Neurotoxicology Division, National Health and Environmental Effects Research Laboratory, Office of Research and Development, US Environmental Protection Agency, Research Triangle Park, North Carolina 27711
1 To whom correspondence should be addressed at NTD (Mail Code B105-04), US EPA, RTP, NC 27711. Fax: (919) 541-4849. E-mail: moser.ginger{at}epa.gov.
Received February 22, 2005; accepted May 5, 2005
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ABSTRACT |
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Key Words: chlorpyrifos; behavior; functional observational battery; Morris water maze; chronic.
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INTRODUCTION |
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Despite the wealth of literature on acute effects of OP pesticides in laboratory animals, there are relatively few reports of long-term exposure, and even fewer involving exposure greater than three to four months. Few neurobehavioral effects have been reported in studies of long-term exposures. Decreased motor activity was seen transiently with subchronic dietary exposure to chlorpyrifos and tebupirimphos (Mattsson et al., 1996; Sheets et al., 1997
), whereas four-month exposure to dietary triphenyl phosphate produced no measurable behavioral effects (Sobotka et al., 1986
). A subchronic study of dietary exposure to parathion produced no adverse behavioral changes, only a transient improvement in learning at the low dose (Ivens et al., 1998
). Shorter-term exposures, however, appear to produce various neuromotor and cognitive effects. For example, six-week exposure to methyl parathion by oral gavage lowered activity and arousal (Schulz et al., 1990
), and 38-day exposure to subcutaneous chlorpyrifos decreased hindlimb grip strength at the end of exposure (Terry et al., 2003
). Fourteen-day subcutaneous exposure to chlorpyrifos (Terry et al., 2003
) or to diisopropylfluorophosphate (DFP; Prendergast et al., 1997
) altered acquisition in the Morris water maze; these effects were seen after AChE had recovered in the one study that measured it (Prendergast et al., 1997
). A 30-day study of intraperitoneally administered disulfoton produced overt toxicity early on, followed by tolerance to some, but not all, of the behavioral effects (Llorens et al., 1993
). Overall, the comparability of these findings to human exposures is limited due to the dose, length, and route of exposures.
This study was initiated to examine the health effects of long-term, low-level exposure to organophosphate (OP) pesticides, as well as the influence of that exposure on intermittent high-dose challenges. Chlorpyrifos (CPF) was chosen as a model OP which is still used extensively world-wide, despite recent limitations of its use in the U.S. Many poisoning episodes, e.g., during crop spraying, occur in farm workers/applicators, who probably also have ongoing low-level exposure. These ongoing exposures may make the individual more sensitive to acute poisoning episodes.
There were two basic questions addressed in this study: (1) Does long-term, low-level OP exposure produce neurotoxicity? And, (2) does ongoing OP exposure influence the subsequent response to higher-level acute exposure? One hypothesis of this study was that the low levels used in this study would not produce acute effects, but would produce tolerance in the form of muscarinic receptor down-regulation. If that occurred, treated rats would show fewer neurobehavioral effects following an acute, high dose exposure. An alternate hypothesis was that the already-compromised rats would show a greater response to acute exposure. A large, multi-investigator project was undertaken to address these hypotheses using endpoints reported to be sensitive to acute or repeated chlorpyrifos exposures. Other papers report biochemical endpoints (Padilla et al., submitted) and measures of operant responding (Samsam, T.E., Bushnell, P.J., Marshall, R.S., and Hunter, D.L., unpublished data, 2005). The present article presents data collected using a neurobehavioral screening battery and a Morris water maze test of cognitive function during the year-long exposure.
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MATERIALS AND METHODS |
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Chemicals.
CPF feed was provided in 5-g wafers (Bio-Serv, Frenchtown, NJ), and was color-coded (using vegetable food dyes) to prevent feeding errors. The wafer concentrations were approximately 117 and 23 mg/kg, which would deliver daily doses of 5 and 1 mg/kg, respectively, when 15 g/day of feed was given to rats weighing 350 g. Shipments were monitored for CPF levels, and were rejected if the nominal values were outside 10% of target (see Padilla et al. for details of analysis).
