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Query: UMLS:C0029713 (immaturity)
 4,335 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The fine structure of unmyelinated cutaneous nerve fibers in newborns was examined in lesions of adnexal polyp of neonatal skin. In the neonatal cutaneous nerves, unmyelinated fibers outnumbered myelinated ones. The unmyelinated fibers consisted of Schwann cells, axons and basal lamina. Their ultrastructural organization was basically similar to that in the adult skin. However, some of the unmyelinated fibers contained axonal bundles which suggested a state of cytoarchitectual immaturity or incomplete growth. Phagocytosis of melanosomes by Schwann cells was also observed.
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PMID:Fine structure of unmyelinated nerves in neonatal skin. 88 28

The normal adult rat corpus callosum contains numerous axonal profiles that are immunoreactive for the high molecular weight subunit of the neurofilament triplet (NF-H). NF-H immunoreactivity develops gradually during the first 2 postnatal weeks. The expression of NF-H immunoreactivity is almost completely suppressed in rats rendered hypothyroid by neonatal treatment with propylthiouracil. To ensure that the cytoskeletal deficit was due to a shortage of thyroid hormones rather than to unspecific, toxic effects of propylthiouracil, hypothyroid animals kept on the propylthiouracil diet were given restorative thyroxine injections daily. Such animals express NF-H at normal levels. This suggests that the callosal axons may be arrested at an immature stage of development. The immaturity of the hypothyroid corpus callosum can also be revealed by a comparison of the myelin content in the corpus callosum between normal rats, hypothyroid rats, and hypothyroid rats under thyroxine therapy. Hypothyroid rats are severely deficient in myelin, and again this deficit can be corrected by postnatal thyroxine treatment. During normal callosal development, there is a progressive spatial restriction of the transcallosal projection that creates in the adult patches of callosally projecting cortex interposed by acallosal regions. Given the structural immaturity of the hypothyroid callosal axons, it was interesting to investigate the state of development of their topography. For this purpose, multiple injections of wheat germ agglutinin-horseradish peroxidase were made into the occipital and parietal cortices of adult hypothyroid animals. In normal rats, the majority of visual callosally projecting cells are located in three groups--in area 18b, at the boundary of area 17 and 18a, and in the lateral portion of area 18a. Within these areas projecting cells are concentrated in layers II-III, Va, and Vc-VIa. The callosal axon terminals are concentrated in these same regions, with a laminar distribution as far as the somata plus layer I. In the midportion of areas 17 and 18a, fewer callosal cells are found, and they occupy mainly layers Vc-VIa, as in the case for terminals in these same areas. In the parietal cortex, callosal cells and terminals are disposed in vertical arrays alternating with almost empty zones. Most are concentrated in layers III and V. The topography of the callosal axon terminal fields is unaffected by hypothyroidism. However, there is a dramatic redistribution of the callosally projecting cell somata.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Maturation of the corpus callosum of the rat: I. Influence of thyroid hormones on the topography of callosal projections. 229 27

The innervation of the adrenal medulla has been investigated in normal Wistar rats from birth to old age and ultrastructural findings compared with biochemical markers of the cholinergic innervation of the adrenal gland and catecholamine storage. Morphological evidence of the immaturity of the innervation during the first postnatal week is provided and using quantitative morphometry the innervation of chromaffin cells is shown to reach a mean total of 5.4 synapses per chromaffin cell during the period 26 days to 12 weeks of age. The variation in contents of synaptic profiles is discussed in the light of recent work that demonstrates a major sensory as well as visceral efferent innervation of the gland. Adrenal medullary neurons usually occur in closely packed groups, intimately associated with Schwann cells. Axodendritic and axosomatic synapses on these neurons are described and the likely origin of axonal processes innervating the neurons discussed. In old age the density of innervation remains the same as in young adult animals even though the medulla shows evidence of hyperplasia and hypertrophy of individual chromaffin cells.
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PMID:The innervation of the adrenal gland. IV. Innervation of the rat adrenal medulla from birth to old age. A descriptive and quantitative morphometric and biochemical study of the innervation of chromaffin cells and adrenal medullary neurons in Wistar rats. 238 34

