74°F, illuminated from 6:00 A.M. to 6:00 P.M.) during theinitial training period. Later, after a move to new laboratoryfacilities, all rats were housed singly in standard Plexiglasrat cages under the same environmental conditions. Rats were 9months of age at the beginning of the experiments, which lasted7 to 9 months.

Apparatus. Rats were trained and tested in four standard two-lever chambers (model G6312, Gerbrands Corp., Arlington, MA) enclosed insound-attenuating Gerbrands enclosures (model G7210). A feedermounted between the levers delivered 97-mg food reinforcer pellets(Noyes Corp., Lancaster, NH) when schedule contingencies had beenmet. A houselight and a stimulus light consisting of 28-V DC bulbswere mounted in the ceiling of the experimental chamber and abovethe right lever. A downward force of 15 g closed the contact onthe right-hand lever and was defined as a response. Responseson the left-hand lever had no consequences. A continuous tone(Sonalert, model SC628H in series with a 15 K-Ohm resistor) occurredwhen contacts were closed. Conditioned events in the chamberswere controlled and monitored by a Firestar 386 computer witha Med Associates Interface (St. Albans, VT) housed in a separate,but adjoining room.

Drugs and testing. Doses of methamphetamine sulfate (Sigma Chemical Co., St. Louis, MO), phencyclidine hydrochloride and $Delta$ ⁹-tetrahydrocannabinol (National Institutes on Drug Abuse, Bethesda,MD) in this order were given in ascending or descending dose orderwith random assignment of the rats to a dose order. Both PCP andMAP (0.3, 1.0, 1.7, 3.0 or 5.6 mg/kg) were dissolved in salineand administered intraperitoneally 10 min before sessions in avolume of 1 ml/kg. $Delta$ ⁹-THC, dissolved in ethanol, was evaporated under nitrogen andredissolved in DMSO (Sigma Chemical Co., St. Louis, MO). $Delta$ ⁹-THC (0.3, 1.0, 1.7, 3.0, 4.2 or 5.6 mg/kg) was administered intraperitoneally1 h before the session in a volume of 0.5 ml/kg. All dose levelswere expressed as the salts, except for $Delta$ ^9-THC, which was reported as the free base. Control injections consistedof saline during the MAP and PCP drug series, and DMSO duringthe $Delta$ ⁹-THC drug series.

Procedure. After all rats learned to lever press, they were randomly assigned to one of the three TRD training schedules and were trainedto differentiate response durations by the general method of differentialreinforcement as described previously (McMillan and Patton, 1965).Under this training procedure, responses are reinforced basedon continuous lever press durations within the required time limitsof the schedule. The minimum response duration required for foodpresentation was progressively incremented (based on a 40% accuracycriterion), then the maximum response duration was progressivelydecremented until the final minimum and maximum response durationsrequired for food presentation were established. Under the TRD1-1.3 sec schedule, progressive increments of 0.3 sec with a final0.1-sec increment of the minimum response duration and decrementsof 0.5 sec with a final decrement of 0.2 sec of the maximum responseduration were used to achieve the final reinforced response durationof at least 1.0 sec, but less than 1.3 sec. Under the TRD 4-5.2sec schedule, both progressive 0.5-sec increments and decrements,with a final 0.3-sec decrement, were used to achieve a final reinforcedduration of at least 4.0 sec, but less than 5.2 sec. Under theTRD 10-13 sec schedule, both 0.5-sec increments and decrementswere used to achieve the final response duration of at least 10sec but less than 13 sec.

Illumination of a houselight mounted in the ceiling of the experimental chamber and a stimulus light above the right leversignaled the beginning of the session. A 5-sec post reinforcementtime-out occurred with food presentation, and the houselight andstimulus light were off during this period. During the time-out,responses had no programmed consequence and were not recorded.The sonalert sounded when the lever was pressed and stopped whenthe lever was released. White noise was present at all times tomask noises outside the chamber. The session ended after the deliveryof 50 pellets, or after 40 min, whichever came first. Sessionswere conducted Monday through Friday between 7:30 and 8:30 A.M.(TRD 1-1.3 sec), 9:30 and 10:30 A.M. (TRD 4-5.2 sec) and 11:30A.M. and 12:30 P.M. (TRD 10-13 sec) with drugs administered onTuesdays and Fridays. Thursdays served as vehicle control sessions.

Data analysis. The total number of responses emitted, response rate (responses/sec), accuracy (% reinforced responses) and mean responsedurations were collected as performance indicators during everysession for each rat. The mean values and standard errors foranimals under each schedule were calculated for each of theseperformance measures. ANOVA was used to determine the significance(P < .05) of base-line values compared across schedules. ANOVAwas also used to assess the effect of each drug compared withthe average of 10 control sessions conducted during the threedrug tests for each group of rats. If animals failed to respondat least 25 times within a session, the data were used to calculateonly response rates.

Each response, dependent on its duration, was sorted into 1 of 24 consecutive time bins. The relative frequency of responsesin each time bin (the number of responses per bin divided by thetotal number of responses made during the session) was calculatedfor each individual rat for each session. The response durationscollected in each time bin were proportional to the time parametersrequired across schedules. The TRD 1-1.3 sec schedule used 0.1-secbins, with all responses shorter than 0.100 sec collected in bin1 and all those greater than 2.300 sec collected in the last bin(bin 24). The TRD 4-5.2 sec schedule used 0.4-sec bins, with anyresponses shorter than 0.400 sec collected in bin 1 and all responsesgreater than 9.200 sec collected in the last bin (bin 24). TheTRD 10-13 sec schedule used 1.0-sec bins, with any responses shorterthan 1.000 sec collected in bin 1 and all response durations of23.000 sec or greater collected in the final bin. Bins 11, 12and 13 collected response durations that were reinforced undereach schedule (1.0 sec to 1.3 sec, 4.0 sec to 5.2 sec or 10.0sec to 13.0 sec).

