Characteristics of the provision of case management services in the community setting in Andalusia based on the RANGECOM registry. / Características de la provisión del servicio de gestión de casos en el entorno comunitario en Andalucía a partir del registro RANGECOM.

OBJECTIVE: To describe the characteristics of case management in terms of population served, interventions, use of services and outcomes such as mortality, readmissions, pressure ulcers, falls, drug problems and institutionalization. METHOD: Follow-up study of a cohort, from the RANGECOM Multicentric Registry of Andalusia. The study population were patients included in the case management services of Health Centres and their family caregivers. RESULTS: Data from 835 patients with a mean age of 76.8years (SD:12.1), 50.24% women, are presented. They had an important comorbidity (Charlson 3.1, SD:2.5) and high dependence (Barthel 37.5, SD:31.4). Sixty-two point two percent of the interventions deployed by the case managers were grouped into three domains: behavioural (26.0%), health system (20.2%) and safety (14.1%). Mortality was 34.4% and hospital admissions 38.1%. Patients with more hospital readmissions had more visits to the Emergency Department (OR:1.41; 95%CI: 1.22-1.63), more telephone interventions by case managers (OR:1.12; 95%CI: 1.02-1.24) and imaging tests (OR:1.37; 95%CI: 1.17-1.60), together with greater caregiver burden (OR:1.31; 95%CI: 1.08-1.59), the presence of medical devices at home (OR:1.69; 95%CI: 1.00-2.87) and received less "Case Management" intervention. CONCLUSIONS: The patients who absorb the demand of case management nurses present high complexity, for which they deploy behavioural interventions, navigation through the health system and clinical safety.

Role of CRF1 receptor in post-incisional plasma extravasation and nociceptive responses in mice.

The corticotropin-releasing factor (CRF) is involved in a number of physiological functions including pain perception. The purpose of this study was to evaluate the role of CRF1 receptor in the long-lasting post-surgical changes in somatic nociceptive thresholds and in local inflammatory responses, using genetically engineered mice lacking functional CRF1 receptor. Animals underwent a plantar incision under anaesthesia with remifentanil (80µg/kg s.c.) and sevoflurane. Mechanical thresholds (von Frey) and plasma extravasation (Evan's blue) were evaluated at different time points. On postoperative day 20, mechanical thresholds had returned to baseline in CD1 mice (3.07±6.21%), while B6,129CRHtklee mice presented significant hyperalgesia, which was similar in wild-type (WT) (-29.81±8.89%) and CRF1 receptor knockout (KO) (-37.10±10.75%) mice, showing strain differences. The administration of naloxone (1mg/kg, s.c.) on postoperative day 21 produced hyperalgesia revealing surgery-induced latent pain sensitization. The extent of hyperalgesia was greater in KO versus WT mice, suggesting a role of CRF1 receptors in the upward modulation of endogenous opioid release. Furthermore, two days after surgery, plasma extravasation returned to baseline in WT mice but remained elevated in KO mice. In non-manipulated B6,129CRHtklee KO mice we observed an increase in the number of writhes (41.25±11.36) versus WT (23.80±4.71), while in the tail immersion test no differences could be detected. Our results show that CRF/CRF1 receptors seem to be a protective role in latent pain sensitization induced by surgery and in the local inflammatory response to injury.

Antihyperalgesic effects of dexketoprofen and tramadol in a model of postoperative pain in mice - effects on glial cell activation.

OBJECTIVES: To define likely targets (i.e. glia) and protocols (analgesic combinations) to improve postoperative pain outcomes and reduce chronic pain after surgery. Specifically, to assess the antihyperalgesic effects of the dexketoprofen : tramadol (DEX : TRM) combination, exploring the implication of glial activation. METHODS: In a mouse model of postincisional pain, we evaluated mechanical nociceptive thresholds (Von Frey) for 21 days postoperatively. We assessed DEX and TRM alone and combined (1 : 1 ratio) on postoperative hyperalgesia (POH, day 1) and delayed latent pain sensitisation (substantiated by a naloxone challenge; PS, day 21). The interactions were analysed using isobolograms, and concomitant changes in spinal glial cell activation were measured. KEY FINDINGS: On day 1, DEX completely blocked POH, whereas TRM induced 32% inhibition. TRM, but not DEX, partially (47%) protected against PS, at 21 days. Co-administration of DEX : TRM (1 : 1 ratio) showed additivity for antihyperalgesia. Both drugs and their combination totally inhibited surgery-induced microglia activation on day 1, but had no effect on surgery-induced astrocyte activation (1 day) or re-activation after naloxone (21 days). CONCLUSIONS: The DEX : TRM combination could have clinical advantages: a complete prevention of POH after surgery, together with a substantial (48%) inhibition of the development of PS by TRM. Microglia, but not astrocyte activation, could play a relevant role in the development of postoperative pain hypersensitivity.