The globus pallidus of 20 monkeys ranging in age from newborn to 4 months was examined in Golgi-impregnated material and ultrastructurally. There was no discernible difference between the lateral and medial segments of the structure. At the light microscope level, all neuronal types described in the adult are found at birth. The most common, the large fusifom cell, shows initial signs of immaturity such as blunt protrusions and dendritic dilations at bifurcation points, as well as growth cones, filopodia, and filiform processes. These features become more rare with age, and by 4 months, the neurons appear fully mature save for the terminal dendritic arborizations which are still underdeveloped. From the earliest ages examined, the large globular cells and the interneurons are more mature than the previous type. The afferent radial fibers of striatal origin are observed from birth, but they are grouped in bundles only after 8 weeks. The density of their climbing branches increases over time, reaching a mature appearance by 16 weeks. Afferents entering from the ventral surface do not yet show clusters of varicosities at 2 weeks. At the latter age, plexuses of fine beaded fibers are already seen covering large extensions of the nucleus. The fine structure correlates well with the Golgi material. The basic features of the neuropil are present at birth, albeit with immature characteristics such as the incomplete covering of the dendrites with axonal boutons and the low level of myelination of the radial fibers. Growth cones and profiles with signs of degeneration are observed during the first month. In the early ages examined, most dendrites show large varicosities and protrusions, some of which are spinelike and can be postsynaptic to multiple terminals. The other dendritic type, with only an occasional axodendritic synapse, is also seen from birth and increases in size as a function of time. The type I axonal boutons, of probable striatal origin, are quite immature at birth, and their characteristic interdigitations are seen only after the first week. The type II, III, IV, and V boutons appear mature at all ages examined but crest synapses formed by the type III terminals are observed in the later stages of the study. Finally, postsynaptic vesicle-containing profiles are present at 4 weeks, but triadic synaptic arrangements are formed only by 16 weeks.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Early postnatal development of the monkey globus pallidus: a Golgi and electron microscopic study. 246 20

We have employed immunocytochemical and axonal transport techniques to study the development of major projections to the dorsal striatum of the North American opossum. The opossum is born in a very immature state, 12-13 days after conception, and climbs into an external pouch where it remains attached to a nipple for several months. Its immaturity at birth and its protracted postnatal development make the opossum a good model for developmental studies. Although tyrosine hydroxylase-like immunoreactive (TH-LI), presumably dopaminergic, neurons were present in the ventral mesencephalon at birth (the presumptive substantia nigra and ventral tegmental area), there was no evidence for TH-LI axons in the striatal anlage. By postnatal day (PD)6, a few immunostained axons were found within the putamen. The subsequent growth of TH-LI axons into the striatum followed general caudal to rostral and ventrolateral to dorsomedial gradients and, at any age, they were most numerous in the areas exhibiting the greatest cytodifferentiation. By estimated (E)PD45, TH-LI axons were present in most, if not all, areas of the striatum. Serotoninergic (5-HT)-LI axons were found lateral to the presumptive striatum at birth but not within it. By PD7, however, a few 5-HT-LI axons could be identified in the putamen. The growth of 5-HT-LI axons into the striatum generally followed the same gradients described for TH-LI axons although at all ages their density was much less. Using the orthograde transport of wheat germ agglutinin conjugated to horseradish peroxidase (WGA-HRP), evidence was obtained for the existence of thalamostriatal projections by PD5 and for corticostriatal projections by PD10. Crossed corticostriatal projections were present by EPD23. Our results suggest that the development of major projections to the striatum occurs postnatally in the opossum, rather than prenatally as in placental animals. The timetable for striatal innervation is discussed in light of the developmental sequences established for other motor circuits.
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PMID:The early development of major projections to the dorsal striatum in the North American opossum. 247 8

Single fibre EMG recordings were made from 152 fasciculating motor units in 17 patients with motor neuron disease. All recordings showed abnormal jitter, many (75%) displayed intermittent blocking, and most had abnormal fibre density (mean 4.3), demonstrating considerable degrees of collateral sprouting supported by the fasciculating motor units, and varying degrees of functional immaturity of the new axonal twigs and the motor end plates. The SFEMG abnormalities reflecting both the degree and the recency of collateral reinnervation correlated with the mean interdischarge interval, suggesting that the properties of the generator site depend on the functional state of the fasciculating motor unit as a whole.
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PMID:Fasciculations in motor neuron disease: discharge rate reflects extent and recency of collateral sprouting. 261 32

Unlike the numerous dispersed bulbospinal pathways that are already well myelinated at term, the more compact corticospinal and corticobulbar tracts are only beginning their myelination cycle in late gestation and do not complete it until two years of age. During this same period, these pathways also develop extensive ramification of terminal axonal segments, growth of collateral axons, and proliferation of synapses. Despite their immaturity in the full-term human newborn, several proposed functions may be attributed to the descending pathways from the neonatal cerebral cortex: a) a contribution to the differential development of passive muscle tone and resting postures; in general they function as an antagonist to the "subcorticospinal pathways" in mediating proximal flexion and distal extension, except for the rubrospinal tract which is probably synergistic with the corticospinal tract; b) enhancement of tactile reflexes originating in the brainstem and spinal cord, including suck and swallow; c) relay of epileptic activity of cortical origin; d) inhibition of complex stereotyped motor reflexes including many phenomena formerly termed "subtle seizures"; e) a possible influence on muscle maturation, particularly in relaying cerebellar impulses that modify the histochemical differentiation of myofibres. However, the bulbospinal tracts are probably more influential on muscle development. The corticospinal and corticobulbar tracts subserve different needs in the newborn than at older ages, but are functionally important pathways even at birth.
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PMID:Do the corticospinal and corticobulbar tracts mediate functions in the human newborn? 273 Oct 81

