Abstract
Previously, we created an 8-h limited-access dual bottle drinking paradigm to deliver methylphenidate (MP) to rats at two dosages that result in a pharmacokinetic profile similar to patients treated for attention deficit hyperactivity disorder. Chronic treatment resulted in altered behavior, with some effects persisting beyond treatment. In the current study, adolescent male Sprague–Dawley rats were split into three groups at four weeks of age: control (water), low-dose MP (LD), and high-dose MP (HD). Briefly, 4 mg/kg (low dose; LD) or 30 mg/kg (high dose; HD) MP was consumed during the first hour, and 10 mg/kg (LD) or 60 mg/kg (HD) MP during hours two through eight. Following three months of treatment, half of the rats in each group (n = 8–9/group) were euthanized, and remaining rats went through a 1-month abstinence period, then euthanized. In vitro receptor autoradiography was performed to quantify binding levels of dopamine transporter (DAT), dopamine type 1 (D1R)-like receptors, and dopamine type 2 (D2R)-like receptors using [3H] WIN35,428, [3H] SCH23390, and [3H] Spiperone, respectively. Immediately following treatment, HD MP-treated rats had increased DAT and D1R-like binding in several subregions of the basal ganglia, particularly more caudal portions of the caudate putamen, which correlated with some previously reported behavioral changes. There were no differences between treatment groups in any measure following abstinence. These findings suggest that chronic treatment with a clinically relevant high dose of MP results in reversible changes in dopamine neurochemistry, which may underlie some effects on behavior.
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Introduction
The psychostimulant methylphenidate (MP) is one of the most frequently prescribed medications used to treat Attention Deficit Hyperactivity Disorder (ADHD) (Greenhill et al. 2002). The prevalence rate of ADHD has jumped to 11% of school-aged children, up to 41% over the last decade (Visser et al. 2014). Two thirds of children diagnosed with ADHD are treated with psychostimulants such as MP, which are also used illegally as cognitive enhancers among adolescents and adults and abused recreationally (McCabe et al. 2006; Wilens et al. 2008). In the United States, studies have found that up to 30% of college students surveyed report using MP illicitly (Bogle and Smith 2009; McCabe et al. 2005; Teter et al. 2006). These striking statistics regarding the increasing use and abuse of MP present concern, as the brain is particularly susceptible to the effects of drugs during adolescence (Dahl 2004; Spear 2000) due to the sprouting and pruning of synapses and changes in neurotransmitter concentrations and receptor levels in several regions such as the prefrontal cortex, hippocampus, and limbic system (Giedd et al. 2008; Rice and Barone 2000; Spear 2000).
MP’s mechanism of action is partly mediated by its ability to block dopamine transporters (DAT) and increase levels of extracellular dopamine (DA) in the prefrontal cortex (PFC) and striatum, while also increasing norepinephrine in the PFC and hippocampus (Bymaster et al. 2002; Kuczenski and Segal 2002; Volkow et al. 2001, 2002). Therefore, determining the effects of long-term MP treatment on catecholamine systems is of great interest. Preclinical studies investigating the effects of chronic exposure to MP during development have shown changes in the catecholamine systems in the medial PFC (mPFC), hippocampus, striatum, and hypothalamus (Gray et al. 2007). Specifically, tyrosine hydroxylase immunoreactivity was increased in the mPFC and decreased in the medial striatum following exposure, while norepinephrine transporter density was decreased in the mPFC and hippocampal dentate gyrus (Gray et al. 2007). In addition, there was an increase in Nissl-stained cells in the mPFC and neuropeptide Y-immunoreactivity in the hypothalamus (Gray et al. 2007). Moreover, chronic MP treatment in rats has resulted in changes in DAT and dopamine receptor levels (Gray et al. 2007; Izenwasser et al. 1999; Randall and Hannigan 1999; Thanos et al. 2007).
