Abstract
The glutamate N-methyl-d-aspartate (NMDA) receptor antagonist ketamine (KET) produces rapid and sustained antidepressant effects in patients. Tiletamine (TIL; 2-ethylamino-2-thiophen-2-yl-cyclohexan-1-one) is another uncompetitive NMDA receptor antagonist, used in a medical (veterinary) setting as an anesthetic tranquilizer. Here, we compared the behavioral actions of KET and TIL in a variety of tests, focusing on antidepressant-like and dissociative-like effects in mice and rats. The minimum effective doses of KET and TIL were 10 mg/kg to reduce mouse forced swim test immobility and 15 mg/kg to reduce marble-burying behavior. However, at similar doses, both compounds diminished locomotor activity and disturbed learning processes in the mouse passive avoidance test and the rat novel object recognition test. KET and TIL also reduced social behavior and accompanying 50-kHz “happy” ultrasonic vocalizations (USVs) in rats. TIL (5–15 mg/kg) displayed additional anxiolytic-like effects in the four-plate test. Neither KET nor TIL affected pain response in the hot plate test. Examination of the “side effects” revealed that only at the highest doses investigated did both compounds produce motor deficits in the rotarod test in mice. While KET produced behavioral effects at doses comparable between species, in the rats, TIL was ~10 times more potent than in the mice. In summary, antidepressant-like properties of both KET and TIL are similar, as are their adverse effect liabilities. We suggest that TIL could be an alternative to KET as an antidepressant with an additional anxiolytic-like profile.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
The rapid and sustained antidepressant effects of ketamine (KET) (Zarate et al. 2006a; Berman et al. 2000) belong to the most intriguing discoveries and most often discussed topics in the current pharmacotherapy of major depression disorder (MDD). However, the mechanism of this unique action remains controversial and unexplained (Schatzberg 2014). KET acts primarily as a use-dependent antagonist at glutamate NMDA receptors (NMDARs; for a broader panel of other CNS targets, see Salat et al. (2015c)); thus, among several mechanisms related to its antidepressant effects, the inhibition of NMDARs is the most important. The observation that NMDAR antagonists display antidepressant-like properties originates from the mid-90s and was first proposed by Skolnick and coworkers at NIH (Skolnick et al. 1996; Trullas and Skolnick 1990). However, other than KET, clinically used uncompetitive NMDAR antagonists such as memantine failed in clinical trials as antidepressants (Zarate et al. 2006b). Another hypothesis involves KET metabolites (Domino 2010), acting perhaps on other targets, likely involving AMPA receptors (Zanos et al. 2016). This area is also controversial, because only norketamine (demonstrating decent affinity at NMDARs, i.e., producing a 56% inhibition of PCP binding sites at 10 μM) reduced immobility in the mouse forced swim test (FST), while dehydronorketamine exhibited no antidepressant-like actions in mice and no substantial activity (12%) at NMDARs (Salat et al. 2015c).
KET (Krystal et al. 1994), like other uncompetitive NMDAR antagonists (Morris and Wallach 2014), produces profound PCP-like (Luby 1959) psychotomimetic effects in humans including dissociative states, alterations in perception, and schizophrenia-like positive and negative symptoms. From this perspective, the failure of memantine to produce clinical antidepressant effects (Zarate et al. 2006b) was likely due either to insufficient dosing and/or to its micromolar affinity at NMDARs which is lower than that of KET (Kornhuber et al. 1991), and thus, the psychotomimetic effects are also lower than those of KET. This hypothesis is at least partly supported both by clinical findings showing that another NR2B subunit-selective NMDAR antagonist, CP-101,606 (traxoprodil), also produced dissociative effects on top of antidepressant actions in patients with MDD (Preskorn et al. 2008) and by studies on KET which revealed that the degree of dissociative symptoms experienced during KET infusions robustly correlated with the degree of reported depression rating scale improvement (Luckenbaugh et al. 2014). On the other hand, GLYX-13 (rapastinel), a novel NMDAR glycine-site functional partial agonist, produced an antidepressant effect without psychotomimetic side effects typical for NMDAR antagonists (Burgdorf et al. 2013; Moskal et al. 2014), which suggests that dissociative effects should not be regarded as the only mechanism underlying antidepressant activity observed in clinical settings.
While clinical trials are now being conducted with several other than KET ligands of NMDARs (AXS-05, AVP-786, Esketamine, CERC-301, GLYX-13; NRX-1074, AV-101; (Murrough 2016)), in the present study, we focused on tiletamine (TIL; 2-ethylamino-2-thiophen-2-yl-cyclohexan-1-one), which is structurally and functionally similar to KET. TIL is a use-dependent NMDAR antagonist (Rao et al. 1991; ffRench-Mullen et al. 1987) and an anesthetic tranquilizer used in veterinary medicine as a component of the product named Telazol® or Zoletil® (tiletamine/zolazepam).
TIL was developed by Parke-Davis in the 1960s as an alternative to KET and phencyclidine (PCP) (Chen et al. 1969). While it is currently contraindicated in patients, anecdotal reports indicate its KET-like or PCP-like properties. For instance, at Erowid Experience Vaults (https://www.erowid.org/pharms/tiletamine/), anonymous psychonauts (individuals who use mind-altered states to explore perceptual and spiritual phenomena) have reported profound dissociative, psychotomimetic, and amnestic properties of Telazol, much stronger than those of KET. Telazol has been reported to produce less cardiovascular depression (c.f., Quail et al. 2001) than KET, which also shows urinary tract/bladder toxicity (c.f. Morris and Wallach 2014). The unique pharmacology of TIL regarding dopaminergic system was studied by Rao et al. (1991), who reported that in contrast to MK-801, KET, and PCP, TIL did not increase pyriform cortex DOPAC levels (i.e., did not increase DA metabolism and/or release), suggesting some unique action not shared by other NMDAR antagonists.
