The effects of ultrasonic energy on peripheral nerves: implications for ultrasound-assisted liposuction

The integration of ultrasound-assisted liposuction with traditional suction-assisted lipoplasty has extended the role of liposuction in body contouring. Although there are ample data regarding the effects of ultrasound on peripheral nerves from studies with the Cavitron ultrasound surgical aspirator, there is little information concerning the effects of modern ultrasound body contouring equipment on neural tissue. This study was designed to evaluate the functional and histologic effects of ultrasound energy on rat peripheral nerves (sciatic nerves) using a commonly-used ultrasound-assisted liposuction generator. After the application of ultrasound to exposed rat sciatic nerves, operative magnification was used to assess any visible injury. The sciatic function index was serially measured to quantify immediate and long-term functional effects on the nerves. Our results showed immediate visible injury using low amplitude settings (level 6), but no functional evidence of injury until much higher settings were used (level 9). All animals in the groups with initial functional impairment had returned to normal or near-normal function at completion of the study (51 days). Histologic examination revealed no evidence of damage in the low amplitude groups. Histologic analysis of the high amplitude groups displayed diffuse infiltration of the nerve, with foamy histiocytes and an increased number of mast cells, consistent with remote neural injury followed by myelin breakdown and repair.     

Morphology of the canine pyloric sphincter in relation to function

The ultrastructure and immunocytochemistry of the canine distal pyloric muscle loop, the pyloric sphincter, were studied. Cells in this muscle were connected by gap junctions, fewer than in the antrum or corpus. The sphincter had a dense innervation and a sparse population of interstitial cells of Cajal. Most such cells were of the circular muscle type but a few were of the type in the myenteric plexus. Nerves were sometimes associated with interstitial cell profiles, but most nerves were neither close to nor associated with interstitial cells nor close to smooth muscle cells. Nerve profiles were characterized by an unusually high proportion of varicosities with a majority or a high proportion of large granular vesicles. Many of these were shown to contain material immunoreactive for vasoactive intestinal polypeptide (VIP) and some had substance P (SP) immunoreactive material. All were presumed to be peptidergic. VIP was present in a higher concentration in this muscle than in adjacent antral or duodenal circular muscle. Interstitial cells of Cajal made gap junctions to smooth muscle and to one another and might provide myogenic pacemaking activity for this muscle, but there was no evidence of a close or special relationship between nerves with VIP or SP and these cells. The absence of close relationships between nerves and either interstitial cells or smooth muscle cells leaves unanswered questions about the structural basis for previous observations of discrete excitatory responses or pyloric sphincter to single stimuli or nerves up to one per second. In conclusion, the structural observations suggest that this muscle has special neural and myogenic control systems and that interstitial cells may function to control myogenic activity of this muscle but not to mediate neural signals.     

Avian enteric nerve plexuses

Summary The enteric nerve plexuses of the domestic fowl (Gallus domesticus) were investigated in sections and stretch preparations by means of the cholinesterase and glyoxylic acid fluorescence histochemical techniques. Cholinesterase-positive and varicose and non-varicose fluorescent nerve fibres were distributed at all levels of the gut in myenteric, submucosal, muscle and mucosal plexuses, and in a perivascular plexus. The density of the innervation and the detailed distribution of the nerves varied in different parts of the intestinal tract. All nerve plexuses appeared to be best developed in the rectum. Whereas the circular muscle coat contained a substantial number of nerves at all levels of the gut, the longitudinal coat was well innervated only in the rectum. The major portion of the mucosal plexus appeared to be associated with the intestinal glands. The nerve cell bodies were restricted to the myenteric and submucosal plexuses and were mainly cholinesterase-positive. Fluorescent ganglion cells were not observed. Pretreatment of stretch preparations with NADH: Nitro BT to stain ganglion cells showed that the majority of the cells were surrounded by a meshwork of fluorescent varicose fibres, although none of the fibres appeared to be associated with individual cells. The perivascular plexus was mainly associated with the arteries. The functional significance of the innervation is discussed.We would like to thank the British Council for financial support for Mr. H.A. Ali     

The distribution of neural crest-derived Schwann cells from subsets of brachial spinal segments into the peripheral nerves innervating the chick forelimb.

