Different Pain, Different Brain: Thalamic Anatomy in Neuropathic and Non-Neuropathic Chronic Pain Syndromes

Gustin, Sylvia M.; Peck, Chris; Wilcox, Sophie L.; Nash, Penelope; Murray, Greg M.; Henderson, Luke A.

doi:10.1523/jneurosci.5980-10.2011

Cited by 203 publications

(203 citation statements)

References 40 publications

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“…Thalamic reorganization occurs following sectioning of peripheral afferents (Garraghty et al, 1991), sensory thalamus stump representations expand in amputees (Davis et al, 1998), and, following complete spinal cord injury, ventral thalamus cells that would normally respond to inputs from upper extremities respond to inputs from the neck and occiput (Lenz et al, 1987). Since neuropathic pain conditions are associated with changes in thalamic anatomy and biochemistry (Pattany et al, 2002;Gustin et al, 2010Gustin et al, , 2011 and thalamic lesions often result in neuropathic pain (Klit et al, 2009), changes in thalamic function may result in neuropathic pain by altering firing patterns of thalamocortical loops (Sarnthein and Jeanmonod, 2008).…”

Section: Figure6mentioning

confidence: 99%

Pain and Plasticity: Is Chronic Pain Always Associated with Somatosensory Cortex Activity and Reorganization?

et al. 2012

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The somatosensory cortex remodels in response to sensory deprivation, with regions deprived of input invaded by neighboring representations. The degree of cortical reorganization is correlated with ongoing pain intensity, which has led to the assumption that chronic pain conditions are invariably associated with somatosensory cortex reorganization. Because the presentation and etiology of chronic pain vary, we determined whether cortical changes in human subjects are similar for differing pain types. Using functional and anatomical magnetic resonance imaging, we found that, while human patients with neuropathic pain displayed cortical reorganization and changes in somatosensory cortex activity, patients with non-neuropathic chronic pain did not. Furthermore, cortical reorganization in neuropathic pain patients was associated with changes in regional anatomy. These data, by showing that pain per se is not associated with cortical plasticity, suggest that treatments aimed at reversing cortical reorganization should only be considered for use in patients with certain types of chronic pain.

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Section: Figure6mentioning

confidence: 99%

Pain and Plasticity: Is Chronic Pain Always Associated with Somatosensory Cortex Activity and Reorganization?

et al. 2012

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“…There is increasing evidence that TNP is associated with anatomical and biochemical changes in the thalamus (14)(15)(16). Moreover, patients with TNP display significant reductions in thalamic volume and neural viability (15), indicating that altered thalamic anatomy, physiology, and biochemistry may result in disturbed thalamocortical oscillatory properties.…”

mentioning

confidence: 99%

“…Abnormal thalamic activity has been investigated in patients with neuropathic pain (3-7, 10-13, 17, 18), including TNP (14)(15)(16). Furthermore, the potential role of thalamic burst firing in abnormally increased low-frequency oscillations has been proposed as a pathophysiological mechanism (2,12).…”

mentioning

confidence: 99%

Pathophysiological implication of Ca _V 3.1 T-type Ca ²⁺ channels in trigeminal neuropathic pain