Most previous studies on the effects of MP treatment on neurochemistry, however, are confounded by the fact that they have utilized an MP dosing regimen that does not mimic the clinical scenario. In ADHD treatment, oral doses of 0.25–1 mg/kg MP are prescribed, resulting in plasma concentrations of 8–40 ng/mL. Most previous studies on MP have injected the drug either subcutaneously or intraperitoneally, which differs significantly from oral administration, specifically with respect to time to peak serum concentration, half-life, and rate of elimination (Kuczenski and Segal 2005), as well as absolute magnitude and time course of increases in extracellular DA and locomotor responses (Gerasimov et al. 2000; Kuczenski and Segal 2001). In these studies, doses were used that have been shown to produce plasma concentrations at the very highest end of the spectrum for clinical relevance (Kuczenski and Segal 2005). Nearly constant dosing would be necessary to maintain clinically relevant plasma concentrations due to the faster metabolism and shorter half-life of MP in rats compared to humans, whereas previous studies in rodents have generally dosed animals only once or twice per day (Kuczenski and Segal 2005). Moreover, most studies included treatment lengths lasting only a few days to a few weeks. With an estimated 50–60% of ADHD cases with symptoms persisting into adulthood (Mick et al. 2004), it is necessary to determine more long-term effects of MP, which may persist long after the cessation of treatment.
Previously, we developed a dual-bottle 8-h limited-access drinking paradigm that allowed MP to be consumed voluntarily in the rats’ drinking water (Thanos et al. 2015). Two dosing regimens were created: 4 mg/kg MP (low dose; LD) or 30 mg/kg MP (high dose; HD) during the first hour, and 10 mg/kg (LD) or 60 mg/kg (HD) MP from hours 2 through 8. In rats, this dosing produces plasma MP concentrations stably within the clinical pharmacokinetic range (peaking at ~8 ng/mL for the LD and ~30 ng/mL for the HD) (Thanos et al. 2015). A control group was provided with water only for the entire 8-h drinking period. We previously examined the developmental and behavioral effects of these treatments from adolescence to young adulthood in male Sprague–Dawley rats, both during the 3-month treatment and following a 1-month abstinence period, to investigate long-lasting consequences of MP use. While LD MP treatment had few effects, HD MP treatment resulted in changes in food intake, body weight, open field activity, and circadian locomotor activity, with some effects persisting through the abstinence period. It remains to be determined, however, the effects of chronic MP exposure on dopamine neurochemistry, which may underlie some of these long-lasting changes in behavior. Assessing MP-induced changes to the dopaminergic system is of great interest, as MP acts on this system, and dopamine is also involved in behaviors previously known to be affected (e.g., feeding and locomotor behavior). Effects of MP on the dopaminergic system also have implications on the drug’s abuse potential and ability to alter susceptibility to other drugs later in life. Therefore, the current study aims to determine the effects of chronic oral MP treatment, with and without abstinence, on DAT binding, as well as D1R-like and D2R-like receptor levels, in relevant regions of the brain.
Materials and methods
Animals
Four-week-old male Sprague–Dawley rats (Taconic, Hudson, New York USA) were individually housed in a controlled room (22 ± 2 °C and 40–60% humidity) with a 12-h reverse light–dark cycle (lights off 0800 h). Rats were split into three groups: control (drinking only water), low-dose MP (LD), or high-dose MP (HD). Rats received respective treatment using a previously established dual-bottle 8-h limited access drinking paradigm, which allowed for an MP pharmacokinetic profile similar to that observed in patients treated with MP (peaking at about 8–10 ng/mL for the LD group and ~25 ng/mL for the HD group) (Thanos et al. 2015). This method also allows for voluntary drinking, reducing stress induced by the gavage method. Rats received 4 mg/kg MP (LD) or 30 mg/kg MP (HD) during the first hour (09:00–10:00), and 10 mg/kg (LD) or 60 mg/kg MP (HD) for the remaining 7 h (10:00–17:00). A lower dose is given in the first bottle, as rats usually consume a larger volume quickly following overnight fluid restriction, bringing plasma concentrations to target range. The second higher dose produces a fairly stable plasma concentration in the target range via intermittent drinking of smaller volumes throughout the rest of the limited access period.
Following a 3-month treatment period, half of the rats in each group (n = 8/group) were euthanized. Remaining rats (n = 9/group for water treated, n = 8/group for LD and HD MP treated) underwent a 1-month abstinence period, during which they were given only water to drink for the entire 8-h limited access drinking period daily, then euthanized. Purina laboratory rat chow was available ad libitum for the entire experiment. All experiments were conducted in conformity with the National Academy of Sciences Guide for Care and Use of Laboratory Animals (National Academy of Sciences NRC, 1996) and approved by the University Institutional Animal Care and Use Committee.
