Cellular Mechanism for Specific Mechanical Antinociception by D2-like Receptor at the Spinal Cord Level.

Intrathecal (i.t.) administration of quinpirole, a dopamine (DA) D2-like receptor agonist, produces antinociception to mechanonociceptive stimuli but not to thermonociceptive stimuli. To determine a cellular mechanism for the specific antinociceptive effect of D2-like receptor activation on mechanonociception, we evaluated the effect of quinpirole on voltage-gated Ca2+ influx in cultured dorsal root ganglion (DRG) neurons and the D2 DA receptor distribution in subpopulations of rat nociceptive DRG neurons. Small-diameter DRG neurons were classified into IB4+ (nonpeptidergic) and IB4- (peptidergic). Intracellular [Ca2+] microfluorometry and voltage-clamp experiments showed that quinpirole reduced Ca2+ influx and inhibited the high voltage-activated Ca2+ current (HVA-ICa) in half of IB4+ neurons, leaving Ca2+ entry and HVA-ICa in IB4- neurons nearly unaffected. Pretreatment with ω-conotoxin MVIIA prevented the effect of quinpirole on HVA-ICa from IB4+ neurons, indicating that quinpirole mainly inhibits CaV2.2 channels. Immunofluorescence experiments showed that D2 DA receptor was present mainly in IB4+ small DRG neurons. Finally, in behavioral experiments in rats, the clinically approved D2-like receptor agonist pramipexole produced spinal antinociception in a similar fashion to quinpirole, with a significant effect only in the mechanonociceptive test. Our results explain, at least in part, why D2-like receptor agonists produce antinociception on mechanonociceptors.

Neuropathic and inflammatory antinociceptive effects and electrocortical changes produced by Salvia divinorum in rats.

ETHNOPHARMACOLOGICAL RELEVANCE: Salvia divinorum is a medicinal plant traditionally used in hallucinogenic ethnopharmacological practices and for its analgesic and antinflammatory properties. Its active compounds include diterpenes known as salvinorins which act as potent κ opioid receptor agonists. AIM OF THE STUDY: Given its effects in acute animal models of pain, as well as its antinflammatory attributes, we decided to investigate the analgesic effects of an SD extract in neuropathic (sciatic loose nerve ligature) and inflammatory (intra plantar carrageenan) pain models in rats. We also determined in this study the electrocorticographic changes to correlate similar hallucinogenic state and behavior as those produced in humans. MATERIAL AND METHODS: Mechanical and thermonociceptive responses, plantar test and von Frey assay, respectively, were measured in adult Wistar rats 30min, 3h and 24h after the intraperitoneal administration of saline or an hydroponic SD extract. We also evaluated carbamazepine and celecoxib, as gold reference drugs, to compare its antinociceptive effects. RESULTS: Our results showed that administration of SD extract induced antialgesic effects in both neuropathic and inflammatory pain models. All those effects were blocked by nor-binaltorphimine (a Kappa opioid receptor antagonist). Moreover, it was observed an increase of the anterior power spectral density and a decrease in the posterior region as electrocorticographic changes. CONCLUSION: The present investigation give evidence that SD is capable to reduce algesic response associated to neuropathic and inflammatory nociception. This study support therapeutic alternatives for a disabling health problem due to the long term pain with high impact on population and personal and social implications.

A D2-like receptor family agonist produces analgesia in mechanonociception but not in thermonociception at the spinal cord level in rats.