For CPF challenges, CPF (Chem-Serve, West Chester, PA) was dissolved in corn oil and administered via po gavage at 1 ml/kg.
Experimental design.
There were six treatment groups: three levels of dietary exposure (control, low, high) and for each diet group, half of the rats received bimonthly CPF challenges (spikes) by po gavage and the other half received vehicle (corn oil). This was a large multi-investigator project, and the entire study was run in two cohorts. Twenty rats/treatment group were designated for these behavioral evaluations, divided into two equal cohorts (n = 10/treatment/cohort; total, 120 rats). Feed exposure lasted one year.
The first CPF spike was 60 mg/kg; however, several rats died at this dose (this occurred in rats allocated to other investigators, and did not affect the sample size in these behavioral studies), and therefore the subsequent spikes were lowered to 45 mg/kg. The unanticipated lethality occurred in the first cohort, but the second cohort was dosed the same way to keep them comparable; in other words, the second cohort also received 60 mg/kg for the first challenge, and 45 mg/kg for subsequent doses.
Neurobehavioral testing.
Rats were tested periodically throughout the year-long exposure period. Testing for neurobehavioral changes, using a functional observational battery (FOB) and an evaluation of motor activity, took place before exposure began and approximately monthly thereafter, except in month 11. On spike days, rats were tested at 3.5 h (time of peak effect; see Moser and Padilla, 1998) after the dose. During the 11th month of exposure, cognitive testing, using a Morris water maze, started two weeks after the 5th spike and continued daily for a month. Table 1 presents the test times by week.
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The FOB and motor activity evaluation are widely used as a screening battery for general neurobehavioral toxicity. Procedural details and scoring criteria for the FOB protocol are provided elsewhere (McDaniel and Moser, 1993). Each rat was evaluated for changes in general appearance, lacrimation, and salivation, in addition to ranking of the animal's reactivity. Open field measurements included ranking the rat's arousal and activity levels, counting the number of times the animal reared, and noting any tremorigenic activity. The rat's reaction to a click stimulus, tail pinch, and penlight were also ranked. Forelimb and hindlimb grip strength, landing foot splay, and rectal temperature were quantified. Motor activity data were collected shortly after FOB testing, using a photocell-based chamber shaped like a figure-eight (Reiter 1983
). Activity counts were recorded in 12 five-min intervals to evaluate habituation of activity during the session. For all testing, the observer was blind with respect to the treatment levels.
Cognitive testing took place in a water maze using procedures described by Morris (1981). The round tank (140-cm diameter) was filled with water made opaque with white tempera paint, and the plexiglass escape platform (9 cm in diameter) was placed 2 cm beneath the surface of the water. Water temperature was maintained at 2526°C and water was changed and the tank cleaned daily. Electronic tracking equipment (HVS Imaging, Ormond Crescent, Hampton, U.K.) was used to measure behavior, including latency to find the platform, pathlength, swim speed, and distribution of swimming throughout the quadrants and concentric zones of the tank. For place training, the platform was located in the same quadrant, and the starting position alternated across trials in a semi-random order.
For cohort 1, place training consisted of one trial per day (Monday through Friday) for three weeks, whereas for cohort 2, place training involved two trials per day for two weeks. Rats had 60 s in which to find the platform, and were guided there by the observer if they did not succeed, followed by 15 s on the platform. Memory was tested in 60-s probe trials, with the platform removed, on day 8 and 15 for cohort 1, and day 5 and 10 for cohort 2. Working memory was evaluated for cohort 1 only. For this, the platform moved each day (five possible positions) for five days, and rats were given two trials per day. The last test for both groups was a visual task using a platform with a black strip along edge, raised 2.5 cm above the water. Dependent variables included latency to find the platform, pathlength, swim speed, percent time in cocentric zones as well as the outermost ring of the tank, and, for probe trials only, percent time in quadrants (dwell time) and proximity score (Gallagher et al., 1993).
Statistical approach.