Choi

Hwang

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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A crucial pathophysiological issue concerning central neuropathic pain is the modification of sensory processing by abnormally increased low-frequency brain rhythms. Here we explore the molecular mechanisms responsible for such abnormal rhythmicity and its relation to neuropathic pain syndrome. Toward this aim, we investigated the behavioral and electrophysiological consequences of trigeminal neuropathic pain following infraorbital nerve ligations in Ca V 3.1 T-type Ca 2+ channel knockout and wild-type mice. Ca V 3.1 knockout mice had decreased mechanical hypersensitivity and reduced low-frequency rhythms in the primary somatosensory cortex and related thalamic nuclei than wild-type mice. Lateral inhibition of gamma rhythm in primary somatosensory cortex layer 4, reflecting intact sensory contrast, was present in knockout mice but severely impaired in wild-type mice. Moreover, cross-frequency coupling between low-frequency and gamma rhythms, which may serve in sensory processing, was pronounced in wild-type mice but not in Ca V 3.1 knockout mice. Our results suggest that the presence of Ca V 3.1 channels is a key element in the pathophysiology of trigeminal neuropathic pain. In agreement with such MEG findings, the excess power of low-frequency oscillation was marked in local-field potential (LFP) recordings from the thalamus (3-5) and electroencephalogram (EEG) recordings from the cortex (6, 7) of patients with neuropathic pain. In addition, the presence of thalamic burst firing, which is a well-known underlying mechanism for cortical low-frequency oscillations through the thalamocortical recurrent network (8, 9), has been confirmed in patients with neuropathic pain (10-13). Results from small lesions in the posterior part of the central lateral nucleus of the medial thalamus, which reduce tonic hyperpolarization of thalamic neurons in chronic neuropathic pain patients, have also provided insight into the role of low-frequency thalamic rhythmicity in neuropathic pain. Following such interventions, a marked decrease in low-frequency EEG power was observed as well as pain relief (7, 12), indicating that alteration of thalamocortical rhythms plays a crucial role in the development and/or persistence of neuropathic pain.Trigeminal neuropathic pain (TNP) is characterized by unilateral chronic facial pain limited to one or more divisions of the trigeminal nerve. There is increasing evidence that TNP is associated with anatomical and biochemical changes in the thalamus (14-16). Moreover, patients with TNP display significant reductions in thalamic volume and neural viability (15), indicating that altered thalamic anatomy, physiology, and biochemistry may result in disturbed thalamocortical oscillatory properties.Abnormal thalamic activity has been investigated in patients with neuropathic pain (3-7, 10-13, 17, 18), including TNP (14-16). Furthermore, the potential role of thalamic burst firing in abnormally increased low-frequency oscillations has been proposed as a pathophysiological mechanism (2, 12). Because T-type...

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“…In contrast, localised thalamic atrophy was detected in trigeminal neuropathy, but not in patients that were classified as having trigeminal neuralgia or temporomandibular disorders [80]. Using MR spectroscopy in the same study, reduced levels of N-acetyl-aspartate, a marker of neuronal viability was found in the affected thalami.…”

Section: Thalamic Volumetrymentioning

confidence: 84%

“…Using MR spectroscopy in the same study, reduced levels of N-acetyl-aspartate, a marker of neuronal viability was found in the affected thalami. The difference between the direction of thalamic volume changes in trigeminal neuropathy and other pain disorder in the trigeminal territory may lie in the different pathomechanisms; peripheral events were proposed in trigeminal neuralgia and temporomandibular disorder, while the reduced volume and neural viability suggest central mechanisms in trigeminal neuropathy [80]. In a recent study on trigeminal neuralgia gray matter volume reduction was described in the thalamus, insula, anterior cingulate cortex, primary somatosensory and orbitofrontal cortices, secondary somatosensory cortex, cerebellum, and dorsolateral prefrontal cortex [81].…”

Section: Thalamic Volumetrymentioning

confidence: 99%

Macro- and microstructural alterations in migraine and cluster headache

Szabó¹

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Different Pain, Different Brain: Thalamic Anatomy in Neuropathic and Non-Neuropathic Chronic Pain Syndromes

Cited by 203 publications

References 40 publications

Pain and Plasticity: Is Chronic Pain Always Associated with Somatosensory Cortex Activity and Reorganization?

Pain and Plasticity: Is Chronic Pain Always Associated with Somatosensory Cortex Activity and Reorganization?

Pathophysiological implication of Ca _V 3.1 T-type Ca ²⁺ channels in trigeminal neuropathic pain

Macro- and microstructural alterations in migraine and cluster headache

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Different Pain, Different Brain: Thalamic Anatomy in Neuropathic and Non-Neuropathic Chronic Pain Syndromes

Cited by 203 publications

References 40 publications

Pain and Plasticity: Is Chronic Pain Always Associated with Somatosensory Cortex Activity and Reorganization?

Pain and Plasticity: Is Chronic Pain Always Associated with Somatosensory Cortex Activity and Reorganization?

Pathophysiological implication of Ca V 3.1 T-type Ca 2+ channels in trigeminal neuropathic pain

Macro- and microstructural alterations in migraine and cluster headache

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Pathophysiological implication of Ca _V 3.1 T-type Ca ²⁺ channels in trigeminal neuropathic pain