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Failure of action potential propagation in sensory neurons: mechanisms and loss of afferent filtering in C‐type units after painful nerve injury
Author(s) -
Gemes Geza,
Koopmeiners Andrew,
Rigaud Marcel,
Lirk Philipp,
Sapunar Damir,
Bangaru Madhavi Latha,
Vilceanu Daniel,
Garrison Sheldon R.,
Ljubkovic Marko,
Mueller Samantha J.,
Stucky Cheryl L.,
Hogan Quinn H.
Publication year - 2013
Publication title -
the journal of physiology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.802
H-Index - 240
eISSN - 1469-7793
pISSN - 0022-3751
DOI - 10.1113/jphysiol.2012.242750
Subject(s) - dorsal root ganglion , neuroscience , stimulation , sensory system , chemistry , soma , axotomy , anatomy , biology , central nervous system
Key pointsThe peripheral terminals of sensory neurons encode physical and chemical signals into trains of action potentials (APs) and transmit these trains to the CNS. Although modulation of this process is thought to predominantly reside at synapses, there are also indications that AP trains are incompletely propagated past points at which axons branch. One such site is the T‐junction, where the single sensory neuron axon branches into peripheral and central processes. In recordings from sensory neurons of dorsal root ganglia excised from adult rats, we identified use‐dependent failure of AP propagation between the peripheral and central processes that results in filtering of rapid AP trains, especially in C‐type neurons. Propagation failure was regulated by membrane input resistance and Ca 2+ ‐sensitive K + and Cl − currents. Following peripheral nerve injury, T‐junction filtering is reduced in C‐type neurons, which may possibly contribute to pain generation.Abstract  The T‐junction of sensory neurons in the dorsal root ganglion (DRG) is a potential impediment to action potential (AP) propagation towards the CNS. Using intracellular recordings from rat DRG neuronal somata during stimulation of the dorsal root, we determined that the maximal rate at which all of 20 APs in a train could successfully transit the T‐junction (following frequency) was lowest in C‐type units, followed by A‐type units with inflected descending limbs of the AP, and highest in A‐type units without inflections. In C‐type units, following frequency was slower than the rate at which AP trains could be produced in either dorsal root axonal segments or in the soma alone, indicating that the T‐junction is a site that acts as a low‐pass filter for AP propagation. Following frequency was slower for a train of 20 APs than for two, indicating that a cumulative process leads to propagation failure. Propagation failure was accompanied by diminished somatic membrane input resistance, and was enhanced when Ca 2+ ‐sensitive K + currents were augmented or when Ca 2+ ‐sensitive Cl − currents were blocked. After peripheral nerve injury, following frequencies were increased in axotomized C‐type neurons and decreased in axotomized non‐inflected A‐type neurons. These findings reveal that the T‐junction in sensory neurons is a regulator of afferent impulse traffic. Diminished filtering of AP trains at the T‐junction of C‐type neurons with axotomized peripheral processes could enhance the transmission of activity that is ectopically triggered in a neuroma or the neuronal soma, possibly contributing to pain generation.

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