For analysis of these data, multivariate ANOVAs would need to include multiple factors: CPF feed (three levels), spike (two levels), cohort (two), and repeated testing over 12 months (for FOB/activity data) or over daily training (for water maze). To focus and decrease the number of overall statistical analyses, only data that targeted three specific questions were analyzed. The first question was, did the feed alone have an effect, and was there a difference in effect across time? For these analyses, data from the non-spike groups (i.e., received oil for the spike) were analyzed across all 12 time points. The second question was, was the response to the spikes different depending on the level of CPF in the feed, and did this change over time? For this, data from the spike groups (i.e., received chlopyrifos for the spike) were analyzed across all spike days. However, since the first spike day used a higher dose (which could erroneously appear as a spike-by-time interaction), that one day was analyzed separately, and the subsequent five spikes were analyzed together (as repeated measures). Finally, were there differences in spike rats compared to non-spike rats, did this depend on the level of CPF in the feed, and did this change over time? For the FOB and motor activity data, these analyses included all groups, analyzed across non-spike days only. Focusing the analyses in this way eliminated the high incidence of overall interactions due to combining spike and non-spike data across all time points. We also felt this approach strengthened the interpretation of this large dataset.
Using this modified approach, overall analyses using factors of feed, spike, cohort, and repeated testing were conducted as described above. Where overall interactions were significant, step-down analyses were conducted to clarify the specific interaction. If there were no interactions between cohort and other factors, the data were combined for subsequent analyses. For analysis of the Morris water maze data, the cohorts were analyzed separately since the experimental testing was different. Analysis procedures for these behavioral test measures have been previously described (Creason, 1989; Moser et al., 1988
). Continuous data (e.g., motor activity, habituation, continuous endpoints of the FOB, and water maze measures) were analyzed by a general linear model (GLM; SAS, 1990
). Rank-order and categorical data of the FOB were analyzed using a categorical modeling procedure (CATMOD; SAS, 1990
). In all cases, probability values p < 0.05 were considered significant.
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RESULTS |
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None of the rats in the first cohort died during the year-long study, but in the second cohort, one rat in the 1-0 group and two rats in the 5-CPF group were euthanized for health reasons unrelated to treatment. Otherwise, rats showed relatively good health. The rats were about 15 months old at the end of the study. However, since rats that are weight-maintained in our facility live at least two years (P. Bushnell, personal communication), they cannot be considered aged. Body weight was consistent across treatment groups, since the amount of feed provided each day was adjusted so as to maintain a 350 g body weight. The only exception was that, after each spike, the rats who received CPF spike tended to lose weight overnight and therefore received a bit more food the next day.
As expected, the bimonthly (every two months) spikes produced overt toxicity, which recovered in each intervening month. A typical pattern of behavior is shown in Figure 1, which shows motor activity counts over the year. There was a sharp drop in activity in the groups receiving each CPF spike. The first spike, being a higher dose, produced greater effects (relative to the controls for that time point) than the subsequent doses. Note that there was also a significant decline in activity across testing for all non-spike groups, and for the spike groups on the non-spike testing days.
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FOB/Motor Activity
Rats receiving CPF feed but only the vehicle spikes showed significant interactions on most of the endpoints evaluating activity and reactivity. There were, however, no consistent or dose-related changes. In addition, there were significant cohort interactions with every endpoint, indicating differences in the cohorts.
In cohort 1, the high feed group showed increased open field activity, but only at the 27-week test, and decreased handling reactivity, only at 52 weeks. However, Cohort 2 rats showed a few more effects. Habituation differences were suggested by the significant influence of cohort and feed, but not time, which was shown by further analyses to be due to the high-dose feed (presented in Fig. 2). The high-dose feed group showed slightly higher activity early in the session, but asymptotic activity later in the session was similar to the other feed groups. Arousal was transiently altered, with decreases in the low feed group at 44 weeks and in the high feed group at 52 weeks. The magnitude of these changes was quite small. Step-down analyses of rearing and click response did not produce any significant differences.