Drugs
Methylphenidate hydrochloride (Sigma-Aldrich, St. Louis, MO) was dissolved in distilled water to produce the 4, 10, 30, and 60 mg/kg solutions. Individual rats’ drinking bottles were made fresh daily based on body weight and the average of their last three days’ fluid intake to achieve desired dosages.
In vitro receptor autoradiography
Tissue preparation
Twenty-four hours following the respective treatment or abstinence period, rats were euthanized under deep isoflurane anesthesia (~3.0%). Brains were harvested, flash frozen, stored at −80 °C until cryosectioned at 14 μm, and mounted on glass microscope slides. Tissue sections were stored at −80 °C until in vitro receptor autoradiography (ARG) was performed.
Dopamine transporter (DAT) binding
Protocol for dopamine transporter (DAT) binding was adapted from previous studies (Coulter et al. 1997; Wilson et al. 1994). Briefly, slides were pre-incubated for 10 min at 4 °C in 30 mM sodium phosphate buffer (pH = 7.4). Slides were incubated for 90 min at 4 °C in 30 mM sodium phosphate buffer solution with 0.32 M sucrose (pH = 7.4) and in the presence of 6.5 nM [3H] WIN 35, 428 (specific activity = 76 Ci/mmol). Non-specific binding was determined in the presence of 60 µM cocaine. Slides were dipped then washed 2 × 1 min in pre-incubation buffer and dipped in dH2O, all at 4 °C.
Dopamine type 1 receptor (D1R)-like binding
Protocol for dopamine type 1-like receptor (D1R) binding was adapted from previous studies (Tarazi et al. 1997, 1998, 1999). Briefly, slides were pre-incubated for 60 min at room temperature in 50 mM Tris–HCl buffer (120 mM NaCl, 5 mM KCl, 2 mM CaCl2, 1 mM MgCl2, pH = 7.4). Slides were incubated for 60 min at room temperature in pre-incubation buffer in the presence of 2.5 nM [3H] SCH 23390 (SA = 85 Ci/mmol) and 40 nM ketanserin. Non-specific binding was determined in the presence of 1 µM flupenthixol. Slides were washed 2 × 5 min at 4 °C in pre-incubation buffer followed by a dip at 4 °C in dH2O.
Dopamine type 2 receptor (D2R)-like binding
Protocol for dopamine type 2-like receptor (D2R) binding was adapted from a previous study (Tarazi et al. 1997). Briefly, slides were pre-incubated for 60 min at room temperature in 50 mM Tris–HCl buffer (120 mM NaCl, 5 mM KCl, 2 mM CaCl2, 1 mM MgCl2, pH = 7.4). Slides were incubated for 60 min at room temperature in pre-incubation buffer in the presence of 0.5 nM [3H] Spiperone (specific activity = 16.2 Ci/mmol) and 40 nM ketanserin. Non-specific binding was determined in the presence of 10 µM sulpiride. Slides were washed 2 × 5 min at 4 °C in pre-incubation buffer followed by a dip at 4 °C in dH2O.
Autoradiography analysis
Slides were dried and apposed to Kodak MR Film (DAT 12 weeks, D1 4 weeks, D2 10 weeks). Film was scanned at 1200 dpi, and images were quantified using Image J software (NIH). Figure 1 shows the regions of interest (ROIs) analyzed, including the dorsolateral (dl PFC) and medial (mPFC) prefrontal cortex, olfactory tubercle (OT), nucleus accumbens [split into pole of the core (Pole AcbC), pole of the shell (Pole AcbS), core (AcbC) and shell (AcbS)], ventral pallidum (VP), rostral and middle caudate putamen [each split into four quadrants: dorsolateral (dl CPu), dorsomedial (dm CPu), ventrolateral (vl CPu), and ventromedial (vm CPu)], and tail of the caudate putamen [split in half into dorsal (d CPu tail) and ventral (v CPu tail) portions]. Binding in each ROI was measured in uCi/g.