Glial cell activation in the spinal cord and dorsal root ganglia induced by surgery in mice.

In rodents, surgery and/or remifentanil induce postoperative pain hypersensitivity together with glial cell activation. The same stimulus also produces long-lasting adaptative changes resulting in latent pain sensitization, substantiated after naloxone administration. Glial contribution to postoperative latent sensitization is unknown. In the incisional pain model in mice, surgery was performed under sevoflurane+remifentanil anesthesia and 21 days later, 1 mg/kg of (-) or (+) naloxone was administered subcutaneously. Mechanical thresholds (Von Frey) and glial activation were repeatedly assessed from 30 min to 21 days. We used ionized calcium binding adaptor molecule 1 (Iba1) and glial fibrillary acidic protein (GFAP) to identify glial cells in the spinal cord and dorsal root ganglia by immunohistochemistry. Postoperative hypersensitivity was present up to 10 days, but the administration of (-) but not (+) naloxone at 21 days, induced again hyperalgesia. A transient microglia/macrophage and astrocyte activation was present between 30 min and 2 days postoperatively, while increased immunoreactivity in satellite glial cells lasted 21 days. At this time point, (-) naloxone, but not (+) naloxone, increased GFAP in satellite glial cells; conversely, both naloxone steroisomers similarly increased GFAP in the spinal cord. The report shows for the first time that surgery induces long-lasting morphological changes in astrocytes and satellite cells, involving opioid and toll-like receptors, that could contribute to the development of latent pain sensitization in mice.

A ¹8F-fluorodeoxyglucose MicroPET imaging study to assess changes in brain glucose metabolism in a rat model of surgery-induced latent pain sensitization.

BACKGROUND: Neuroplastic changes involved in latent pain sensitization after surgery are poorly defined. We assessed temporal changes in glucose brain metabolism in a postoperative rat model using positron emission tomography. We also investigated brain metabolism after naloxone administration. METHODS: Rats were given remifentanil anesthetic and underwent a plantar incision, with 1 mg/kg of (-)-naloxone subcutaneously administered on postoperative days 20 and 21. Using the von Frey test, mechanical thresholds were measured pre- and postoperatively at different time points in awake animals during F-fluorodeoxyglucose (F-FDG) uptake. Brain images were also obtained the day before mechanical testing, using a positron emission tomography R4 scanner (Concorde Microsystems, Siemens, Knoxville, TN). Differences in brain activity were assessed utilizing a statistical parametric mapping. RESULTS: Surgery induced minor changes in F-FDG uptake in the cerebellum, hippocampus, and posterior cortex, which extended to the thalamus, hypothalamus, and brainstem on days 6 and 7. Changes were still present on day 21. Maximal postoperative hypersensitivity was observed on day 2. The administration of (-)-naloxone on day 21 induced significant hypersensitivity, greatly enhancing the effect on F-FDG uptake. In sham-operated rats, naloxone induced changes limited to the striatum and the cerebellum. Nonnociceptive stimulation with von Frey filaments had no effect on F-FDG uptake. CONCLUSIONS: Surgery, remifentanil, and their combination induced long-lasting and significant metabolic changes in the pain brain matrix, with a positive correlation with hypersensitivity after naloxone. Changes in brain F-FDG precipitated by naloxone suggest that surgery under remifentanil anesthetic induces the greatest neuroplastic brain adaptations in opioid-related pathways involved in nociceptive processing and long-lasting pain sensitization.

