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Relative growth and maturation of axin size and myelin thickness in the tibial nerve of the rat (1990)

Thomas, P. K. ; Fraher, J. P. ; O'Leary, D. ; [et al.]

Springer

Acta neuropathologica 79 (1990), S. 375-386

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ISSN: 1432-0533

Keywords: Peripheral nerve ; Morphometry ; Diabetes mellitus ; Hypomyelination

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary The relative changes in the growth and maturation of axon size and myelin thickness were studied in the medial plantar division of the tibial nerve in the lower leg and in the motor branches of the tibial nerve to the calf muscles in rats in which diabetes mellitus had been induced with streptozotocin at the time of weaning. Observations were made at 6 weeks and 3, 6, 9 and 12 months of diabetes for comparison with age-matched controls. Similar changes were observed in both nerves. Growth in body weight and skeletal growth was severely retarded from the time of induction of diabetes but at the 6-week stage axon size was not reduced, suggesting that neural growth may initially be relatively protected. At later stages axon size was consistently reduced in the diabetic animals as compared with the controls and showed an absolute reduction at 12 months, as compared with 9 months, that was greater than in the controls. Myelin thickness became reduced earlier and was more severely affected than axon size so that the fibers were relatively hypomyelinated. The myelin changes were greater in larger than in smaller fibers. The index of circularity of axons was reduced in the diabetic nerves. These results show that induction of diabetes in prepubertal rats produces effects on peripheral nerve fibers which differ from those resulting from diabetes induced in adult animals. The effects also differ between large and small nerve fibres. These observations may explain some of the disparate findings obstained in previous studies on experimental diabetes in rats.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00308713

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Relative growth and maturation of axon size and myelin thickness in the tibial nerve of the rat (1990)

Fraher, J. P. ; O'Leary, D. ; Moran, M. A. ; [et al.]

Springer

Acta neuropathologica 79 (1990), S. 364-374

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ISSN: 1432-0533

Keywords: Peripheral nerve morphometry ; Axons ; Myelin ; Growth changes

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Morphometric observations have been made on the medial plantar division of the tibial nerve (MPD) and on the motor branches of the tibial nerve to the calf muscles (MBC) in rats ranging in age from weaning (3 weeks) to 12 months. Axon size, assessed by measurements of circumference and cross-sectional area, increased rapidly until 3 months with further slight increases between 3 and 9 months and a slight fall between 9 and 12 months. Axon size distributions were unimodal throughout in the MPD but bimodal for the MBC except at 3 weeks. Distributions of myelin thickness were bimodal throughout for both nerves. Scatter plots of g ratios (axon diameter: total fibre diameter) confirmed the presence of two fibre populations: a group of small fibres with relatively thin myelin sheaths, and a group of larger fibres within which sheath thickness was relatively less on the larger than on the smaller axons. These two fibres populations were less easily separable in the MBC than in the MPD nerves. These results document morphometrically the normal growth changes in the rat tibial nerve and also provide control data for the analysis of the effects of experimental procedures on the growth and maturation of peripheral nerve fibres.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00308712

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The ventral motoneurone axon bundle in the CNS — a cordone system? (1998)

O'brien, D. ; Dockery, P. ; McDermott, K. ; [et al.]

Springer

Journal of neurocytology 27 (1998), S. 247-258

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ISSN: 1573-7381

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract In the developing CNS neighbouring structures are commonly separated by transient barriers termed cordones, some of which coincide with glial elements. Where ventral motoneuron axons cross the spinal white matter as intramedullary bundles to reach the CNS-PNS transitional zone they are surrounded from early development by a glial sleeve resembling a cordone. This becomes better developed with age and, like some cordones, persists into adult life. This could provide a radial conduit which might underlie the capacity of central segments of mature ventral motoneurone axons to regenerate. It may also provide a pathway for glial migration from the central cord to more superficial levels, including the transitional zone, where they help form the CNS-PNS barrier. Axons in the intramedullary bundle and in the surrounding ventral white column mature at different rates. Glial sleeve cells of the intramedullary bundles are apposed to both. Morphometric analysis of the axon-glial relationships of the two populations indicates that glial development proceeds at a different rate in relation to each axon class and that this is influenced by the degree of axonal maturation, which may in turn be related to target contact. Furthermore, early axon glial relationships differ between the two populations. For ventral motoneurone axons these take place in two stages: firstly, glial segregation of axons (resembling that in the PNS) and secondly, oligodendrocytic contact and ensheathment, which leads on to myelination. Axon-glial relationships in the ventral white column begin with the second of these events, as is more typical of early CNS myelination in general.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1023/A:1006932931160

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Segment length and root orientation in normal and sacrally attached spinal cords: A morphometric study (1993)

Hynes, P. J. ; Fraher, J. P. ; O'Sullivan, V. R.