Statistical analysis
Three-way repeated measures ANOVAs [between-subject factors: treatment (water, LD 4/10 mg/kg MP, or HD 30/60 mg/kg MP) and abstinence (rats euthanized immediately following treatment or following an abstinence period); within-subject factor: region of interest (ROI)] were used to analyze autoradiography data by ligand separately. ANOVAs were followed by multiple pairwise comparisons (Fisher method). Pearson correlations were run between D1R-like, D2R-like, and DAT binding within ROIs, as well as autoradiography binding measures and food intake, body weight, and dark cycle circadian locomotor activity, for rats euthanized immediately following treatment and abstinence separately. Food intake, body weight, and dark cycle circadian locomotor activity data used for correlations were previously reported (Thanos et al. 2015). Statistical significance was set at α = 0.05 for ANOVA main effects and interactions, and α = 0.01 for ANOVA pairwise comparisons and correlations to control for multiple tests. All statistical tests were run using SigmaStat 3.5 software.
Results
In vitro autoradiography for dopamine transporter binding
A three-way repeated measures ANOVA was performed to determine the effects of MP treatment, with and without abstinence, on dopamine transporter binding in each region of interest (Fig. 2). The main effects of abstinence [F(1,43) = 6.046, p = 0.018] and ROI [F(17,731) = 97.016, p < 0.001] were significant, as were the treatment × ROI [F(34,731) = 1.892, p = 0.002], abstinence × ROI [F(17,731) = 4.523, p < 0.001], and treatment × abstinence × ROI [F(34,731) = 1.726, p = 0.007] interactions. The main effect of treatment [F(2,43) = 1.871, p = 0.166] and the treatment × abstinence interaction [F(2,43) = 1.056, p = 0.357] were not significant. Pairwise comparison testing of the treatment × abstinence × ROI interaction found that HD MP treatment increased DAT binding in several ROIs in rats euthanized immediately following treatment. HD MP rats had greater binding in the mid dl CPu, mid dm CPu, mid vl CPu, mid vm CPu, and v CPu tail compared to water-treated rats, and in the mid dl CPu, mid dm CPu, mid vl CPu, and mid vm CPu compared to LD MP-treated rats (p ≤ 0.01 for all). LD MP rats did not differ from water-treated rats in any ROI measured, and there were no differences between treatment groups in rats euthanized following an abstinence period.
In vitro autoradiography for dopamine type 1 receptor (D1R)-like binding
A three-way repeated measures ANOVA was performed to determine the effects of MP treatment, with and without abstinence, on dopamine type 1 receptor (D1R)-like binding in each region of interest (Fig. 3). The main effect of ROI [F(17,731) = 993.03, p < 0.001] and the treatment × ROI [F(34,731) = 1.92, p = 0.001] and treatment × abstinence × ROI [F(34,731) = 1.68, p = 0.010] interactions were significant. The main effects of treatment [F(2,43) = 0.86, p = 0.432] and abstinence [F(1,43) = 2.06, p = 0.158], and the treatment × abstinence [F(2,43) = 2.30, p = 0.112] and abstinence × ROI [F(17,731) = 0.89, p = 0.586] interactions were not significant. Pairwise comparison testing of the treatment × abstinence × ROI interaction found that HD MP treatment increased D1R binding in several ROIs in rats euthanized immediately following treatment. HD MP rats had greater binding in the OT, mid dl CPu, mid dm CPu, mid vm CPu, and d CPu tail compared to water-treated rats, and in the OT, vm CPu, and d CPu tail compared to LD MP-treated rats (p ≤ 0.01 for all). LD MP rats did not differ from water-treated rats in any ROI measured, and there were no differences between treatment groups in rats euthanized following an abstinence period.
In vitro autoradiography for dopamine type 2 receptor (D2R)-like binding
A three-way repeated measures ANOVA was performed to determine the effects of MP treatment, with and without abstinence, on dopamine type 2 receptor (D2R)-like binding in each region of interest (Fig. 4). Only the main effect of ROI [F(17,731) = 182.43, p < 0.001] and the abstinence × ROI interaction [F(17,731) = 16.151, p < 0.001] were significant. There was no significant main effect of treatment [F(2,43) = 0.956, p = 0.392], nor was there any significant interaction of treatment with any of the other factors: treatment × abstinence [F(2,43) = 0.061, p = 0.941], treatment × ROI [F(34,731) = 0.748, p = 0.851], treatment × abstinence × ROI [F(34,731) = 0.461, p = 0.997]. The main effect of abstinence was also not significant [F(1,43) = 0.087, p = 0.770].