Delayed postoperative latent pain sensitization revealed by the systemic administration of opioid antagonists in mice.

The long-lasting post-surgical changes in nociceptive thresholds in mice, indicative of latent pain sensitization, were studied. The contribution of kappa opioid and N-methyl-d-aspartate (NMDA) receptors was assessed by the administration of nor-binaltorphimine or MK-801; dynorphin levels in the spinal cord were also determined. Animals underwent a plantar incision and/or a subcutaneous infusion of remifentanil (80µg/kg), and mechanical thresholds (von Frey) were evaluated at different times. On day 21, after complete recovery of mechanical thresholds and healing of the wound, one of the following drugs was administered subcutaneously: (-)-naloxone (1mg/kg), (+)-naloxone (1mg/kg), naloxone-methiodide (3mg/kg), or nor-binaltorphimine (5mg/kg). Another group received subcutaneous MK-801 (0.15mg/kg) before nor-binaltorphimine administration. Dynorphin on day 21 was determined in the spinal cord by immunoassay. In mice receiving remifentanil during surgery, the administration of (-)-naloxone or nor-binaltorphimine induced significant hyperalgesia even 5months after manipulation. Nociceptive thresholds remained unaltered after (+)-naloxone or naloxone-methiodide. On day 21 after manipulation, the administration of MK-801 prevented nor-binaltorphimine-induced hyperalgesia. No changes in dynorphin levels were observed before or after opioid antagonist administration. In conclusion, surgery produced latent pain sensitization evidenced by opioid antagonist-precipitated hyperalgesia. The effect was stereospecific, centrally originated, and mediated by kappa opioid receptors. The blockade of nor-binaltorphimine-induced hyperalgesia by MK-801, suggests that NMDA receptors are also involved. Our results show for the first time that surgery induces latent, long-lasting changes in the processing of nociceptive information that can be induced by non-nociceptive stimuli such as the administration of opioid antagonists.

Antinociceptive effects of morphine, fentanyl, tramadol and their combination, in morphine-tolerant mice.

The development of morphine-tolerance after chronic administration, reduces analgesic efficacy and is a significant clinical problem in some patients; may be managed clinically by increasing the doses of morphine and/or the administration of a second mu-opioid agonist. In morphine-tolerant mice, we investigated the presence of an interaction when two opioids are administered simultaneously. We determined the antinociceptive effects of morphine (M), fentanyl (FEN), and tramadol (TRM) individually and combined in a 1:1 proportion, based on their potency. Nociceptive thresholds were evaluated in CD1 mice using the hot plate test. Morphine tolerance was induced by the subcutaneous implantation of a 75mg morphine pellet, whereas control animals received a placebo pellet; the experiments were performed three days later. In both (placebo and morphine pellets), dose-response curves for M, FEN and TRM, individually and combined were obtained, and the doses that produced 50% inhibition (ED(50)) were determined. Sustained exposure to morphine induced a significant decrease in antinociceptive potency to acute M or FEN administration (tolerance), which was of a lesser magnitude after acute TRM; in these experiments the analysis of the interaction between chronic morphine and each opioid, demonstrated functional antagonism. The simultaneous administration of two opioids in morphine-tolerant mice, demonstrated antagonism for the M:FEN combination, whereas the effects of TRM combined with M or FEN, remained additive. The results suggest that during morphine-tolerance, TRM could be a useful drug to induce effective analgesia when combined with FEN or M.

Analysis of the opioid-opioid combinations according to the nociceptive stimulus in mice.

The purpose of the present study was to characterize the antinociceptive effects of tramadol, fentanyl and morphine, when two of them were systemically combined in a 1:1 potency ratio, in the hot plate, the acetic acid writhing, and the formalin tests in mice. Interaction indexes and isobolographic analysis were used to assess the type of interaction. Fentanyl was the most potent drug, followed by morphine and tramadol, with the exception in the phase I of formalin test. Synergistic interactions were obtained when tramadol was combined with fentanyl or with morphine in the writhing and formalin tests. But, in the hot plate only additive interactions were obtained. Changes were induced on the type of interaction depending on the level of effect of opioid-opioid combinations. Moreover, co-administration of fentanyl with morphine showed additivity, regardless of the type of stimulus. Standard rotarod test analysis confirmed intact motor coordination. The present findings suggest that the type of interaction between opioids is not only related to the nature of nociceptive stimulus but also to non-opioid analgesic pathways.

