Buy Dimethocaine - 94-15-5

Dimethocaine (DMC), a synthetic derivative of cocaine, is distributed and consumed as "new psychoactive substance" (NPS) without any safety testing at the forefront. It is mainly metabolized by N-acetylation, N-deethylation or hydroxylation. Therefore, the aim of the presented study was to determine the human NAT and P450 isozymes involved in this major metabolic steps, to measure the kinetics of the reactions, and to estimate the contribution on in vivo hepatic clearance. For these studies, cDNA-expressed NATs and P450s were used and formation of metabolites after incubation was measured using LC-MS or LC-MS(n). For N-acetylation, NAT2 could be shown to be the only isoform catalyzing the reaction in vitro hence assuming to be the only relevant enzyme for in vivo acetylation. Kinetic profiles of all P450 catalyzed metabolite formations followed classic Michaelis-Menten behavior with enzyme affinities (Km values) between 3.6 and 220 μM. Using the relative activity factor approach, the net clearances for deethylation of DMC were calculated to be 3% for P450 1A2, 1% for 2C19, <1% for 2D6, and 96% for 3A4. The net clearances for hydroxylation of DMC were calculated to be 32% for P450 1A2, 5% for 2C19, 51% for 2D6, and 12% for 3A4. Furthermore, these data were confirmed by chemical inhibition tests in human liver microsomes. As DMC is metabolized via two main steps and different P450 isoforms were involved in the hepatic clearance of DMC, a clinically relevant interaction with single P450 inhibitors should not be expected. However, a slow acetylation phenotype or inhibition of NAT2 could lead to decreased N-acetylation and hence leading to an increased risk of side effects caused by this arylamine.


Dimethocaine (DMC, larocaine), a synthetic derivative of cocaine, is a widely distributed "legal high" consumed as a "new psychoactive substance" (NPS) without any safety testing, for example studies of metabolism. Therefore, the purpose of this work was to study its in-vivo and in-vitro metabolism by use of liquid chromatography-(high resolution) mass spectrometry (LC-HRMS(n)). DMC was administered to male Wistar rats (20 mg kg(-1)) and their urine was extracted either by solid-phase extraction after enzymatic cleavage of conjugates or by use of protein precipitation (PP). The metabolites were separated and identified by LC-HRMS(n). The main phase I reactions were ester hydrolysis, deethylation, hydroxylation of the aromatic system, and a combination of these. The main phase II reaction was N-acetylation of the p-aminobenzoic acid part of the unchanged parent compound and of several phase I metabolites. The metabolites identified were then used for identification of DMC in rat urine after application of a common user's dose. By use of GC-MS and LC-MS(n) standard urine-screening approaches (SUSAs), DMC and its metabolites could be detected in the urine samples.


Human esterases such as the human carboxylesterases (hCES) are important for the catalytic ester hydrolysis of xenobiotics and they play an important role in the detoxification of drugs (e.g., cocaine) but also in the activation of prodrugs (e.g., ramipril). Therefore, the aim of the presented study was to characterize the enzyme-catalyzed ester hydrolysis of ten drugs (cocaine, dimethocaine, ethylphenidate, 4-fluoro-3α-tropacocaine, 4-fluoro-3β-tropacocaine, heroin, methylphenidate, mitragynine, ramipril, and thebacon) by different esterase-containing systems (recombinant hCES1b, hCES1c, and hCES2, pooled human liver microsomes, pooled human liver S9 fraction, and pooled human plasma). Michaelis-Menten kinetic studies were done using in vitro incubations with the aforementioned enzyme-containing systems and LC coupled to ion trap MS for analysis. Ramipril and heroin were used as known model substrates to ensure reliable incubation conditions. The hydrolysis reactions followed classic Michaelis-Menten kinetics with exception of cocaine and 4-fluoro-3α-tropacocaine, for which hydrolysis rate was too low for reliable modeling. The substrates were mainly metabolized by the following enzymes systems: cocaine, hCES1c; dimethocaine, human plasma esterases; ethylphenidate, hCES1c; 4-fluoro-3β-tropacocaine, human plasma esterases; heroin, hCES2; methylphenidate, hCES1c; mitragynine, hCES1c; ramipril, hCES1b; thebacon, hCES2. Compounds bearing a small alcohol part and a larger acyl part showed higher affinity to hCES1 while those with a large alcohol part showed higher affinity to hCES2. The collected data are important for prediction of drug-drug or drug-food interactions as well as for individual variations in metabolism of drugs of abuse due to enzyme polymorphisms.