Correlations
Correlations in rats euthanized following treatment
Correlations were run between D1R-like, D2R-like, and DAT binding, as well as autoradiography binding measures and behavior, for rats euthanized immediately following treatment (Table 1). Positive correlations between DAT and D1R-like binding levels approached significance (p ≤ 0.07) in the mid dm CPu, mid vl CPu, mid vm CPu, and OT.
Dark cycle circadian locomotor activity was positively correlated with D1R-like binding in the middle vm CPu, and this association approached significance in the OT, mid dl CPu, mid dm CPu, mid vl CPu, and d CPu tail. Dark cycle circadian activity was also positively correlated with DAT binding in all quadrants of the middle CPu, as well as the v CPu tail, and this correlation approached significance in the d CPu tail.
Body weight was negatively correlated with D1R-like binding in the mid dm CPu and d CPu tail, and this association approached significance in the mid dl CPu and mid vm CPu. The negative association between body weight and DAT binding in the middle dm CPu approached significance.
Correlations were also run between behavioral measures. There was no correlation between food intake and body weight; however, there was a significant negative correlation between body weight and dark cycle circadian activity. There was also a positive correlation between dark cycle circadian activity and food intake that approached significance.
Correlations in rats euthanized following abstinence
Correlations found to be significant in rats euthanized immediately following treatment were run between D1R-like, D2R-like, and DAT binding, as well as autoradiography binding measures and behavior, for rats euthanized following abstinence. Significant correlations between binding measures and behavior observed in rats euthanized immediately following treatment were not significant in rats euthanized immediately following abstinence. The positive correlation between dark cycle circadian activity and food intake approached significance, r(22) = 0.362, p = 0.075. Despite not being significant in rats euthanized immediately following treatment, there was a positive correlation between food intake and body weight that approached significance, r(22) = 0.486, p = 0.014, in rats euthanized following abstinence.
Discussion
Chronic treatment with a clinically relevant high dose (HD) of methylphenidate (MP) resulted in increased DAT binding compared to water-treated controls in the middle dorsolateral (89%), dorsomedial (106%), ventrolateral (78%), and ventromedial (54%) caudate putamen (CPu), as well as the ventral CPu tail (69%). HD MP treatment also increased D1R-like binding in the olfactory tubercle (14%) and middle dorsolateral (15%), dorsomedial (21%), and ventromedial (28%) CPu, as well as the dorsal CPu tail (24%). Following an abstinence period, DAT and D1R-like binding levels in rats previously treated with either dose of MP were not significantly different from water-treated controls. Neither dose of MP treatment affected D2R-like binding in rats euthanized immediately following treatment or abstinence. These findings suggest that chronic oral treatment with clinically relevant high doses of MP results in reversible increases in DAT and D1R in several subregions of the basal ganglia, with more caudal portions of the caudate putamen seemingly being particularly vulnerable to these effects. Increased binding in many of these regions following treatment was associated with previously reported developmental and behavioral effects of this drug treatment (attenuated body weight and increased dark cycle circadian locomotor activity) (Thanos et al. 2015), and these correlations were no longer significant following abstinence.