Neural crest cells from brachial levels of the neural tube populate the ventral roots, spinal nerves, and peripheral nerves of the chick forelimb where they give rise to Schwann cells. The distribution of neural crest cells in the developing forelimb was examined using homotopic and heterotopic chick-quail chimeras to label neural crest cells from subsets of the brachial spinal segments. Neural crest cells from particular regions of the spinal cord populated ventral roots and spinal nerves adjacent to or immediately posterior to the graft. Crest cells also populated the brachial plexus in accord with their segmental origins. In the forelimb, neural crest cells populated muscle nerves with anterior brachial spinal segments populating nerves to anterior musculature of the forelimb and posterior brachial spinal segments populating nerves to posterior musculature. Similar patterns were seen following both homotopic and heterotopic transplantation. In both types of grafts, the distribution of neural crest cells largely matched the sensory and motor projection pattern from the same spinal segmental level. This suggests that neural crest-derived Schwann cells from a particular spinal segment may use sensory and motor fibers emerging from the same segmental level as substrates to guide their migration into the periphery.     

The location and distribution of neural crest-derived Schwann cells in developing peripheral nerves in the chick forelimb.

The location and distribution of neural crest-derived Schwann cells during development of the peripheral nerves of chick forelimbs were examined using chick-quail chimeras. Neural crest cells were labeled by transplantation of the dorsal part of the neural tube from a quail donor to a chick host at levels of the neural tube destined to give rise to brachial innervation. The ventral roots, spinal nerves, and peripheral nerves innervating the chick forelimb were examined for the presence of quail-derived neural crest cells at several stages of embryonic development. These quail cells are likely to be Schwann cells or their precursors. Quail-derived Schwann cells were present in ventral roots and spinal nerves, and were distributed along previously described neural crest migratory pathways or along the peripheral nerve fibers at all stages of development examined. During early stages of wing innervation, quail-derived Schwann cells were not evenly distributed, but were concentrated in the ventral root and at the brachial plexus. The density of neural crest-derived Schwann cells decreased distal to the plexus, and no Schwann cells were ever seen in advance of the growing nerve front. When the characteristic peripheral nerve branching pattern was first formed, Schwann cells were clustered where muscle nerves diverged from common nerve trunks. In still older embryos, neural crest-derived Schwann cells were evenly distributed along the length of the peripheral nerves from the ventral root to the distal nerve terminations within the musculature of the forelimb. These observations indicate that Schwann cells accompany axons into the developing limb, but they do not appear to lead or direct axons to their targets. The transient clustering of neural crest-derived Schwann cells in the ventral root and at places where axon trajectories diverge from one another may reflect a response to some environmental feature within these regions.     

The early development of cranial sensory ganglia and the potentialities of their component cells studied in quail-chick chimeras

The quail-chick marker system has been used to study the early developmental stages of the ganglia located along cranial nerves VII, IX, and X. The streams of neural crest cells arising from the rhombencephalic-vagal neural crest were followed from the onset of their migration up to the localization of crest cells in the trunk and root ganglia of these nerves. It was shown that two different populations of crest cells are segregated early as a result of morphogenetic movements in the hypobranchial region. The dorsal population gives rise to the root ganglia of nerves IX and X located close to the encephalic vesicles, where the crest cells differentiate both into neurons and into glia. In contrast, the ventral stream of neural crest cells contributes together with cells from epibranchial placodes to the trunk ganglia (geniculate, petrous, and nodose ganglia) of cranial nerves VII, IX, and X. The successive steps of the invasion of the placodal anlage by crest cells can be followed owing to the selective labeling of the neural crest cells. It appears that the latter give rise to the satellite cells of the geniculate, petrous, and nodose ganglia while the large sensory neurons originate from the placodes. The nodose ganglion has been the subject of further studies aimed to investigate whether neuronal potentialities can be elicited in the neural crest-derived cells that it contains. The ability to label selectively either the neurons or the glia by the quail nuclear marker made this investigation possible in the particular case of the nodose ganglion whose neurons and satellite cells have a different embryonic origin. By the technique already described (N. M. Le Douarin, M. A. Teillet, C. Ziller, and J. Smith, 1978, Proc. Nat. Acad. Sci. USA75, 2030–2034) of back-transplantation into the neural crest migration pathway of a younger host, it was shown that the presumptive glial cells of the nodose ganglion are able to remigrate when transplanted into a 2-day chick host and to differentiate into autonomic structures (sympathetic ganglion cells, adrenomedullary cells, and enteric ganglia). It is proposed as a working hypothesis that neuronal potentialities contained in the neural crest cells which invade the placodal primordium of the nodose ganglion are repressed through cell-cell interactions occurring between placodal and crest cells.     

