A tracking system for laboratory mice to support medical researchers in behavioral analysis.

The behavioral analysis of laboratory mice plays a key role in several medical and scientific research areas, such as biology, toxicology, pharmacology, and so on. Important information on mice behavior and their reaction to a particular stimulus is deduced from a careful analysis of their movements. Moreover, behavioral analysis of genetically modified mice allows obtaining important information about particular genes, phenotypes or drug effects. The techniques commonly adopted to support such analysis have many limitations, which make the related systems particularly ineffective. Currently, the engineering community is working to explore innovative identification and sensing technologies to develop new tracking systems able to guarantee benefits to animals' behavior analysis. This work presents a tracking solution based on passive Radio Frequency Identification Technology (RFID) in Ultra High Frequency (UHF) band. Much emphasis is given to the software component of the system, based on a Web-oriented solution, able to process the raw tracking data coming from a hardware system, and offer 2D and 3D tracking information as well as reports and dashboards about mice behavior. The system has been widely tested using laboratory mice and compared with an automated video-tracking software (i.e., EthoVision). The obtained results have demonstrated the effectiveness and reliability of the proposed solution, which is able to correctly detect the events occurring in the animals' cage, and to offer a complete and user-friendly tool to support researchers in behavioral analysis of laboratory mice.

Pain and child: a translational hypothesis on the pathophysiology of a mild type-2 diabetes model.

Pediatric pain management underwent many changes since the undertreatment of pain in children was reported in the literature in 1980. Increasing data also suggest that long-term behavioural effects can be observed in children, following pain episodes as early as in the neonatal period. Therefore, the knowledge about safe and effective management of pain in children should be applied with greater effectiveness into clinical practice. Other advances in the field include the findings of long-term residual behavioural and metabolic effects induced by pain experienced during the critical periods of development in laboratory animals. Recent data in laboratory animals and clinical data in children suggest that early repeated and/or severe pain and other stressful procedures applied in the perinatal periods may produce not only behavioral, but also important hormonal, immune and metabolic long-term effects. In this paper we shall report data on some metabolic conditions described in adult humans following disruption of hormonal-metabolic programming produced in the peri-natal period. Quite similar signs can be found between animal models and human conditions, most of them being connected with hypothalamus-pituitary-adrenal hormones (HPA) dysfunction. In addition, some signs in animal models, such as overweight and abdominal overweight are prevented by treatment with the µ- and δ-opioid receptor antagonist naloxone during the lactating period. This indicates that some long-term consequences following stress received during the early phases of life in mammals may be bound to the HPA system dysregulation, whereas others are bound to different (e,g., opioid) endogenous brain receptors and/or neuromediators alteration.

Studies on the antinociceptive effect of [Nphe1]nociceptin(1-13)NH2 in mice.

Nociceptin/orphanin FQ (NC) and its receptor (OP(4)) have been implicated in the regulation of various functions including nociception. [Nphe(1)]NC(1-13)NH(2) (Nphe) is a selective OP(4) antagonist which prevents the pronociceptive effects of supraspinal NC and causes per se a naloxone-insensitive antinociceptive effect. In the present study, we tested Nphe in wild type (WT) and OP(4) receptor knock out mice and found that a clear antinociceptive effect of the antagonist was evident only in WT mice. Moreover, we evaluated, over 5 days of treatment, the antinociceptive effects of Nphe in comparison with those of DAMGO and found that tolerance develops to the effects of the opioid receptor agonist but not to Nphe. These data demonstrate that the antinociceptive action of Nphe is due to the block of OP(4) receptors and that no tolerance develops to this kind of antinociception.

Dexamethasone blocking effects on mu- and delta-opioid-induced seizures involves kappa-opioid activity in the rabbit.

