3-2-01. Decreased motor axonal potassium currents in peripheral nerve hyperexcitability syndrome with negativity for anti-VGKC antibody and positivity for anti-CRMP5 antibody

Publication date: June 2017
Source:Clinical Neurophysiology, Volume 128, Issue 6
Author(s): Tomoko Nakazato, Kazuaki Kanai, Kenya Nishioka, Motoki Fujimaki, Genko Oyama, Yasushi Shimo, Kazumasa Yokoyama, Nobutaka Hattori
Peripheral nerve hyperexcitability (PNH) syndromes are caused by spontaneous discharges originating from motor axons. Antibodies against voltage-gated potassium channels (VGKC) are detected in some patients with PNH syndrome, but the cause in the remaining patients has not yet been clarified. The index patient was a 46-year-old female with recurred thymoma and myasthenia gravis. Six month after the start of chemotherapy, she developed myokymia, fasciculations and muscle cramps in both her lower limbs. A nerve conduction studies revealed mild axonal polyneuropathy and a motor F-wave examination showed marked after-discharges. Needle electromyography showed fasciculation potentials and myokymic discharges. From these results, the patient was diagnosed with PNH syndrome. Nerve excitability study showed extremely greater supernormality in the recovery cycle and greater changes in depolarizing threshold electrotonus than control, suggesting decreased slow potassium currents in the motor axons. Serological tests revealed the absence of anti-VGKC antibody and the presence of anti-collapsin response mediator protein 5 (CRMP5) antibody. A recent study reported that CRMP5 plays an important role in axon–Schwann cell cooperation during development and nerve regeneration. The coexistence of nerve regeneration and anti-CRMP5 antibody may cause abnormal axon–Schwann cell interaction, which would result in slow potassium channel dysfunction and associated symptoms such as myokymia.



from Physiology via xlomafota13 on Inoreader http://ift.tt/2pANVCn
via IFTTT