An update on the spinal and peripheral pathways of pain signalling

AbstractPainful or potentially tissue-damaging stimuli are detected by primary sensory afferents that innervate the skin as well as internal tissues. The neurons that give rise to sensory afferents are located in the dorsal root ganglia (DRG) and transmit sensory information to the spinal cord where it is processed and further relayed to higher brain regions to ultimately generate the perception of pain. Both the DRGs as well as the spinal cord comprise a variety of morphologically, molecularly and functionally diverse neurons. The objective of this review is to provide an overview of the different types of sensory neurons and their proposed role in pain signalling. Moreover, I will discuss how pain related sensory information is processed in the dorsal horn of the spinal cord with an emphasis on recently delineated neural circuits that mediate pain hypersensitivity in the setting of nerve injury and inflammation.

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AMPK controls the axonal regenerative ability of dorsal root ganglia sensory neurons after spinal cord injury

Nature Metabolism ◽

10.1038/s42255-020-0252-3 ◽

2020 ◽

Vol 2 (9) ◽

pp. 918-933

Author(s):

Guiping Kong ◽

Luming Zhou ◽

Elisabeth Serger ◽

Ilaria Palmisano ◽

Francesco De Virgiliis ◽

...

Keyword(s):

Spinal Cord ◽

Spinal Cord Injury ◽

Sensory Neurons ◽

Dorsal Root Ganglia ◽

Dorsal Root ◽

Cord Injury ◽

Regenerative Ability

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2D vs 3D morphological analysis of dorsal root ganglia in health and painful neuropathy

European Journal of Histochemistry ◽

10.4081/ejh.2021.3276 ◽

2021 ◽

Vol 65 (s1) ◽

Author(s):

Valentina Alda Carozzi ◽

Chiara Salio ◽

Virginia Rodriguez-Menendez ◽

Elisa Ciglieri ◽

Francesco Ferrini

Keyword(s):

Sensory Neurons ◽

Dorsal Root Ganglia ◽

Dorsal Root ◽

Sensory Information ◽

Painful Neuropathy ◽

Tissue Slices ◽

Satellite Glial Cells ◽

Whole Mount ◽

Functional Features ◽

Neurochemical Changes

Dorsal root ganglia (DRGs) are clusters of sensory neurons that transmit the sensory information from the periphery to the central nervous system, and satellite glial cells (SGCs), their supporting trophic cells. Sensory neurons are pseudounipolar neurons with a heterogeneous neurochemistry reflecting their functional features. DRGs, not protected by the blood brain barrier, are vulnerable to stress and damage of different origin (i.e., toxic, mechanical, metabolic, genetic) that can involve sensory neurons, SGCs or, considering their intimate intercommunication, both cell populations. DRG damage, primary or secondary to nerve damage, produces a sensory peripheral neuropathy, characterized by neurophysiological abnormalities, numbness, paraesthesia and dysesthesia, tingling and burning sensations and neuropathic pain. DRG stress can be morphologically detected by light and electron microscope analysis with alterations in cell size (swelling/atrophy) and in different sub-cellular compartments (i.e., mitochondria, endoplasmic reticulum, and nucleus) of neurons and/or SGCs. In addition, neurochemical changes can be used to portray abnormalities of neurons and SGC. Conventional immunostaining, i.e., immunohistochemical detection of specific molecules in tissue slices can be employed to detect, localize and quantify particular markers of damage in neurons (i.e., nuclear expression ATF3) or SGCs (i.e., increased expression of GFAP), markers of apoptosis (i.e., caspases), markers of mitochondrial suffering and oxidative stress (i.e., 8-OHdG), markers of tissue inflammation (i.e., CD68 for macrophage infiltration), etc. However classical (2D) methods of immunostaining disrupt the overall organization of the DRG, thus resulting in the loss of some crucial information. Whole-mount (3D) methods have been recently developed to investigate DRG morphology and neurochemistry without tissue slicing, giving the opportunity to study the intimate relationship between SGCs and sensory neurons in health and disease. Here, we aim to compare classical (2D) vs whole-mount (3D) approaches to highlight “pros” and “cons” of the two methodologies when analysing neuropathy-induced alterations in DRGs.