The administration of dopaminergic drugs produces analgesia in individuals experiencing different types of pain. Analgesia induced by these drugs at the spinal cord level is mediated by D2-like agonists, which specifically inhibit the detection of nociceptive stimuli by sensory afferents. The extent of the analgesia provided by spinal dopamine agonists remains controversial, and the cellular mechanism of this analgesic process is poorly understood. The objective of this study was to evaluate the analgesic effect of quinpirole, a D2-like agonist, based on two nociceptive tests and at various doses that were selected to specifically activate dopamine receptors. We found that intrathecal quinpirole administration produces analgesia of mechanical but not thermal nociception and that the analgesic effect of quinpirole is reversed by a mix of D2, D3, and D4 receptor-specific antagonists, suggesting that the activation of all D2-like receptors is involved in the analgesia produced by intrathecal quinpirole. The differential effect on thermal and mechanical nociception was also tested upon the activation of µ-opioid receptors. As reported previously, low doses of the µ-opioid receptor agonist DAMGO produced analgesia of only thermonociception. This evidence shows that a D2-like receptor agonist administered at the spinal cord level produces analgesia specific to mechanonociception but not thermonociception.

Inhibition of peripheral nociceptors by aminoglycosides produces analgesia in inflammatory pain models in the rat.

Aminoglycosides (AGs) modulate nociceptors and ionic channels expressed in sensory neurons. The AG applied in situ could be useful to alleviate hyperalgesia in animal models of inflammatory pain. We tested streptomycin (ST) and neomycin (NEO) as analgesic agents applied in situ in rat paw inflammation caused by formalin or carrageenan administration. The action of ST and NEO on the action potential discharge produced by acidic stimuli in isolated dorsal root ganglion neurons was also studied in current-clamp recordings. In the formalin test, ST and NEO significantly reduced the nociceptive behaviour. ST reduced the N-(4-methyl-2-quinazolinyl)-guanidine (GMQ)-induced nociceptive behaviour, and NEO diminished the hyperalgesia to thermonociception and mechanonociception produced by CAR. In the current-clamp experiments, ST and NEO reduced the generation of action potentials when an acidic solution was applied. We conclude that ST and NEO produce analgesia to inflammatory pain, an effect that is due in part to the inhibition of ASIC activation in sensory neurons.

Inflammatory nociception responses do not vary with age, but diminish with the pain history.

Some of the relevant factors that must be considered when dealing with old age include its growing numbers in the general population and pain contention in this age group. In this sense, it is important to study whether antinociceptive responses change with age. To elucidate this point, persistent pain in animals is the preferred model. In addition, the response to inflammatory pain in the same individual must be explored along its lifetime. Male Wistar rats were infiltrated with carrageenan (50 µl intraplantar) and tested 3 h and 24 h after injection using thermal (plantar test) and mechanociceptive tests (von Frey). The rats were divided into the following groups: (a) young rats infiltrated for the first time at 12 weeks of age and re-infiltrated at 15 and 17 weeks; (b) adult rats infiltrated for the first time at 28 weeks of age and re-infiltrated at 44 and 56 weeks; and (c) old rats infiltrated for the first time at 56 weeks of age and re-infiltrated at 72 weeks. The rats tested for the first time at 12 and 56 weeks of age showed hyperalgesia due to carrageenan infiltration at 3 h and 24 h after injection. This result showed that old rats maintain the same antialgesic response due to inflammation. However, when the injection was repeated in the three age groups, the latency to the thermal and mechanociceptive responses at 3 h is increased when compared to animals exposed for the first time to inflammation. The response to thermal and mechanociception in old rats is the same as in young animals as long as the nociceptive stimulus is not repeated. The repetition of the stimulus produces changes compatible with desensitization of the response and evidences the significance of algesic stimulus repetition in the same individual rather than the age of the individual.

Mecanismo celular y molecular de la adicción a benzodiacepinas / Cellular and molecular mechanism of the benzodiazepines addiction

Benzodiazepines (BZD) are a group of psychiatric drugs widely prescribed since their introduction in the clinical practice in the early 60's. These drugs have a high therapeutic efficacy in the anxiety treatment. The pharmacological action of BZD at molecular level over the Central Nervous System is very well established. However, there has always been a strong concern from different health systems about the addictive effects that the BZD may cause. The aim of this article is to give a precise description about the BZD molecular mechanism of addiction that has been resolved in recent time, based on results obtained in basic research, as well provide information about the epidemiological impact of the medical use of the BZD over the population.

