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The development of analgesic tolerance to opioids is an important limitation in the management of chronic pain. Spinal cord glial cell activation appears to play a pivotal role in the development and maintenance of opioid tolerance, indicating the presence of an opioid-induced neuronal-glial interaction; however, how opioids drive this cross-talk is still elusive. In search of treatments to attenuate morphine analgesic tolerance, our research focused on the role of Notch signaling pathway, one of the most important mechanisms of cell-to-cell interactions, in the spinal dorsal horn after morphine repeated exposure and whether Notch inhibition attenuates morphine analgesic tolerance. Double immunofluorescence experiments on spinal sections from morphine-tolerant mice showed a neuronal localization of Notch-1 receptor whereas the Notch ligand Jagged was localized on neighboring astrocytes. Morphine-induced μ opioid receptor (MOR) stimulation triggered Notch-1 signaling activation and this event was mediated by astrocyte JNK activation. Notch-1 activation selectively reduced the expression of histone deacetylase (HDAC)-1, resulting in an overphosphorylation of PKC and ERK, kinases involved in MOR phosphorylation and internalization after repeated morphine exposure. Notch-1 signaling inhibition, through intrathecal administration of the γ-secretase inhibitor, DAPT, counteracted PKC and ERK overphosphorylation, MOR internalization, and analgesic tolerance. Conversely, the HDAC-1 inhibitor, LG325, further aggravated MOR internalization, PKC overphosphorylation, and analgesic tolerance.Our findings implicate the MOR-triggered Notch-1 signaling in promoting MOR internalization and morphine analgesic tolerance by epigenetic regulation mechanisms. These data suggest that Notch-1 inhibitors could represent an innovative therapeutic perspective for the management of opioid tolerance in chronic pain therapy.
To assess the efficacy of erenumab across the spectrum of response thresholds (≥50%, ≥75%, 100%) based on monthly migraine days (MMD) reduction in patients with chronic migraine from a 12-week, randomized study (NCT02066415).
Pain and cartilage destruction caused by rheumatoid arthritis (RA) are major challenges during clinical treatment. Traditional systemic administration not only has obvious side effects but also provides limited relief for local symptoms in major joints. Local delivery of therapeutics for RA treatment is a potential strategy but is limited by rapid intraarticular release.
It is known that perivascular application of CGRP induces cerebral vasodilatation. However, it is unclear whether intravenous alfa CGRP (αCGRP) induces changes in cerebral and systemic hemodynamics. Therefore, we studied the influence of an αCGRP intravenous infusion at a rate of 1.5 mcg/min in 20 min on mean arterial velocity in the middle cerebral artery (vm MCA) and in the posterior cerebral artery (vm PCA) in twenty healthy subjects using transcranial Doppler (TCD). We found out that αCGRP decreased vm MCA ( < 0.001), vm PCA ( < 0.001), mean arterial pressure (MAP) ( < 0.001) and end-tidal CO (Et-CO) ( = 0.030). The heart rate (HR) increased during αCGRP infusion ( < 0.001). In addition, we found a positive relationship between Et-CO and vm MCA ( = 0.001) as well as vm PCA ( = 0.043). In our view, αCGRP induces changes in cerebral and systemic circulation in healthy volunteers. It might cause vasodilatation of MCA and PCA and a compensatory decrease of Et-CO to αCGRP related hemodynamic changes.
Severe chronic postsurgical pain has a prevalence of 4-10% in the surgical population. The underlying nociceptive mechanisms have not been well characterized. Following the late resolution phase of an inflammatory injury, high-dose μ-opioid-receptor inverse agonists reinstate hypersensitivity to nociceptive stimuli. This unmasking of latent pain sensitization has been a consistent finding in rodents while only observed in a limited number of human volunteers. Latent sensitization could be a potential triggering venue in chronic postsurgical pain. The objective of the present trial was in detail to examine the association between injury-induced secondary hyperalgesia and naloxone-induced unmasking of latent sensitization. Healthy volunteers (n = 80) received a cutaneous heat injury (47°C, 420 s, 12.5 cm2). Baseline secondary hyperalgesia areas were assessed 1 h post-injury. Utilizing an enriched enrollment design, subjects with a magnitude of secondary hyperalgesia areas in the upper quartile ('high-sensitizers' [n = 20]) and the lower quartile ('low-sensitizers' [n = 20]) were selected for further study. In four consecutive experimental sessions (Sessions 1 to 4), the subjects at two sessions (Sessions 1 and 3) received a cutaneous heat injury followed 168 h later (Sessions 2 and 4) by a three-step target-controlled intravenous infusion of naloxone (3.25 mg/kg), or normal saline. Assessments of secondary hyperalgesia areas were made immediately before and stepwise during the infusions. Simple univariate statistics revealed no significant differences in secondary hyperalgesia areas between naloxone and placebo treatments (P = 0.215), or between 'high-sensitizers' and 'low-sensitizers' (P = 0.757). In a mixed-effects model, secondary hyperalgesia areas were significantly larger following naloxone as compared to placebo for 'high-sensitizers' (P < 0.001), but not 'low-sensitizers' (P = 0.651). Although we could not unequivocally demonstrate naloxone-induced reinstatement of heat injury-induced hyperalgesia, further studies in clinical postsurgical pain models are warranted.