Previous data indicate that intracerebroventricular administration of agonists for mu- and delta-opioid receptors induces limbic seizures in rats, but no data are reported in rabbits. We found that the mu- and delta-opioid peptides [D-Ala(2)-N,Me-Phe(4)-Gly(5)-ol]enkephalin (DAMGO), beta-endorphin and deltorphin II, induced EEG non-convulsive hippocampal seizures, and changes in hippocampal background EEG, physical parameters and overt behaviour after central administration. Dexamethasone pre-treatment prevented DAMGO-, deltorphin II- and beta-endorphin-induced seizures as well as changes in background EEG, physical parameters and overt behaviour induced by mu-opioid agonists. Dexamethasone antagonism on opioid action was blocked by pre-treatment with a protein synthesis inhibitor, cycloheximide or by the kappa-opioid antagonist nor-binaltorphimine. Our data suggest that dexamethasone influences opioid actions at mu- and delta-receptors via a protein synthesis mechanism involving kappa-opioid receptors.

Striatal dopamine sensitization to D-amphetamine in periadolescent but not in adult rats.

The neurobiological and behavioral facets of adolescence have been poorly investigated in relation to the vulnerability to psychostimulants. Periadolescent (33-43 days) and adult (>70 days) Sprague-Dawley rats underwent a 3-day treatment history with D-amphetamine (AMPH) at 0, 2, or 10 mg/kg (once a day). After a short 5-day-long withdrawal interval, freely moving animals were challenged with a 2-mg/kg AMPH dose and their behavior as well as in vivo intrastriatum dopamine (DA) release in the CNS were assessed. Microdialysis data indicated that AMPH-history periadolescent rats showed a prominent sensitization of AMPH-stimulated DA release, whereas no such change was found in adult subjects. As expected, acute AMPH administration strongly reduced time spent lying still and increased levels of cage exploration in animals of both ages. A treatment history of high AMPH dosage was associated with a marked sensitization of the exploratory behavior in adults, whereas it induced a quite opposite profile in periadolescents. The latter group only was also characterized by a compulsive involvement in the stereotyped head-bobbing response. These results indicate that differently from adults, marked alterations in neurobiological target mechanisms are observed in rats around periadolescence as a consequence of a quite mild regimen of intermittent AMPH exposure. Thus, a neurobiological substrate for an age-related increased vulnerability towards the addictive risks of these drugs is suggested.

Nociceptin differentially affects morphine-induced dopamine release from the nucleus accumbens and nucleus caudate in rats.

The effects induced by nociceptin on morphine-induced release of dopamine (DA), 3,4-dihydroxyphenilacetic acid (DOPAC) and homovanillic acid (HVA) in the nucleus accumbens and nucleus caudate were studied in rats by microdialysis with electrochemical detection. Nociceptin administered intracerebroventricularly (i.c.v.) at doses of 2, 5 and 10 nmol/rat changed neither DA nor metabolites release in the shell of the nucleus accumbens or in the nucleus caudate. Morphine administered intraperitoneally (i.p.) (2, 5, and 10 mg/kg) increased DA and metabolites release more in the shell of the nucleus accumbens than in the nucleus caudate. When nociceptin (5 or 10 nmol) was administered 15 min before morphine (5 or 10 mg/kg), it significantly reduced morphine-induced DA and metabolites release in the shell of the nucleus accumbens, whereas only a slight, nonsignificant reduction was observed in the nucleus caudate. Our data indicate that nociceptin may regulate the stimulating action associated with morphine-induced DA release more in the nucleus accumbens than in the nucleus caudate, and are consistent with recent observations that nociceptin reversed ethanol- and morphine-induced conditioned place preference. Therefore, the nociceptin-induced reduction of DA release stimulated by morphine in the nucleus accumbens, and the results obtained with nociceptin in the conditioned place preference procedure suggest a role for nociceptin in the modulation of the behavioral and neurochemical effects of abuse drugs.

Orphanin FQ reduces morphine-induced dopamine release in the nucleus accumbens: a microdialysis study in rats.