These relative frequency measures of responses in the 24 time bins were used to construct relative frequency histograms. Additionally,the relative frequencies for each schedule were summed to calculatecumulative frequencies. These cumulative frequencies were plottedas sigmoidal curves. The portion of these curves correspondingto data collected in bins 7 through 15 was relatively linear andsubjected to regression analysis of the slopes of these lines.Changes in these slopes caused by drug treatments could then beexamined. An F statistic was calculated by use of the formula:

F=<FR><NU><AR><R><C>[(SS of control<IT> +</IT>SS of drug dose)<IT>−</IT>pooled SS]<IT>×</IT>[(DF control</C></R><R><C><IT>+</IT>DF drug dose)<IT>−</IT>pooled DF]<SUP>−1</SUP></C></R></AR></NU><DE>[pooled SS]<IT>×</IT>[pooled DF]<SUP>−1</SUP></DE></FR>

(1)

where SS = sum of squares; DF = degrees of freedom; and pooled is the combined data of both the control and the effect ofthe dose of the individual drug. A significant F value (P < .05)indicates that the two regression lines are significantly differentbecause of either a change in the slope or the intercept of theline.

	Results

Top Abstract Introduction Methods Results Discussion References

Base-line performance. Under the TRD 1-1.3 sec, TRD 4-5.2 sec and TRD 10-13 sec schedules, animals reached the initial stability within 50 sessions,65 sessions and 85 sessions, respectively. Initial stability foreach rat was defined as consistent accuracy which varied no morethan ±5% for 10 consecutive sessions, after completion of trainingprocedures. At the beginning of the experiments, all rats underthe TRD 1-1.3 sec schedule had accuracy levels equal to or greaterthan 45%, whereas the accuracy of all rats under the 4-5.2 secand 10-13 sec schedules was 55% or greater. Base-line levels ofaccuracy continued to increase slightly under some schedules afterthe initial stability criterion was reached. However, an asymptotewas reached for all groups at which continued daily training hadno additional effects. Before each drug series, consistent accuracylevels (±5%) during the previous five base-line trials were requiredbefore drugs were administered and drug effects assessed.

The data in table 1 show the mean accuracy, mean response duration and mean response rate of rats under all reinforcementschedules from 10 base-line sessions. The 10 base-line sessionswere selected from sessions before and after the MAP, PCP and $Delta$ ⁹-THC drug series, along with 4 Thursday-training days during thedrug series with MAP and PCP, but not $Delta$ ⁹-THC. Thursday-training days during the $Delta$ ⁹-THC series were excluded because of concern that its long half-lifemight produce residual effects on control performance. This selectionprocess for base-line sessions was done to include trials representativeof the entire drug period. As the minimum duration of lever holdrequired for food presentation increased, the mean response durationand accuracy increased, whereas the response rate decreased. ANOVAindicated that significant differences occurred across the threeTRD schedules for the base-line mean response durations and responserates. The accuracy level of animals trained under the TRD 1-1.3sec schedule was also significantly different from that of animalstrained under the other two schedules. However, accuracy levelsof animals trained under the TRD 4-5.2 sec and 10-13 sec scheduleswere not significantly different.

View this table:
[in this window]
[in a new window]

TABLE 1
Effect of MAP, PCP and $Delta$ ⁹-THC on performance indicators for TRD schedules with differing timing requirements

A normal distribution of response durations was characteristic of responding under all schedules (fig. 1). The mode for allTRD response durations occurred in bin 11 (the first time binof the reinforced durations). Bins 11 to 13 collected responsedurations greater than the minimum, but less than the maximumtime duration required to produce the reinforcer and are referredto as the reinforcer window in this manuscript. Under all TRDschedules, the sharply defined peaks of the bell-shaped curvesof their relative frequency distributions, and corresponding verticalslopes of the cumulative response-duration curves indicated goodschedule control.

View larger version (27K):
[in this window]
[in a new window]

Fig. 1. Comparison of base-line cumulative frequencies of distributions and relative frequency distributions of response durationsfor TRD schedules with differing timing requirements. Abscissa:Response durations in 0.1-, 0.4- or 1.0-sec time bins. Ordinate:Percentage of total response durations in each bin (left) or cumulativenumber of response durations in each bin as a percentage of thetotal number of response durations (right). Shaded bins show reinforcedresponse durations. The frequency of each bin represents a meanbased on 10 observations in each of four rats. Brackets show ±1standard error.

General performance measures after drug administration. Table 1 shows the effects of MAP, PCP and $Delta$ ⁹-THC on the various measures of performance under all TRD schedules. MAP causeda dose-dependent decrease in accuracy under all TRD schedules,with greater decreases in accuracy occurring with increasing timeduration requirements. For MAP, statistically significant effectsoccurred under the TRD 1-1.3 sec schedule (1.7 and 3 mg/kg), underthe TRD 4-5.2 sec schedule (1.7 and 3.0 mg/kg) and under the TRD10-13 sec schedule (all doses tested). There was no effect onmean response duration under the TRD 1-1.3 sec schedule, whereaslarge decreases in mean response durations occurred under eitherthe TRD 4-5.2 sec schedule (5-fold) and the TRD 10-13 sec schedule(10-fold). Response rates were generally not affected by MAP untildose levels were reached that nearly eliminated responding.