The myenteric plexus and intramuscular nerve bundles in the circular muscle layer of the pylorus from 37 children with infantile hypertrophic pyloric stenosis (IHPS) obtained at pyloromyotomy were studied by light and electron microscopy and compared to six control cases without clinical evidence of IHPS. In certain IHPS cases degenerative alterations of the axons predominated. The axonal changes consisted of (1) severely increased variability of diameters with evidence of degeneration and regeneration of some axons, (2) accumulation of electron-dense bodies, lysosomes and pleomorphic membranous cytoplasmic bodies, (3) increase in the number of maloriented neurofilaments, and (4) aggregation of glycogen granules. Degenerative changes or immaturity of perikarya of neurons and glial cells in the myenteric plexus were not a significant feature. While axonal changes predominated in some IHPS cases there were severe changes of smooth muscle cells in others suggesting that a primarily neurogenic type of IHPS can be distinguished from a predominantly myogenic type. Although the etiology of the axonal changes in IHPS is not clear, it is suggested that they play an important role in the pathogenesis of pyloric stenosis and hypertrophy.
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PMID:Myenteric plexus neuropathy in infantile hypertrophic pyloric stenosis. 281 7

Cytochrome oxidase (CytOx) is known to preferentially stain those regions of the visual cortex which receive direct projections from the thalamus. The pattern of CytOx stain has been used to investigate the maturation of thalamic input to areas V1 and V2 in the newborn monkey. In both areas, the intensity of CytOx activity was similar in newborns and adults. The distribution of CytOx in area V2 was not found to vary with age. In area V1, the only difference in CytOx activity in newborns was a relative immaturity of staining in layer 4C. The callosal connections of visual areas V1 and V2 were investigated by the axonal transport of wheat germ agglutinin conjugated to horseradish peroxidase and free horseradish peroxidase. In the adult, V1 was found to be reciprocally callosally connected for a distance of 1-2.5 mm from the V1/V2 border, whilst V2 was connected for a distance of 3-8 mm from the border. In both areas, callosal connections showed a certain degree of clustering, particularly in V2 which contained 97-98% of the total number of callosal connections of these two areas. In the newborn, the number, tangential extent and clustered distribution of callosal connections were as in the adult. In the newborn, as in the adult, callosal connections coincided with regions of high CytOx activity in area V2. The results showing a relative maturity of the tangential distribution of callosal projecting neurons on the one hand, and an immaturity of thalamic projections on the other, are discussed in terms of: (1) the maturational status of the newborn monkey compared to other mammals at the moment of birth and (2) the possible role of visual experience in shaping cortical connections.
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PMID:The maturational status of thalamocortical and callosal connections of visual areas V1 and V2 in the newborn monkey. 316 1

The commonly held belief that the fetal blood-brain and blood-CSF barriers are immature is reviewed. Results obtained from carefully conducted experiments with horseradish peroxidase and optimal freeze-fracturing suggest that the chick, rat and monkey brain barrier systems to proteins are tight from the earliest stages of development. Previous studies are reviewed in the light of new information on retrograde axonal transport, circumventricular organs, the proper use of horseradish peroxidase, freeze-fracturing, immunocytochemistry and plasma protein gene expression in the developing human brain. Original data on the development of human brain barrier systems are included. Tight junctions between cerebral endothelial and choroid plexus epithelial cells form the morphological basis for these systems. CSF in the fetus contains a remarkably high concentration of protein in contrast to adult CSF which is characterized by a very low protein concentration. This has previously been interpreted as due to immaturity of barriers in the fetal brain. Tight junctions between cerebral endothelial cells and between choroid plexus epithelial cells have been investigated in human embryos and fetuses by freeze fracture and thin section electron microscopy. As soon as the choroid plexus and the brain capillaries differentiated they exhibited well formed tight junctions. These junctions were very complex at early stages of development. A new barrier consisting of 'strap junctions' was found in the developing germinal matrix. The very high concentration of protein in early human fetal CSF cannot be accounted for by a lack of tight junctions in the developing brain barrier systems. Some transfer of proteins from blood to CSF, possibly via an intracellular route, has been demonstrated in immature experimental animals, but it seems that an important contribution to CSF proteins in the fetus may be synthesis by the developing brain and choroid plexuses with subsequent release into the CSF.
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PMID:The development of the human blood-brain and blood-CSF barriers. 353 22


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