Other CNS-related properties of TIL are much less explored as compared to those of KET, and therefore knowledge of its psychopharmacological profile is limited. In particular, little is known about its potential antidepressant activity. Hence, the main aim of this study was to compare the pharmacological properties of TIL to those of KET in rodent models. Because of its clinical (veterinary) use and established safety, its psychoactive properties resembling KET’s dissociative states, and somewhat different from KET pharmacology, we compared the behavioral properties of TIL to those of KET in rodent tests of depression, anxiety, cognition, and negative-like symptoms of psychoses. To interpret the results from in vivo tests properly, we also investigated the influence of TIL and KET on animals’ locomotor activity, pain threshold, and potential motor deficits.
Materials and Methods
Animals
The study included adult male albino Swiss (CD-1) mice weighing 18–22 g (Animal Breeding Farm of the Jagiellonian University Faculty of Pharmacy, Poland) and male Sprague-Dawley rats (Charles River, Germany), weighing 200–250 g (novel object recognition test (NORT)) or 125–150 g (social interaction test) on arrival.
Mice were kept in groups of 10 in standard plastic cages and housed under controlled conditions (room temperature of 22 ± 2 °C, light/dark (12:12) cycle, lights on at 8.00 a.m., humidity 50–60%, and free access to food and water). Rats were housed in a temperature- (21 ± 1 °C) and humidity-controlled (40–50%) colony room under a 12:12-h light/dark cycle (lights on at 06:00 a.m.).
All experiments, except for sucrose preference tests, were performed between 9 a.m. and 3 p.m. All procedures were approved by the respective local ethics committees, and the treatment of animals was in full accordance with ethical standards laid down in respective Polish and EU regulations (Directive No. 86/609/EEC).
Chemicals
TIL hydrochloride (MedChemExpress, NJ, USA) was prepared in 0.9% saline solution. KET (aqueous solution (115.34 mg/ml), Vetoquinol Biowet, Gorzów Wielkopolski, Poland) was diluted in distilled water to the appropriate concentrations. Drugs were administered intraperitoneally at a volume of 10 ml/kg (mice) and 1 ml/kg (rats), 30 min before the behavioral tests. The doses of KET used in the present research were chosen based on our previous studies (Potasiewicz et al. 2017; Salat et al. 2015c) and available literature data (Eskelund et al. 2017; Koike et al. 2011; Zhu et al. 2017). Since there is a limited amount of data regarding effective doses of TIL in rodents (Gargiulo et al. 2012; Su et al. 2017), we conducted preliminary dose-response studies (data not shown) to establish the starting dose of TIL (5 mg/kg in mice and 0.5 mg/kg in rats).
Behavioral Procedures
Antidepressant-Like: Mouse Forced Swim Test
This experiment was carried out according to the method originally described by Porsolt et al. (1977) with some minor modifications (Salat et al. 2015c). Mice were dropped individually into glass cylinders (height = 25 cm, diameter = 10 cm) filled with water to a height of 10 cm and maintained at 23–25 °C. The animals were left in the cylinder for 6 min. The total duration of immobility was recorded during the final 4 min of the whole 6-min testing period. Mice were judged to be immobile when they remained floating passively in the water, making only small movements to keep their heads above the water surface.
Antidepressant-Like (Anhedonia): Mouse Sucrose Preference Test
Prior to the experiment, mice were placed into separate cages. Two pre-weighed bottles, one containing tap water and the other containing 1% sucrose solution, were placed on each cage. The bottle order (left-right placement of water vs. sucrose bottles) was counterbalanced among mice in each group. In this test, the mice were given a 48-h free choice between the two bottles. At the beginning and the end of the test, the bottles were weighed and consumption was calculated. The test was begun with the onset of the dark (active) phase of the animals’ cycle. The position of the bottles in the cage was switched every 12 h. Before the test, no food or water deprivation was applied (Strekalova et al. 2004). The preference for sucrose was calculated as a percentage of consumed sucrose solution in terms of the total amount of liquid drunk.
Anxiety: Mouse Four-Plate Test
The four-plate apparatus (Bioseb, France) consists of a cage (25 cm × 18 cm × 16 cm) that is floored with four rectangular metal plates (11 cm × 8 cm). The plates are separated from one another by a gap of 4 mm, and they are connected to an electroshock generator. The test was performed according to Bourin et al. (2005). After the habituation period (15 s), each mouse was subjected to an electric shock (0.8 mA, 0.5 s) when crossing from one plate to another (two limbs on one plate and two on another). The number of punished crossings was counted during 60 s.
Anxiety (Obsessive-Compulsive Behavior), Depression, Irritability and Impulsivity: Mouse Marble-Burying Test
The test was performed according to a method described by Broekkamp et al. (1986), with some minor modifications. Briefly, the mice were placed individually into plastic cages identical to their home cages. The cages contained a 5-cm layer of sawdust and 20 black glass marbles (1.5 cm diameter), which were gently placed in the cage, equidistant in a 4 × 5 arrangement. After a 30-min testing period, the mice were removed from the cages and the number of marbles at least 2/3 buried was counted.
