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Nerve Innervation (nerve + innervation)

Distribution by Scientific Domains
Life Sciences62%

Selected Abstracts

Variance of Peptidic Nerve Innervation in a Canine Model of Atrial Fibrillation Produced by Prolonged Atrial Pacing

PACING AND CLINICAL ELECTROPHYSIOLOGY, Issue 2 2008
XIUFEN QU Ph.D.
Background:Long-term rapid atrial pacing may result in nerve sprouting and sympathetic hyperinnervation in atrial fibrillation (AF) in dogs. Whether peptidic nerve is involved in neural remodeling is unclear. Method and Results:We performed rapid left atrial pacing in six dogs to induce sustained AF. Tissues from six healthy dogs were used as controls. Nerve was identified by immunocytochemical techniques. The degree of nerve innervation was quantified by measuring the amount of staining area for each antibody and the heterogeneity of nerve distribution was qualitatively studied. In dogs with AF, the density of growth-associated protein 43 (GAP43) immunopositivenerve fibers in the left atrium (LA), atrial septum (AS), and right atrium (RA) was significantly (19,454.31 ± 1,592.81 ,m2/mm2 vs 1,673.41 ± 142.62 ,m2/mm2P < 0.001, 3,931.26 ± 361.78 ,m2/mm2 vs 1,614.20 ± 140. 41 ,m2/mm2 P < 0.05 and 2,324.15 ± 1,123.77 ,m2/mm2 vs 1,620.47 ± 189.05 ,m2/mm2 P < 0.05, respectively) higher than the nerve density in control tissues. The density of (neuropeptide Y) NPY-positive nerves in the, AS, and RA was (13,547.62 ± 2,983.37 ,m2/mm2 vs 703.72 ± 287.52 ,m2/mm2 P < 0.01, 2,689.22 ± 340.93 ,m2/mm2 vs 651.7 ± 283.02 ,m2/mm2 P < 0.01 and 1,574.70 ± 424.37 ,m2/mm2 vs 580.42 ± 188.12 ,m2/mm2 P < 0.001, respectively) higher than the nerve density in control tissues. At the same time, vasoactive intestinal polypeptide (VIP) positive nerve innervation shrank in dogs with AF. The density of VIP positive in LA, AS, and RA was statistically lower than the nerve density in control tissues, respectively. (110.48 ± 45.63,m2/mm2 vs 1679.32 ± 1020.34,m2/mm2 P < 0.01, 265.92 ± 52.51 ,m2/mm2 vs 2602.68 ± 1257.16,m2/mm2 P < 0.001 and 609.56 ± 139.75,m2/mm2 vs 2771.68 ± 779.08,m2/mm2 P < 0.01, respectively) Conclusions:Combined with VIP-ergic nerve denervation, significant nerve sprouting and NPY-ergic nerve hyperinnervation are present in a canine model of sustained AF produced by prolonged atrial pacing. [source]

Development of otolith receptors in Japanese quail

DEVELOPMENTAL NEUROBIOLOGY, Issue 6 2010
David Huss
Abstract This study examined the morphological development of the otolith vestibular receptors in quail. Here, we describe epithelial growth, hair cell density, stereocilia polarization, and afferent nerve innervation during development. The otolith maculae epithelial areas increased exponentially throughout embryonic development reaching asymptotic values near posthatch day P7. Increases in hair cell density were dependent upon macular location; striolar hair cells developed first followed by hair cells in extrastriola regions. Stereocilia polarization was initiated early, with defining reversal zones forming at E8. Less than half of all immature hair cells observed had nonpolarized internal kinocilia with the remaining exhibiting planar polarity. Immunohistochemistry and neural tracing techniques were employed to examine the shape and location of the striolar regions. Initial innervation of the maculae was by small fibers with terminal growth cones at E6, followed by collateral branches with apparent bouton terminals at E8. Calyceal terminal formation began at E10; however, no mature calyces were observed until E12, when all fibers appeared to be dimorphs. Calyx afferents innervating only Type I hair cells did not develop until E14. Finally, the topographic organization of afferent macular innervation in the adult quail utricle was quantified. Calyx and dimorph afferents were primarily confined to the striolar regions, while bouton fibers were located in the extrastriola and Type II band. Calyx fibers were the least complex, followed by dimorph units. Bouton fibers had large innervation fields, with arborous branches and many terminal boutons. © 2010 Wiley Periodicals, Inc. Develop Neurobiol 70: 436,455, 2010 [source]

Neural connectivity in hand sensorimotor brain areas: An evaluation by evoked field morphology