Patterning of the cranial nerves in the chick embryo is dependent on cranial mesoderm and rhombomeric metamerism

The vertebrate peripheral nervous system (PNS) consists of two groups of nerves that have a metamerical series of proximal roots along the body axis: the branchial and spinal nerves. Spinal nerve metamerism is brought about by the presence of somites, while that of the branchial nerves is, in part, intrinsic to rhombomeres, the segmental compartments of the hind-brain. As the distribution pattern of neural crest cells prefigures the morphology of the PNS, we constructed tissue-recombinant chick embryos in order to determine factors that might regulate the crest cell distribution pattern. When the segmental plate was transplanted between the hind-brain and the head mesoderm before crest cell emigration, it developed into ectopic somites that inhibited the dorsolateral migration of crest cells such that formation of the cranial nerve trunks was disturbed. Even so, proximal portions of the nerve roots were intact. An ectopic graft of lateral mesoderm did not inhibit the directional migration of the crest cells, but allowed their ectopic distribution, resulting in the fusion of cranial nerve trunks. When spinal neurectoderm was transplanted into the hind-brain, the graft behaved like an even-numbered rhombomere and caused the fusion of cranial nerve roots. The identity of the spinal neurectoderm was preserved in the ectopic site analyzed by the immunolocalization of Hoxb-5 protein, a spinal cord marker. We conclude that the spatial distribution of cephalic crest cells is regulated by successive processes that act on their proximal and distal distribution. The migratory behavior of crest cells is achieved partly by an embryonic environment that is dependent upon the presence of somitomeres, which do not epithelialize as somites, in the trunk.     

Neural Stem Cells Enhance Nerve Regeneration after Sciatic Nerve Injury in Rats

With the development of tissue engineering and the shortage of autologous nerve grafts in nerve reconstruction, cell transplantation in a conduit is an alternative strategy to improve nerve regeneration. The present study evaluated the effects and mechanism of brain-derived neural stem cells (NSCs) on sciatic nerve injury in rats. At the transection of the sciatic nerve, a 10-mm gap between the nerve stumps was bridged with a silicon conduit filled with 5?×?10⁵ NSCs. In control experiments, the conduit was filled with nerve growth factor (NGF) or normal saline (NS). The functional and morphological properties of regenerated nerves were investigated, and expression of hepatocyte growth factor (HGF) and NGF was measured. One week later, there was no connection through the conduit. Four or eight weeks later, fibrous connections were evident between the proximal and distal segments. Motor function was revealed by measurement of the sciatic functional index (SFI) and sciatic nerve conduction velocity (NCV). Functional recovery in the NSC and NGF groups was significantly more advanced than that in the NS group. NSCs showed significant improvement in axon myelination of the regenerated nerves. Expression of NGF and HGF in the injured sciatic nerve was significantly lower in the NS group than in the NSCs and NGF groups. These results and other advantages of NSCs, such as ease of harvest and relative abundance, suggest that NSCs could be used clinically to enhance peripheral nerve repair.     