Cognition: Mouse Passive Avoidance Task
The test was conducted according to Salat et al. (2015b) using a passive avoidance apparatus (Panlab Harvard Apparatus, Spain) consisting of a large white-painted illuminated compartment (26 × 26 × 34 cm) and a small black-painted dark compartment (13 × 7.5 × 7.5 cm) separated from each other by a guillotine gate. Mice underwent two separate trials, an acquisition trial (conditioning phase) and a retention trial (testing phase), conducted 24 h after the acquisition trial. For the acquisition trial, each mouse was initially placed for 30 s in the light compartment (exploration period; guillotine gate is closed). At the end of the exploration period, the guillotine door (5 × 5 cm) was opened and the time elapsed before entering the black chamber was recorded. As soon as the mouse entered the dark compartment, the door was automatically closed and an electrical shock (current intensity = 0.2 mA, duration = 2 s) was delivered through the grid floor. For the retention trial, the mice were placed in the illuminated white compartment again, and the latency time between door opening and entry into the dark compartment was recorded for each mouse up to 180 s (cutoff latency).
Cognition: Rat Novel Object Recognition Test
The protocol described earlier (Nikiforuk et al. 2013a) was adapted from the original work of Ennaceur and Delacour (1988). At least 1 h before the start of the experiment, rats were transferred to the experimental room for acclimation. Animals were tested in a dimly lit (25 lx) open field apparatus made of a dull gray plastic (66 × 56 × 30 cm). After each measurement, the floor was cleaned and dried. The procedure consisted of a 5–min habituation to the arena without any objects, 24 h before the test. The testing comprised two trials, separated by an inter-trial interval (ITI) of 1 h. During the first (familiarization, T1) test period, two identical objects (A1 and A2) were presented in opposite corners of the arena, approximately 10 cm from the walls. Following T1, the objects were cleaned with water containing a dishwashing agent and dried. In the second trial (recognition, T2), one of the objects was replaced by a novel one (A = familiar and B = novel). Both trials lasted for 3 min. After T1, animals were returned to their home cages. The objects used were a 250-ml glass beaker (diameter of 8 cm, height of 14 cm) and a 250-ml plastic bottle (6 × 6 × 13 cm). The location of the novel object in T2 was randomly assigned for each rat. Exploration of an object was defined as rats looking, licking, sniffing, or touching the object but not leaning against or standing or sitting on the object. Exploration time of the objects was measured using the Any-maze® tracking system (Stoelting Co., IL, USA). Based on the exploration time (E) of two objects, a discrimination index was calculated in accordance with formula DI = (EB − EA) / (EA + EB), where EA is defined as the time spent exploring the familiar object and EB is the time spent exploring the novel object, respectively.
Negative Symptoms of Schizophrenia-Like Measure: Rat Social Behavior
The experiments were conducted in an open field arena (length × width × height = 57 × 67 × 30 cm) made of black Plexiglas. The arena was dimly illuminated with an indirect light of 18 lx. The behavior of the rats was recorded using two cameras placed above the arena and connected to a Noldus MPEG recorder 2.1. An experimenter blind to the treatment conditions analyzed the videos off-line using Noldus Observer® XT, version 10.5. The rats were individually housed for 5 days prior to the start of the procedure. The animals were subsequently handled and weighed, and the backsides of one half of the animals were dyed with a gentian violet (2% methylrosanilinium chloride) solution. On the test day (the sixth day of social isolation), to reduce aggressive and territorial behaviors and to increase the level of social behavior, two unfamiliar rats of matched body weight (±5 g) were placed in the open field arena, and their behaviors were recorded for 10 min. The social interaction time was measured for each rat separately. The following active social behaviors were scored: sniffing (the rat sniffs the body of the conspecific), anogenital sniffing (the rat sniffs the anogenital region of the conspecific), social grooming (the rat licks and chews the fur of the conspecific), following (the rat moves toward and follows the other rat), mounting (the rat stands on the back of the conspecific), and climbing (the rat climbs over the back of the conspecific) (Holuj et al. 2015). No overt aggressive behaviors (such as biting, kicking, boxing, and threatening behavior) were observed in control animals or after treatment with KET or TIL. As the mean total time of aggressive behaviors was <3% of the session duration, aggression was not included in the analysis. The time of active social behaviors was summed to yield a total score. As both animals in a pair yielded approximately equal scores (for either total time spent in social interactions or separate social behaviors), social interaction time was expressed as a summed score for each pair of animals.
In addition, we also measured the number of 50-kHz ultrasonic vocalizations (USVs) that accompany rat social interactions and reflect a positive effect. This was done as described earlier (Nikiforuk et al. 2013b).
Mouse Locomotor Activity
The locomotor activity test was performed as previously described (Salat et al. 2015c) using activity cages (40 cm × 40 cm × 30 cm) supplied with I.R. beam emitters (Activity Cage 7441, Ugo Basile, Italy) connected to a counter for the recording of light-beam interrupts. The animals’ movements (i.e., the number of light-beam crossings) were counted during the next 30 min of the test in 10-min time epochs.
Analgesia: Mouse Hot Plate Test
The hot plate apparatus (Hot/Cold Plate, Bioseb, France) consists of an electrically heated surface and it is equipped with a temperature controller that keeps the temperature constant at 55–56 °C. The test was performed as previously described (Salat et al. 2015a). One day before the experiment, the animals were tested for their pain sensitivity threshold (baseline latency). For further pain tests, only mice with baseline latencies ≤30 s were selected. The latency time to pain reaction (licking hind paws or jumping) was measured as the indicative of nociception. The cutoff time was established (60 s) and animals that did not respond within 60 s were removed from the hot plate apparatus and assigned a score of 60 s.
Motor Coordination: Mouse Rotarod Test
Before the test, mice were trained daily for three consecutive days on a rotarod apparatus (May Commat RR0711, Turkey; rod diameter = 2 cm) that was rotating at a fixed speed of 18 rpm. In each session, the mice were placed on the rotating rod for 3 min with an unlimited number of trials. The proper experiment was performed 24 h after the last training session with the apparatus revolving at 6 or 24 rpm. Motor impairments were defined as the inability to remain on the rotarod apparatus for 1 min, and these were expressed as the mean time spent on the rotarod (Salat et al. 2015a).