Las benzodiacepinas (BZD) son un grupo de psicofármacos ampliamente prescritos desde su introducción en la práctica clínica a principios de los años 1960. Estos fármacos cuentan con una alta eficacia terapéutica en el tratamiento de la ansiedad. Su mecanismo de acción sobre el Sistema Nervioso Central a nivel molecular es bien conocido, sin embargo siempre ha existido preocupación entre distintos sistemas de salud por los efectos de adicción farmacológica que provocan. El objetivo de este trabajo es abordar los resultados obtenidos recientemente en investigación básica y describir el mecanismo por el cual las benzodiacepinas producen sus efectos adictivos a nivel molecular, así como informar sobre el impacto epidemiológico que tiene su uso.

Taurine enhances antinociception produced by a COX-2 inhibitor in an inflammatory pain model.

The temporal activation of the sensory systems, especially in pain, determines intermediate states that define the future of the response to sensory stimulation. In this work, we interfere pharmacologically with those states that produce peripheral and central sensitisation after an acute inflammatory process, inhibiting at the periphery the COX-2 with celecoxib and using taurine (glycine A receptor agonist) for central pain relief. We tested the paw withdrawal reflex latencies to thermo- and mechanonociception after the induction of an acute inflammatory process with carrageenan. Celecoxib at low doses [0.13 and 1.3 mg/kg, intraperitoneal (i.p.)] in combination with taurine (300 mg/kg, i.p.) produces a decrease of the nociceptive response in thermo- and mechanonociception, as compared with the effect of both drugs alone. We propose that the enhancement of the analgesic effect of celecoxib in combination with taurine could be due the simultaneous action of these drugs at both, peripheral and central levels.

Insular cortex lesion diminishes neuropathic and inflammatory pain-like behaviours.

Injury to the insular cortex in humans produces a lack of appropriate response to pain. Also, there is controversial evidence on the lateralization of pain modulation. The aim of this study was to test the effect of insular cortex lesions in three models of pain in the rat. An ipsilateral, contralateral or bilateral radiofrequency lesion of the rostral agranular insular cortex (RAIC) was performed 48h prior to acute, inflammatory or neuropathic pain models in all the experimental groups. Acute pain was tested with paw withdrawal latency (PWL) after thermal stimulation. Inflammation was induced with carrageenan injected in the paw and PWL was tested 1h and 24h afterwards. Neuropathic pain was tested after ligature of the sciatic nerve by measuring mechanical nociceptive response after stimulation with the von Frey filaments. Another model of neuropathy consisted of thermo stimulation followed by right sciatic neurectomy prior to the recording of autotomy behaviour. Acute pain was not modified by the RAIC lesion. All the RAIC lesion groups showed diminished pain-related behaviours in inflammatory (increased PWL) and neuropathic models (diminished mechanical nociceptive response and autotomy score). The lesion of the RAIC produces a significant decrease in pain-related behaviours, regardless of the side of the lesion. This is a clear evidence that the RAIC plays an important role in the modulation of both inflammatory and neuropathic - but not acute - pain.

Inflammatory nociception diminishes dopamine release and increases dopamine D2 receptor mRNA in the rat's insular cortex.

BACKGROUND: The insular cortex (IC) receives somatosensory afferent input and has been related to nociceptive input. It has dopaminergic terminals and D1 (D1R) -excitatory- and D2 (D2R) -inhibitory- receptors. D2R activation with a selective agonist, as well as D1R blockade with antagonists in the IC, diminish neuropathic nociception in a nerve transection model. An intraplantar injection of carrageenan and acute thermonociception (plantar test) were performed to measure the response to inflammation (paw withdrawal latency, PWL). Simultaneously, a freely moving microdyalisis technique and HPLC were used to measure the release of dopamine and its metabolites in the IC. Plantar test was applied prior, one and three hours after inflammation. Also, mRNA levels of D1 and D2R's were measured in the IC after three hours of inflammation. RESULTS: The results showed a gradual decrease in the release of dopamine, Dopac and HVA after inflammation. The decrease correlates with a decrease in PWL. D2R's increased their mRNA expression compared to the controls. In regard of D1R's, there was a decrease in their mRNA levels compared to the controls. CONCLUSIONS: Our results showed that the decreased extracellular levels of dopamine induced by inflammation correlated with the level of pain-related behaviour. These results also showed the increase in dopaminergic mediated inhibition by an increase in D2R's and a decrease in D1R's mRNA. There is a possible differential mechanism regarding the regulation of excitatory and inhibitory dopaminergic receptors triggered by inflammation.