PCP also decreased accuracy as a function of increasing dose and the mean response duration decreased with dose under allthe reinforcement schedules. PCP increased response rates significantlyat low doses under the TRD 1-1.3 sec schedule; but under the TRD4-5.2 sec and 10-13 sec schedules, PCP only decreased responserates significantly at the highest dose. $Delta$ ⁹-THC had little effect on the accuracy under the TRD 1-1.3 secand 4-5.2 sec schedules; however, under the TRD 10-13 sec schedule,there was a consistent decrease in accuracy and mean responseduration with increasing doses. Response rates significantly decreasedat high doses with $Delta$ ⁹-THC under the TRD 1-1.3 and 10-13 sec schedules.

MAP effects on distribution of response durations under the TRD 1-1.3 sec schedule. Figure 2 shows cumulative frequency curves which were generated from the relative frequency data with inserts showing therelative frequency distributions. At the 0.3 mg/kg dose, therewas an increase in the relative frequency of response durationsthat were too short to produce the reinforcer and the peak ofthe distribution shifted one bin to the left (fig. 2A). As thedose of MAP increased, the relative frequency of response durationsthat were too short, as well as those that were too long to producethe reinforcer increased, which resulted in a progressive flatteningof the response distribution (fig. 2D).

View larger version (42K):
[in this window]
[in a new window]

Fig. 2. Effects of MAP on the cumulative frequency of response-duration distributions under the TRD 1-1.3 sec schedule. Abscissa:Response durations in 0.1-sec time bins. Ordinate: Cumulativenumber of responses in each bin as a percentage of the total numberof responses. Each point for MAP curves represents a mean of singleobservations in each of four rats. Each point for the controlcurve represents a mean based on 10 observations in each of fourrats. Brackets show ±1 standard error. * Signifies a significantdifference from the control curve. Doses are as indicated in thekey. The inserts show the relative frequency distributions forthe cumulative curves as indicated in the key. Insert Ordinate:Percentage of total responses in each bin. Shaded bins show reinforcedresponse durations.

Cumulative frequency curves allowed all the relative frequency distributions to be plotted on the same graph for easier comparisons.As the dose of MAP increased, the curve shifted upward and leftwardbecause of the increase in short response durations (see fig.2, curves A and B). At the higher doses, the curve did not reachasymptote until the later time bins (fig.2, curves C and D) becauseof the increased relative frequency of longer response durations(fig. 2D). This increase in both shorter and longer response durationscaused a flattening of the relative frequency distributions andwas reflected in curves C and D (1.7 and 3.0 mg/kg doses) as abisection of the control curve. Statistical analysis was conductedon the cumulative frequency curves as described under "Data Analysis."The F statistic, used for regression analysis, indicated thatthe linear portions of the MAP curves at all doses were significantlydifferent from the linear portion of the cumulative frequencycontrol curve.

MAP effects on distribution of response durations under the TRD 4-5.2 sec schedule. Figure 3 shows the cumulative frequency curves of response durations based on the relative frequencies with increasing dosesof MAP under the TRD 4-5.2 sec schedule. With each increasingdose, the cumulative frequency curves were shifted upward andto the left without any change in asymptote; this reflected shiftsof the entire distribution toward short response durations asthe dose of MAP increased. At the 1.0 mg/kg dose, an increasein the frequency of responses of short duration (<1.2 sec in duration)began to occur although there was little effect on the mode ofthe relative frequency distribution (fig. 3B). This is reflectedin the cumulative frequency curves with the large increase inshort duration responses (bins 1 and 2) causing an initial increasein the slope of the curve before a further vertical rise. However,with a quarter log increase in dose to 1.7 mg/kg, a large increasein short responses occurred. At the highest dose, more than 50%of the responses are short (<1.6 sec in length) causing the curveto shift upward and to the left. These effects of MAP under theTRD 4-5.2 sec schedule were much larger than those under the TRD1-1.3 sec schedule. The linear portions of the MAP curves weresignificantly different from the control curve at all dose levelsof MAP.

View larger version (48K):
[in this window]
[in a new window]

Fig. 3. Effects of MAP on cumulative frequency distributions of response durations under the TRD 4-5.2 sec schedule. Abscissa: Responseduration time bins in 0.4 sec. Other details as in figure 2.

MAP effects on response-duration distribution under the TRD 10-13 sec schedule. Figure 4 shows the cumulative frequency curves based on the relative response-duration distributions under the TRD 10-13 secschedule. The cumulative frequency distributions again showeda shift upward and to the left, and at lower doses this shiftoccurred with little change in the asymptotic portion of the curve.At the 0.3 mg/kg dose, there was an increase in the relative frequencyof short response durations in nonreinforced bins, shifting thecumulative curve leftward. This effect was more pronounced withhigher doses (fig. 4, B and D) with a high relative frequencyof short responses causing cumulative curves to shift upward andleftward. At the 1.7 mg/kg dose, more than 50% of the responseshad occurred by bin 2 (<2 sec in duration), and at the 3.0 mg/kgdose (fig. 4D), 67% of all responses were less than 1 sec in duration.At that dose, the asymptote was reached in bin 4, which indicatedthat more than 90% of the responses were less that 4.0 sec induration and almost no responses were long enough to fall in thereinforcer window. All doses of MAP produced cumulative curvesin which the linear portions were significantly different fromthe linear portion of the control curve.