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The paradigm used for cohort 2 training involved two trials each day, and for the statistical analyses trial was nested within daily blocks. Unlike in cohort 1, there was an overall effect of feed (F(2,54) = 3.53, p = 0.0366) on the latency to find the platform in cohort 2 during the second week of training. As shown in Figure 4, the high-dose feed group latency was significantly higher. There were no differences among treatment groups in swim speed or pathlength at any time.
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Unlike the first cohort, neither probe trial showed any significant effects on any dependent variables in the second cohort. The time in quadrants data for the second probe trial are shown in Figure 5.
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Question 2: Was the response to the spikes different depending on the level of CPF in the feed, and did this change over time?
FOB/Motor Activity
Although the feed itself had relatively little effect, CPF dietary exposure resulted in greater response on some endpoints in the rats receiving the CPF challenges. This was generally true for both feed levels, but was not consistent across spikes nor always dose-responsive. A summary of the influences of feed exposure on the response to CPF challenge is presented in Table 3. Dietary exposure made the most difference following the first spike (60 mg/kg). For lacrimation, tremor, righting reflex, foot splay, and open field activity, there was a main effect of feed; only open field activity showed an interaction with cohort (see Table 2). The data for lacrimation and tremor severity scores are shown in Figure 7. After the first spike, the high-dose feed group showed a greater response in terms of lacrimation, tremor, abnormal righting ability, and increased landing foot splay in both cohorts. Open field activity was more depressed in the high-dose feed group in cohort 1, but the opposite finding (less depression) was seen in the low-dose feed group in cohort 2.
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The water maze testing took place between the spikes, not during, so those data cannot be used to address the second question.
Question 3: Were there differences in spike rats compared to non-spike rats, did this depend on the level of CPF in the feed, and did this change over time?
FOB/Motor Activity
On non-spike days, groups receiving the CPF spikes were different on some measures from the vehicle control groups. Statistically, the spike factor had the greatest influence; only a few of these measures depended on the level of feed or differed between the cohorts (Table 2).
There were significant overall effects of spike on several FOB measures on some, but not all, non-spike days, regardless of the level of CPF in the feed. These differences in the spike group included lowered tail-pinch response (week 21), increased handling reactivity (week 13), and slightly (67%) higher forelimb grip strength (weeks 21 and 32). The effect on hindlimb grip strength was not due to spike exposures, since it was significant at four weeks (before the first spike) as well as later time points.
Landing foot splay and body temperature (presented in Fig. 8) showed significant overall effects of spike. Foot splay values were higher in the spike group even before the first spike, and the magnitude of difference did not change throughout the study. Even though there was no significant influence of time, body temperature was equal between the groups until after the first spike, and the spike group remained about 0.2°C lower thereafter.
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For several endpoints, the influence of spike and/or feed depended on the cohort. Open field activity was lower in spiked groups across all times in cohort 1. Habituation was also altered in this cohort (Fig. 2). As was observed in the feed-only groups, the spike group had higher activity levels early in the session, but the asymptotic levels were the same between the spike and non-spike groups. In cohort 2, the high feed group had less rearing activity than controls only at week 21, regardless of whether or not they received the CPF spike.
Morris Water Maze
During spatial training of cohort 1, the time in each annulus (zone) was altered by CPF exposure; however, the pattern of effect was not clear. In the first week of training, the spike groups (F(1,54) = 6.58, p = 0.0132) spent less time in the innermost zone. There were significant interactions of trial, spike, and feed (trial*feed F(12,324) = 2.24, p = 0.0102; trial*spike F(6,324) = 2.21, p = 0.0419) in the middle zone data with effects only in certain trials and in opposite directions. Time in the outer zone showed an interaction of feed and spike (trial*feed*spike F(10,270) = 1.89, p = 0.0467) during the second week, but step-down analyses did not reach significance.