The effects of selected local anesthetics on in vitro and in vivo measurements of dopamine transporter activity were determined to investigate the role of local anesthetic activity in the neuronal actions of cocaine. Cocaine inhibited [3H]2-beta-carbomethoxy-3-beta-(4-fluorophenyl)tropane 1.5-naphthalenedisulfonate (CFT) binding and [3H]dopamine uptake with estimated Ki and IC50 values of 0.6 microM and 0.7 micorM, respectively. Of the local anesthetics tested, only dimethocaine showed full displacement of CFT binding (0-30 microM tested) and full inhibition of dopamine uptake (0-100 microM tested). Dimethocaine was only slightly less potent than cocaine with an estimated Ki of 1.4 micorM and an IC50 value of 1.2 microM for [3H]CFT binding and dopamine uptake. At a maximum concentration of 100 microM, the ester containing local anesthetics procaine, tetracaine, piperocaine and the amide containing local anesthetic dibucaine and bupivacaine partially inhibited dopamine uptake by 47-70%. The ester containing local anesthetic propoxycaine and the amide containing local anesthetics prilocaine, etidocaine, procainamide, and lidocaine inhibited dopamine uptake by 8-30% at 100 microM. A 10 min administration of cocaine, dimethocaine, or procaine in the dialysis solution produced dose-dependent, reversible increases in endogenous dopamine efflux from the striata of awake rats. Cocaine and dimethocaine produced similar 12-fold increases in dialysate dopamine at concentrations of 0.1 mM and 1 mM respectively. Procaine (10 mM) produced a 6-fold increase in dialysate dopamine while lidocaine (1 mM) produced a reproducible and reversible decrease (30%). These results show that the cocaine-like actions of certain local anesthetics such as dimethocaine and procaine result from their direct actions of dopamine uptake inhibitors.


The effects of cocaine on dopaminergic function in the rat were compared with those of other local anesthetics having an esteratic linkage (dimethocaine, procaine) or an amide linkage (lidocaine). By means of reverse-phase HPLC with electrochemical detection and gas chromatography-mass spectrometry, levels of dopamine (DA) and its metabolites 3-methoxytyramine (3-MT) and dihydroxyphenylacetic acid were quantified in the striatum, nucleus accumbens and prefrontal cortex after i.p. injection of the drugs or saline. Time course and dose response studies determined the effects of the drugs on these parameters of dopaminergic function. These studies provide strong evidence that the three esteratic local anesthetics cocaine, dimethocaine and procaine all increase the synaptic presence of DA, as reflected in increased levels of 3-MT and the ratio of 3-MT to DA, in the striatum, nucleus accumbens and prefrontal cortex. Surprisingly, procaine had an equal or greater effect than cocaine and dimethocaine on 3-MT levels and the ratio 3-MT/DA. The effects of these drugs on dihydroxyphenylacetic acid, an indicator of intraneuronal metabolism of DA, were more variable. However, the amidergic local anesthetic lidocaine did not affect DA metabolism. Although the exact mechanisms behind the dopaminergic activities of procaine and dimethocaine remain unknown, it is clear that these drugs, as well as cocaine, activate dopaminergic systems in the intact animal.


The present study evaluated the effects of dimethocaine and procaine, esteratic local anesthetics, on locomotor activity, conditioned place preference and on the elevated plus-maze test of anxiety in mice, behavioral tests believed to be sensitive to cocaine action. Acute administration of dimethocaine (10-40 mg/kg, IP) significantly increased locomotor activity and time spent on the drug-paired side and reduced the relative number of entries and time spent on the open arms of the plus-maze in mice. Procaine (20-50 mg/kg, IP) failed to affect these responses. These data demonstrate the locomotor stimulant, reinforcing and anxiogenic actions of dimethocaine similar to those reported for cocaine in animals. In addition, these findings support a role for dopaminergic activity, rather than local anesthetic action, in the behavioral effects caused by dimethocaine.


