Activation of 5‐HT<sub>1B/1D</sub> receptor in the periaqueductal gray inhibits nociception

Bartsch, Thorsten; Knight, Yolande E.; Goadsby, Peter J.

doi:10.1002/ana.20193

Cited by 172 publications

(129 citation statements)

References 83 publications

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“…Because there are certainly differences in the central consequences of complete transection versus chronic constriction injury, it will be of great interest to determine whether dorsal horn 5-HT 1D -IR is regulated differently in the latter model of neuropathic pain. Together with other reports that triptans are differentially analgesic for pain after activation of trigeminal afferents, we cannot exclude the possibility of a differential regulation of 5-HT 1D receptor in the trigeminal nucleus, or the differential activation of descending nociceptive controls by triptans (Cumberbatch et al, 1998;Bartsch et al, 2004).…”

Section: Are Triptans General Analgesics?mentioning

confidence: 61%

“…In the periphery, triptans prevent or block neurogenic inflammation (Moskowitz, 1993;Bolay et al, 2002), at least in part, by inhibiting the release of substance P (SP) and CGRP from peptidergic afferents (Buzzi et al, 1991). There is also evidence for a central action of triptans (Kaube et al, 1993;Shepheard et al, 1995), including presynaptic regulation of neurotransmitter release from the central terminals of primary afferents in the trigeminal nucleus caudalis (Jennings et al, 2004;Levy et al, 2004), postsynaptic regulation of the responses of caudalis neurons to glutamate or an NMDA agonist (Goadsby et al, 2001), and activation of triptan receptors expressed by pain-modulatory neurons in the periaqueductal gray (Bartsch et al, 2004).…”

Section: Introductionmentioning

confidence: 99%

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Tissue Injury Regulates Serotonin 1D Receptor Expression: Implications for the Control of Migraine and Inflammatory Pain

Ahn

Basbaum²

2006

J. Neurosci.

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The anti-migraine action of "triptan" drugs involves the activation of serotonin subtype 1D (5-HT 1D ) receptors expressed on "painresponsive" trigeminal primary afferents. In the central terminals of these nociceptors, the receptor is concentrated on peptidergic dense core vesicles (DCVs) and is notably absent from the plasma membrane. Based on this arrangement, we hypothesized that in the resting state the receptor is not available for binding by a triptan, but that noxious stimulation of these afferents could trigger vesicular release of DCVs, thus externalizing the receptor. Here we report that within 5 min of an acute mechanical stimulus to the hindpaw of the rat, there is a significant increase of 5-HT 1D -immunoreactivity (IR) in the ipsilateral dorsal horn of the spinal cord. We suggest that these rapid immunohistochemical changes reflect redistribution of sequestered receptor to the plasma membrane, where it is more readily detected. We also observed divergent changes in 5-HT 1D -IR in inflammatory and nerve-injury models of persistent pain, occurring at least in part through the regulation of 5-HT 1D -receptor gene expression. Finally, we found that 5-HT 1D -IR is unchanged in the spinal cord dorsal horn of mice with a deletion of the gene encoding the neuropeptide substance P. This result differs from that reported for the Ѩ-opioid receptor, which is also sorted to DCVs, but is greatly reduced in preprotachykinin mutant mice. We suggest that a "pain"-triggered regulation of 5-HT 1D -receptor expression underlies the effectiveness of triptans for the treatment of migraine. Moreover, the widespread expression of 5-HT 1D receptor in somatic nociceptive afferents suggests that triptans could, in certain circumstances, treat pain in nontrigeminal regions of the body.

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Section: Are Triptans General Analgesics?mentioning

confidence: 61%

Section: Introductionmentioning

confidence: 99%

Tissue Injury Regulates Serotonin 1D Receptor Expression: Implications for the Control of Migraine and Inflammatory Pain

Ahn

Basbaum²

2006

J. Neurosci.

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“…The authors acknowledged that this experiment did not exclude the interesting possibility of triptan action on an intrinsic interneuron that modulates the activity of the neuron in question. Perhaps the most direct evidence for multiple CNS sites of triptan action is the report that microinjection of naratriptan into the periaqueductal gray selectively inhibits durally-evoked nociceptive responses of TNC neurons with shared dural and facial receptive fields (Bartsch et al, 2004).…”

Section: Cns Mechanisms Of Tripan Actionmentioning

confidence: 99%

Where do triptans act in the treatment of migraine?