With cohort 2, there were again significant interactions of feed, spike, block, and trial for the measure of thigmotaxis during spatial training (trial*block*feed*spike F(6,153) = 2.18, p = 0.0475). As shown in Figure 4, this complex interaction appeared to be due to the increase in percent hugtime in the feed groups in the second trial of each day. However, step-down analyses showed only a significant overall feed effect in trial 3, and a feed-by-spike interaction in trial 8. In the first week of training, the feed groups showed an interaction between trials and the time spent in the innermost zone (trial*feed F(2,51) = 5.90, p = 0.0050), but no trial showed a difference in feed groups. During the second week, the interactions were among the spike groups in the inner zone (time*trial*spike F(3,153) = 2.91, p = 0.0364) and the middle zone (trial*spike F(1,51) = 6.67, p = 0.0127). The spike groups spent less time in these zones in certain trials only, specifically trial 9 and 14 for the inner zone, the middle zone showed only a trend (p's < 0.07) in trials 12 and 13.
In the second probe test for cohort 1, there was a significant interaction of feed and spike in the percent time in quadrant variable, for both the first 30 s (quadrant*feed*spike F(2,54) = 3.69, p = 0.0316) as well as the full 60-s measure (quadrant*feed*spike F(2,54) = 3.93, p = 0.0255). Figure 5 shows that the 5-CPF group spent less time in the correct quadrant compared to the 0-0 control group. The proximity measure for the first 30 s showed a significant interaction with spike (quadrant*spike F(1,54) = 6.65, p = 0.0127), in that the spike groups had lower proximity values in the incorrect quadrants. This finding was not evident in the 60-s analysis. There were no differences among treatment groups on the time in the different areas of the tank in the second probe. There was a significant effect on swim speed in the second probe (feed*spike F(2,54) = 3.55, p = 0.0355). Post-hoc comparisons revealed that the 10 group swam faster than 1-CPF, 0-CPF, and 5-0 groups.
As mentioned above, the working memory paradigm revealed an overall effect of spike, with the spike groups showing higher latencies. In the analyses of spatial distribution, there was an interaction with spike on the hugtime measure (trial*time*spike F(4,216) = 2.81, p = 0.0266), but step-down analyses did not identify significant contrasts.
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DISCUSSION |
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We have shown that acute doses of CPF which produce 6070% brain inhibition will produce hypothermia, altered gait, and decreased motor activity (Nostrandt et al., 1997). Even though the high-dose feed group had similar levels of brain ChE inhibition on a chronic basis, such signs were not evident. While the FOB and motor activity measures indicated increased activity and decreased excitability, the dose-response and effective times were not consistent between cohorts and the data are not convincing. Other reports of subchronic dietary OP exposures (Ivens et al., 1998
; Mattsson et al., 1996
; Sheets et al., 1997
) also found relatively few behavioral effects using similar observational batteries and activity measures.
A possible explanation for the lack of behavioral response to dietary exposure (despite clear ChE inhibition) could be tolerance. Repeated exposure to OPs leads to the development of tolerance, presumably due to down-regulation of the muscarinic receptors mediating the toxicity (reviewed by Costa, 1982). While tolerance is the accepted sequelae of repeated anticholinesterase exposure, studies have often used doses which produce high ChE inhibition and/or clear toxicity. In this study, muscarinic receptor assays, using QNB as the ligand, showed decreased binding in the whole brain (but not the pons or retina; Padilla et al., submitted). The high-dose feed group showed 12% decrease in binding, and the spiked groups showed 6% lower binding across all levels of feed. As with ChE inhibition, this parameter had reached steady-state by six months. This muscarinic receptor down-regulation could have contributed to a form of tolerance, and attenuated the effects of ChE inhibition following the dietary exposure.
In rats receiving the spike, both brain and blood ChE were greatly inhibited at 24 h, and the inhibition in the high-dose feed group was greater than that of the control feed group receiving the same spike (brain, 92% vs. 79% inhibition, and blood, 98% vs. 93% inhibition for the 5-CPF vs 0-CPF groups, respectively; Padilla, S., Marshall, R.S., Hunter, D.L., Oxendine, S., Moser, V., Southerland, S.B., and Mailman, R.B., unpublished data, 2005). Likewise, the level of dietary CPF clearly impacted the behavioral effects of the spikes. Generally, exposure to CPF in the feed potentiated the behavioral responses, and this was significant with both feed levels for some endpoints. This phenomenon was clearer following the first spike, which produced greater effects than the lower dose used thereafter. Overall, the CPF feed potentiated some autonomic, neuromuscular, and convulsive endpoints, while less consistent effects were observed on the activity and excitability endpoints.