Post-training intracerebroventricular administration of procaine (20 micrograms/microliter) and dimethocaine (10 or 20 micrograms/microliter), local anesthetics of the ester class, prolonged the latency (s) in the retention test of male and female 3-month-old Swiss albino mice (25-35 g body weight; N = 140) in the elevated plus-maze (mean +/- SEM for 10 male mice: control = 41.2 +/- 8.1; procaine = 78.5 +/- 10.3; 10 micrograms/microliter dimethocaine = 58.7 +/- 12.3; 20 micrograms/microliter dimethocaine = 109.6 +/- 5.73; for 10 female mice: control = 34.8 +/- 5.8; procaine = 55.3 +/- 13.4; 10 micrograms/microliter dimethocaine = 59.9 +/- 12.3 and 20 micrograms/microliter dimethocaine = 61.3 +/- 11.1). However, lidocaine (10 or 20 micrograms/microliter), an amide class type of local anesthetic, failed to influence this parameter. Local anesthetics at the dose range used did not affect the motor coordination of mice exposed to the rota-rod test. These results suggest that procaine and dimethocaine impair some memory process(es) in the plus-maze test. These findings are interpreted in terms of non-anesthetic mechanisms of action of these drugs on memory impairment and also confirm the validity of the elevated plus-maze for the evaluation of drugs affecting learning and memory in mice.


Cocaine and several other local anesthetics were tested for their ability to induce rotational behavior in rats with unilateral 6-hydroxydopamine lesions of substantia nigra. Acute administration of bupivacaine, chloroprocaine, etidocaine, lidocaine, mepivacaine, procaine or tetracaine failed to induce active rotation in this sensitive assay of dopamine agonist activity. On the other hand, cocaine or dimethocaine treatment induced active rotation directed ipsilaterally to the lesioned side, indicating indirect dopamine agonist activity. Repeated administration of cocaine or dimethocaine at 1-week intervals resulted in increased rotational response (i.e., sensitization) while there was no suggestion of sensitization or induction of rotational behavior after weekly repeated administration of procaine or tetracaine. Daily administration of mepivacaine, procaine or tetracaine for 5 days also failed to induce rotation. Dimethocaine thus was found similar to cocaine and different from the other local anesthetics tested both in terms of frank stimulant activity and development of sensitization upon repeated administration.


A number of esteratic local anesthetics serve as positive reinforcers and produce cocaine-like discriminative stimulus effects in animals. It has been suggested that the affinity of these compounds for a site on the dopamine transporter, and not their local anesthetic actions, is responsible for these abuse-related behavioral effects. In the present study, three local anesthetics previously shown to be self-administered in animals were examined in squirrel monkeys trained to discriminate cocaine (0.3 mg/kg) from saline in a two-lever, food-reinforced procedure. Dimethocaine (0.1-3.0 mg/kg) fully and dose-dependently substituted for cocaine. Doses of dimethocaine (1.7 mg/kg) and cocaine (0.3 mg/kg) which produced full (> 80%) substitution for cocaine were administered in combination with the dopamine D1 receptor antagonist SCH 39166 ((-)-trans-6,7,7a,8,9,13b-hexahydro-3-chloro-2-hydroxy-N-methyl-5H -benzo [d]naphtho-(2,1-b)azepine) and the dopamine D2 receptor antagonist raclopride (both at 0.003-0.03 mg/kg). SCH 39166 fully blocked the cocaine-like discriminative stimulus effects of dimethocaine and cocaine, but raclopride produced only partial antagonism of cocaine-lever selection. In addition, there was some evidence that raclopride blocked cocaine-lever responding produced by a lower dose of dimethocaine. In substitution studies, neither procaine (1-10 mg/kg) nor chloroprocaine (1-30 mg/kg) produced cocaine-like effects. These results support a role for dopamine in the behavioral effects of some local anesthetics.


1. Different local anesthetics were tested for analgesic activity in three antinociceptive models, the acetic acid-induced abdominal constriction, tail-flick and hot plate tests in the mouse. 2. In the abdominal constriction test, subcutaneous, SC, injection of lidocaine (10, 20 or 30 mg/kg) and dimethocaine (5, 10 or 20 mg/kg) induced dose-dependent antinociceptive responses. Procaine (20, 30 or 50 mg/kg) was also able to reduce the response to noxious chemical stimuli. 3. The IP injection of lidocaine and dimethocaine significantly inhibited the tail-flick and paw-licking hot plate responses; procaine was weak or inactive in these tests, in which heat was the noxious stimulus. 4. Taken together, these results suggest that antinociception produced by systemically administered lidocaine and dimethocaine at nontoxic doses in mice is due, at least in part, to their central effects.