Nerve repair and behavioral recovery following brain transplantation in Notoplana acticola, a polyclad flatworm

Although Notoplana acticola, a marine polyclad, cannot regenerate brain tissue, neuronal repair is rapid. Brains were transplanted into decerebrate flatworms to determine the anatomical patterns and functionality of neural connections established between a new brain and the peripheral nerve network of the recipient animal. Sixty-nine transplants were performed. Four brain transplant orientations were used: normal, reversed, inverted, and reversed inverted. The functionality of the transplanted brains was tested and measured using both behavioral and electrophysiological criteria. Within 23 days, 56% of the transplants that survived and retained the transplants recovered the four behaviors tested: righting behavior, avoidance turning, ditaxic locomotion, and feeding. Nerves exiting the brain tended to join with the peripheral nerves closest to them. Anatomical connections were made within 24 hr of surgery. Some normal behavior was seen within the first 36 hrs after surgery. Control decerebrate worms did not recover behavior. Preliminary intracellular recordings from three types of identified brain sensory interneurons, in transplants, revealed normal electrophysiological properties and this implied that appropriate connections with peripheral sensory cells had been reestablished. Intracellular dye-marking of these neurons in reverse-oriented brains revealed that, although individual nerve processes apparently leave the brain and associate with inappropriate nerve cords, some of the processes turn 180 degrees to reinervate nerve cords, which they normally occupy in unoperated animals. Thus, although anatomical and functional neural connections apparently were made rapidly following brain transplantation, the specificity of the reconnections remains to be shown.     

Paraneuronal pseudobranchial neurosecretory cells in scorpion catfish Heteropneustes fossilis: an environment scanning electron microscope and transmission electron microscope study

Yadav, L., Sengar, M., Zaccone, D. and Gopesh, A. 2011. Paraneuronal pseudobranchial neurosecretory cells in scorpion catfish Heteropneustes fossilis: an environment scanning electron microscope and transmission electron microscope study. —Acta Zoologica (Stockholm) 00 : 1–8. Pseudobranchial neurosecretory system (PNS), found in the gill region of certain groups of teleosts, falls under the category of the ‘diffuse neuroendocrine system’ (DNES). The cells belonging to the system share morpho‐functional features with the paraneuronal cells observed in respiratory tract and airway surfaces of higher vertebrates. On the basis of the experimental observations, a role in condition of hypoxia has been recorded for this system. In an attempt to elucidate the ultrastructure of pseudobranchial neurosecretory cells, present investigation was undertaken using environment scanning electron microscope (ESEM) and TEM in an air‐breathing catfish, Heteropneustes fossilis. The external morphology of PNS under ESEM appeared as a mass of cells supplied with nerves and blood capillaries. Each cell mass is made up of numerous pear‐shaped neurosecretory cells, confirmed by neurosecretion‐specific acid violet stain. The TEM investigation of the cells revealed the presence of different sizes of dense‐cored vesicles in the cytoplasm, which was observed as granular cytoplasm under light microscope. Presence of large number of mitochondria in the cytoplasm confirmed active involvement of these cells in the physiology of fishes. Although lacuna prevails regarding the exact function of this system of fish, its probable role in hypoxic condition and surfacing behavior are speculated.     

Neurogenesis in the spider: new insights from comparative analysis of morphological processes and gene expression patterns

While there is a detailed understanding of neurogenesis in insects and partially also in crustaceans, little is known about neurogenesis in chelicerates. In the spider Cupiennius salei Keyserling, 1877 (Chelicerata, Arachnida, Araneae) invaginating cell groups arise sequentially and in a stereotyped pattern comparable to the formation of neuroblasts in Drosophila melanogaster Meigen, 1830 (Insecta, Diptera, Cyclorrhapha, Drosophilidae). In addition, functional analysis revealed that in the spider homologues of the D. melanogaster proneural and neurogenic genes control the recruitment and singling out of neural precursors like in D. melanogaster. Although groups of cells, rather than individual cells, are singled out from the spider neuroectoderm which can thus not be homologized with the insect neuroblasts, similar genes seem to confer neural identity to the neural precursor cells of the spider. We show here that the pan-neural genes snail and the neural identity gene Krüppel are expressed in neural precursors in a heterogenous spatio-temporal pattern that is comparable to the pattern in D. melanogaster. Our data suggest that the early genetic network involved in recruitment and specification of neural precursors is conserved among insects and chelicerates.     