View larger version (48K):
[in this window]
[in a new window]

Fig. 4. Effects of MAP on cumulative frequency distributions of response durations under the TRD 10-13 sec schedule. Abscissa: Responseduration time bins in 1.0 sec. Other details as in figure 2.

PCP effects on distribution of response durations under the TRD 1-1.3 sec schedule. Figure 5 shows the cumulative response frequency curves for PCP. The distributions shifted to the left with shorter responsedurations occurring at the 0.3 mg/kg dose level (fig. 5A). Thistrend increased with increasing doses of PCP. At the 3.0 mg/kgdose, there was an increase in relative frequency across all thenonreinforced bins (fig. 5D) to the left of the reinforcer window(bins 1-10), which caused a decrease in the cumulative curve slope.There was a rather large shift to the left between the 1.7 andthe 3.0 mg/kg dose levels corresponding with the rather steepdose-effect curve that exists with PCP. There were no correspondinglong-duration responses as with the TRD 1-1.3 sec schedule forMAP, and therefore little change in the asymptote with any dose.A significant difference between the linear portion of the controlcurve and the PCP curves existed at all doses.

View larger version (42K):
[in this window]
[in a new window]

Fig. 5. Effects of PCP on cumulative frequencies of distributions of response durations under the TRD 1-1.3 sec schedule. Abscissa:Response duration time bins in 0.1 sec. Each point for PCP curvesrepresents a mean of single observations in each of four rats.Other details as in figure 2.

PCP effects on response-duration distribution under the TRD 4-5.2 sec schedule. The cumulative frequency curves (fig. 6) showed an increasing shift to the left with increasing doses of PCP. A feature ofthis drug's effect on the relative frequency of the response-durationdistribution was an increase in short-duration responses witha bimodal pattern starting at the 1.0 mg/kg level (fig. 6B). Atdoses of 1.0 and 1.7 mg/kg, a bimodal pattern produced by an increasein relative frequencies in early bins caused the early portionof the cumulative curve to shift leftward (curves B and C). Atthe highest dose, the curve had shifted far to the left and thefrequency of short-response durations was more similar acrossall the first 10 bins (curve D). The final effect was that ofa fairly uniform frequency of short response durations with fewlong enough to be reinforced. At doses of 1.0, 1.7 and 3.0 mg/kgthe linear portions of the PCP curves were significantly differentfrom the linear portion of the control curve. Again, the effectswere more pronounced under the TRD 4-5.2 sec than under the TRD1-1.3 sec schedule.

View larger version (47K):
[in this window]
[in a new window]

Fig. 6. Effects of PCP on cumulative frequency distributions of response durations under the TRD 4-5.2 sec schedule. Abscissa: Responseduration time bins in 0.4 sec. Each point for PCP curves representsa mean of single observations in each of four rats. Other detailsas in figure 2.

PCP effects on response-duration distributions under the TRD 10-13 sec schedule. The cumulative frequency curves (fig. 7) again showed a shift to the left at low doses of 1.0 and 1.7 mg/kg PCP. Also, asunder the TRD 4-5.2 sec schedule at the highest dose, few responsedurations were long enough to be reinforced (fig. 7D), and thedistribution in the first 10 bins represented a fairly uniformoverestimation of time (responses too short). A statisticallysignificant difference from the control curve existed in the linearportions of the PCP curves at doses of 1.0, 1.7 and 3.0 mg/kg.

View larger version (45K):
[in this window]
[in a new window]

Fig. 7. Effects of PCP on cumulative frequency distributions of response durations under the TRD 10-13 sec schedule. Abscissa: Responseduration time bins in 1.0 sec. Each point for PCP curves representsa mean of single observations in each of three rats (nos. 422,424 and 428). Each point for the control curve represents a meanbased on 10 observations in each of the same three rats. Otherdetails as in figure 2.

$Delta$ ⁹-THC effects on performance under the TRD 1-1.3 sec schedule. The cumulative frequency curves (fig. 8) emphasized the lack of effect on the response-duration distributions. Although the1.7 mg/kg dose produced a slight shift to the right, which indicateda slight increase in longer responses, none of the curves weresignificantly different from control in the linear regions ofthe curves.

View larger version (32K):
[in this window]
[in a new window]

Fig. 8. Effects of $Delta$ ⁹-THC on cumulative frequencies of distributions of response durations under the TRD 1-1.3 sec schedule. Abscissa:Response duration time bins in 0.1 sec. Each point for $Delta$ ⁹-THC curves represents a mean of single observations in each offour rats. Other details as in figure 2.

$Delta$ ⁹-THC effects on performance under the TRD 4-5.2 sec schedule. The cumulative frequency curves (fig. 9) showed little effect of the various doses, similar to the lack of effect under theTRD 1-1.3 sec schedule. At the 0.3 mg/kg dose, there was a slightshift to the left in the upper part of the curve, which indicateda slight increase in shorter responses and the loss of some longerresponses in or near the reinforcer window. The 1.7 mg/kg dosecaused the slope to be altered in the early portion of the curvecharacteristic of an increase in short responses in the earlybins and a slight decrease in asymptote caused by the long responses.Both the 0.3 and 1.7 mg/kg curves were significantly differentfrom the control curve when the linear portions of the $Delta$ ⁹-THC curves were analyzed. None of the other curves were significantlydifferent from the control curve.

View larger version (34K):
[in this window]
[in a new window]

Fig. 9. Effects of $Delta$ ⁹-THC on cumulative frequency distributions of response durations under the TRD 4-5.2 sec schedule. Abscissa: Responseduration time bins in 0.4 sec. Each point for $Delta$ ⁹-THC curves represents a mean of single observations in each offour rats. Other details as in figure 2.