Expression of muscarinic M1 and M2 receptors in the anterior cingulate cortex associated with neuropathic pain.

The anterior cingulate cortex (ACC) and muscarinic receptors modulate pain. This study investigates changes in the expression of muscarinic-1 and -2 receptors (M1R, M2R) in rats' ACC (cg1-rostral- and cg2-caudal) using a model of neuropathic pain by denervation, measured as autotomy score (AS) for 8 days. Changes were analysed with painful stimuli and with scopolamine into the ACC prior to this scheme. We used reverse transcriptase-polymerase chain reaction (RT-PCR) and immunofluorescence to determine M1R and M2R's mRNA and protein levels, respectively. Animals were divided in low, medium and high AS groups. Cg1 showed decreased mRNA levels for both M1R and M2R in the low AS group, as opposed to an increased expression in the medium and high AS groups. Both receptors correlated positively with AS in these groups. In the scopolamine-treated animals there was an increase in mRNA levels for both receptors in cg1, whereas in cg2, mRNA levels of M1R decreased in all the AS and scopolamine groups. The increased M2R mRNA in cg2 correlated with AS in the low, medium and high AS groups whereas all the scopolamine groups showed an increase. Immunoreactivity of the M2R in cg1 decreased in the medium AS group in comparison to controls but scopolamine treatment produced an increase in the medium scopolamine AS group compared to the medium AS group. The M1R in cg1 and both receptors in cg2 showed no immunoreactivity changes. These results highlight the role of the M2R in cg1 related to the degree of autotomy.

Long-lasting enhancement of rapid eye movement sleep and pontogeniculooccipital waves by vasoactive intestinal peptide microinjection into the amygdala temporal lobe.

STUDY OBJECTIVES: The effect of a vasoactive intestinal peptide (VIP) microinjection into the amygdaloid central (CN) and basal nuclei (BN) on sleep organization and on the number and pattern of occurrence of pontogeniculooccipital (PGO) waves was analyzed. DESIGN: One group of 8 cats was studied in baseline conditions and after the microinjection of two doses of VIP applied into the CN and BN. SETTING: Sleep research laboratory. PARTCIPANTS AND INTERVENTIONS: Eight cats were prepared with sleep-recording electrodes and with guide tubes in both amygdalae for saline and VIP microinjections. Neuropeptide doses of 0.10 microg/1 microl (30 microM) and 0.33 microg/1 microl (99.24 microM) were employed. MEASUREMENTS AND RESULTS: Once the microinjection was applied, 23-hour polygraphic sleep recordings were performed for 5 consecutive days. Concomitantly the PGO waves were tape-recorded on each day and computationally analyzed. Results show that the 0.10 microg/1 microl microinjection produced no change. Unilateral VIP 0.33 microg/1 microl injection into the CN provoked a significant and lasting increase in the percentage of slow-wave sleep with PGO waves. Bilateral application of VIP increased the percentage of slow-wave sleep with PGO waves and rapid eye movement sleep for 5 days. Bilateral microinjection of the neuropeptide into the BN only enhanced the percentage of slow wave sleep with PGO waves. For both amygdaloid nuclei, we observed that VIP increased the number and modified the PGO wave pattern of occurrence during slow-wave sleep with PGO waves and during rapid eye movement sleep. CONCLUSIONS: The VIP microinjection into both the CN and BN induces increased amounts of rapid eye movement sleep, PGO waves, and slow-wave sleep with PGO waves, having a more robust effect on all of these three variables when applied into the CN.