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Spinal Roots (spinal + root)

Distribution by Scientific Domains
Life Sciences60%
Medical Sciences40%

Selected Abstracts

Schwann cell myelination occurred without basal lamina formation in laminin ,2 chain-null mutant (dy3K/dy3K) mice

GLIA, Issue 2 2001
Masahiro Nakagawa
Abstract The laminin ,2 chain is a major component of basal lamina in both skeletal muscle and the peripheral nervous system. Laminin ,2 chain deficiency causes merosin-deficient congenital muscular dystrophy, which affects not only skeletal muscles, but also the peripheral and central nervous systems. It has been reported that the formation of basal lamina is required for myelination in the peripheral nervous system. In fact, the spinal root of dystrophic mice (dy/dy mice), whose laminin ,2 chain expression is greatly reduced, shows lack of basal lamina and clusters of naked axons. To investigate the role of laminin ,2 chain and basal lamina in vivo, we examined the peripheral nervous system of dy3K/dy3Kmice, which are null mutants of laminin ,2 chain. The results indicate the presence of myelination although Schwann cells lacked basal lamina in the spinal roots of dy3K/dy3K mice, suggesting that basal lamina is not an absolute requirement for myelination in vivo. Immunohistochemically, the expression of laminin ,4 chain was increased and laminin ,5 chain was preserved in the endoneurium of the spinal root. Laminin ,4 and ,5 chains may play the critical role in myelination instead of laminin ,2 chain in dy3K/dy3Kmice. In addition, the motor conduction velocity of the sciatic nerve was significantly reduced compared with that of wild-type littermate. This reduction in conduction velocity may be due to small axon diameter, thin myelin sheath and the patchy disruption of the basal lamina of the nodes of Ranvier in dy3K/dy3Kmice. GLIA 35:101,110, 2001. © 2001 Wiley-Liss, Inc. [source]

Magnetically evoked motor potentials in demyelinating and axonal polyneuropathy: a comparative study

EUROPEAN JOURNAL OF NEUROLOGY, Issue 1 2000
H. Takada
We investigated the value of magnetically evoked motor potentials (MEPs) for the differentiation of demyelinating and axonal polyneuropathies. The study population comprised 107 patients, with polyneuropathy verified by electromyography (EMG) and nerve conduction study (NCS), who had also been examined by means of MEP. MEPs were evoked by magnetic stimulation of the cortex and the spinal roots and were recorded from three upper limb muscles and two lower limb muscles bilaterally. From the EMG/NCS results 53 patients were characterized as having primary demyelination (demyelinating patients) and 54 as having axonal involvement (axonal patients). Demyelinating patients were classified as acute (acute inflammatory demyelinating polyradiculoneuropathy: AIDP ) or chronic (chronic inflammatory demyelinating polyradiculoneuropathy: CIDP ) according to the duration of illness. A series of indices were calculated from MEP results. One demyelinating patient and two axonal patients had normal MEPs. The MEPs of the demyelinating patients showed significantly longer peripheral conduction times, larger interside differences and lower amplitudes than the axonal patients. The central conduction index and the amplitudes upon cortical stimulation were significantly higher in patients with CIDP than in those with AIDP. Peripheral conduction time prolonged by more than 85% in at least one of the 10 muscles studied or a peripheral conduction index of above 9.4 were pathognomonic for demyelination . By combining all criteria 75% of the patients could be categorized as CIDP vs. AIDP in accordance with the EMG/NCS diagnosis. Likewise, 83% were categorized correctly as demyelinating versus axonal according to the EMG/NCS data. [source]

Schwann cell myelination occurred without basal lamina formation in laminin ,2 chain-null mutant (dy3K/dy3K) mice