$Delta$ ⁹-THC effects on performance under the TRD 10-13 sec schedule. The cumulative frequency curves (fig. 10) showed a shift to the left, which indicated shorter responses at even the lowestdose. The 4.2 mg/kg dose shifted the curve greatly to the leftwith most of the responses occurring in only a few early binsindicated by the vertical slope and the earlier point of asymptote.More than 90% of the responses are less than 6 sec in duration.The linear portions of all the $Delta$ ⁹-THC curves were significantly different from control curve atall doses.

View larger version (40K):
[in this window]
[in a new window]

Fig. 10. Effects of $Delta$ ⁹-THC on cumulative frequency distributions of response durations under the TRD 10-13 sec schedule. Abscissa: Responseduration time bins in 1.0 sec. Each point for $Delta$ ⁹-THC curves represents a mean of single observations in each ofthree rats (nos. 422, 424 and 427). Each point for control curverepresents a mean based on 10 observations in each of the samethree rats. Other details as in figure 2.

	Discussion

Top Abstract Introduction Methods Results Discussion References

All of the drugs in the present study have been reported anecdotally to alter time perception and to produce overestimationof the passage of time in controlled studies (Hicks et al., 1984;Karniol et al., 1975; Yesavage and Freeman, 1978; Meck, 1983).The present experiments showed that the effects of these drugson responding under TRD schedules differed from each other andthat the differences depended not only on the drug and the doselevel, but also on the time requirements of the TRD schedule.Therefore, a simple characterization of these drugs as drugs thatalter time perception is overly simplistic.

TRD schedules with longer timing requirements produced behaviors that were more sensitive to drug effects than did the TRDschedules with shorter timing requirements. For example, the TRD10-13 sec schedule was the only schedule in which effects of $Delta$ ⁹-THC were apparent. Furthermore, the effects of both PCP and MAPappear to be larger under the two longer TRD schedules than underthe TRD 1-1.3 sec schedule (compare figs. 3 and 4 with fig. 2and figs. 6 and 7 with fig. 5). The reasons for the greater sensitivityto these drugs under the TRD schedules with longer timing requirementsis not clear. One possibility is the control performance. As theminimum lever press required for food presentation increased,the accuracy increased under control conditions without an increasein the variability. Perhaps these base-line differences in accuracyinfluenced the size of the drug effect.

The effects of each drug also depended on the schedule requirements. The most striking example was $Delta$ ⁹-THC, in which few effects were observed under the TRD 1-1.3 andTRD 4-5.2 sec schedules, but large effects were observed underthe TRD 10-13 sec schedule. Schulze et al. (1988) studied theeffects of $Delta$ ⁹-THC in rhesus monkeys responding under a TRD 10-14 sec scheduleand reported effects similar to those observed in this study.It is unlikely that tolerance, which may develop extremely rapidlyto $Delta$ ⁹-THC with a single dose, influenced the effects under some TRDschedules in these studies and not others. Each schedule was performedby a different group of animals and animals within each groupwere randomly assigned an ascending or descending dose order.The observed greater effects of $Delta$ ⁹-THC under schedules with longer time durations and little effectunder the other schedules with shorter time duration requirementswere consistent among the rats within each group.

MAP decreased accuracy as a function of dose under all TRD schedules, but the effects were different under TRD schedules withdifferent timing requirements for food presentation. Under theTRD 1-1.3 sec schedule, MAP flattened the relative frequency distribution,but under the TRD 4-5.3 sec and TRD 10-13 schedules, the relativefrequency distribution shifted to the left with high doses producingonly responses of short duration. The flattening of the relativefrequency distributions by MAP under the TRD 1-1.3 sec scheduleis consistent with reports by Hudzik and McMillan (1994b) andMcMillan et al. (1994). These investigators reported a flatteningof the relative response-duration distributions after MAP, especiallyat the 3.0 mg/kg dose. The shift of the response-duration distributionsto the left after amphetamines that was seen under the TRD 10-14sec schedule has also been observed when rhesus monkeys servedas subjects (Schulze and Paule, 1990).

That a drug such as MAP might produce differential effects under the TRD 1-1.3 sec schedule than under TRD schedules withlonger timing requirements is not too surprising. The TRD 1-1.3sec schedule requires that a precision motor response be made.Release of the lever within a 300-msec period may require motorresponses not required by the longer TRD schedules. The coordinatedmotor movements required by the TRD 1-1.3 sec schedule may bevery different from the requirements of longer TRD schedules inwhich motor precision is less likely to be important. Failureto release the lever promptly might be more likely to cause responsedurations longer than those reinforced under the 300-msec reinforcedtime span. This coupled with the short-duration responses seenunder all three TRD schedules could produce a flattening of therelative frequency distribution. Such effects would seem lesslikely to occur under the wider reinforcer window associated withTRD schedules that required longer lever holds for food presentation.This suggests that although TRD schedules with longer timing parametersrequire behaviors that are more sensitive to the effects of thedrugs, the shorter timing parameters associated with the TRD 1-1.3sec schedule may involve quite different behaviors that are differentiallyaffected by the drugs used in this study.

In contrast to MAP and $Delta$ ⁹-THC, PCP produced similar effects across all TRD schedules, although the effects were smaller atTRD 1-1.3 sec than for the longer TRD schedules. The shift inthe relative frequency distribution to the left with a fairlyequal distribution over the first 10 bins was similar to thatreported in previous studies with the TRD 1-1.3 sec schedule (Hudzikand McMillan, 1994b) in which a similar effect was observed. Itis not clear why PCP effects appear to depend less on the timerequirements of the TRD schedules than do those of MAP and $Delta$ ⁹-THC.