These findings on dopamine transporter levels are in agreement with a recent clinical study, which found that long term (12 months) of treatment with MP significantly increases DAT availability in the caudate and putamen, but not in the ventral striatum (Wang et al. 2013). The present findings can also be compared to those from studies on the neurochemical effects of other psychostimulants like cocaine, which has the same mechanism of action as MP (blocking of DAT) (Gatley et al. 1999; Volkow et al. 1997, 1998). In humans and non-human primates, chronic psychostimulant administration is associated with increased striatal levels of DAT (Letchworth et al. 2001; Little et al. 1998; Mash et al. 2002), while prolonged abstinence from cocaine normalizes previously elevated DAT binding levels in the striatum (Beveridge et al. 2009). Increased DAT levels observed following HD MP treatment may represent an adaptive response to maintain homeostatic levels of synaptic DA. Previous studies suggest that MP administration increases extracellular DA, as measured by in vivo microdialysis in rats (Gerasimov et al. 2000), and as a reduction in Bmax/Kd (measure of D2 receptor availability) in humans (Volkow et al. 2001). Therefore, higher DAT levels would be necessary to clear excess DA from the synapse (Zahniser and Doolen 2001). Oral MP at therapeutic doses of 0.25–1.0 mg/kg (resulting in plasma concentration of 8–40 ng/mL) dose dependently blocks 50–75% of DAT (Volkow et al. 1998), while an oral dose of ~0.8 mg/kg MP (resulting in plasma concentrations of ~30 ng/mL of the pharmacologically active D-enantiomer) significantly increases extracellular DA in the striatum (Volkow et al. 2001). It has been shown that repeated treatment with MP and other psychostimulants results in increased midbrain DA neuron firing, while abstinence from these drugs results in reduced DA neuron activity (Brandon et al. 2003; Imperato et al. 1992, 1996; Parsons et al. 1991; Robertson et al. 1991; Segal and Kuczenski 1992; Zhang et al. 2001). These effects could contribute to the changes in DAT density following treatment and abstinence observed in the current study. LD MP treatment had no effect on any binding measure in any region assessed. In mice, acute administration of an MP dose producing similar plasma levels (6–10 ng/mL) to our LD does not increase striatal DA levels. Assessment of these dosing regimens’ ability to elicit regional increases in extracellular DA is needed to further explore this possible relationship.
This study also found that while neither dose of MP influenced D2R-like binding, HD MP increased D1R-like binding in the OT and caudal portions of the caudate putamen, an effect that was no longer apparent in rats undergoing an abstinence period following treatment. While one methodologically different study found no effect of MP on D1R levels (Randall and Hannigan 1999), another found that the highest dose tested (8 mg/kg subcutaneous) increased D1R receptors (Gill et al. 2012). Similar to our findings, chronic cocaine self-administration in mice increases D1R in caudal portions of the CPu, with no reported effect in the rostral CPu or nucleus accumbens (Schlussman et al. 2003). In non-human primates, chronic cocaine administration is also associated with increased striatal levels of D1R (Nader et al. 2002), while prolonged abstinence from cocaine normalizes previously elevated D1R binding levels in the striatum (Beveridge et al. 2009). The lack of MP-induced changes in D2R levels is in agreement with a prior study of chronic MP treatment in rats (Randall and Hannigan 1999) and cocaine administration in non-human primates (Beveridge et al. 2009). Our lab previously found that 2 months of oral MP treatment results in decreases in striatal D2R availability, while 8 months of treatment enhances striatal D2R availability (Thanos et al. 2007). This study, however, differed from the current study in a number of ways, including MP dose, length of treatment, and unlike this study measured in vivo D2R availability (using 11C raclopride microPET), which measures availability of D2R in the presence of endogenous dopamine (DA).
D1R-like receptors are coupled to stimulatory G proteins and D1R agonists promote locomotor activity, while D2R-like receptors are coupled to inhibitory G proteins and D2R agonists attenuate locomotor activity (Eilam et al. 1991; Halberda et al. 1997). Increased D1R-like binding with no change in D2R-like binding in several brain regions in HD MP rats would consequently alter the ratio of D1R:D2R signaling towards the D1R. It has been suggested that repeated administration of other psychostimulants alters the D1R:D2R ratio, favoring D1R, and that this effect mediates behavioral sensitization to the drug (Thompson et al. 2010). Previously, we found that the same chronic oral HD MP treatment resulted in marked hyperactivity that was greater during later weeks of treatment (Thanos et al. 2015); therefore, it is plausible that this apparent locomotor sensitization to the drug is mediated by an altered ratio of D1R:D2R signaling caused by an increase in D1R receptors. Sensitization is believed to underlie some aspects of addictive behavior (Robinson and Berridge 1993; Steketee and Kalivas 2011), creating concerns regarding the drug’s possible addictive properties and potential as a “gateway drug” at these doses, especially since epidemiological studies have shown that ADHD patients are at a significantly higher risk of substance abuse disorders (Elkins et al. 2007; Grant and Dawson 1997). A major concern about treating children and adolescents with psychostimulants is that prolonged treatment could alter reward-related neurochemistry, predisposing individuals to substance abuse later in life. While animal studies have shown mixed results on the effects of MP on reactivity and vulnerability to other drugs (Brandon et al. 2001; Carlezon Jr et al. 2003; Thanos et al. 2007), clinical studies have shown that psychostimulant treatment either has no effect (Biederman et al. 2008; Mannuzza et al. 2008) or reduces the risk of later substance abuse (Wilens et al. 2003), possibly by attenuating risk-taking and disinhibited behavior. Further investigation is necessary to determine the abuse liability of MP and its ability to alter predisposition to other drugs later in life.