The current review provides a recapitulation of recent advances in pharmacological neuroimaging in headache, a promising tool to understanding of how a drug works in the brain and how it may lead to new insights of disease mechanisms of headache.
Anti-GD2 therapy with dinutuximab is effective in improving the survival of high-risk neuroblastoma patients in remission and after relapse. However, allodynia is the major dose-limiting side effect, hindering its use for neuroblastoma patients at higher doses and for other GD2-expressing malignancies. As polyamines can enhance neuronal sensitization, including development of allodynia and other forms of pathological pain, we hypothesized that polyamine depletion might prove an effective strategy for relief of anti-GD2 induced allodynia.
As a field, psychiatry is undergoing an exciting paradigm shift toward early identification and intervention that will likely minimize both the burden associated with severe mental illnesses as well as their duration. In this context, the rapid-acting antidepressant ketamine has revolutionized our understanding of antidepressant response and greatly expanded the pharmacologic armamentarium for treatment-resistant depression. Efforts to characterize biomarkers of ketamine response support a growing emphasis on early identification, which would allow clinicians to identify biologically enriched subgroups with treatment-resistant depression who are more likely to benefit from ketamine therapy. This chapter presents a broad overview of a range of translational biomarkers, including those drawn from imaging and electrophysiological studies, sleep and circadian rhythms, and HPA axis/endocrine function as well as metabolic, immune, (epi)genetic, and neurotrophic biomarkers related to ketamine response. Ketamine's unique, rapid-acting properties may serve as a model to explore a whole new class of novel rapid-acting treatments with the potential to revolutionize drug development and discovery. However, it should be noted that although several of the biomarkers reviewed here provide promising insights into ketamine's mechanism of action, most studies have focused on acute rather than longer-term antidepressant effects and, at present, none of the biomarkers are ready for clinical use.
An imbalance in perioperative cytokine response may cause acute pain and postoperative complications. Anesthetic drugs modulate this cytokine response, but their role in non-major breast cancer surgery is unclear. In an exploratory study, we investigated whether intravenous lidocaine and dexamethasone could modulate the cytokine response into an anti-inflammatory direction. We also evaluated interrelationships between cytokine levels, pain scores and postoperative complications. Our goal is to develop multimodal analgesia regimens optimizing outcome after breast cancer surgery.
Dihydroergotamine (DHE) is an ergot alkaloid derivative of substances produced by rye fungus. Ergotamine was first used in the field of gynecology and obstetrics, then used for migraine treatment a few years later. DHE was developed as a derivative of ergotamine. DHE, when compared to ergotamine, demonstrates greater alpha-adrenergic antagonist activity, lower arterial vasoconstriction, less dopaminergic agonism, and lower emetic potential. DHE can be delivered via several routes including intravenous (IV), intramuscular (IM), subcutaneous (SC), intranasal (IN), oral, and orally inhaled (although the latter two are not available in the USA and the last remains experimental only). DHE can be used in an outpatient basis in infusion centers, emergency departments, and urgent care centers, as well as inpatient treatment for admitted patients. There are protocols for adults as well as pediatric migraine treatment. DHE and other ergot alkaloids are considered contraindicated in pregnant women as they decrease uterine blood flow and increase uterine muscle contractility predisposing to spontaneous abortion. DHE during lactation is also not recommended as it can lead to gastrointestinal distress and weakness in infants; it can also suppress milk production. Caution should be taken before administering DHE in patients with cardiovascular risk factors. DHE is an older drug with an interesting history, yet it is still clinically useful today for patients with migraine attacks not responsive to triptans, who have a greater burden from migraine, and in refractory migraine.