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Experimental Porcine Polioencephalomyelitis in Germfree Pigs

Pathologia veterinaria ◽

10.1177/030098586700400207 ◽

1967 ◽

Vol 4 (2) ◽

pp. 186-198

Author(s):

John F. Long ◽

Adalbert Koestner ◽

Leopold Liss

Keyword(s):

Spinal Cord ◽

Sensory Neurons ◽

Dorsal Root Ganglia ◽

Motor Neurons ◽

Dorsal Root ◽

Ganglion Cells ◽

Silver Impregnation ◽

Microglial Cells ◽

Regressive Phase

The neuronal changes and glial response in the spinal cord were studied by silver impregnation techniques in 23 germfree pigs orally infected with a porcine polioencephalomyelitis viras. By the sixth day swelling occurred in motor neurons. During the next 24 to 96 hours this progressed to diffuse chromatolysis, vesiculation, necrosis, and neuronophagia in massive areas of the ventral horns. Massive degeneration of axons in tracts originating in the ventral horns and from dorsal root ganglia correlated well with the extensive destruction of both motor and sensory neurons. The initial responses to necrosis of ganglion cells were infiltration and proliferation of microglial cells. As active neuronal destruction ceased (about two weeks following infection) the microglial reaction began to decline and proliferative astrocytosis became the predominant feature. The paucity of surviving neurons in the ventral horns, and the density of the mesh of astrocytic processes marked the chronic regressive phase of the disease.

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Painful Nerve Injury Decreases Resting Cytosolic Calcium Concentrations in Sensory Neurons of Rats

Anesthesiology ◽

10.1097/00000542-200506000-00023 ◽

2005 ◽

Vol 102 (6) ◽

pp. 1217-1225 ◽

Cited By ~ 33

Author(s):

Andreas Fuchs ◽

Philipp Lirk ◽

Cheryl Stucky ◽

Stephen E. Abram ◽

Quinn H. Hogan

Keyword(s):

Nerve Injury ◽

Sensory Neurons ◽

Dorsal Root Ganglia ◽

Dorsal Root ◽

Sensory Information ◽

Cytosolic Calcium ◽

Skin Incision ◽

Cellular Level ◽

Spinal Nerve ◽

Control Group

Background Neuropathic pain is difficult to treat and poorly understood at the cellular level. Although cytoplasmic calcium ([Ca]c) critically regulates neuronal function, the effects of peripheral nerve injury on resting sensory neuronal [Ca]c are unknown. Methods Resting [Ca]c was determined by microfluorometry in Fura-2 AM-loaded neurons dissociated from dorsal root ganglia of animals with hyperalgesia to mechanical stimulation after spinal nerve ligation and section (SNL) at the fifth and sixth lumbar (L5 and L6) levels and from animals after skin incision alone (control group). Axotomized neurons from the L5 dorsal root ganglia were examined separately from adjacent L4 neurons that share the sciatic nerve with degenerating L5 fibers. Results After SNL, large (34 mum or larger) neurons from the L4 ganglion showed a 29% decrease in resting [Ca]c, whereas those from the L5 ganglion showed a 54% decrease. Small neurons only showed an effect of injury in the axotomized L5 neurons, in which resting [Ca]c decreased by 30%. A decrease in resting [Ca]c was not seen in neurons isolated from rats in which hyperalgesia did not develop after SNL. In separate experiments, SNL reduced resting [Ca]c in capsaicin-insensitive neurons of the L5 ganglion by 60%, but there was no change in neurons from L4. Resting [Ca]c of capsaicin-sensitive neurons was not affected by injury in either ganglion. SNL injury decreased the proportion of neurons sensitive to capsaicin in the L5 group but increased the proportion in the L4 group. Conclusions Painful SNL nerve injury depresses resting [Ca]c in sensory neurons. This is most marked in axotomized neurons, especially the large and capsaicin-insensitive neurons presumed to transmit non-nociceptive sensory information.

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