[Clinical features of neuroferritinopathy].

Neuroferritinopathy is an autosomal dominant basal ganglia disease with iron accumulation caused by a mutation of the gene encoding ferritin light polypeptide (FTL). Six pathogenic mutations in the FTL gene have so far been reported. One such mutation was found in a Japanese family, thus suggesting that a new mutation in the FTL gene can therefore occur anywhere in the world. The typical clinical features of neuroferritinopathy are dystonia (especially orofacial dystonia related to speech and leading to dysarthrophonia) and involuntary movement, but such features vary greatly among the affected individuals. The findings of excess iron storage and cystic changes involving the globus pallidus and the putamen on brain MRI. and low serum ferritin levels are characteristic in neuroferritinopathy. Brain histochemistry shows abnormal aggregates of ferritin and iron throughout the central nervous system. Iron atoms are stored in the central cavity of the ferritin polymer and the E-helices of ferritin play an important role in maintaining the central cavity. A mutation in exon 4 of the FTL gene is known to alter the structure of E-helices, thereby leading to the release of free iron and excessive oxidative stress. Iron depletion therapy by iron chelation in symptomatic patients has not been shown to be beneficial, however before the nset of clinical symptoms, such a treatment strategy may still have some benefit. Neuroferritinopathy should therefore be considered in all patients presenting with basal ganglia disorders of unknown origin. These characteristic MRI findings may help to differentiate neuroferritinopathy from other diseases showing similar clinical features.

Microneurography as a tool in clinical neurophysiology to investigate peripheral neural traffic in humans.

Microneurography is a method using metal microelectrodes to investigate directly identified neural traffic in myelinated as well as unmyelinated efferent and afferent nerves leading to and coming from muscle and skin in human peripheral nerves in situ. The present paper reviews how this technique has been used in clinical neurophysiology to elucidate the neural mechanisms of autonomic regulation, motor control and sensory functions in humans under physiological and pathological conditions. Microneurography is particularly important to investigate efferent and afferent neural traffic in unmyelinated C fibers. The recording of efferent discharges in postganglionic sympathetic C efferent fibers innervating muscle and skin (muscle sympathetic nerve activity; MSNA and skin sympathetic nerve activity; SSNA) provides direct information about neural control of autonomic effector organs including blood vessels and sweat glands. Sympathetic microneurography has become a potent tool to reveal neural functions and dysfunctions concerning blood pressure control and thermoregulation. This recording has been used not only in wake conditions but also in sleep to investigate changes in sympathetic neural traffic during sleep and sleep-related events such as sleep apnea. The same recording was also successfully carried out by astronauts during spaceflight. Recordings of afferent discharges from muscle mechanoreceptors have been used to understand the mechanisms of motor control. Muscle spindle afferent information is particularly important for the control of fine precise movements. It may also play important roles to predict behavior outcomes during learning of a motor task. Recordings of discharges in myelinated afferent fibers from skin mechanoreceptors have provided not only objective information about mechanoreceptive cutaneous sensation but also the roles of these signals in fine motor control. Unmyelinated mechanoreceptive afferent discharges from hairy skin seem to be important to convey cutaneous sensation to the central structures related to emotion. Recordings of afferent discharges in thin myelinated and unmyelinated fibers from nociceptors in muscle and skin have been used to provide information concerning pain. Recordings of afferent discharges of different types of cutaneous C-nociceptors identified by marking method have become an important tool to reveal the neural mechanisms of cutaneous sensations such as an itch. No direct microneurographic evidence has been so far proved regarding the effects of sympathoexcitation on sensitization of muscle and skin sensory receptors at least in healthy humans.

Assessment of mechanical and thermal thresholds of human C nociceptors during increases in skin sympathetic nerve activity.

OBJECTIVES: The objective of the present study is to investigate the relationship between C-fiber nociceptor sensitivity and skin sympathetic nerve activity during mental arithmetic. METHODS: Single afferent C-fibers were identified simultaneously with spontaneous postganglionic sympathetic discharges and recorded from the peroneal nerve using microneurography in 23 normal subjects. Mechanical and heat thresholds were measured by 'marking' the nociceptor with suprathreshold stimuli, causing increased latency after a subsequent threshold stimulus at rest and during mental arithmetic. Skin sympathetic nerve activity was estimated by counting the number of bursts per minute. RESULTS: Thirty-two single C-fibers were identified. Eleven had polymodal receptors (mechanical and heat sensitive), eight were only sensitive to mechanical stimuli, two were only sensitive to heat stimuli, and 11 were insensitive to both. C-fibers were selected when the ratio of skin sympathetic nerve activity during mental arithmetic to that at rest was over 1.00. In 19 selected mechanical sensitive units, average mechanical threshold was 4.86 at rest and 4.84 during mental arithmetic. In 6 selected heat sensitive units, average heat threshold was 45.0 degrees C at rest and 43.4 degrees C during mental arithmetic. However, differences were not statistically significant. CONCLUSIONS: Physiological sympathetic stimulation did not affect afferent C-fiber nociceptor sensitivity to mechanical and heat stimuli in healthy subjects.