GLIA, Issue 2 2001
Masahiro Nakagawa
Abstract The laminin ,2 chain is a major component of basal lamina in both skeletal muscle and the peripheral nervous system. Laminin ,2 chain deficiency causes merosin-deficient congenital muscular dystrophy, which affects not only skeletal muscles, but also the peripheral and central nervous systems. It has been reported that the formation of basal lamina is required for myelination in the peripheral nervous system. In fact, the spinal root of dystrophic mice (dy/dy mice), whose laminin ,2 chain expression is greatly reduced, shows lack of basal lamina and clusters of naked axons. To investigate the role of laminin ,2 chain and basal lamina in vivo, we examined the peripheral nervous system of dy3K/dy3Kmice, which are null mutants of laminin ,2 chain. The results indicate the presence of myelination although Schwann cells lacked basal lamina in the spinal roots of dy3K/dy3K mice, suggesting that basal lamina is not an absolute requirement for myelination in vivo. Immunohistochemically, the expression of laminin ,4 chain was increased and laminin ,5 chain was preserved in the endoneurium of the spinal root. Laminin ,4 and ,5 chains may play the critical role in myelination instead of laminin ,2 chain in dy3K/dy3Kmice. In addition, the motor conduction velocity of the sciatic nerve was significantly reduced compared with that of wild-type littermate. This reduction in conduction velocity may be due to small axon diameter, thin myelin sheath and the patchy disruption of the basal lamina of the nodes of Ranvier in dy3K/dy3Kmice. GLIA 35:101,110, 2001. © 2001 Wiley-Liss, Inc. [source]

Genes Differentially Expressed By Schwann Cells Of Motor Versus Sensory Nerves

JOURNAL OF THE PERIPHERAL NERVOUS SYSTEM, Issue 1 2001
D Imperiale
Charcot-Marie-Tooth (CMT) disease includes a heterogeneous group of inherited demyelinating peripheral neuropathies related to genetic defects of myelin-forming Schwann cells (SC). In CMT, as in other common acquired demyelinating neuropathies (Guillain Barré syndrome, chronic inflammatory demyelinating polyneuropathy), motor nerves are invariably more involved than sensory nerves. Also in transgenic mouse models of peripheral neuropathy, there is a preferential demyelination of motor districts independent of the type of genetic alteration. The basis for differential susceptibility to demyelination is unknown. The aim of this study was to identify differences in gene and protein expression that may underlie the differential susceptibility to demyelination of motor and sensory myelin-forming SC. Since spinal roots are the only portion of mammalian PNS in which motor and sensory axons are segregated, we extracted RNA from adult rat dorsal (sensory) and ventral (motor) spinal roots and compared corresponding cDNAs by an RNA fingerprint approach. Four differentially displayed bands were isolated. We first characterized the most differentially expressed band, which was highly enriched in sensory roots. Sequence analysis showed that the band encoded a portion of rat sarco/endoplasmic reticulum calcium transporting ATPase type 1 coding sequence (SERCA1). RT-PCR experiments confirmed SERCA1 enrichment in dorsal sensory roots. SERCA enzymes are ubiquitous calcium regulatory systems in muscle and non-muscle cells and SERCA1 is selectively enriched in skeletal muscle. To our knowledge, no studies have investigated SERCA isoform expression in peripheral nerve. Identification of a calcium regulatory molecule in SC is interesting, as calcium is essential for the proper structure and function of the nodal and paranodal portions of SC, as well as the myelin sheath. However, calcium homeostasis in SC is relatively unexplored. Experiments to localize SERCA1 transcript and protein in different PNS districts and to clarify its functional role in peripheral nerve are underway. [source]

Sprouting capacity of lumbar motoneurons in normal and hemisected spinal cords of the rat

THE JOURNAL OF PHYSIOLOGY, Issue 15 2010
T. Gordon
Nerve sprouting to reinnervate partially denervated muscles is important in several disease and injury states. To examine the effectiveness of sprouting of active and inactive motor units (MUs) and the basis for a limit to sprouting, one of three rat lumbar spinal roots was cut under normal conditions and when the spinal cord was hemisected at T12. Muscle and MU isometric contractile forces were recorded and muscle fibres in glycogen-depleted single muscle units enumerated 23 to 380 days after surgery. Enlargement of intact MUs by sprouting was effective in compensating for up to 80% loss of innervation. For injuries that removed >70,80% of the intact MUs, muscle contractile force and weight dropped sharply. For partial denervation of <70%, all MUs increased contractile force by the same factor in both normally active muscles and muscles whose activity was reduced by T12 hemisection. Direct measurements of MU size by counting glycogen-depleted muscle fibres in physiologically and histochemically defined muscle units, provided direct evidence for a limit in MU size, whether or not the activity of the muscles was reduced by spinal cord hemisection. Analysis of spatial distribution of muscle fibres within the outer boundaries of the muscle unit demonstrated a progressive increase in fibres within the territory to the limit of sprouting when most of the muscle unit fibres were adjacent to each other. We conclude that the upper limit of MU enlargement may be explained by the reinnervation of denervated muscle fibres by axon sprouts within the spatial territory of the muscle unit, formerly distributed in a mosaic pattern. [source]