Dimethocaine (DMC), a synthetic derivative of cocaine, is distributed and consumed as "new psychoactive substance" (NPS) without any safety testing at the forefront. It is mainly metabolized by N-acetylation, N-deethylation or hydroxylation. Therefore, the aim of the presented study was to determine the human NAT and P450 isozymes involved in this major metabolic steps, to measure the kinetics of the reactions, and to estimate the contribution on in vivo hepatic clearance. For these studies, cDNA-expressed NATs and P450s were used and formation of metabolites after incubation was measured using LC-MS or LC-MS(n). For N-acetylation, NAT2 could be shown to be the only isoform catalyzing the reaction in vitro hence assuming to be the only relevant enzyme for in vivo acetylation. Kinetic profiles of all P450 catalyzed metabolite formations followed classic Michaelis-Menten behavior with enzyme affinities (Km values) between 3.6 and 220 μM. Using the relative activity factor approach, the net clearances for deethylation of DMC were calculated to be 3% for P450 1A2, 1% for 2C19, <1% for 2D6, and 96% for 3A4. The net clearances for hydroxylation of DMC were calculated to be 32% for P450 1A2, 5% for 2C19, 51% for 2D6, and 12% for 3A4. Furthermore, these data were confirmed by chemical inhibition tests in human liver microsomes. As DMC is metabolized via two main steps and different P450 isoforms were involved in the hepatic clearance of DMC, a clinically relevant interaction with single P450 inhibitors should not be expected. However, a slow acetylation phenotype or inhibition of NAT2 could lead to decreased N-acetylation and hence leading to an increased risk of side effects caused by this arylamine.Dimethocaine (DMC, larocaine), a synthetic derivative of cocaine, is a widely distributed "legal high" consumed as a "new psychoactive substance" (NPS) without any safety testing, for example studies of metabolism. Therefore, the purpose of this work was to study its in-vivo and in-vitro metabolism by use of liquid chromatography-(high resolution) mass spectrometry (LC-HRMS(n)). DMC was administered to male Wistar rats (20 mg kg(-1)) and their urine was extracted either by solid-phase extraction after enzymatic cleavage of conjugates or by use of protein precipitation (PP). The metabolites were separated and identified by LC-HRMS(n). The main phase I reactions were ester hydrolysis, deethylation, hydroxylation of the aromatic system, and a combination of these. The main phase II reaction was N-acetylation of the p-aminobenzoic acid part of the unchanged parent compound and of several phase I metabolites. The metabolites identified were then used for identification of DMC in rat urine after application of a common user's dose. By use of GC-MS and LC-MS(n) standard urine-screening approaches (SUSAs), DMC and its metabolites could be detected in the urine samples.Human esterases such as the human carboxylesterases (hCES) are important for the catalytic ester hydrolysis of xenobiotics and they play an important role in the detoxification of drugs (e.g., cocaine) but also in the activation of prodrugs (e.g., ramipril). Therefore, the aim of the presented study was to characterize the enzyme-catalyzed ester hydrolysis of ten drugs (cocaine, dimethocaine, ethylphenidate, 4-fluoro-3α-tropacocaine, 4-fluoro-3β-tropacocaine, heroin, methylphenidate, mitragynine, ramipril, and thebacon) by different esterase-containing systems (recombinant hCES1b, hCES1c, and hCES2, pooled human liver microsomes, pooled human liver S9 fraction, and pooled human plasma). Michaelis-Menten kinetic studies were done using in vitro incubations with the aforementioned enzyme-containing systems and LC coupled to ion trap MS for analysis. Ramipril and heroin were used as known model substrates to ensure reliable incubation conditions. The hydrolysis reactions followed classic Michaelis-Menten kinetics with exception of cocaine and 4-fluoro-3α-tropacocaine, for which hydrolysis rate was too low for reliable modeling. The substrates were mainly metabolized by the following enzymes systems: cocaine, hCES1c; dimethocaine, human plasma esterases; ethylphenidate, hCES1c; 4-fluoro-3β-tropacocaine, human plasma esterases; heroin, hCES2; methylphenidate, hCES1c; mitragynine, hCES1c; ramipril, hCES1b; thebacon, hCES2. Compounds bearing a small alcohol part and a larger acyl part showed higher affinity to hCES1 while those with a large alcohol part showed higher affinity to hCES2. The collected data are important for prediction of drug-drug or drug-food