HUMAN BRAIN MAPPING, Issue 2 2005
Franca Tecchio
Abstract The connectivity pattern of the neural network devoted to sensory processing depends on the timing of relay recruitment from receptors to cortical areas. The aim of the present work was to uncover and quantify the way the cortical relay recruitment is reflected in the shape of the brain-evoked responses. We recorded the magnetic somatosensory evoked fields (SEF) generated in 36 volunteers by separate bilateral electrical stimulation of median nerve, thumb, and little fingers. After defining an index that quantifies the shape similarity of two SEF traces, we studied the morphologic characteristics of the recorded SEFs within the 20-ms time window that followed the impulse arrival at the primary sensory cortex. Based on our similarity criterion, the shape of the SEFs obtained stimulating the median nerve was observed to be more similar to the one obtained from the thumb (same median nerve innervation) than to the one obtained from the little finger (ulnar nerve innervation). In addition, SEF shapes associated with different brain regions were more similar within an individual than between subjects. Because the SEF morphologic characteristics turned out to be quite diverse among subjects, we defined similarity levels that allowed us to identify three main classes of SEF shapes in normalcy. We show evidence that the morphology of the evoked response describes the anatomo-functional connectivity pattern in the primary sensory areas. Our findings suggest the possible existence of a thalamo-cortico-thalamic responsiveness loop related to the different classes. Hum Brain Mapp 24:99,108, 2005. © 2004 Wiley-Liss, Inc. [source]

Comparative innervation of cephalic photophores of the loosejaw dragonfishes (Teleostei: Stomiiformes: Stomiidae): Evidence for parallel evolution of long-wave bioluminescence

JOURNAL OF MORPHOLOGY, Issue 4 2010
Christopher P. Kenaley
Abstract Four genera of the teleost family Stomiidae, the loosejaw dragonfishes, possess accessory cephalic photophores (AOs). Species of three genera, Aristostomias, Malacosteus, and Pachystomias, are capable of producing far-red, long-wave emissions (>650nm) from their AOs, a character unique among vertebrates. Aristostomias and Malacosteus posses a single far-red AO, while Pachystomias possesses anterior and posterior far-red AOs, each with smaller separate photophores positioned in their ventral margins. The purpose of this study was to establish the primary homology of the loosejaw AOs based on topological similarity of cranial nerve innervation, and subject these homology conjectures to tests of congruence under a phylogenetic hypothesis for the loosejaw dragonfishes. On the basis of whole-mount, triple-stained specimens, innervation of the loosejaw AOs is described. The AO of Aristostomias and the anterior AO of Pachystomias are innervated by the profundal ramus of the trigeminal (Tpr), while the far-red AO of Malacosteus and a small ventral AO of Pachystomias are innervated by the maxillary ramus of the trigeminal (Tmx). The largest far-red AO of Pachystomias, positioned directly below the orbit, and the short-wave AO of Photostomias are innervated by a branch of the mandibular ramus of the trigeminal nerve. Conjectures of primary homology drawn from these neuroanatomical similarities were subjected to tests of congruence on a phylogeny of the loosejaws inferred from a reanalysis of a previously published morphological dataset. Optimized for accelerated transformation, the AO innervated by the Tpr appears as a single transformation on the new topology, thereby establishing secondary homology. The AOs innervated by the Tmd found in Pachystomias and Photostomias appear as two transformations in a reconstruction on the new topology, a result that rejects secondary homology of this structure. The secondary homology of AOs innervated by the Tmx found in Malacosteus and Pachystomias is rejected on the same grounds. Two short-wave cephalic photophores present in all four genera, the suborbital (SO) and the postorbital (PO), positioned in the posteroventral margin of the orbit and directly posterior to the orbit, respectively, are innervated by separate divisions of the Tmd. The primary homologies of the loosejaw PO and SO across loosejaw taxa are proposed on the basis of similar innervation patterns. Because of dissimilar innervation of the loosejaw SO and SO of basal stomiiforms, primary homology of these photophores cannot be established. Because of similar function and position, the PO of all other stomiid taxa is likely homologous with the loosejaw PO. Nonhomology of loosejaw long-wave photophores is corroborated by previously published histological evidence. The totality of evidence suggests that the only known far-red bioluminescent system in vertebrates has evolved as many as three times in a closely related group of deep-sea fishes. J. Morphol., 2010. © 2009 Wiley-Liss, Inc. [source]

Variance of Peptidic Nerve Innervation in a Canine Model of Atrial Fibrillation Produced by Prolonged Atrial Pacing

