Failure of action potential propagation in sensory neurons: mechanisms and loss of afferent filtering in C‐type units after painful nerve injury

Gemes, Geza; Koopmeiners, Andrew S.; Rigaud, Marcel; Lirk, Philipp; Sapunar, Damir; Bangaru, Madhavi Latha Yadav; Vilceanu, Daniel; Garrison, Sheldon R; Ljubković, Marko; Mueller, Samantha J; Stucky, Cheryl L.; Hogan, Quinn H.

doi:10.1113/jphysiol.2012.242750

Cited by 87 publications

(130 citation statements)

References 92 publications

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“…All testing was completed within three minutes following GFS. On the basis of prior studies and our own collision experiments using this preparation , recording of either a full AP or a reduced electrotonic residue in the soma was considered evidence of successful passage of an AP through the DRG, whereas complete failure of somatic depolarization was interpreted as failure of AP propagation through the DRG.…”

Section: Methodsmentioning

confidence: 99%

“…Third, we determined the ability of the recorded neuron to conduct APs through the DRG, which we quantified by identifying the maximal rate of APs in trains that successfully transited the DRG without AP failure. This last measure is relevant because the T‐junction where the stem axon of the pseudounipolar sensory neuron branches into the peripheral process and central process is a point of low safety factor for AP propagation due to impedance mismatch at that site, by which process the T‐junction functions as a low‐pass filter for afferent sensory traffic .…”

Section: Introductionmentioning

confidence: 99%

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Effect of Electrical Field Stimulation on Dorsal Root Ganglion Neuronal Function

Koopmeiners¹,

Mueller

Kramer

et al. 2013

Neuromodulation: Technology at the Neural Interface

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134

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Effect of Electrical Field Stimulation on Dorsal Root Ganglion Neuronal Function

Koopmeiners¹,

Mueller

Kramer

et al. 2013

Neuromodulation: Technology at the Neural Interface

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134

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“…Electrical stimulation of nerve fibers with 100-Hz bursts is a common stimulation protocol to induce synaptic LTP (Ruscheweyh et al 2011). It has been shown that not all C fibers can follow this high frequency (Fang et al 2005;Gemes et al 2013;Lawson 2002;Raymond et al 1990). However, so far it remains unknown if slowly-conducting muscle and skin afferents differ systematically in their ability to follow electrical HFS.…”

Section: Limitations Of the Studymentioning

confidence: 99%

High-frequency modulation of rat spinal field potentials: effects of slowly conducting muscle vs. skin afferents

Zhang

Hoheisel

Klein

et al. 2016

Journal of Neurophysiology

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Zhang J, Hoheisel U, Klein T, Magerl W, Mense S, Treede RD. High-frequency modulation of rat spinal field potentials: effects of slowly conducting muscle vs. skin afferents. J Neurophysiol 115: 692-700, 2016. First published November 11, 2015 doi:10.1152/jn.00415.2015 in rat spinal dorsal horn neurons was induced by electrical high-frequency stimulation (HFS) of afferent C fibers. LTP is generally assumed to be a key mechanism of spinal sensitization. To determine the contribution of skin and muscle afferents to LTP induction, the sural nerve (SU, pure skin nerve) or the gastrocnemiussoleus nerve (GS, pure muscle nerve) were stimulated individually. As a measure of spinal LTP, C-fiber-induced synaptic field potentials (SFPs) evoked by the GS and by the SU were recorded in the dorsal horn. HFS induced a sustained increase of SFPs of the same nerve for at least 3 h, indicating the elicitation of homosynaptic nociceptive spinal LTP. LTP after muscle nerve stimulation (HFS to GS) was more pronounced (increase to 248%, P Ͻ 0.05) compared with LTP after skin nerve stimulation (HFS applied to SU; increase to 151% of baseline, P Ͻ 0.05). HFS applied to GS also increased the SFPs of the unconditioned SU (heterosynaptic LTP) significantly, whereas HFS applied to SU had no significant impact on the SFP evoked by the GS. Collectively, the data indicate that HFS of a muscle or skin nerve evoked nociceptive spinal LTP with large effect sizes for homosynaptic LTP (Cohen's d of 0.8 -1.9) and small to medium effect sizes for heterosynaptic LTP (Cohen's d of 0.4 -0.65). The finding that homosynaptic and heterosynaptic LTP after HFS of the muscle nerve were more pronounced than those after HFS of a skin nerve suggests that muscle pain may be associated with more extensive LTP than cutaneous pain.