Previously, we found that this chronic HD MP treatment resulted in significantly enhanced dark cycle circadian locomotor activity and an attenuation of body weight that does not appear to be directly linked to changes in food intake (Thanos et al. 2015). During abstinence, hyperactivity was markedly attenuated, and body weight increased but did not return to control levels. LD MP treatment did not produce the hyperactivity observed in HD rats (Thanos et al. 2015). Given that dopaminergic signaling in the basal ganglia plays a role in motor behavior (DeLong and Georgopoulos 2011; Takakusaki et al. 2004), and that behavioral changes seem to parallel the pattern of changes to the dopaminergic system, the link between MP-induced changes in DA neurochemistry and behavior was assessed. Several correlations were found to be significant in rats euthanized immediately following MP treatment. Dark cycle circadian locomotor activity was positively correlated with D1R-like binding in the OT, middle CPu, and dorsal tail of the CPu. Dark cycle circadian activity was also positively correlated with DAT binding in the middle CPu and caudal tail of the CPu. Body weight was negatively correlated with D1R-like binding in the middle CPu, as well as the dorsal tail of the CPu. Body weight was negatively correlated with dark cycle circadian locomotor activity, but surprisingly was not correlated with food intake. Food intake was, however, positively correlated with dark cycle circadian activity. Taken together, these results suggest that MP-induced changes in DA signaling may drive increases in locomotor behavior that appear to reduce body weight while enhancing food intake to maintain energy balance. Following abstinence, none of the aforementioned correlations were significant; however, there was a positive correlation between food intake and body weight as would have been expected.
It should be noted that aspects of the study, in addition to the MP treatment itself, could have influenced the results of the binding assays. Rats in this study were single housed out of necessity to accurately monitor and control treatment dosages. Single housing is acknowledged as a “deprived” rather than “standard” environment, which can impact the dopaminergic system (Fone and Porkess 2008; Isovich et al. 2001; King et al. 2009; Zakharova et al. 2009). Animals reared in socially isolated environments have also been shown to be more sensitive to psychostimulants via dopamine-dependent mechanisms (Howes et al. 2000; Jones et al. 1990; Zakharova et al. 2009). Additionally, animals in this study went through behavioral testing, completed at least three days prior to euthanasia, which also could have influenced dopamine neurochemistry. Behavior and binding assays, however, were performed in the same rats to assess the possible mechanistic relationship between these measures. Although all groups were single housed to control for housing effects and went through the same behavioral testing, it cannot be ruled out that there was an interaction of the drug with either of these factors to create the observed effects. Future studies should address these concerns.
Conclusion
Previously, we created an 8-h limited-access dual bottle drinking paradigm to deliver methylphenidate (MP) in a manner that mimics the pharmacokinetic profile of patients treated with this drug for ADHD (Thanos et al. 2015). Three months of treatment with the high-dose regimen (30 mg/kg MP for the first hour; 60 mg/kg for the remaining 7 h), which results in plasma concentrations at the high end of the clinical spectrum (~30 ng/mL), was found to increase binding levels of (DAT) and D1R in several subregions of the basal ganglia, particularly the middle and caudal portions of the caudate putamen. These increases were no longer apparent following a 1-month abstinence period, suggesting the reversibility of these effects. Interestingly, DAT and D1R binding in several of these regions were correlated with previously reported effects on locomotor activity and body weight in rats euthanized immediately following treatment, suggesting that MP-induced changes in dopamine neurochemistry may contribute to some of these effects.
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This work was supported by the New York Research Foundation [Q0942016] and the National Institute of Health [R01HD70888].
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Robison, L.S., Ananth, M., Hadjiargyrou, M. et al. Chronic oral methylphenidate treatment reversibly increases striatal dopamine transporter and dopamine type 1 receptor binding in rats. J Neural Transm 124, 655–667 (2017). https://doi.org/10.1007/s00702-017-1680-4
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DOI: https://doi.org/10.1007/s00702-017-1680-4