We had hypothesized that tolerance would develop during the long-term exposure, which was indeed evident in the receptor down-regulation. We anticipated that this would have been measurable as an attenuated response to the CPF spikes, but we observed the opposite. Potentiation of effect was evident with measures of ChE inhibition and behavior, with the rats receiving CPF feed showing greater inhibition following the spikes. The magnitude of muscarinic receptor down-regulation was not great (612%), and this may not be sufficient to attenuate the greater ChE inhibition experienced in the CPF-feed rats. Higher dietary levels, which would produce greater persistent ChE inhibition, and greater receptor down-regulation, may show a completely different pattern of response.
Another goal of this study was to evaluate the persistent effects of the spikes. Generally, there were more effects in the spike groups with little influence of feed, indicating that, for some measures, recovery was not complete in the intervening months. Some of the differences correlated with the acute effects of CPF, specifically, decreased tail pinch and hypothermia (Moser, 1995). However, increased reactivity, grip strength, and foot splay were also observed, and these are responses that are opposite to the acute effects. Since ChE was not measured in the intervening months between spikes, we do not know if the inhibition had recovered by a month. Behavioral changes like this have not been reported in the literature. Indeed, Gordon and Padnos (2002)
reported that, using a telemetry system, increased temperature was measured in the high-dose feed rats, in contrast to the persistent decreased temperature that we measured. They did, however, report a similar potentiation of the hypothermic response to the spikes. In another study, Terry et al. (2003)
reported decreased hindlimb grip strength at the end of 38-day CPF exposure. While we observed an increase in hindlimb grip strength, this was most likely a pre-existing difference since it emerged before the first spike.
There were significant differences between the cohorts on some endpoints, despite our extreme efforts to keep everything the same. Furthermore, there was variation between responses to the six spikes administered over the year. Every batch of feed, and all the dosing solutions were analyzed for CPF concentration and found to be within 10% of the nominal concentration. The source of the rats, down to the breeding area at the supplier, was the same. Gaines and Linder (1986) reported some seasonal differences in the lethality of one OP (parathion), and it is apparent that this confounding factor is not well understood. Seasonal effects could at least partially explain the differences across spikes, which took place every two months, and between cohorts, since the cohorts did not start at the same time of year.
There is general agreement in human studies that cognitive deficits occur during episodic or prolonged pesticide exposure, although the cognitive construct altered varies depending on the report. We evaluated spatial learning using the Morris water maze, which has been used in other studies of OPs as well (Prendergast et al., 1997; Sanchez-Santed et al., 2004
; Terry et al., 2003
). Using the typical measures of learning and memory, we observed several changes that we interpret as evidence of learning deficits. As with the FOB, there were cohort differences in the outcomes, but since a different training paradigm was used in the second cohort, there is no way to conduct formal comparisons. In the first cohort, learning (acquisition during place learning) was not altered. The second probe trial provided evidence of impaired memory in the high-dose feed/spike group, in that they showed less preference for the correct quadrant compared to controls. Working memory training showed no evidence of cognitive differences. In the second cohort, the high-dose feed group showed slower latencies during acquisition (second week of training), but there were no differences on the probe trials, indicating that they had learned and remembered the platform location. The effects were mostly a function of dietary exposure (high-dose feed group), although there were a few interactions with the spike.