New York, NY [u.a.] : Wiley-Blackwell

Clinical Anatomy 6 (1993), S. 167-172

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ISSN: 0897-3806

Keywords: spinal nerve root angulation ; spinal cord segment length ; normal cord ; sacral cord ; Life and Medical Sciences ; Miscellaneous Medical

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Medicine

Notes: This study compares human spinal cord segment length and spinal nerve root orientation in normal and sacrally attached cords. The proportion of the total length of the mature normal spinal cord made up by individual segments varies little between C1 and T1. Between T2 and T6 it increases gradually to a maximum and decreases steadily from T7 to the caudal termination of the cord. The C1 and C2 roots run superolaterally from the cord to their intervertebral foramina. C3 runs almost horizontally. From C4 to T2 roots run progressively more caudally. At T3 and lower levels each root runs caudally in contact with the lateral cord margin before turning laterally to its intervertebral foramen. The pattern of variation in segment length of a sacrally attached cord resembles that in normal cords between upper cervical and lower thoracic levels. In the sacrally attached cord, segment length remains relatively unchanged between mid-thoracic and mid-lumbar levels and decreases rapidly caudal to L3. © 1993 Wiley-Liss, Inc.

Additional Material: 3 Ill.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1002/ca.980060307

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Intermingling of central and peripheral nervous tissues in rat dorsolateral vagal rootlet transitional zones (1990)

Rossiter, J. P. ; Fraher, J. P.

Springer

Journal of neurocytology 19 (1990), S. 385-407

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ISSN: 1573-7381

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary The morphology of the CNS-PNS transitional zone of adult rat dorsolateral vagus nerve rootlets is uniquely complex. A typical rootlet contains a transitional zone over 300 μm long, consisting of a central tissue projection extending distally into each rootlet and a peripheral tissue insertion extending for a longer distance deep into the brainstem. The peripheral tissue insertion is continuous with the peripheral tissue of the free rootlet through channels traversing or running parallel to the central tissue projection. Accordingly, the vagal CNS-PNS interface is topologically much more complex than that found elsewhere. In some rootlets the peripheral tissue in the brainstem constitutes an isolated island deep within the neuraxis. In others, peripheral continuity is established only through a cross connection with the peripheral tissue insertion of a neighbouring rootlet. About one fifth of all vagal myelinated axons alternate between the CNS and PNS tissue compartments. This distinguishes the vagus from all other nerves studied to date. These axons are myelinated by Schwann cells distal to the transitional zone, by oligodendrocytes in the central tissue projection and by one or more short intercalated Schwann internodes further centrally, mostly in the peripheral tissue insertion, where their perikarya commonly form closely apposed aggregates. More than four fifths of all unmyelinated axon bundles alternate between central and peripheral tissue compartments, commonly more than once. In the peripheral tissue insertion axons are enveloped by series of non-myelinating Schwann cells. Schwann processes commonly extend for over 50 (Am into the central compartment at each central-peripheral transition. Around one fifth of peripherally unmyelinated axons have an oligodendrocytic sheath in the central compartment. Of those axons possessing more than one intercalated Schwann internade, over one quarter display alternation of myelinated and unmyelinated segments in the peripheral tissue insertion. Astrocytes in the transitional zone segregate PNS tissue, a role played by sheath cells further peripherally in the vagal rootlets. Astrocytes form the surface limiting membranes of the central tissue projection and the barrier between the peripheral tissue insertion and the surrounding brainstem. The barrier consists only of an attenuated layer of processes. This is deficient in places, where oligodendrocytic myelin sheaths are directly exposed to the endoneurial space of the peripheral tissue insertion and in some instances are apposed to myelinating or non-myelinating Schwann cells. Such communication between the central and peripheral compartments is unique to the vagal transitional zone. The findings are consistent with a range of possible events during development. For example, considerable migration and intermingling of central and peripheral tissues, possible overgrowth of rootlet segments by developing myelencephalic tissue, failure of part of the neural crest to separate from the developing neural tube, and the origin of peripheral tissue insertion Schwann cells from the neural tube, or combinations of these factors.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01188406

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