Tissue engineered, guided nerve tube consisting of aligned neural stem cells and astrocytes

Injury of the nervous system, particularly in the spinal cord, impairs the quality of life of the patient by resulting in permanent loss of neurologic function. The main limitation in spinal cord regeneration is the lack of extracellular matrix to guide nerves for functional recovery of the transected nerve tissue. In the present study, a tissue engineered nerve tube was prepared by wrapping neural stem cells (NSCs) on aligned fibers using a micropatterned film with astrocytes aligned along the microgrooves to support the NSCs. Initially the cell behavior on micropatterns and parallel fibers was investigated with cytoskeletal and nuclear staining, immunocytochemistry, and proliferation assay using the fiber and the film system separately. The results showed that both cells, NSCs in undifferentiated and astrocytes in differentiated form, were oriented in the direction of the guiding and support elements, the microgrooves, and the microfibers. They were able to grow and increase in number on these cell carriers. This trend was also maintained after the components were brought together in a nerve tube form and testing in coculture. The cells were able to survive and maintained their orientation in the 3D tissue engineered construct. The guided nerve tissue engineering approach tested in the present study with parallel NSCs and support cells in the tubular construct is expected to provide an appropriate environment for nerve regeneration in vivo.     

Quantitative and phenotypic analysis of bone marrow-derived cells in the intact and inflamed central nervous system

Bone marrow has been proposed as a possible source of cells capable of replacing injured neural cells in diseases such as Multiple Sclerosis (MS). Previous studies have reported conflicting results regarding the transformation of bone marrow cells into neural cells in vivo. This study is a detailed analysis of the fate of bone marrow derived cells (BMDC) in the CNS of C57Bl/6 mice with and without experimental autoimmune encephalomyelitis using flow cytometry to identify GFP-labeled BMDC that lacked the pan-hematopoietic marker, CD45 and co-expressed neural markers polysialic acid-neural cell adhesion molecule or A2B5. A small number of BMDC displaying neural markers and lacking CD45 expression was identified within both the non-inflamed and inflamed CNS. However, the majority of BMDC exhibited a hematopoietic phenotype.     

The distribution of noradrenergic nerves and small,intensely fluorescent (SIF) cells in the cat urinary bladder

Summary Fluorescence and electron microscopy have been used to study the distribution of noradrenergic nerves in the smooth muscle of the cat urinary bladder. Using the former technique, relatively few fluorescent noradrenergic nerves were observed in the body and fundus, while a rich plexus occurred adjacent to muscle cells of the bladder neck. The trigone could not be distinguished neuromorphologically from detrusor muscle in this region. Electron microscopy showed that the majority of noradrenergic terminals in the body and fundus were associated with presumptive cholinergic axons, while in the bladder neck noradrenergic terminals formed typical neuroeffector relationships with individual smooth muscle cells.Numerous ganglia occurred both in the adventitia and among the smooth muscle bundles, particularly in the bladder neck. The majority of the nerve cell bodies were non-fluorescent, although many contained bright orange autofluorescent granules, believed to be lysosomes. A small minority of ganglion cells were associated with fluorescent noradrenergic nerve terminals, thereby providing structural evidence for limited intraganglionic inhibition. In addition, occasional groups of small intensely fluorescent (SIF) cells were observed in some intramural ganglia and these were subsequently identified in the electron microscope. The possibility that these cells may provide a second inhibitory influence on bladder activity was considered.     