Statistics
Data were analyzed using one-way and/or two-way ANOVA (IBM/SPSS 21 for Windows) with Dunnett’s post hoc test. The alpha value was set at P < 0.05. The homogeneity of variance was measured with Levene’s test.
Results
Antidepressant-Like: Mouse Forced Swim Test
In the FST, two-way ANOVA demonstrated an overall effect of treatment with KET (F(4, 51) = 4.64; P < 0.01). Time did not affect the results (F(1, 51) = 1.38) and drug × time interaction was also insignificant (F(4, 51) = 2.44). For the sake of curiosity, separate one-way ANOVAs were calculated on 30-min post-treatment and 24-h post-treatment times, which showed significant effects of the treatment at 30 min (F(4, 51) = 5.73; P < 0.001) but not at 24-h post-administration (F(4, 51) = 2.19). Insignificant effects of KET 24-h post-administration could have masked an apparent effect of 30-min post-administration; indeed, at that time, KET reduced immobility at doses of 10, 15, and 25 mg/kg (Fig. 1a).
For TIL, two-way ANOVA showed the following values: drug effect (F(3, 28) = 3.41; P < 0.05), time effect (F(1, 28) = 21.91; P < 0.001), and drug × time interaction (F(3, 28) = 2.52). Again, separate one-way ANOVAs were calculated on two post-treatment times, which showed significant effects of treatment at 30 min (F(3, 28) = 3.62; P < 0.05) but not for the 24-h post-administration (F(3, 28) = 1.70). Again, insignificant effects of TIL 24-h post-administration could have masked an apparent effect of 30-min post-administration; indeed, at that time, TIL reduced immobility at the dose of 10 mg/kg (Fig. 1b).
Antidepressant-Like (Anhedonia): Mouse Sucrose Preference Test
In the sucrose preference assay, a significant effect of KET on sucrose preference was demonstrated (F(4, 35) = 3.083, P < 0.05; Fig. 1c), while TIL displayed no activity (F(3, 35) = 1.59; Fig. 1d).
Anxiety: Mouse Four-Plate Test
KET and TIL significantly affected the number of punished crossings: F(4, 43) = 2.59 and P < 0.05 and F(3, 34) = 13.29 and P < 0.001, respectively. While TIL at doses of 5–15 mg/kg significantly increased the number of crossings (Fig. 2b), none of the KET doses significantly affected the number of punished crossings (Fig. 2a).
Anxiety (Obsessive-Compulsive Behavior), Depression, Irritability, and Impulsivity: Mouse Marble-Burying Test
Statistical analyses showed the following ANOVA values: F(4, 25) = 3.53 and P < 0.05 and F(3, 20) = 3.79 and P < 0.05 for KET and TIL, respectively. KET significantly reduced the number of buried marbles at the doses of 15–25 mg/kg (Fig. 2c); for TIL, only the dose of 15 mg/kg exerted a statistically significant effect (Fig. 2d).
Cognition: Mouse Passive Avoidance Task
In the passive avoidance task, two-way ANOVA demonstrated an overall effect of treatment with KET (F(4, 45) = 2.91; P < 0.05). Time affected the results significantly (F(1, 45) = 102.95; P < 0.001) and drug × time interaction was also significant (F(4, 45) = 3.21; P < 0.05). In the acquisition trial, none of the KET doses affected entry latency in comparison with the vehicle. However, in the retention trial, KET at doses 5 and 10 (but not 15 or 25) mg/kg significantly reduced the latency to enter the dark compartment as compared with the vehicle, suggesting cognitive impairment produced by relatively lower doses.
In the passive avoidance test, increased latency to reenter the dark box serves as an index of learning. When latencies at acquisition and retention trials were compared within a given treatment, for the vehicle and all doses of KET, except for 5 mg/kg, retention latencies were longer than respective acquisition latencies, suggesting somewhat unimpaired learning except for only a KET dose of 5 mg/kg (Fig. 3a).
For TIL, two-way ANOVA showed the following values: drug effect (F(3, 36) = 2.68; P = 0.06), time effect (F(1, 36) = 5.54; P < 0.05), and drug × time interaction (F(3, 36) = 18.83; P < 0.001. In the acquisition trial, TIL doses of 10 and 15 mg/kg appeared to increase entry latencies, suggesting potential sedative action or motor impairment. In the retention trial, TIL at doses of 5–15 mg/kg reduced latencies to enter the dark compartment, suggesting cognitive impairment.
When latencies in acquisition and retention trials were compared within a given treatment, only for the vehicle-treated group was retention latency longer than respective acquisition latency. Only one dose of TIL (15 mg/kg) resulted in a shorter retention than acquisition latency, suggesting learning deficit (Fig. 3b).
Cognition: Rat Novel Object Recognition Test
As shown in Fig. 3c, d, KET (10–20 mg/kg) and TIL (1–2 mg/kg) disturbed NORT at relatively short ITI of 1 h: F(2, 26) = 26.86 and P < 0.001 and F(3, 28) = 16.95 and P < 0.001, respectively.
In the same test, we measured the total time of either the exploration of objects in the acquisition (T1) trial, purportedly reflecting rats’ propensity to explore novel objects, or sedation. While KET (Fig. 3e) did not affect this measure (F(2, 26) = 0.49), TIL (0.5 and 2 mg/kg; Fig. 3f) reduced it compared to the vehicle (F(3, 28) = 4.82, P < 0.01).