Although relatively few investigators have studied the effects of drugs on responding under TRD schedules, there are severalstudies of the effects of these drugs on responding under DRLschedules at similar time parameters. Both TRD and DRL schedulesmay be considered to be time production schedules, in that theTRD schedule requires an animal to make a response (lever press)of a specified duration to produce the reinforcer, whereas theDRL schedule requires the animal to terminate a time period ofa specified duration with a response.

Amphetamines generally shift IRT distributions toward shorter IRTs under DRL 10-sec schedules (Wenger and Wright, 1990; Luckiand DeLong, 1983), although a few studies have found increasesin long IRTs after amphetamines (Balster and Baird, 1979). PCPhas been reported to produce variable results on responding underDRL 10-sec schedules. In most studies PCP has shifted the IRTdistributions toward shorter times (Sanger, 1992), similar tothe effects observed in the present studies, although there arealso reports of flattening of the IRT distributions (Freeman etal., 1984; Balster and Baird, 1979). $Delta$ ⁹-THC also usually produces shifts to the left in the IRT distributionsunder DRL 10-sec schedules (Ferraro et al., 1971; Galbicka etal., 1980; Manning, 1973), similar to the findings in the presentexperiments. Thus in general, TRD 10-13 sec schedules and DRL10-sec schedules do not differ much in the effects that thesedrugs produce on behavior maintained under these schedules. Allof the drugs are most frequently characterized by shifts towardshorter IRTs or shorter response durations under these schedules.

DRL schedules requiring minimum IRTs shorter than 10 sec have rarely been used in behavioral pharmacology. An exception isthe work of McClure and McMillan (1997) who studied the effectsof these same drugs under DRL schedules with the same timing requirementsas those for the present TRD schedules in a direct attempt atcomparison. The relative frequency distributions with PCP underTRD 4-5.2 and TRD 10-13 sec schedules were similar to those producedunder similar DRL schedules. However, under the TRD 1-1.3 secschedule, PCP shifted responding toward short-response durations,whereas under the DRL 1-1.3 sec schedule, the relative frequencydistribution shifted toward long interresponse times. Sanger (1992)and Sanger and Jackson (1989) have also reported a shift in therelative frequency distributions to the left with a flat relativefrequency distribution of short responses in studies with ratsunder a DRL 15-sec schedule. However, Balster and Baird (1979)and Freeman et al. (1984) found more extreme effects in mice respondingunder a DRL 10-sec schedule with most response durations occurringin the first few bins, although these effects were obtained onlyat a high dose (19.0 mg/kg).

With MAP, the extreme leftward shift of the relative frequency distribution under TRD 4-5.2 sec and TRD 10-13 sec schedulesdiffered from the flatter distribution of early responses presentunder the DRL 4-5.2 sec and 10-13 sec schedules (McClure and McMillan,1997). This effect under the DRL 10-13 sec schedule (McClure andMcMillan, 1997) is not unlike the pattern that is produced withMAP or d-amphetamine under many DRL schedules with time parametersof 10 sec or slightly longer (Balster and Baird, 1979; Wengerand Wright, 1990). Under schedules requiring longer IRTs (Sidman,1955; Pradhan and Dutta, 1970; Sanger et al., 1974; Hodos et al.,1962; Adam-Carriere et al., 1978; Seiden et al., 1979; Levineet al., 1980) MAP produces a leftward shift of the relative frequencydistribution that is more extreme, like the effect of MAP underthe TRD 4-5.2 sec or TRD 10-13 sec schedules.

$Delta$ ⁹-THC also produced a greater effect on responding under TRD schedules than under comparable DRL schedules. Although littleor no effect on responding occurred at 1-1.3 sec or 4-5.2 sectime parameters under either TRD or DRL schedules, relative frequencydistributions showed leftward shifts under both 10-13 sec schedules.At these longer timing requirements, $Delta$ ⁹-THC produced a more prominent shift to the left under the TRD10-13 sec schedule than under the DRL 10-13 sec schedule (McClureand McMillan, 1997). The effect of $Delta$ ⁹-THC under the DRL 10-13 sec schedule was remarkably similar tothe effects of $Delta$ ⁹-THC on responding under all DRL patterns reviewed for comparison(Ferraro et al., 1971, 1972; Manning, 1976; Galbicka et al., 1980).In all DRL studies surveyed, if the lower limit of the reinforcedwindow is 10 sec or longer, all distributions retain the bell-shapedistribution but shifted to the left toward shorter IRTs. Themore extreme leftward shift under the TRD 10-13 sec schedule indicateda greater effect of $Delta$ ⁹-THC under this TRD schedule than that under the other DRL schedulesreviewed. Therefore, the contrasting effects of MAP and $Delta$ ⁹-THC under TRD and DRL schedules suggest that the two types oftiming schedules may require different behavioral processes.

The comparison between TRD and DRL schedules and the effects of drugs on responding maintained by these schedules suggeststhat differential drug effects can occur for responding underTRD and DRL schedules even when the time duration requirementsfor the schedules are identical. Because both TRD and DRL schedulesare time production tasks, they must differ from each other issome other way if drugs are to have differential effects on behaviorunder these schedules. The base-line accuracy rates for the TRDschedules were much higher and the standard errors were much lowerthan those under the comparable DRL schedules (McClure and McMillan,1997). These base-line differences may contribute to the differentialeffects of some drugs. Because TRD schedules require the animalto maintain contact with the lever, they restrict the animal'smovement relative to DRL schedules where the animal is free tomove about the cage during the IRT. This would be a logical placeto begin to look for the determinants of the differential sensitivityto the drug effects.