Ahn

Basbaum

2005

Pain

110

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Migraine headache is a pervasive but poorly understood primary pain disorder. Sumatriptan and the 'triptan' class of serotonin receptor subtype-selective drugs have well-established efficacy in treating the pain of migraine. Although sumatriptan was originally selected to target vasoactive properties thought to be fundamental to the etiology of migraine, other studies point to an action of triptans at several levels of the nervous system. To this day, however, it is not clear whether the antimigraine activity of the triptans involves an action only in the periphery or in the CNS as well. Because sumatriptan is hydrophilic, it penetrates the blood-brain barrier poorly, suggesting a peripheral site of action. On the other hand, it has been proposed that the barrier is compromised in migraineurs, so a CNS site of action has not been ruled out. Finally, the basis for the apparent selectivity of triptans in the treatment of migraine pain but not other kinds of somatic pain is still not understood. Determining that mechanism of triptan action will likely provide important new insights into the unique and essential features of migraine. Graham and Wolff (1938) first proposed that the pain of migraine results from abnormal cranial vascular distention. They were influenced by (1) the association between migraine relieving properties of ergotamine tartrate infusion and arterial vasoconstriction and (2) the finding that compression of the common carotid artery or superficial temporal artery reduces pain in many migraine attacks. Although the relationship between vascular changes and migraine was still uncertain, the vasoactive, serotonergic properties of ergotamine on isolated artery and vein preparations led to the development of sumatriptan, a serotonergic agonist with selective activity on 5-HT 1B , 5-HT 1D , and 5-HT 1F receptors. The vasoconstrictive properties of triptans are mediated by an action on 5-HT 1B in arterial smooth muscle. On the other hand, although sumatriptan-mediated vasoconstriction can dose-dependently increase blood flow velocity in middle cerebral vessels, because these vascular changes are not temporally related to the resolution of the migraine attack (Limmroth et al., 1996), it is still unclear whether triptan activation of vascular 5-HT 1B receptors is necessary for the treatment of migraine. Peripheral mechanismsThe triptans are also thought to inhibit the abnormal activation of peripheral nociceptors. In an experimental model of migraine, called sterile neurogenic inflammation, an abnormal activation of nociceptors in the dura mater triggers vascular changes, including plasma protein *

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“…The receptive field was assessed for both non-noxious, with gentle brushing, and noxious inputs; the latter was assessed by pinching with forceps or applying heavy pressure that was painful when applied to humans. When a neuron sensitive to stimulation of the ophthalmic dermatome of the trigeminal nerve was identified, it was tested for convergent input from the dura mater (Bartsch et al, 2004). According to the cutaneous receptive field properties, neurons were classified as low-threshold mechanoreceptors that responded only to innocuous stimulation, nociceptivespecific receptors that responded to only noxious input, or widedynamic range that responded to both noxious and non-noxious stimuli (Hu et al, 1981).…”

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confidence: 99%

Cannabinoid (CB₁) Receptor Activation Inhibits Trigeminovascular Neurons

Akerman

Holland²,

Goadsby³

2006

J Pharmacol Exp Ther

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Migraine is a common and disabling neurological disorder that involves activation or the perception of activation of the trigeminovascular system. Cannabinoid (CB) receptors are present in brain and have been suggested to be antinociceptive. Here we determined the effect of cannabinoid receptor activation on neurons with trigeminovascular nociceptive input in the rat. Neurons in the trigeminocervical complex (TCC) were studied using extracellular electrophysiological techniques. Responses to both dural electrical stimulation and cutaneous facial receptive field activation of the ophthalmic division of the trigeminal nerve and the effect of cannabinoid agonists and antagonists were studied. Nonselective CB receptor activation withinhibited neuronal responses to A-(by 52%) and C-fiber (by 44%) afferents, an effect blocked by the CB 1 receptor antagonist SR141716 [N-(piperidin-1-yl)-5-(4-chlorophenyl)-1-(2,4-dichlorophenyl)-4-methyl-1H-pyrazole-3-carboxamide; 3 mg kg Ϫ1 ] but not the CB 2 receptor antagonist AM630 (6-iodopravadoline; 3 mg kg Ϫ1 ). Anandamide (10 mg kg Ϫ1 ) was able to inhibit both A-and C-fiber-elicited TCC firing, only after transient receptor potential vanilloid 1 receptor inhibition. Activation of cannabinoid receptors had no effect on cutaneous receptive fields when recorded from TCC neurons. The data show that manipulation of CB 1 receptors can affect the responses of trigeminal neurons with A-and C-fiber inputs from the dura mater. This may be a direct effect on neurons in the TCC itself or an effect in discrete areas of the brain that innervate these neurons. The data suggest that CB receptors may have therapeutic potential in migraine, cluster headache, or other primary headaches, although the potential hazards of psychoactive side effects that accompany cannabinoid treatments may be complex to overcome.

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Activation of 5‐HT_1B/1D receptor in the periaqueductal gray inhibits nociception

Cited by 172 publications

References 83 publications

Tissue Injury Regulates Serotonin 1D Receptor Expression: Implications for the Control of Migraine and Inflammatory Pain

Tissue Injury Regulates Serotonin 1D Receptor Expression: Implications for the Control of Migraine and Inflammatory Pain

Where do triptans act in the treatment of migraine?

Cannabinoid (CB₁) Receptor Activation Inhibits Trigeminovascular Neurons

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Activation of 5‐HT1B/1D receptor in the periaqueductal gray inhibits nociception

Cited by 172 publications

References 83 publications

Tissue Injury Regulates Serotonin 1D Receptor Expression: Implications for the Control of Migraine and Inflammatory Pain

Tissue Injury Regulates Serotonin 1D Receptor Expression: Implications for the Control of Migraine and Inflammatory Pain

Where do triptans act in the treatment of migraine?

Cannabinoid (CB1) Receptor Activation Inhibits Trigeminovascular Neurons

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Product

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Activation of 5‐HT_1B/1D receptor in the periaqueductal gray inhibits nociception

Cannabinoid (CB₁) Receptor Activation Inhibits Trigeminovascular Neurons