Deletion of the inducible nitric oxide synthase gene reduces peripheral morphine tolerance in a mouse model of chronic inflammation.

The implication of inducible nitric-oxide synthase (iNOS) on peripheral tolerance to morphine was evaluated in wild-type (WT) and iNOS knockout mice. Chronic inflammation was induced by subplantar (s.p.) injection of Complete Freund's Adjuvant (CFA), and morphine tolerance by subcutaneous implantation of a 75 mg morphine-pellet. Withdrawal was assessed after the intraperitoneal injection of 2 mg/kg naloxone. Antinociception was assessed (Randall-Selitto test) 5 min after a fixed dose of s.p. morphine (16 microg). In the absence of inflammation, s.p. morphine did not induce antinociception, while during CFA-inflammation produced 47.4 +/- 0.8 and 38.8 +/- 2.7% inhibitions respectively, in each genotype (P < 0.05). In morphine-tolerant mice with CFA-inflammation, no antinociception could be elicited in WT mice (2.4 +/- 0.3% inhibition); however, iNOS knockout mice showed significant antinociception (33.1 +/- 0.9%) (P < 0.001). Thus, iNOS gene deletion partially prevented tolerance to the peripheral effects of morphine, and significantly attenuated withdrawal-induced hyperactivity.

Increased spinal dynorphin levels and phospho-extracellular signal-regulated kinases 1 and 2 and c-Fos immunoreactivity after surgery under remifentanil anesthesia in mice.

In humans, remifentanil anesthesia enhances nociceptive sensitization in the postoperative period. We hypothesized that activation of extracellular signal-regulated kinases 1 and 2 (ERK1/2) and the expression of c-Fos, prodynorphin (mRNA), and dynorphin in the spinal cord could participate in the molecular mechanisms underlying postoperative opioid-induced sensitization. In a mouse model of incisional pain, we evaluated thermal (Hargreaves test) and mechanical (von Frey) hyperalgesia during the first 21 postoperative days. Moreover, prodynorphin (mRNA, real-time polymerase chain reaction), dynorphin (enzymatic immunoassay), c-Fos expression, and ERK1/2 phosphorylation (both by immunohistochemistry) in the lumbar spinal cord were assessed. Surgery performed under remifentanil anesthesia induced a maximal decrease in nociceptive thresholds between 4 h and 2 days postoperatively (p < 0.001) that lasted 10 to 14 days compared with noninjured animals. In the same experimental conditions, a significant increase in prodynorphin mRNA expression (at 2 and 4 days) followed by a sustained increase of dynorphin (days 2 to 10) in the spinal cord was observed. We also identified an early expression of c-Fos immunoreactivity in the superficial laminae of the dorsal horn of the spinal cord (peak at 4 h; p < 0.001), together with a partial activation of ERK1/2 (4 h; p < 0.001). These findings suggest that activated ERK1/2 could induce c-Fos expression and trigger the transcription of prodynorphin in the spinal cord. This in turn would result in long-lasting increased levels of dynorphin that, in our model, could participate in the persistence of pain but not in the manifestation of first pain.

Pronociceptive effects of remifentanil in a mouse model of postsurgical pain: effect of a second surgery.