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“…We have identified dysfunction of these processes in axotomized neurons following painful nerve injury, including elevated function of the plasma membrane Ca 2+ -ATPase (PMCA) (Gemes et al, 2012b), accompanied by decreased resting cytoplasmic Ca 2+ ([Ca 2+ ] c ) (Fuchs et al, 2005), reduced function of the sarcoplasmic/endoplasmic reticulum Ca 2+ -ATPase (SERCA) (Duncan et al, 2013) that reduces ER Ca 2+ stores (Gemes et al, 2009; Rigaud et al, 2009), with resulting elevation of store-operated Ca 2+ entry (SOCE) (Gemes et al, 2011) and diminished release of Ca 2+ from stores upon neuronal activity through the process of Ca 2+ -induced Ca 2+ release. Together, these disturbances of Ca 2+ signaling contribute to elevated generation and transmission of high-frequency trains of action potentials in the injured sensory neurons (Gemes et al, 2009; Gemes et al, 2012a; Hogan et al, 2008; Lirk et al, 2008; Sapunar et al, 2005; Tang et al, 2012). …”

Section: Introductionmentioning

confidence: 99%

Divergent effects of painful nerve injury on mitochondrial Ca2+ buffering in axotomized and adjacent sensory neurons

et al. 2014

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Mitochondria critically regulate cytoplasmic Ca2+ concentration ([Ca2+]c), but the effects of sensory neuron injury have not been examined. Using FCCP (1μM) to eliminate mitochondrial Ca2+ uptake combined with oligomycin (10μM) to prevent ATP depletion, we first identified features of depolarization-induced neuronal [Ca2+]c transients that are sensitive to blockade of mitochondrial Ca2+ buffering in order to assess mitochondrial contributions to [Ca2+]c regulation. This established the loss of a shoulder during the recovery of the depolarization (K+)-induced transient, increased transient peak and area, and elevated shoulder level as evidence of diminished mitochondrial Ca2+ buffering. We then examined transients in Control neurons and neurons from the 4th lumbar (L4) and L5 dorsal root ganglia after L5 spinal nerve ligation (SNL). The SNL L4 neurons showed decreased transient peak and area compared to control neurons, while the SNL L5 neurons showed increased shoulder level. Additionally, SNL L4 neurons developed shoulders following transients with lower peaks than Control neurons. Application of FCCP plus oligomycin elevated resting [Ca2+]c in SNL L4 neurons more than in Control neurons. Whereas application of FCCP plus oligomycin 2s after neuronal depolarization initiated mitochondrial Ca2+ release in most Control and SNL L4 neurons, this usually failed to release mitochondrial Ca2+ from SNL L5 neurons. For comparable cytoplasmic Ca2+ loads, the releasable mitochondrial Ca2+ in SNL L5 neurons was less than Control while it was increased in SNL L4 neurons. These findings show diminished mitochondrial Ca2+ buffering in axotomized SNL L5 neurons but enhanced Ca2+ buffering by neurons in adjacent SNL L4 neurons.

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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

Cited by 87 publications

References 92 publications

Effect of Electrical Field Stimulation on Dorsal Root Ganglion Neuronal Function

Effect of Electrical Field Stimulation on Dorsal Root Ganglion Neuronal Function

High-frequency modulation of rat spinal field potentials: effects of slowly conducting muscle vs. skin afferents

Divergent effects of painful nerve injury on mitochondrial Ca2+ buffering in axotomized and adjacent sensory neurons

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