The first cohort was tested with one trial per day, a paradigm that may be more difficult and therefore more sensitive to disruption by chemical treatment. This was not the case in this study, but the general effects were somewhat differentmemory but no learning differences in cohort 1, learning but no memory differences in cohort 2. The magnitude of these cognitive differences was not as great as reported elsewhere. In the Morris water maze, repeated exposures of varying length to CPF or other OP pesticides has been reported to alter both acquisition and memory (e.g., Llorens et al., 1993; Prendergast et al., 1997
; Terry et al., 2003
). Likewise, other cognitive tasks are altered as well (e.g., Bushnell et al., 1991
; Cohn and MacPhail, 1997
; McDonald et al., 1988
). In another project from the present study, Samsam et al. (submitted) reported that this exposure paradigm altered acquisition of an autoshaped operant response. After exposure (when ChE activity had returned to normal) response accuracy was reduced in the high-dose-feed/spike group.
Alterations in the search strategy used by the CPF-treated rats were the most reproducible finding in this study. A detailed analysis of swimming patterns revealed a consistently altered spatial distribution in the high-dose feed group, which consisted of either thigmotaxis (hugging closely to the side of the tank) or higher percentages of time in the outer zone of the tank. This was sometimes accompanied by a decrease of time in the middle zone as well, which is where the platform is located. Since the latency or quadrant preference was often not altered, this implies that the rats were swimming along the outside of the tank until the platform area was reached, at which time they swam directly to the platform.
Such tendencies to not venture into the middle of an open field is interpreted as anxiety, which is often measured as thigmotaxis in rodents (Simon et al., 1994; Treit and Fundytus, 1988
). Sanchez-Amate and coworkers (2001)
reported an anxiolytic effect of CPF using the elevated plus-maze, although much higher, acute doses with the subcutaneous route were used. In another study (Sanchez-Amate et al., 2002
), CPF substituted for pentylenetetrazol, a GABA antagonist, in a drug discrimination paradigm. The pattern of spatial behavior in an open field was altered (i.e., thigmotaxis) a pyrethroid pesticide (Righi and Palermo-Neto, 2003
). Given the number of human complaints of anxiety (Levin et al., 1976
; Mearns et al., 1994
), these findings are even more interesting. Such finding indicate similarities in the actions of pesticides, and this common action could underlie the thigmotaxic effects of CPF that we observed in this study. On the other hand, studies of rats with dorsomedial caudate-putamen (Devan et al., 1999
) or prefrontal cortical (Goss et al., 2003
) lesions reported a dissociation between thigmotaxis in the water maze compared to a dry-land open field. In mice overexpressing the alpha2C-adrenoceptor, thigmotaxis in the water maze was not released by treatment with the classic antianxiolytic, diazepam (Björklund et al., 1999
). Thus, the relationship between water maze thigmotaxis and anxiety is not clear. A potential follow-up would be to repeat these studies using commonly accepted measures of anxiety.
Based on the overall pattern of behavioral effects evaluated in this study, one could predict that humans similarly exposed would exhibit mild cognitive dysfunction and subtle neuromotor changes. If exposed to a high dose (poisoning, accidental exposure), those with ongoing exposure would show greater effects. It should be noted, however, that both doses used in this study produced ChE inhibition in blood, and we therefore did not identify a no-effect dose. These levels of intake are about 30-fold higher than the dose used to base determination of the chlorpyrifos chronic reference dose, and many orders of magnitude higher than estimates for chronic dietary exposure in the general population (U.S. EPA, 2000). While occupational exposures may be higher, few epidemiological studies have solid measures of exposure other than blood ChE inhibition and/or urinary TCP. In a review of human studies, Colosio et al. (2003)
included increased reaction time, fatigue, and non-specific emotional and intellectual changes. Other studies have reported changes in sustained attention and information processing, general malaise, and poor performance on motor and vestibular tasks, to list a few (Dick et al., 2001
; Kamel and Hoppin, 2004
; Steenland et al., 2000
; Stephens et al., 1996
). The data we present here may be reconciled with at least some of these human reports, but no clear pattern or syndrome of effects has emerged from either the present study or the human literature. Thus, the available data are insufficient to assess fully the predictability of chronic animal studies to outcomes in the human population.
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NOTES |
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Portions of this research were presented at the International Neurotoxicology Association meeting, June 2001, and at the 41st annual meeting of the Society of Toxicology, March 2002, Nashville, TN.
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ACKNOWLEDGMENTS |
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