BACKGROUND: Remifentanil anesthesia enhances postoperative pain in animals and humans. The authors evaluated the impact of the dose (microg x kg(-1) x min(-1)) and duration of remifentanil infusion, and the effects of a second surgery on postoperative pain sensitization. METHODS: Mice received different doses of remifentanil over 30 or 60 min. The authors assessed thermal (Hargreaves) and mechanical hyperalgesia (von Frey) at 2, 4, 7, and 10 days. In other experiments, mice had a plantar incision during sevoflurane with or without remifentanil anesthesia that was repeated 27 days later, when nociceptive thresholds returned to baseline. Linear mixed models were used for statistical analysis. RESULTS: Remifentanil induced dose-dependent pronociceptive effects with calculated ED(50)s of 1.7 (95% confidence interval, 1.3-2.1) and 1.26 (1.0-1.6) microg x kg(-1) x min(-1) for thermal and mechanical hyperalgesia, respectively, which lasted longer with higher doses (P < 0.001). The duration of infusion did not alter the pronociceptive effects of remifentanil when administered at a constant dose of infusion. When given during surgery, high (2.66 microg x kg(-1) x min(-1)) or low (0.66 microg x kg(-1) x min(-1)) remifentanil increased the extent (P < 0.05) and duration (P < 0.01) of thermal and mechanical hyperalgesia. The latter was further enhanced after a second surgery performed in the same experimental conditions (P < 0.05). Surgery or remifentanil infusion, each one individually, induced significant mechanical hyperalgesia, which was greater when repeated (P < 0.05). CONCLUSIONS: In this model of incisional pain, remifentanil induces pronociceptive effects, which are dose dependent but unaltered by the duration of administration. A second surgery performed on the same site and experimental conditions induces greater postoperative hyperalgesia that is enhanced when remifentanil is used as an anesthetic.

Tolerance to the antinociceptive effects of peripherally administered opioids. Expression of beta-arrestins.

Tolerance to peripheral antinociception after chronic exposure to systemic morphine was assessed in mice with chronic CFA-inflammation; cross-tolerance to locally administered mu, delta and kappa-opioid agonists and levels of beta-arrestins in the injured paw, were also evaluated. Tolerance was induced by the subcutaneous implantation of a 75 mg morphine-pellet, and antinociception evaluated with the Randall-Selitto test, 5 min after the subplantar injection of morphine, fentanyl, buprenorphine, DPDPE, U-50488H or CRF. Experiments were performed in the absence and presence of CFA-inflammation, in animals implanted with a morphine or placebo pellet. Beta-arrestin protein levels were determined by western blot. In mice without inflammation, subplantar opioids did not induce antinociception, while during CFA-inflammation, all drugs generated dose-response curves with an order of potency of: U-50488H < DPDPE < morphine < buprenorphine < fentanyl << CRF. During CFA-inflammation plus morphine-pellet, the potency of fentanyl decreased 1.25 times, while that of DPDPE, U-50488H and CRF diminished approximately 2.5-4.3 times. For each drug, the ratio between the ED(50)'s in tolerant and naive animals, was significantly higher than 1 (except for buprenorphine and fentanyl), demonstrating partial cross-tolerance to systemic morphine. Inflammation induced a twofold increase in beta-arrestin expression (p<0.01), and the levels decreased after acute morphine exposure (p<0.05). Tolerance did not alter beta-arrestins, but partially prevented the increase induced by inflammation. The results suggest that peripheral beta-arrestins could facilitate peripheral OR-desensitization and tolerance development. Clinically, the experiments could be useful to establish the effectiveness of local opioid administration in patients with musculoskeletal pain, chronically receiving morphine analgesia.

Effects of chronic inflammation and morphine tolerance on the expression of phospho-ERK 1/2 and phospho-P38 in the injured tissue.

Opioids are used in humans in the treatment of chronic osteoarticular pain, but the development of tolerance to the analgesic effects after continuous administration is still not well understood. The aim of the present study was to evaluate the expression of phospho-ERK 1/2 and phospho-p38 in mice with monoarthritis chronically exposed to morphine as a possible explanation for the development of tolerance. Inflammation was induced by intraplantar injection of complete Freund's adjuvant (CFA) and the tolerance by implantation of 75 mg morphine pellets. The results of the present study show that ERKs phosphorylation is unaltered by inflammation or morphine tolerance, each one individually, in the plantar tissue. In contrast, phospho-p38 is similarly decreased by inflammation or morphine tolerance. In naïve but not in tolerant animals, acute injection of morphine induces significant increase in phospho-p38 without any changes in phospho-ERK 1/2 expression. During inflammation, the acute injection of morphine induces a significant increase in the expression of ERK 1/2, but not in phospho-p38, in naïve animals. Phospho-ERK 1/2 expression was significantly decreased in the presence of inflammation plus tolerance. In contrast, no significant differences in phospho-p38 expression were observed between naïve and tolerant animals acutely injected with saline or morphine in presence of CFA inflammation. These results suggest that ERK but not p38 could be implicated in the development of morphine tolerance during peripheral inflammation. These experiments could contribute to establish the mechanisms implicated in the development of morphine tolerance in presence of inflammatory pain.

