Fred Schwaller scite author profile

Pain in infancy influences pain reactivity in later life, but how and why this occurs is poorly understood. Here we review the evidence for developmental plasticity of nociceptive pathways in animal models and discuss the peripheral and central mechanisms that underlie this plasticity. Adults who have experienced neonatal injury display increased pain and injury-induced hyperalgesia in the affected region but mild injury can also induce widespread baseline hyposensitivity across the rest of the body surface, suggesting the involvement of several underlying mechanisms, depending upon the type of early life experience. Peripheral nerve sprouting and dorsal horn central sensitization, disinhibition and neuroimmune priming are discussed in relation to the increased pain and hyperalgesia, while altered descending pain control systems driven, in part, by changes in the stress/HPA axis are discussed in relation to the widespread hypoalgesia. Finally, it is proposed that the endocannabinoid system deserves further attention in the search for mechanisms underlying injury-induced changes in pain processing in infants and children.

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USH2A is a Meissner’s corpuscle protein necessary for normal vibration sensing in mice and humans

Schwaller

Bégay

García‐García

et al. 2020

Nat Neurosci

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Targeting p38 Mitogen-activated Protein Kinase to Reduce the Impact of Neonatal Microglial Priming on Incision-induced Hyperalgesia in the Adult Rat

Schwaller

Beggs²,

Walker

2015

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The developmental emergence of differential brainstem serotonergic control of the sensory spinal cord

Schwaller

Kanellopoulos²,

Fitzgerald³

2017

Sci Rep

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Descending connections from brainstem nuclei are known to exert powerful control of spinal nociception and pain behaviours in adult mammals. Here we present evidence that descending serotonergic fibres not only inhibit nociceptive activity, but also facilitate non-noxious tactile activity in the healthy adult rat spinal dorsal horn via activation of spinal 5-HT3 receptors (5-HT3Rs). We further show that this differential serotonergic control in the adult emerges from a non-modality selective system in young rats. Serotonergic fibres exert background 5-HT3R mediated facilitation of both tactile and nociceptive spinal activity in the first three postnatal weeks. Thus, differential descending serotonergic control of spinal touch and pain processing emerges in late postnatal life to allow flexible and context-dependent brain control of somatosensation.

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Postnatal maturation of the spinal-bulbo-spinal loop

Schwaller

Kwok

Fitzgerald

2016

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Fred Schwaller

The consequences of pain in early life: injury‐induced plasticity in developing pain pathways

USH2A is a Meissner’s corpuscle protein necessary for normal vibration sensing in mice and humans

Targeting p38 Mitogen-activated Protein Kinase to Reduce the Impact of Neonatal Microglial Priming on Incision-induced Hyperalgesia in the Adult Rat

The developmental emergence of differential brainstem serotonergic control of the sensory spinal cord

Postnatal maturation of the spinal-bulbo-spinal loop

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