Negative Symptoms of Schizophrenia-Like Measure: Rat Social Behavior
Administration of KET (20 mg/kg) and TIL (2 mg/kg) reduced total social interaction time compared to the vehicle-treated animals (one-way ANOVA: F(5, 24) = 6.29; P < 0.001; Fig. 4a) and the number of USVs emitted by the rats during social encounters (F(5, 24) = 6.17; P < 0.001; Fig. 4b).
Mouse Locomotor Activity, Analgesia, and Motor Coordination
An overall treatment effect of KET on locomotor activity was observed (F(4, 35) = 3.82; P < 0.05). Time affected the results significantly (F(2, 70) = 9.20; P < 0.001) and drug × time interaction was also significant (F(8, 70) = 2.27; P < 0.05; Fig. 5a). KET reduced activity at 25 (but not 5–15) mg/kg and only within the first measurement epoch, i.e., up to 10 min following administration. For TIL, statistical analysis showed the following ANOVA values: drug effect (F(3, 28) = 3.90; P < 0.05), time effect (F(2, 56) = 4.82; P < 0.05), and drug × time interaction (F(6, 56) = 3.55; P < 0.01; Fig. 5b). TIL at 10–15 mg/kg reduced activity at the beginning of the measurement; the dose of 15 mg/kg also reduced it up to 20 min following administration.
In the hot plate test, KET at doses of 5–25 mg/kg did not demonstrate analgesic properties (F(4, 35) = 0.70; Fig. 5c). While for TIL, ANOVA yielded significant treatment differences (F(3, 36) = 3.0; P < 0.05; Fig. 5d) and none of the doses produced significant alterations in pain reaction latency.
In the mouse rotarod test, the impact of KET and TIL on motor coordination was assessed at 6 and 24 rpm separately (Fig. 5e and f, respectively). For 6 rpm, ANOVA values were F(7, 48) = 9.36 and P < 0.001 and for 24 rpm F(7, 48) = 7.05 and P < 0.001. At both speeds, KET at 25 and TIL at 15 mg/kg reduced motor coordination.
Discussion
The main goal of the present study was to assess potential antidepressant-like properties of TIL and compare them to those of KET. We also attempted to hypothesize as to which tests could be indicative or useful in elucidating KET’s enduring antidepressant-like effects. An unexpected finding of the present study was that while KET produced behavioral effects at doses comparable between species, in rats, TIL was ~10 times more potent. At present, we cannot offer an explanation for this finding; however, both compounds are antagonists at NMDARs, with KET affinity of 119–1000 nM (see (Salat et al. 2015c) and references therein). Our unpublished data (A. Siwek) revealed that TIL K i at [3H]-MK-801 sites was 69 ± 14 nM (N = 3), which agrees with Rao et al. (1991) data (IC50 at [3H]-TCP labeled sites ~79 nM), suggesting that TIL is six to eight times more potent than KET at NMDARs.
The results of the present in vivo study are summarized in Table 1 that shows that while KET and TIL produced antidepressant-like action in the mouse FST and anti-obsessive-compulsive effect in marble-burying test, they also reduced locomotor activity and disturbed learning processes. The reduction of locomotor activity indicates the specific anti-immobility effect in the FST, because stimulant effects are regarded as unspecific. However, the antidepressant-like activity of TIL in FST was not stronger than that of KET, and TIL reduced immobility at only one - (mid-) dose, whereas KET was effective at doses 10–25 mg/kg. Moreover, investigating behaviorally naive mice, we noted no enduring antidepressant-like effects of KET and TIL in FST, which agrees with previous reports (Bechtholt-Gompf et al. 2011; Popik et al. 2008). This confirms that the “normal” mouse FST is not suitable and sensitive enough to detect persistent antidepressant-like effects of KET and that animal models of depression such as rat chronic mild stress (Papp et al. 2017) and mouse chronic social defeat stress and lipopolysaccharide-induced depression-like phenotypes (Yang et al. 2017) are more appropriate. The limitation of the present experiments was the lack of a time-course study.
KET at the lowest dose tested (5 mg/kg) unexpectedly reduced sucrose preference, i.e., it augmented anhedonia, whereas the treatment with TIL did not influence sucrose intake at any of the doses used. The sucrose preference test is a reward-based assay used to detect anhedonia-like state in rodents (Strekalova et al. 2004; Papp et al. 2017). The results obtained for KET appear to contradict those reported by Papp et al. (2017) and Yang et al. (2017), who, however, investigated the effect of KET in animal models of depression, while we used naive mice. Also, in the Papp et al. study, KET did not affect sucrose intake in non-stressed controls (Papp et al. 2017).
Examination of dissociative-like effects revealed that both compounds disturbed social behavior and reduced 50-kHz USV emission in rats. Of note was the fact that in both assays for KET, this effect reached statistical significance at a dose 10-fold higher than that for TIL (20 vs. 2 mg/kg). Investigation of the “side effects” demonstrated that only at the highest doses did both compounds produce motor deficits in the rotarod test. In addition, neither KET nor TIL affected pain response in the hot plate test. This acute pain model was used as a control for the passive avoidance and four-plate tests, and it enabled the exclusion of potential false positive results in these two assays.