Anti-exudative effects of opioid receptor agonists in a rat model of carrageenan-induced acute inflammation of the paw.

We evaluated the anti-exudative effects (Evan's blue) of mu-, delta- and kappa-opioid receptor agonists in a rat model of carrageenan-induced acute inflammation. The contribution of different components was assessed after the administration of: cyclosporine A, capsaicin, 6-hydroxydopamine, compound 48/80, and specific histamine-receptor antagonists. The results show that the mu-opioid receptor agonists morphine and fentanyl and the delta-opioid receptor agonists DPDPE (enkephalin, [D-Pen(2,5)]) and SNC 80 ((+)-4-[(alpha R)-alpha((2S,5R)-4-allyl-2,5-dimethyl-1-piperazinyl)-3-methoxybenzyl]-N,N diethylbenzamide) decrease plasma extravasation in a dose-dependent manner, with a biphasic response. The effects were reversed by specific antagonists, and are predominantly mediated by peripheral opioid receptors. The integrity of sensory and sympathetic fibres is essential for the anti-exudative effects of fentanyl and DPDPE. Histamine and functional histamine H(2) and H(3) receptors are required for morphine and fentanyl (but not DPDPE) inhibition of plasma extravasation, suggesting different mechanism for mu- and delta-opioid receptor agonists. The present findings implicate multiple sites and mechanisms in the anti-exudative effects of exogenous opioids.

Non-steroidal anti-inflammatory drugs antagonise the constipating effects of tramadol.

We report an antagonistic interaction between tramadol and non-steroidal anti-inflammatory drugs (NSAIDs), on gastrointestinal transit in rats. Transit was evaluated with charcoal and results are expressed as %inhibition. Tramadol and morphine had ED(50)s of 120.70+/-9.54 and 3.20+/-0.26 mg/kg, respectively, while metamizol (85 mg/kg), paracetamol (100 mg/kg) or ibuprofen (50 mg/kg) had no effect. All combinations of tramadol plus an NSAID, resulted in a rightward, non-parallel shift of the curves, which showed (two-way analysis of variance, ANOVA) significant differences from tramadol alone for the dose (P<0.0001), the drug (P<0.0001) and their interaction (P<0.0001), demonstrating antagonism. No interaction was present for morphine plus NSAIDs. The results demonstrate that NSAIDs antagonise the constipating effects of tramadol in rats, a fact that could have clinical relevance when combinations of these drugs are used in pain management in humans.

Interaction between metamizol and tramadol in a model of acute visceral pain in rats.

Tramadol (TRM) and metamizol (MTZ) are drugs with complex mechanisms of action, extensively used in combination in pain management. In the present investigation we have evaluated the interaction between MTZ:TRM in the ethacrinic acid writhing test in rats. Dose-response curves (s.c.) were obtained for each drug individually, combined in fixed potency ratios (1:0.3, 1:1, 1:3), and for MTZ in presence of a fixed-dose of TRM (3.5 mg/kg). Interactions were analysed using isobolograms, interaction indexes (INT-I) and ANOVA. We used naloxone (1 mg/kg s.c.) to determine the opioid-component of the effects (ED80). Isobolograms demonstrated antagonism at the ED20, for 1:0.3 and 1:3 mixtures (p<0.01), whereas 1:1 was additive. At the ED50 and ED80 all combinations showed synergy. Fixed-dose experiments demonstrated that treatment (p<0.0001), dose (p<0.0001), and their interaction (p<0.0001) were statistically significant. Naloxone partially antagonized TRM (67%), but not MTZ; the percentage reversal of the combinations was directly related to the dose of TRM in the combination. The results show that the MTZ:TRM interaction on antinociception is synergistic or antagonistic depending on the level of effect. Synergy is demonstrated at 50% or higher levels, thus supporting the results obtained in humans by our group. Below the ED50 antagonism or additivity is present depending on the ratio of the combination. The mechanisms of the interaction remain unknown.