The effects induced by orphanin FQ (OFQ) on morphine-induced dopamine (DA), 3,4-dihydroxyphenilacetic acid (DOPAC) and homovanillic acid (HVA) release in the nucleus accumbens were studied in rats by using microdialysis with electrochemical detection. Morphine administered intraperitoneally (i.p., 2, 5 and 10 mg/kg) dose-dependently increased DA and metabolites release in the nucleus accumbens. OFQ intracerebroventricularly (i.c.v.) administered at doses of 2, 5 and 10 nmol did not change DA and metabolites release in the nucleus accumbens. OFQ (10 nmol) administered i.c.v. 15 min before morphine (5 and 10 mg/kg, i.p.) significantly reduced morphine-induced DA and metabolites release in the nucleus accumbens. These effects suggest that OFQ may regulate the stimulant action linked to morphine-induced DA release in the nucleus accumbens.

Antinociceptive activity of a 3(2H)-pyridazinone derivative in mice.

The antinociceptive activity of a 3(2H)-pyridazinone derivative (18a) was investigated in mice. 18a administered at doses which did not change either motor coordination or locomotor activity was able to induce antinociceptive effects in four nociceptive tests, the hot plate test, the tail flick test, the writhing test, and the formalin test. In the hot plate and tail flick test, 18a-induced antinociception was observed both after intraperitoneal administration and after intracerebroventricular injection thus indicating 18a has a central site of action. The pretreatment with the opioid antagonist naloxone, the alpha2-antagonist yohimbine or the GABA(B) antagonist CGP 35348 did not change 18a-induced antinociception in the hot plate test and in the tail flick test. Pretreatment with nicotinic antagonist mecamylamine did not change 18a effects either. A reversion of the 18a effects was observed after pretreatment with the muscarinic antagonists atropine and pirenzepine. Binding experiments revealed that 18a binds to muscarinic receptors, suggesting that 18a antinociception is mediated by central muscarinic receptors. The above findings together with the lack of parasympathomimetic cholinergic side effects indicate useful clinical application for this compound.

Dexamethasone modifies the behavioral effects induced by clonidine in mice.

The present study examines the influence of dexamethasone on behavioral effects induced by clonidine in mice. 2. The behavior elements considered were locomoter activity, rota rod, catalepsy and stereotyped behavior (rearing, grooming, social response test, crossing, smelling, washing face, scratching and bar holding). 3. Clonidine (0.1-0.5-1.0 mg/kg, IP) induced a significant reduction of all behavioral elements studied when compared to the saline treated group: the behavioral reduction was significant 10 min after administration and lasted for the entire recording period (120 min). 4. Dexamethasone (0.1-0.5-1.0 mg/kg, IP) per se did not induce significant changes in the behavior elements recorded. 5. Dexamethasone (0.1-0.5 mg/kg, IP) dod not affect behavioral effects induced by the 3 doses of clonidine, whereas the high dose (1 mg/kg) of the steroid significantly reduced its behavioral inhibition. 6. The results of the present study suggest that dexamethasone induces significant effects on clonidine-induced behavioral effects and that this may be related to an interference with the monoaminergic system.

Dexamethasone reduced clonidine-induced hypoactivity in mice.

Reduced clonidine anti-nociception in mice given low doses of dexamethasone has encouraged us to investigate the effects of dexamethasone pretreatment on locomotor hypoactivity, another example of clonidine-induced behaviour in mice. Dexamethasone administered intraperitoneally (0.1, 1.0, 10 mg kg-1) 30 min before clonidine reduced clonidine-induced locomotor hypoactivity in the activity cage to an extent which was dose-dependent. Dexamethasone administered centrally (10 ng/mouse) 30 min before clonidine was also able to reduce clonidine-induced locomotor hypoactivity. Cycloheximide administered at a dose of 10 mg kg-1 2 h before clonidine did not change the effects of clonidine but was able to prevent the effects of dexamethasone on clonidine-induced hypoactivity. The glucocorticoid receptor antagonist RU38486 administered centrally at the dose of 1 ng/mouse did not change the effects of clonidine, whereas it was able to block the effects of dexamethasone on clonidine-induced locomotor hypoactivity. These results suggest that the effects of dexamethasone on clonidine-induced locomotor hypoactivity depend on the stimulating effects that dexamethasone exerts on the protein synthesis via the glucocorticoid receptor in the brain.