Using a preliminary assay based on the unconditioned fear model of anxiety, i.e., the four-plate test, we also investigated if KET or TIL could have anxiolytic-like properties in mice. This test revealed that TIL, in contrast to KET, possessed additional anxiolytic-like properties. These results should be taken with care, as we implemented only one behavioral test and further extended research is required to confirm this activity of TIL in other tests, such as the elevated plus maze which is based on the natural aversion of mice for open and elevated areas and on their natural spontaneous exploratory behavior in novel environments. Hayase et al. (2006) reported no effects of KET in the elevated plus maze test in ICR mice, while Silvestre et al. (1997) used three non-conflict tests (holeboard, social interaction, and elevated plus maze paradigms) and observed (a) decreased time spent in the active social interaction, (b) decreased percentage of time spent in open arms of the elevated plus maze, and (c) no significant effect on head dipping in the holeboard test. These authors suggested an anxiogenic-like effect of KET that contrasted with the effects produced by other uncompetitive NMDAR antagonists and resembled those described for stimulant drugs such as caffeine, cocaine, or amphetamine. While we used a different (four-plate) test, our data agree with the above, in that KET displays no anxiolytic-like actions. However, TIL increased the number of punished crossings in the four-plate test and this effect appeared specific, as this drug did not increase animals’ locomotor activity.
The marble-burying behavior, similarly to the four-plate test, comprises many kinds of domains related to anxiety, so it can be interpreted in various ways. Firstly, marble-burying has been suggested to reflect a form of impulsive behavior (Gyertyan 1995), and has even been regarded as a model of obsessive-compulsive disorder (Borsini et al. 2002; Njung'e and Handley 1991; Broekkamp et al. 1986; Li et al. 2006) in which the majority of antidepressants are effective in the attenuation of symptoms (reviewed by Borsini et al. 2002; Ammar et al. 2015). Acute administration of selective serotonin reuptake inhibitors, tricyclic antidepressants, selective noradrenaline reuptake inhibitors, and dual noradrenaline/serotonin reuptake inhibitors selectively and dose-dependently suppressed marble-burying behavior in mice (Schneider and Popik 2007; Marinova et al. 2017; Rodriguez et al. 2013). Secondly, the suppression of spontaneous burying of harmless objects by rodents is known to be sensitive to anxiolytic drugs rather than antipsychotics (Broekkamp et al. 1986; Njung'e and Handley 1991). Recently, a positive effect of memantine as an augmentation therapy for obsessive-compulsive disorder has been demonstrated (Marinova et al. 2017). KET is effective in patients with treatment-resistant depression, obsessive-compulsive disorder, and post-traumatic stress disorder (Glue et al. 2017; Rodriguez et al. 2013). This rapid anti-obsessive-compulsive effect achieved after a single intravenous dose of KET persisted for at least 1 week (Rodriguez et al. 2013). Our findings are in line with those mentioned above, as both KET and TIL significantly reduced marble-burying behavior at a comparable dose of 15 mg/kg. However, the analysis of both the four-plate test’s and marble-burying test’s results indicates the superiority of TIL over KET in anxiety-spectrum disorders.
The analysis of social behaviors of pairs of unfamiliar rats represents an ethologically valid approach for the preclinical assessment of social functions (Sams-Dodd 2013) and in some settings, not used in the present study (unfamiliar environment and high level of lights), serves to measure anxiety. NMDAR antagonists (Koros et al. 2007), including KET (Nikiforuk et al. 2013b), are capable of modeling negative-like symptoms of psychoses expressed as a social withdrawal. The present data are consistent with these findings, in that both KET and TIL reduced the time spent in active social interactions. In addition, we showed that both compounds reduced 50-kHz ultrasonic “happy” calls that accompany social behavior (Nikiforuk et al. 2013b). Such effects have been interpreted as being indicative for psychotomimetic actions, that is, hallucinations and delusions (Sams-Dodd 2013). In the context of enduring antidepressant actions of KET (Zarate et al. 2006a; Berman et al. 2000), we do not view these data as “undesired side” effects, particularly in light of the reports presented in the “Introduction” section (Griffiths et al. 2016).
Both the passive avoidance test in mice and the novel object recognition test in rats demonstrated amnestic actions of KET and TIL. While NMDAR antagonists impaired cognitive processes in naive subjects, KET displays pro-cognitive effects in stressed or “depressed” rats (Nikiforuk and Popik 2014; Papp et al. 2017). Nonetheless, these data further suggest that both compounds could have dissociative-like effects reflecting disturbed attention of animals.
Using the hot plate test (i.e., the thermally induced pain model), we examined whether purported analgesic properties of KET or TIL could have contributed to the amnestic effects observed in the passive avoidance task and anxiolytic-like action in the four-plate test. However, the present data agree with earlier reports (Plesan et al. 1998) and demonstrate no changes in heat pain thresholds after treatment with KET and TIL.
In summary, antidepressant-like properties of both KET and TIL, as well as their adverse effect liabilities, are similar. TIL has an additional anxiolytic-like profile. The present data demonstrate the usefulness of animal research in finding the dissociative-like states in preclinical settings purportedly necessary for the enduring antidepressant effects of noncompetitive NMDAR antagonists.