PACING AND CLINICAL ELECTROPHYSIOLOGY, Issue 2 2008
XIUFEN QU Ph.D.
Background:Long-term rapid atrial pacing may result in nerve sprouting and sympathetic hyperinnervation in atrial fibrillation (AF) in dogs. Whether peptidic nerve is involved in neural remodeling is unclear. Method and Results:We performed rapid left atrial pacing in six dogs to induce sustained AF. Tissues from six healthy dogs were used as controls. Nerve was identified by immunocytochemical techniques. The degree of nerve innervation was quantified by measuring the amount of staining area for each antibody and the heterogeneity of nerve distribution was qualitatively studied. In dogs with AF, the density of growth-associated protein 43 (GAP43) immunopositivenerve fibers in the left atrium (LA), atrial septum (AS), and right atrium (RA) was significantly (19,454.31 ± 1,592.81 ,m2/mm2 vs 1,673.41 ± 142.62 ,m2/mm2P < 0.001, 3,931.26 ± 361.78 ,m2/mm2 vs 1,614.20 ± 140. 41 ,m2/mm2 P < 0.05 and 2,324.15 ± 1,123.77 ,m2/mm2 vs 1,620.47 ± 189.05 ,m2/mm2 P < 0.05, respectively) higher than the nerve density in control tissues. The density of (neuropeptide Y) NPY-positive nerves in the, AS, and RA was (13,547.62 ± 2,983.37 ,m2/mm2 vs 703.72 ± 287.52 ,m2/mm2 P < 0.01, 2,689.22 ± 340.93 ,m2/mm2 vs 651.7 ± 283.02 ,m2/mm2 P < 0.01 and 1,574.70 ± 424.37 ,m2/mm2 vs 580.42 ± 188.12 ,m2/mm2 P < 0.001, respectively) higher than the nerve density in control tissues. At the same time, vasoactive intestinal polypeptide (VIP) positive nerve innervation shrank in dogs with AF. The density of VIP positive in LA, AS, and RA was statistically lower than the nerve density in control tissues, respectively. (110.48 ± 45.63,m2/mm2 vs 1679.32 ± 1020.34,m2/mm2 P < 0.01, 265.92 ± 52.51 ,m2/mm2 vs 2602.68 ± 1257.16,m2/mm2 P < 0.001 and 609.56 ± 139.75,m2/mm2 vs 2771.68 ± 779.08,m2/mm2 P < 0.01, respectively) Conclusions:Combined with VIP-ergic nerve denervation, significant nerve sprouting and NPY-ergic nerve hyperinnervation are present in a canine model of sustained AF produced by prolonged atrial pacing. [source]

Defective development of sensory neurons innervating the levator ani muscle in fetal rats with anorectal malformation

BIRTH DEFECTS RESEARCH, Issue 7 2009
Kaoping Guan
Abstract BACKGROUND: Defects of the pelvic nerve innervation of levator ani muscle are associated with poor postoperative anorectal function in patients with anorectal malformation (ARM). We have previously shown deficient development of motoneurons innervating the levator ani muscle in rats with ARM. In this study we investigate whether there is a deficiency in the development of sensory neurons that innervate the levator ani muscle in rats with ARM. METHODS: ARM was induced by ethylenethiourea (ETU) in fetal rats. Retrograde tracer fluorogold (FG) was injected into the levator ani muscle. Serial transverse sections encompassing the entire length of the lumbosacral spinal cord were examined. The number of FG-labeled sensory neurons was scored and compared between fetuses with ARM and normal fetuses. RESULTS: The number of FG-labeled sensory neurons innervating the levator ani muscle in normal control fetuses, ETU-fed fetuses with no malformation, low type of imperforate anus, high type of imperforate anus, and high type of imperforate anus combined with neural tube defects were determined to be (mean ± SEM) 11,804 ± 2362, 10,429 ± 1708, 2886 ± 705, 1026 ± 425, and 964 ± 445, respectively. FG-labeled sensory neurons in fetuses with imperforate anus with or without neural tube defects were significantly fewer than in control and ETU-fed fetuses without malformation (p < 0.05). CONCLUSIONS: Defective sensory neurons innervating the levator ani muscle is a primary anomaly that coexists with the alimentary tract anomaly in ARM during fetal development. Nerve innervation deficiency of the pelvic muscles contributes to the poor postoperative anorectal functions in ARM patients. Birth Defects Research (Part A), 2009. © 2009 Wiley-Liss, Inc. [source]

Restoration of motor function of the deep fibular (peroneal) nerve by direct nerve transfer of branches from the tibial nerve: An anatomical study,

CLINICAL ANATOMY, Issue 3 2004
Kale D. Bodily
Abstract Traction injuries of the common fibular (peroneal) nerve frequently result in significant morbidity due to tibialis anterior muscle paralysis and the associated loss of ankle dorsiflexion. Because current treatment options are often unsuccessful or unsatisfactory, other treatment approaches need to be explored. In this investigation, the anatomical feasibility of an alternative option, consisting of nerve transfer of motor branches from the tibial nerve to the deep fibular nerve, was studied. In ten cadaveric limbs, the branching pattern, length, and diameter of motor branches of the tibial nerve in the proximal leg were characterized; nerve transfer of each of these motor branches was then simulated to the proximal deep fibular nerve. A consistent, reproducible pattern of tibial nerve innervation was seen with minor variability. Branches to the flexor hallucis longus and flexor digitorum longus muscles were determined to be adequate, based on their branch point, branch pattern, and length, for direct nerve transfer in all specimens. Other branches, including those to the tibialis posterior, popliteus, gastrocnemius, and soleus muscles were not consistently adequate for direct nerve transfer for injuries extending to the bifurcation of the common fibular nerve or distal to it. For neuromas of the common fibular nerve that do not extend as far distally, branches to the soleus and lateral head of the gastrocnemius may be adequate for direct transfer if the intramuscular portions of these nerves are dissected. This study confirms the anatomical feasibility of direct nerve transfer using nerves to toe-flexor muscles as a treatment option to restore ankle dorsiflexion in cases of common fibular nerve injury. Clin. Anat. 17:201,205, 2004. © 2004 Wiley-Liss, Inc. [source]