Ultrastructure of different neuropil zones of the procerebrum in snails and slugs

Ultrastructure and peculiarities of interneuronal connections in various zones of neuropil of procerebral olfactory centers of the brain in snails and slugs: in the outer and inner neuropil, zone of input of afferent fibers of labial nerves, as well as zones of running of afferent and efferent fibers of tentacular nerves, were studied. A pronounced spatial morpho-functional differentiation and a complex zonal synaptoarchitectonics of procerebrums is revealed. It has been shown that the procerebrum neural elements, both intrinsic and numerous ones coming from other brain regions and chemosensory systems, contain an enormous variety of vesicles. These vesicles provide connections between neural elements in various synapses and synapse-like junctions and in the composite divergent and convergent complexes formed by them. A positive polychemical nature of granular cells, the main neural elements of procerebrums, and functional significance of symmetric junctions predominant in procerebrums is discussed.     

NEUROPHYSIOLOGY AND HUMAN TASTE SENSATIONS

Taste sensations are of primary importance in food flavor. Any attempt to synthesize chemically the flavor of a natural food involves mainly taste active compounds. Many distinct taste sensations can be identified as associated with food compounds. Thirteen different taste sensations are discussed herein. These different taste sensations are differentiated on the basis of stimulus chemistry and peripheral nerve conveying the taste information. Neurophysiological examination of the peripheral nerves involved in taste reveals that the sensory neurons can, in any species, be subdivided into distinct neural groups. These different neural groups respond to distinct classes of chemicals and often display different neurophysiological characteristics. Altogether in four different species, nine functional neural taste groups can be distinguished. In many cases, these neural groups can be taken as analogs for the neural groups assumed to underly human taste sensations. Distinct human taste sensations can be considered to arise from the excitation or inhibition of different neural groups. For certain human taste sensations there are no animal neural analog groups; and for certain neural groups there are no analog human sensations.     

Adrenergic innervation of the human gall bladder.

Adrenergic innervation of the human gall bladder was studied using two specific fluorescence histochemical methods. Blue-green fluorescing varicose nerves were scarce and mostly followed the course of blood vessels as typical perivascular plexuses. However, some adrenergic nerves not associated with the vessels were occasionally seen, as well as structures suggestive of a pericellular arrangement of varicose adrenergic nerve terminals on non-fluorescing ganglion cells. A few enterochromaffin cells were seen in the epithelial lining, also in the deep invaginations obviously representing the Aschoff-Rokitansky sinuses. Occasionally, small rounded cells with a rounded, relatively large nucleus, and exhibiting a weak yellow-green to blue-green granular cytoplasmic fluorescence, were observed in the wall of the gall bladder. The possible functional and evolutionary significance of these neural and endocrine elements was discussed against the data on physiological and pharmacological studies obtained from the literature. It was concluded that their significance is, in all probability, secondary to the influence of the intestinal polypeptide hormones, vagal innervation and circulating catecholamines upon the normal function of the gall bladder. The glyoxylic acid-induced fluorescence histochemical method was found to be superior to the conventional formaldehyde technique in studies on human tissue.     

Adrenergic innervation of the human gall bladder

Summary Adrenergic innervation of the human gall bladder was studied using two specific fluorescence histochemical methods. Blue-green fluorescing varicose nerves were scarce and mostly followed the course of blood vessels as typical perivascular plexuses. However, some adrenergic nerves not associated with the vessels were occasionally seen, as well as structures suggestive of a pericellular arrangement of varicose adrenergic nerve terminals on non-fluorescing ganglion cells. A few enterochromaffin cells were seen in the epithelial lining, also in the deep invaginations obviously representing the Aschoff-Rokitansky sinuses. Occasionally, small rounded cells with a rounded, relatively large nucleus, and exhibiting a weak yellow-green to blue-green granular cytoplasmic fluorescence, were observed in the wall of the gall bladder. The possible functional and evolutionary significance of these neural and endocrine elements was discussed against the data on physiological and pharmacological studies obtained from the literature. It was concluded that their significance is, in all probability, secondary to the influence of the intestinal polypeptide hormones, vagal innervation and circulating catecholamines upon the normal function of the gall bladder. The glyoxylic acid-induced fluorescence histochemical method was found to be superior to the conventional formaldehyde technique in studies on human tissue.