	Acknowledgments

The authors thank W. C. Hardwick and Dean W. Wright for skilled technical assistance, and the National Institute on Drug Abusefor providing phencyclidine and $Delta$ ⁹-tetrahydrocannabinol used in this study.

	Footnotes

Accepted for publication February 28, 1997.

Received for publication February 7, 1996.

¹ This work was supported National Institute on Drug Abuse Grant DA 02257.

Send reprint requests to: D. E. McMillan, Dept. Pharmacology and Toxicology, University of Arkansas for Medical Sciences, 4301 W Markham Street, Little Rock, AR 72205.

	Abbreviations

$Delta$ ⁹-THC, delta⁹-tetrahydrocannabinol; DMSO, dimethyl sulfoxide; DRL, differential reinforcement of low rates of responding; IRT, interresponse time; MAP, methamphetamine; PCP, phencyclidine; T, a time variable; TRD, temporal response differentiation; ANOVA, analysis of variance.

	References

Top Abstract Introduction Methods Results Discussion References

Adam-Carriere, D., Merali, Z. and Stretch, R.: Effects of morphine, naloxone, d,l-cyclazocine, and d-amphetamine on behaviour controlled by a schedule of interresponse time reinforcement. Can. J. Physiol. Pharmacol. 56: 707-720, 1978[Medline].
Balster, R. L. and Baird, J. B.: Effects of phencyclidine, d-amphetamine and pentobarbital on spaced responding in mice. Pharmacol. Biochem. Behav. 11: 617-623, 1979[Medline].
Buffalo, E. A., Gillam, M. P., Allen, R. R. and Paule, M. G.: Acute effects of caffeine on several operant behaviors in rhesus monkeys. Pharmacol. Biochem. Behav. 46: 733-737, 1993[Medline].
Ferguson, S. A. and Paule, M. G.: Acute effects of chlorpromazine in a monkey operant behavioral test battery. Pharmacol. Biochem. Behav. 42: 333-341, 1992[Medline].
Ferguson, S. A. and Paule, M. G.: Acute effects of pentobarbital in a monkey operant behavioral test battery. Pharmacol. Biochem. Behav. 45: 107-116, 1993[Medline].
Ferraro, D. P.: Effects of $Delta$ ⁹-trans-tetrahydrocannabinol on simple and complex learned behavior in animals. In Current Research in Marijuana, ed. by M. F. Lewis 49-95, Academic Press, New York, 1972.
Ferraro, D. P., Grilly, D. M. and Lynch, W. C.: Effects of marihuana extract on the operant behavior of chimpanzees. Psychopharmacologia 22: 333-351, 1971.
Ferraro, D. P. and Grilly, D. M.: Response differentiation: A psychophysical method for response produced stimuli. Percept. Psychophys. 7: 206-208, 1970.
Freeman, A. S., Martin, B. R. and Balster, R. L.: Relationship between the development of behavioral tolerance and the biodisposition of phencyclidine in mice. Pharmacol. Biochem. Behav. 20: 373-377, 1984[Medline].
Galbicka, G., Lee, D. M. and Branch, M. N.: Schedule-dependent tolerance to behavioral effects of $Delta$ ⁹-tetrahydrocannabinol when reinforcement frequencies are matched. Pharmacol. Biochem. Behav. 12: 85-91, 1980[Medline].
Hicks, R. E., Gualtieri, C. T., Mayo, J. P., JR. and Perez-Reyes, M.: Cannabis, atropine and temporal information processing. Neuropsychobiology 12: 229-237, 1984[Medline].
Hodos, W., Ross, G. S. and Brady, J. V.: Complex response patterns during temporally spaced responding. J. Exp. Anal. Behav. 5: 473-479, 1962[Medline].
Hollister, L. E. and Gillespie, H. K.: Marihuana, ethanol and dextroamphetamine. Mood and mental function alterations. Arch. Gen. Psychiatry 23: 199-203, 1970[Abstract/Free Full Text].
Hudzik, T. J. and McMillan, D. E.: Drug effects on response-duration differentiation. II: Selective effects of antidepressant drugs. J. Pharmacol. Exp. Ther. 268: 1335-1342, 1994a[Abstract/Free Full Text].
Hudzik, T. J. and McMillan, D. E.: Drug effects on response duration differentiation: I. Differential effects of drugs of abuse. Psychopharmacology 114: 620-627, 1994b[Medline].
Karniol, I. G., Shirakawa, I., Takahashi, R. N., Knobel, E. and Musty, R. E.: Effects of $Delta$ ⁹-tetrahydrocannabinol and cannabinol in man. Pharmacology 13: 502-512, 1975[Medline].
Levine, T. E., McGuire, P. S., Heffner, T. G. and Seiden, L. S.: DRL performance in 6-hydroxydopamine-treated rats. Pharmacol. Biochem. Behav. 12: 287-291, 1980[Medline].
Lucki, I. and DeLong, R. E.: Control rate of response or reinforcement and amphetamine's effect on behavior. J. Exp. Anal. Behav. 40: 123-132, 1983[Medline].
Manning, F. J.: Acute tolerance to the effects of $Delta$ ⁹-tetrahydrocannabinol on spaced responding by monkeys. Pharmacol. Biochem. Behav. 1: 665-671, 1973[Medline].
Manning, F. J.: Role of experience in acquisition and loss of tolerance to the effect of $Delta$ ⁹-THC on spaced responding. Pharmacol. Biochem. Behav. 5: 269-273, 1976[Medline].