Actinomycin D blocks the reducing effect of dexamethasone on amphetamine and cocaine hypermotility in mice.

1. The present study examined a time-course effect of dexamethasone (DEX) on amphetamine and cocaine-induced hypermotility in mice and the influence of actinomycin D (dactinomycin), a protein synthesis inhibitor, on DEX effects. 2. Amphetamine (5 mg/kg IP) and cocaine (10 mg/kg IP) increased markedly the locomotor activity of mice, whereas DEX alone (0.1-1.0-10 mg/kg IP) did not modify the activity of control mice. 3. DEX pretreatment 0, 15, 30, 60 and 120 min before amphetamine or cocaine strongly decreased both amphetamine and cocaine effects, but no dose-related effect was observed. 4. The time-course study performed with DEX revealed differences in its reducing effect on cocaine and amphetamine hypermotility when the groups of animals treated with the steroid immediately before the cocaine (or amphetamine) injection were compared to those treated with the steroid later (15, 30, 60 and 120 min). 5. Furthermore, actinomycin D was able to block the reducing effect of DEX on both amphetamine and cocaine hypermotility. 6. Therefore, considering that the administration time of the steroid seems to be an important factor for reducing both cocaine and amphetamine hypermotility, and actinomycin D was able to block the reducing effect of the steroid, our study suggests that DEX exerts its reducing effect through a genomic activation.

Dexamethasone selective inhibition of acute opioid physical dependence in isolated tissues.

The effect of dexamethasone on acute opiate withdrawal induced by mu, kappa and delta receptor agonists was investigated in vitro. After a 4-min in vitro exposure to morphine (less selective mu agonist), D-Ala2-N-methyl-Phe4-Gly5-ol)-enkephalin (DAGO; highly selective mu agonist) and trans(+/-)-3,4-dichloro-N-methyl-N-[2(1-pyrrolidynyl)cyclohexyl]- benzeneacetamide (U50-488H; highly selective kappa agonist) a strong contracture of guinea pig isolated ileum was observed after the addition of naloxone. This effect was also observed when rabbit isolated jejunum was pretreated with deltorphin (highly selective delta agonist). Dexamethasone treatment before or after the opioid agonists tested was capable of both preventing and reverting the naloxone-induced contracture after exposure to mu opiate agonists morphine and DAGO in a concentration- and time-dependent fashion. Also, the steroid reduced naloxone-induced contracture after the exposure to U50-488H only when injected before the kappa opiate agonist. Finally, it did not affect the naloxone contracture after exposure to deltorphin. Pretreatment with RU-38486, a glucocorticoid receptor antagonist, inhibited dexamethasone antagonism on responses to both mu and kappa agonists, whereas pretreatment with cycloheximide, a protein synthesis inhibitor, blocked only the antagonistic effects of dexamethasone on responses to the mu opioid agonists. Overall, these data indicate that dexamethasone induces significant effects on mu-mediated opiate with-drawal in vitro, which suggest an important functional interaction between corticosteroids and the opioid system primarily at the mu receptor level. The ability of RU-38486 and cycloheximide to block dexamethasone effects indicates that the steroid interference on mu-mediated withdrawal involves a protein synthesis-dependent mechanism via glucocorticoid receptor.

Dexamethasone pretreatment reduces the psychomotor stimulant effects induced by cocaine and amphetamine in mice.

1. The present study examined a comparison of the effect of DEX on psychomotor stimulant effects of cocaine and amphetamine in mice by using the locomotor activity test. 2. Cocaine (10 mg/kg/i.p.) and amphetamine (5 mg/kg/i.p.) increased markedly locomotor activity of mice whereas DEX per se (0.1-1.0-10 mg/kg/i.p.) did not modify the activity of control mice. 3. DEX pretreatment decreased the stimulating effects induced both by cocaine and amphetamine but no consistent dose-related effects were observed. 4. The results suggest that DEX may play an important role on the stimulating effects of cocaine and amphetamine and that it may be of some utility in the clinical management of psychostimulants abuse.