interactions as well as for individual variations in metabolism of drugs of abuse due to enzyme polymorphisms.The effects of selected local anesthetics on in vitro and in vivo measurements of dopamine transporter activity were determined to investigate the role of local anesthetic activity in the neuronal actions of cocaine. Cocaine inhibited [3H]2-beta-carbomethoxy-3-beta-(4-fluorophenyl)tropane 1.5-naphthalenedisulfonate (CFT) binding and [3H]dopamine uptake with estimated Ki and IC50 values of 0.6 microM and 0.7 micorM, respectively. Of the local anesthetics tested, only dimethocaine showed full displacement of CFT binding (0-30 microM tested) and full inhibition of dopamine uptake (0-100 microM tested). Dimethocaine was only slightly less potent than cocaine with an estimated Ki of 1.4 micorM and an IC50 value of 1.2 microM for [3H]CFT binding and dopamine uptake. At a maximum concentration of 100 microM, the ester containing local anesthetics procaine, tetracaine, piperocaine and the amide containing local anesthetic dibucaine and bupivacaine partially inhibited dopamine uptake by 47-70%. The ester containing local anesthetic propoxycaine and the amide containing local anesthetics prilocaine, etidocaine, procainamide, and lidocaine inhibited dopamine uptake by 8-30% at 100 microM. A 10 min administration of cocaine, dimethocaine, or procaine in the dialysis solution produced dose-dependent, reversible increases in endogenous dopamine efflux from the striata of awake rats. Cocaine and dimethocaine produced similar 12-fold increases in dialysate dopamine at concentrations of 0.1 mM and 1 mM respectively. Procaine (10 mM) produced a 6-fold increase in dialysate dopamine while lidocaine (1 mM) produced a reproducible and reversible decrease (30%). These results show that the cocaine-like actions of certain local anesthetics such as dimethocaine and procaine result from their direct actions of dopamine uptake inhibitors.The effects of cocaine on dopaminergic function in the rat were compared with those of other local anesthetics having an esteratic linkage (dimethocaine, procaine) or an amide linkage (lidocaine). By means of reverse-phase HPLC with electrochemical detection and gas chromatography-mass spectrometry, levels of dopamine (DA) and its metabolites 3-methoxytyramine (3-MT) and dihydroxyphenylacetic acid were quantified in the striatum, nucleus accumbens and prefrontal cortex after i.p. injection of the drugs or saline. Time course and dose response studies determined the effects of the drugs on these parameters of dopaminergic function. These studies provide strong evidence that the three esteratic local anesthetics cocaine, dimethocaine and procaine all increase the synaptic presence of DA, as reflected in increased levels of 3-MT and the ratio of 3-MT to DA, in the striatum, nucleus accumbens and prefrontal cortex. Surprisingly, procaine had an equal or greater effect than cocaine and dimethocaine on 3-MT levels and the ratio 3-MT/DA. The effects of these drugs on dihydroxyphenylacetic acid, an indicator of intraneuronal metabolism of DA, were more variable. However, the amidergic local anesthetic lidocaine did not affect DA metabolism. Although the exact mechanisms behind the dopaminergic activities of procaine and dimethocaine remain unknown, it is clear that these drugs, as well as cocaine, activate dopaminergic systems in the intact animal.The present study evaluated the effects of dimethocaine and procaine, esteratic local anesthetics, on locomotor activity, conditioned place preference and on the elevated plus-maze test of anxiety in mice, behavioral tests believed to be sensitive to cocaine action. Acute administration of dimethocaine (10-40 mg/kg, IP) significantly increased locomotor activity and time spent on the drug-paired side and reduced the relative number of entries and time spent on the open arms of the plus-maze in mice. Procaine (20-50 mg/kg, IP) failed to affect these responses. These data demonstrate the locomotor stimulant, reinforcing and anxiogenic actions of dimethocaine similar to those reported for cocaine in animals. In addition, these findings support a role for dopaminergic activity, rather than local anesthetic action, in the behavioral effects caused by dimethocaine.Post-training intracerebroventricular administration of procaine (20 micrograms/microliter) and dimethocaine (10 or 20 micrograms/microliter), local anesthetics of the ester class, prolonged the latency (s) in the retention test of male and female 3-month-old Swiss albino mice (25-35 g body