Maricq, A. V., Roberts, S. and Church, R. M.: Methamphetamine and time estimation. J. Exp. Psychol. Anim. Behav. Process 7: 18-30, 1981[Medline].
McClure, G. Y. H. and McMillan, D. E.: Effects of drugs on response duration differentiation. VI: Differential effects under differential reinforcement of low rates of responding schedules. J. Pharmacol. Exp. Ther. 281: 1368-1380, 1997[Abstract/Free Full Text].
McMillan, D. E., Adams, S. L., Wenger, G. R., McClure, G. Y. and Hardwick, W. C.: Effects of drugs on response duration differentiation. III. Acute variation of reinforced duration. Pharmacol. Biochem. Behav. 48: 941-957, 1994[Medline].
McMillan, D. E. and Patton, R. A.: Differentiation of a precise timing response. J. Exp. Anal. Behav. 8: 219-226, 1965.
Meck, W. H.: Selective adjustment of the speed of internal clock and memory processes. J. Exp. Psychol. Anim. Behav. Process 9: 171-201, 1983[Medline].
Meck, W. H. and Church, R. M.: A mode control model of counting and timing processes. J. Exp. Psychol. Anim. Behav. Process 9: 320-334, 1983[Medline].
Pradhan, S. N. and Dutta, S. N.: Comparative effects of nicotine and amphetamine on timing behavior in rats. Neuropharmacology 9: 9-16, 1970[Medline].
Sanger, D. J., Key, M. and Blackman, D. E.: Differential effects of chlordiazepoxide and d-amphetamine on responding maintained by a DRL schedule of reinforcement. Psychopharmacologia 38: 159-171, 1974.
Sanger, D. J.: NMDA antagonists disrupt timing behaviour in rats. Behav. Pharmacol. 3: 593-600, 1992.[Medline]
Sanger, D. J. and Jackson, A.: Effects of phencyclidine and other N-methyl-D-aspartate antagonists on the schedule-controlled behavior of rats. J. Pharmacol. Exp. Ther. 248: 1215-1221, 1989[Abstract/Free Full Text].
Schulze, G. E., McMillan, D. E., Bailey, J. R., Scallet, A., Ali, S. F., Slikker, W., Jr. and Paule, M. G.: Acute effects of $Delta$ ⁹-tetrahydrocannabinol in rhesus monkeys as measured by performance in a battery of complex operant tests. J. Pharmacol. Exp. Ther. 245: 178-186, 1988[Abstract/Free Full Text].
Schulze, G. E., Slikker, W., Jr. and Paule, M. G.: Multiple behavioral effects of diazepam in rhesus monkeys. Pharmacol. Biochem. Behav. 34: 29-35, 1989[Medline].
Schulze, G. E. and Paule, M. G.: Acute effects of d-amphetamine in a monkey operant behavioral test battery. Pharmacol. Biochem. Behav. 35: 759-765, 1990[Medline].
Schulze, G. E. and Paule, M. G.: Effects of morphine sulfate on operant behavior in rhesus monkeys. Pharmacol. Biochem. Behav. 38: 77-83, 1991[Medline].
Seiden, L. S., Andersen, J. and MacPhail, R. C.: Methylphenidate and d-amphetamine: Effects and interactions with alpha-methyl-tyrosine and tetrabenazine on DRL performance in rats. Pharmacol. Biochem. Behav. 10: 577-584, 1979[Medline].
Sidman, M.: Technique for assessing the effects of drugs on timing behavior. Science 122: 925, 1955[Free Full Text].
Sidman, M.: Time discrimination and behavioral interaction in a free operant situation. J. Comp. Physiol. Psychol. 49: 469-473, 1956[Medline].
Tinklenberg, J. R., Roth, W. T. and Kopell, B. S.: Marijuana and ethanol: Differential effects on time perception, heart rate, and subjective response. Psychopharmacology 49: 275-279, 1976[Medline].
Wenger, G. R. and Wright, D. W.: Behavioral effects of cocaine and its interaction with d-amphetamine and morphine in rats. Pharmacol. Biochem. Behav. 35: 595-600, 1990[Medline].
Yesavage, J. A., Freeman, A. M. and Bourgeois, M. L.: Time distortion in acute phencyclidine (PCP) psychosis. A correlation between 30 seconds estimation and urine drugs levels. Encephale 4: 281-285, 1978[Medline].
Yesavage, J. A. and Freeman, A. M.: Acute phencyclidine (PCP) intoxication: psychopathology and prognosis. J. Clin. Psychiatry 39: 664-666, 1978[Medline].

This article has been cited by other articles:

G. Y.贌. Mcclure and D. E. Mcmillan

J. Pharmacol. Exp. Ther., June 1, 1997; 281(3): 1368 - 1380.
[Abstract] [Full Text]

This Article

Abstract

Full Text (PDF)

Submit a response

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Similar articles in this journal

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Google Scholar

Google Scholar

Articles by Mcclure, G. Y.贌.

Articles by Mcmillan, D. E.

Search for Related Content

PubMed

PubMed Citation

Articles by Mcclure, G. Y.贌.

Articles by Mcmillan, D. E.

Effects of Drugs on Response Duration Differentiation. V: Differential Effects under Temporal Response Differentiation Schedules1

Effects of Drugs on Response Duration Differentiation. V: Differential Effects under Temporal Response Differentiation Schedules¹