3-(3-Hydroxyphenyl)-N-(1-propyl)piperidine elicits convulsant effects in mice.

1. The behaviour and EEG effects of the dopamine and sigma (sigma) ligands (+) 3-(3-hydroxyphenyl)-N-(1-propyl)piperidine ((+)3-PPP) were studied in mice. 2. (+) 3-PPP dose-dependently (60-100 mg/kg i.p.) produced behavioural and electrical tonic-clonic seizures. 3. The incidence of the tonic seizures elicited by 100 mg/kg of the drug was significantly (P < 0.05) prevented by spiperone (0.5 mg/kg i.p.) and haloperidol (0.5 mg/kg i.p.). 4. The results show an influence on the behavioural and electrical threshold of convulsions by (+) 3-PPP depending on a prevalent interference on dopamine receptors.

Dexamethasone reduces the behavioural effects induced by baclofen in mice.

The present study examines the influence of dexamethasone on the behavioural effects induced by baclofen in mice. The behaviour elements considered were locomotor activity, motor co-ordination, catalepsy, stereotyped behaviour and antinociception. Baclofen (1.0-4.0-6.0 mg kg-1, i.p.) induced a significant reduction of all behavioural elements studied and an antinociceptive effect was recorded. Dexamethasone alone (0.1-0.5-1.0 mg kg-1, i.p.) did not induce significant changes in the behaviour elements considered. On the other hand, when the steroid was injected immediately before baclofen a significant reduction of baclofen's behavioural effects was found. Our results suggest a possible link between glucocorticoid and the GABA-ergic system.

Time-related antiepileptic effects of the synthetic glucocorticoid dexamethasone in rat hippocampal slices.

The in vitro antiepileptic activity of the synthetic glucocorticoid dexamethasone (DEX) was tested in rat hippocampal slices on the CA1 epileptiform activity induced by sodium penicillin (PEN). Slice perfusion with 1 mM PEN produced within 60 min the development of a CA1 epileptiform bursting made up of an increase of the primary CA1 population spike followed by the appearance of secondary epileptiform population spikes. Slice perfusion with 100 microM DEX together with PEN (1 mM) partially prevented but did not block the expression of the CA1 epileptiform bursting as evidenced by a significant (P < 0.05) reduction of the duration of the bursting due to the epileptogenic agent. Slice perfusion with 50 microM DEX together with PEN (1 mM) failed to prevent or block the expression of the CA1 penicillin-induced epileptiform bursting. A 60 min slice pretreatment with 50-100 microM DEX followed by a slice perfusion with 50-100 microM DEX together with PEN (1 mM) prevented the expression of the CA1 epileptiform bursting. Cycloheximide (1 microM), a protein synthesis inhibitor, perfused together with DEX reverted the inhibitory effects of dexamethasone on the expression of the penicillin-induced CA1 epileptiform bursting. The results indicate that the synthetic glucocorticoid DEX presents concentration- and time-related in vitro antiepileptic effects. In addition, the data suggest that this inhibitory effect occurs via a protein synthesis-dependent mechanism.

Dexamethasone-induced selective inhibition of the central mu opioid receptor: functional in vivo and in vitro evidence in rodents.

1. Endogenous corticosteroids and opioids are involved in many functions of the organism, including analgesia, cerebral excitability, stress and others. Therefore, we considered it important to gain information on the functional interaction between corticosteroids and specific opioid receptor subpopulations. 2. We have found that systemic administration (i.p.) of the potent synthetic corticosteroid, dexamethasone, reduced the antinociception induced by the highly selective mu agonist, DAMGO or by less selective mu agonists morphine and beta-endorphin administered i.c.v.. On the contrary dexamethasone exerted little or no influence on the antinociception induced by a delta 1 agonist, DPDPE and a delta 2 agonist deltorphin II. Dexamethasone potentiated the antinociception induced by the kappa agonist, U50,488. 3. In experiments performed in an in vitro model of cerebral excitability in the rat hippocampal slice, dexamethasone strongly prevented both the increase of the duration of the field potential recorded in CA1, and the appearance and number of additional population spikes induced by mu receptor agonists. 4. In both models pretreatment with cycloheximide, a protein synthesis inhibitor, prevented the antagonism by dexamethasone of responses to the mu opioid agonists. 5. Our data indicate that in the rodent brain there is an important functional interaction between the corticosteroid and the opioid systems at least at the mu receptor level, while delta and kappa receptors are modulated in different ways.