weight; N = 140) in the elevated plus-maze (mean +/- SEM for 10 male mice: control = 41.2 +/- 8.1; procaine = 78.5 +/- 10.3; 10 micrograms/microliter dimethocaine = 58.7 +/- 12.3; 20 micrograms/microliter dimethocaine = 109.6 +/- 5.73; for 10 female mice: control = 34.8 +/- 5.8; procaine = 55.3 +/- 13.4; 10 micrograms/microliter dimethocaine = 59.9 +/- 12.3 and 20 micrograms/microliter dimethocaine = 61.3 +/- 11.1). However, lidocaine (10 or 20 micrograms/microliter), an amide class type of local anesthetic, failed to influence this parameter. Local anesthetics at the dose range used did not affect the motor coordination of mice exposed to the rota-rod test. These results suggest that procaine and dimethocaine impair some memory process(es) in the plus-maze test. These findings are interpreted in terms of non-anesthetic mechanisms of action of these drugs on memory impairment and also confirm the validity of the elevated plus-maze for the evaluation of drugs affecting learning and memory in mice.Cocaine and several other local anesthetics were tested for their ability to induce rotational behavior in rats with unilateral 6-hydroxydopamine lesions of substantia nigra. Acute administration of bupivacaine, chloroprocaine, etidocaine, lidocaine, mepivacaine, procaine or tetracaine failed to induce active rotation in this sensitive assay of dopamine agonist activity. On the other hand, cocaine or dimethocaine treatment induced active rotation directed ipsilaterally to the lesioned side, indicating indirect dopamine agonist activity. Repeated administration of cocaine or dimethocaine at 1-week intervals resulted in increased rotational response (i.e., sensitization) while there was no suggestion of sensitization or induction of rotational behavior after weekly repeated administration of procaine or tetracaine. Daily administration of mepivacaine, procaine or tetracaine for 5 days also failed to induce rotation. Dimethocaine thus was found similar to cocaine and different from the other local anesthetics tested both in terms of frank stimulant activity and development of sensitization upon repeated administration.A number of esteratic local anesthetics serve as positive reinforcers and produce cocaine-like discriminative stimulus effects in animals. It has been suggested that the affinity of these compounds for a site on the dopamine transporter, and not their local anesthetic actions, is responsible for these abuse-related behavioral effects. In the present study, three local anesthetics previously shown to be self-administered in animals were examined in squirrel monkeys trained to discriminate cocaine (0.3 mg/kg) from saline in a two-lever, food-reinforced procedure. Dimethocaine (0.1-3.0 mg/kg) fully and dose-dependently substituted for cocaine. Doses of dimethocaine (1.7 mg/kg) and cocaine (0.3 mg/kg) which produced full (> 80%) substitution for cocaine were administered in combination with the dopamine D1 receptor antagonist SCH 39166 ((-)-trans-6,7,7a,8,9,13b-hexahydro-3-chloro-2-hydroxy-N-methyl-5H -benzo [d]naphtho-(2,1-b)azepine) and the dopamine D2 receptor antagonist raclopride (both at 0.003-0.03 mg/kg). SCH 39166 fully blocked the cocaine-like discriminative stimulus effects of dimethocaine and cocaine, but raclopride produced only partial antagonism of cocaine-lever selection. In addition, there was some evidence that raclopride blocked cocaine-lever responding produced by a lower dose of dimethocaine. In substitution studies, neither procaine (1-10 mg/kg) nor chloroprocaine (1-30 mg/kg) produced cocaine-like effects. These results support a role for dopamine in the behavioral effects of some local anesthetics.1. Different local anesthetics were tested for analgesic activity in three antinociceptive models, the acetic acid-induced abdominal constriction, tail-flick and hot plate tests in the mouse. 2. In the abdominal constriction test, subcutaneous, SC, injection of lidocaine (10, 20 or 30 mg/kg) and dimethocaine (5, 10 or 20 mg/kg) induced dose-dependent antinociceptive responses. Procaine (20, 30 or 50 mg/kg) was also able to reduce the response to noxious chemical stimuli. 3. The IP injection of lidocaine and dimethocaine significantly inhibited the tail-flick and paw-licking hot plate responses; procaine was weak or inactive in these tests, in which heat was the noxious stimulus. 4. Taken together, these results suggest that antinociception produced by systemically administered lidocaine and dimethocaine at nontoxic doses in mice is due, at least in part, to their central effects.