References
Ammar G, Naja WJ, Pelissolo A (2015) Treatment-resistant anxiety disorders: a literature review of drug therapy strategies. Encéphale 41:260–265
Bechtholt-Gompf AJ, Smith KL, John CS et al (2011) CD-1 and Balb/cJ mice do not show enduring antidepressant-like effects of ketamine in tests of acute antidepressant efficacy. Psychopharmacology 215:689–695
Berman RM, Cappiello A, Anand A et al (2000) Antidepressant effects of ketamine in depressed patients. Biol Psychiatry 47:351–354
Borsini F, Podhorna J, Marazziti D (2002) Do animal models of anxiety predict anxiolytic-like effects of antidepressants? Psychopharmacology 163:121–141
Bourin M, Masse F, Dailly E et al (2005) Anxiolytic-like effect of milnacipran in the four-plate test in mice: mechanism of action. Pharmacol Biochem Behav 81:645–656
Broekkamp CL, Rijk HW, Joly Gelouin D et al (1986) Major tranquillizers can be distinguished from minor tranquillizers on the basis of effects on marble burying and swim- induced grooming in mice. Eur J Pharmacol 126:223–229
Burgdorf J, Zhang XL, Nicholson KL, et al (2013) GLYX-13, a NMDA receptor glycine-site functional partial agonist, induces antidepressant-like effects without ketamine-like side effects. Neuropsychopharmacology 38
Chen G, Ensor CR, Bohner B (1969) The pharmacology of 2-(ethylamino)-2-(2-thienyl)-cyclohexanone-HCl (CI-634). J Pharmacol Exp Ther 168:171–179
Domino EF (2010) Taming the ketamine tiger. 1965. Anesthesiology 113:678–684
Ennaceur A, Delacour J (1988) A new one-trial test for neurobiological studies of memory in rats. 1: behavioral data. Behav Brain res 31:47–59
Eskelund A, Li Y, Budac DP, et al (2017) Drugs with antidepressant properties affect tryptophan metabolites differently in rodent models with depression-like behavior. J Neurochem
ffRench-Mullen JM, Lehmann J, Bohacek R et al (1987) Tiletamine is a potent inhibitor of N-methyl-aspartate-induced depolarizations in rat hippocampus and striatum. J Pharmacol ExpTher 243:915–920
Gargiulo S, Greco A, Gramanzini M et al (2012) Mice anesthesia, analgesia, and care, part I: anesthetic considerations in preclinical research. ILAR j 53:E55–E69
Glue P, Medlicott NJ, Harland S, et al (2017) Ketamine's dose-related effects on anxiety symptoms in patients with treatment refractory anxiety disorders. J Psychopharmacol: 269881117705089
Griffiths RR, Johnson MW, Carducci MA et al (2016) Psilocybin produces substantial and sustained decreases in depression and anxiety in patients with life-threatening cancer: a randomized double-blind trial. J Psychopharmacol 30:1181–1197
Gyertyan I (1995) Analysis of the marble burying response: marbles serve to measure digging rather than evoke burying. Behav Pharmacol 6:24–31
Hayase T, Yamamoto Y, Yamamoto K (2006) Behavioral effects of ketamine and toxic interactions with psychostimulants. BMCNeurosci 7:1–10
Holuj M, Popik P, Nikiforuk A (2015) Improvement of ketamine-induced social withdrawal in rats: the role of 5-HT7 receptors. Behav Pharmacol 26:766–775
Koike H, Iijima M, Chaki S (2011) Involvement of AMPA receptor in both the rapid and sustained antidepressant-like effects of ketamine in animal models of depression. Behav Brain res 224:107–111
Kornhuber J, Bormann J, Hubers M et al (1991) Effects of the 1-amino-adamantanes at the MK-801-binding site of the NMDA-receptor-gated ion channel: a human postmortem brain study. Eur J Pharmacol 206:297–300
Koros E, Rosenbrock H, Birk G et al (2007) The selective mGlu5 receptor antagonist MTEP, similar to NMDA receptor antagonists, induces social isolation in rats. Neuropsychopharmacology 32:562–576
Krystal JH, Karper LP, Seibyl JP et al (1994) Subanesthetic effects of the noncompetitive NMDA antagonist, ketamine, in humans. Psychotomimetic, perceptual, cognitive, and neuroendocrine responses. Arch gen Psychiatry 51:199–214
Li X, Morrow D, Witkin JM (2006) Decreases in nestlet shredding of mice by serotonin uptake inhibitors: comparison with marble burying. Life Sci 78:1933–1939
Luby ED (1959) Study of a new schizophrenomimetic drug—Sernyl. AMAArchNeurolPsychiat 81:363–369
Luckenbaugh DA, Niciu MJ, Ionescu DF et al (2014) Do the dissociative side effects of ketamine mediate its antidepressant effects? J AffectDisord 159:56–61
Marinova Z, Chuang DM, Fineberg N (2017) Glutamate-modulating drugs as a potential therapeutic strategy in obsessive-compulsive disorder. Curr Neuropharmacol
Morris H, Wallach J (2014) From PCP to MXE: a comprehensive review of the non-medical use of dissociative drugs. Drug Test Anal 6:614–632
Moskal JR, Burch R, Burgdorf JS et al (2014) GLYX-13, an NMDA receptor glycine site functional partial agonist enhances cognition and produces antidepressant effects without the psychotomimetic side effects of NMDA receptor antagonists. Expert Opin Investig Drugs 23:243–254
Murrough JW (2016) Ketamine for depression: an update. Biol Psychiatry 80:416–418
Nikiforuk A, Popik P (2014) Ketamine prevents stress-induced cognitive inflexibility in rats. Psychoneuroendocrinology 40:119–122
Nikiforuk A, Fijal K, Potasiewicz A et al (2013a) The 5-hydroxytryptamine (serotonin) receptor 6 agonist EMD 386088 ameliorates ketamine-induced deficits in attentional set shifting and novel object recognition, but not in the prepulse inhibition in rats. J Psychopharmacol 27:469–476
Nikiforuk A, Kos T, Fijal K et al (2013b) Effects of the selective 5-HT7 receptor antagonist SB-269970, and amisulpride on ketamine-induced schizophrenia-like deficits in rats. PLoS One 8:e66695
Njung'e K, Handley SL (1991) Evaluation of marble-burying behavior as a model of anxiety. Pharmacol Biochem Behav 38:63–67