Effect of des-tyrosine-gamma-endorphin on neocortical spike-and-wave spindling in DBA/2J mice.

The effect of a beta-endorphin cleavage product devoid of opioid effects, des-tyrosine-gamma-endorphin (DT gamma E) on the neocortical spike-and-wave spindling episodes in the electrocorticogram (ECoG) of DBA/2J mice was studied. DT gamma E (0.01-1.0 mg/kg, i.p.) dose dependently reduced the spike-and-wave bursts duration. However, the low dose did not induce consistent modifications of the spike-and-wave bursts number while the dose of 0.1 and 1.0 mg/kg induced a progressive diminution. Furthermore, at all doses DT gamma E did not induce any alterations of the spike-and-wave bursts amplitude, frequency, and desynchronized activity when compared to the pre-drug period. These results indicate that this beta-endorphin fragment may affect brain excitability.

Dexamethasone influence on morphine-induced analgesia in outbred Swiss and inbred DBA/2J and C57BL/6 mice.

1. The influence of dexamethasone on morphine analgesia in three different strains of mice (Swiss, DBA/2J and C57BL/6) was studied by using the tail flick test. 2. I.c.v. as well as i.p. injections of dexamethasone did not modify nociceptive response in all strains. 3. I.c.v. injection of dexamethasone significantly reduced morphine analgesia in Swiss mice whereas no effects were observed in DBA/2J and C57BL/6 mice. 4. In addition, i.p. injection of dexamethasone significantly reduced morphine analgesia in all three strains. 5. These results suggest that the use of different genetic strains may provide an useful approach for studying dexamethasone-morphine analgesia interaction.

Subchronic treatment with fragments of beta-endorphin prevents electroencephalographic seizures and behavioral alterations induced by centrally administered beta-endorphin in the rabbit.

The effects of some beta-endorphin fragments with neuroleptic-like properties, i.e., tau-endorphin, des-tyr1-tau-endorphin (DT tau E), desenkephalin-tau-endorphin (DE tau E), in comparison with the dopaminergic antagonist haloperidol,- were studied on the EEG and behavioral alterations induced by beta-endorphin in the rabbit. beta-Endorphin administered i.c.v. (5-30 nmol) induced EEG nonconvulsive limbic seizures as well as EEG background and behavioral alterations which were antagonized by naloxone administered i.v. (1-2 mg/kg). Haloperidol, tau-endorphin, DT tau E and DE tau E were unable to prevent beta-endorphin-induced alterations when injected in a single dose i.v. (25-50 micrograms/kg), 15 min before beta-endorphin. Subchronic i.v. administration of DT tau E or DE tau E (25 micrograms/kg/day) for 4 consecutive days prevented completely EEG limbic seizures as well as EEG background and behavioral alterations induced by i.c.v. beta-endorphin injected 15 min after the fourth dose; however, haloperidol (30 micrograms/kg/day) administered with the same schedule as DT tau E or DE tau E was able to prevent only EEG epileptiform and EEG background alterations induced by beta-endorphin. tau-Endorphin administered i.v. for 4 consecutive days (25 micrograms/kg/day) did not consistently influence any of the beta-endorphin effects. Our results show that DT tau E and DE tau E, which are devoid of opioid activity, exert a strong antagonism on ictal seizures as well as on other EEG alterations and behavioral alterations induced by beta-endorphin, and suggest that the antagonism shown by these drugs and by haloperidol on the EEG effects induced by beta-endorphin are exerted at least in part through an indirect action, i.e., an interaction with the dopaminergic system.