Modulating the delicate glial–neuronal interactions in neuropathic pain: Promises and potential caveats

Tiwari, Vinod; Guan, Yun; Raja, Srinivasa N.

doi:10.1016/j.neubiorev.2014.05.002

Cited by 78 publications

(63 citation statements)

References 100 publications

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“…Neuroprotection is in fact a major function of glia, although the net effect of increased glial activity after injury is often pronociceptive [3,79,80]. The TSPO agonist has been shown to attenuate persistent pain in animal models [10,11].…”

Section: Introductionmentioning

confidence: 99%

Activity-triggered tetrapartite neuron–glial interactions following peripheral injury

Ren

Dubner

2016

Current Opinion in Pharmacology

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Recent studies continue to support the proposition that non-neuronal components of the nervous system, mainly glial cells and associated chemical mediators, contribute to the development of neuronal hyperexcitability that underlies persistent pain conditions. In the event of peripheral injury, enhanced or abnormal nerve input is likely the most efficient way to activate simultaneously central neurons and glia. Injury induces phenotypic changes in glia and triggers signaling cascades that engage reciprocal interactions between presynaptic terminals, postsynaptic neurons, microglia and astrocytes. While some responses to peripheral injury may help the nervous system to adapt positively to counter the disastrous effect of injury, the net effect often leads to long-lasting sensitization of pain transmission pathways and chronic pain.

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Section: Introductionmentioning

confidence: 99%

Activity-triggered tetrapartite neuron–glial interactions following peripheral injury

Ren

Dubner

2016

Current Opinion in Pharmacology

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“…Hence, our results are in agreement with several other recent lines of evidence, suggesting a role for the RAS in the pathophysiology of neuropathic pain. Given that angiotensinogen is synthesized by astrocytes, one might speculate that our findings perhaps indicate glial activation in human neuropathic pain [157,236]. Although many animal studies have shown glial activation in neuropathic pain models, direct evidence for glial involvement in humans has hitherto been almost non-existent [236].…”

Section: From Statistical Models To Biological Hypothesesmentioning

confidence: 87%

“…CNS microglia are thought to be important initiators of neuropathic pain, whereas astrocytes have a role in the maintainance of neuropathic pain [76]. However, there is a knowledge gap between animal models and clinical pain medicine: whereas glial changes are evident in animal models of neuropathic pain, evidence for such changes in humans are almost non-existent, and glial cells (at least astrocytes) from mice and monkeys are quite different from humans [236].…”

Section: The Specific Case Of Neuropathic Painmentioning

confidence: 99%

The Cerebrospinal Fluid in Severe Pain Conditions : Clinical, Pharmacological and Proteomic Aspects

Bäckryd¹

2015

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The treatment of both cancer pain and non-cancer chronic pain is still suboptimal. The overall aim of this PhD thesis was to conduct translational pain research at the interface between clinical pain medicine and the field of human proteomics, using the practice of intrathecal analgesia at our institution as a starting point. Hence, the cerebrospinal fluid (CSF) is at the centre of the present dissertation, both as a target for infusing analgesics (Papers I and II – clinical and pharmacological aspects) and as an important biofluid for human biomarker studies (Papers III and IV – proteomic aspects). In Paper I, 28 cases of intrathecal analgesia in cancer patients were prospectively followed. Movement-evoked breakthrough pain remained a major clinical problem throughout the study month despite otherwise successful intrathecal analgesia (defined as good control of spontaneous resting pain paralleled by a marked decrease of concomitant systemic opioid doses). This study therefore illustrates the importance of considering not only spontaneous resting pain but also movement-evoked breakthrough pain. In Paper II, an expert-based algorithm for trialing the intrathecal analgesic ziconotide by bolus injections was evaluated in an open-label study of 23 patients with chronic neuropathic pain. We found few responders (13%) according to the strict criteria of the algorithm, but ziconotide bolus injection trialing seems feasible. The predictive power of ziconotide bolus trialing remains unclear, and the pharmacological profile of ziconotide (with very slow tissue penetration due to high hydrophilicity) calls the rationale for ziconotide bolus trialing into question. In Paper III, we found low levels of beta-endorphin in the CSF of chronic neuropathic pain patients (n=15) compared to healthy controls (n=19). We speculate that this might indicate dysfunctional top-down control of nociception. Substance P levels in the CSF did not differ by univariate statistics. In Paper IV, the CSF proteome of 11 patients with chronic neuropathic pain and 11 healthy controls was exploratively studied, combining gel-based proteomics with multivariate data analysis. After eliminating four proteins associated with age, 32 proteins were found to highly discriminate between groups. Among these, the seven proteins having the highest discriminatory power between patients and controls were: one isoform of angiotensinogen, two isoforms of alpha-1-antitrypsin, three isoforms of haptoglobin, and one isoform of pigment epithelium-derived factor. In conclusion, this PhD thesis demonstrates the fruitfulness of studying the CSF, both as a target for infusing analgesics and as a potential mirror of the neurobiological processes involved in pathological pain conditions. The thesis points to the need for more research into the mechanisms of different pain conditions, in order to hopefully achieve the vision of mechanism-based pain diagnoses

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“…1 Previous studies reported that blockade of the activation of spinal microglia and astrocytes attenuated pain hypersensitivity. Peripheral nerve injury leads to activation of microglia and astrocytes, and this activation can contribute to the amplification of pain via the production and release of proinflammatory cytokines and neuroexcitatory substances.…”

Section: Intrathecal Injection Of Pudk-hgf Inhibited Spinal Glial Cmentioning

confidence: 99%

Gene therapy for neuropathic pain induced by spared nerve injury with naked plasmid encoding hepatocyte growth factor

Lu²,

Cheng³

et al. 2017

The Journal of Gene Medicine

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Modulating the delicate glial–neuronal interactions in neuropathic pain: Promises and potential caveats

Cited by 78 publications

References 100 publications

Activity-triggered tetrapartite neuron–glial interactions following peripheral injury

Activity-triggered tetrapartite neuron–glial interactions following peripheral injury

The Cerebrospinal Fluid in Severe Pain Conditions : Clinical, Pharmacological and Proteomic Aspects

Gene therapy for neuropathic pain induced by spared nerve injury with naked plasmid encoding hepatocyte growth factor

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