Papp M, Gruca P, Lason-Tyburkiewicz M et al (2017) Antidepressant, anxiolytic and procognitive effects of subacute and chronic ketamine in the chronic mild stress model of depression. Behav Pharmacol 28:1–8
Plesan A, Hedman U, Xu XJ et al (1998) Comparison of ketamine and dextromethorphan in potentiating the antinociceptive effect of morphine in rats. Anesth Analg 86:825–829
Popik P, Kos T, Sowa-Kucma M et al (2008) Lack of persistent effects of ketamine in rodent models of depression. Psychopharmacology 198:421–430
Porsolt RD, Le Pichon M, Jalfre M (1977) Depression: a new animal model sensitive to antidepressant treatments. Nature 266:730–732
Potasiewicz A, Holuj M, Kos T et al (2017) 3-Furan-2-yl-N-p-tolyl-acrylamide, a positive allosteric modulator of the alpha7 nicotinic receptor, reverses schizophrenia-like cognitive and social deficits in rats. Neuropharmacology 113:188–197
Preskorn SH, Baker B, Kolluri S et al (2008) An innovative design to establish proof of concept of the antidepressant effects of the NR2B subunit selective N-methyl-D-aspartate antagonist, CP-101,606, in patients with treatment-refractory major depressive disorder. J Clin Psychopharmacol 28:631–637
Quail MT, Weimersheimer P, Woolf AD et al (2001) Abuse of telazol: an animal tranquilizer. J Toxicol Clin Toxicol 39:399–402
Rao TS, Contreras PC, Cler JA et al (1991) Contrasting neurochemical interactions of tiletamine, a potent phencyclidine (PCP) receptor ligand, with the N-methyl-D-aspartate-coupled and -uncoupled PCP recognition sites. J Neurochem 56:890–897
Rodriguez CI, Kegeles LS, Levinson A et al (2013) Randomized controlled crossover trial of ketamine in obsessive-compulsive disorder: proof-of-concept. Neuropsychopharmacology 38:2475–2483
Salat K, Podkowa A, Kowalczyk P et al (2015a) Anticonvulsant active inhibitor of GABA transporter subtype 1, tiagabine, with activity in mouse models of anxiety, pain and depression. Pharmacol rep 67:465–472
Salat K, Podkowa A, Mogilski S et al (2015b) The effect of GABA transporter 1 (GAT1) inhibitor, tiagabine, on scopolamine-induced memory impairments in mice. Pharmacol Rep 67:1155–1162
Salat K, Siwek A, Starowicz G et al (2015c) Antidepressant-like effects of ketamine, norketamine and dehydronorketamine in forced swim test: role of activity at NMDA receptor. Neuropharmacology 99:301–307
Sams-Dodd F (2013) Is poor research the cause of the declining productivity of the pharmaceutical industry? An industry in need of a paradigm shift. Drug DiscovToday 18:211–217
Schatzberg AF (2014) A word to the wise about ketamine. Am J Psychiatry 171:262–264
Schneider T, Popik P (2007) Attenuation of estrous cycle-dependent marble burying in female rats by acute treatment with progesterone and antidepressants. Psychoneuroendocrinology 32:651–659
Silvestre JS, Nadal R, Pallares M et al (1997) Acute effects of ketamine in the holeboard, the elevated-plus maze, and the social interaction test in Wistar rats. DepressAnxiety 5:29–33
Skolnick P, Layer RT, Popik P et al (1996) Adaptation of the N-methyl-D-aspartate (NMDA) receptors following antidepressant treatment: implications for the pharmacotherapy of depression. Pharmacopsychiatry 29:23–26
Strekalova T, Spanagel R, Bartsch D et al (2004) Stress-induced anhedonia in mice is associated with deficits in forced swimming and exploration. Neuropsychopharmacology 29:2007–2017
Su LX, Shi XX, Yang P et al (2017) Effects of tiletamine on the adenosine monophosphate-activated protein kinase signaling pathway in the rat central nervous system. Res vet Sci 114:101–108
Trullas R, Skolnick P (1990) Functional antagonists at the NMDA receptor complex exhibit antidepressant actions. Eur J Pharmacol 185:1–10
Yang C, Qu Y, Abe M et al (2017) (R)-ketamine shows greater potency and longer lasting antidepressant effects than its metabolite (2R,6R)-hydroxynorketamine. Biol Psychiatry. doi:10.1016/j.biopsych.2016.12.020
Zanos P, Moaddel R, Morris PJ et al (2016) NMDAR inhibition-independent antidepressant actions of ketamine metabolites. Nature 533:481–486
Zarate CA Jr, Singh JB, Carlson PJ et al (2006a) A randomized trial of an N-methyl-D-aspartate antagonist in treatment-resistant major depression. Arch gen Psychiatry 63:856–864
Zarate CA, Singh JB, Quiroz JA et al (2006b) A double-blind, placebo-controlled study of memantine in the treatment of major depression. Am J Psychiatry 163:153–155
Zhu X, Ye G, Wang Z et al (2017) Sub-anesthetic doses of ketamine exert antidepressant-like effects and upregulate the expression of glutamate transporters in the hippocampus of rats. Neurosci Lett 639:132–137
Acknowledgments
The authors wish to thank Dr. Agata Siwek for tiletamine binding data and Dr. Phil Skolnick for his helpful comments.
Author information
Authors and Affiliations
Corresponding authors
Ethics declarations
Conflict of Interest
The authors declare that there are no conflicts of interest.
Funding
This study was supported by the statutory funds K/ZDS/006281 of the Faculty of Health Sciences, Jagiellonian University Medical College, and by statutory activity of the Institute of Pharmacology, Polish Academy of Sciences, Kraków, Poland.
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.
About this article
Cite this article
Popik, P., Hołuj, M., Kos, T. et al. Comparison of the Psychopharmacological Effects of Tiletamine and Ketamine in Rodents. Neurotox Res 32, 544–554 (2017). https://doi.org/10.1007/s12640-017-9759-0
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s12640-017-9759-0