Immunohistochemical observation of growth-associated protein 43 (GAP-43) in the developing circumvallate papilla of the rat

The distribution and development of growth-associated protein 43 (GAP-43)-like immunoreactivity (-LI) in the rat circumvallate papilla (CVP) were compared to those of protein gene product 9.5 (PGP 9.5)-LI. In the adult, thick GAP-43-like immunoreactive (-IR) structures gathered densely in the subgemmal region. Some of these further penetrated the apical epithelium and trench wall epithelium. At least two types of GAP-43-IR structures were recognized; taste bud-related and non-gustatory GAP-43-IR neural elements. Immunoelectron microscopy revealed that GAP-43-LI was localized predominantly in the Schwann cells, and a few axons displayed GAP-43-LI in the lamina propria. In the trench epithelium, GAP-43-LI was detected in the cytoplasmic side of the axonal membrane. Some intragemmal GAP-43-IR axons made synaptic-like contacts with taste bud cells. At least four developmental stages were defined on the basis of the changes in distribution of GAP-43-LI. In stage I [embryonic day (E) 16–17] GAP-43-IR structures accumulated at the lamina propria just beneath the newly-formed circumvallate papilla. In stage II (E18–19) GAP-43-IR nerve fibers began to penetrate the apical epithelium. In stage III [E20-postnatal day (P) 0] GAP-43-IR nerve fibers first appeared in the trench wall epithelium. Penetration of GAP-IR nerve fibers occurred in the inner trench wall epithelium first, and then in the outer trench wall epithelium. In stage IV (P1-) the distribution of GAP-43-LI was similar to that observed in the adult; but the density of GAP-43-LI was much higher than in adults. PGP 9.5-LI showed a similar distribution pattern to that of GAP-43-LI, except for round-shaped cells in the apical epithelium at the late embryonic stages, and in taste bud cells and intralingual ganglionic cells which lacked GAP-43-LI. The similarities in distribution patterns of GAP-43-LI and PGP 9.5-LI during the development and mature circumvallate papilla suggest that GAP-43 may be a key neuronal molecule for induction and maintenance of the taste buds.     

Relationship between the chondrocyte maturation cycle and the endochondral ossification in the diaphyseal and epiphyseal ossification centers

The chondrocyte maturation cycle and endochondral ossification were studied in human, fetal cartilage Anlagen and in postnatal meta‐epiphyses. The relationship between the lacunar area, the inter‐territorial fibril network variations, and calcium phosphorus nucleation in primary and secondary ossification centers were assessed using light microscopy and scanning electron microscopy (SEM) morphometry. The Anlage topographic, zonal classification was derived from the anatomical nomenclature of the completely developed long bone (diaphysis, metaphyses and epiphyses). A significant increase in the chondrocyte lacunar area was documented in the Anlage of epiphyseal zones 4 and 3 to zone 2 (metaphysis) and zone 1 (diaphysis), with the highest variation from zone 2 to zone 1. An inverse reduction in the intercellular matrix area and matrix interfibrillar empty space was also documented. These findings are consistent with the osmotic passage of free cartilage water from the interfibrillar space into the swelling chondrocytes, which increased the ion concentrations to a critical threshold for mineral precipitation in the matrix. The mineralized cartilage served as a scaffold for osteoblast apposition both in primary and secondary ossification centers and in the metaphyseal growth plate cartilage, though at different periods of bone Anlage development and with distinct patterns for each zone. All developmental processes shared a common initial pathway but progressed at different rates, modes and organization in diaphysis, metaphysis and epiphysis. In the ossification phase the developing vascular supply appeared to play a key role in determining the cortical or trabecular structure of the long bones. J. Morphol. 277:1187–1198, 2016. © 2016 Wiley Periodicals, Inc.     

The pattern of ATP-creatine phosphotransferase activity in growing long bones of new-born mice

Synopsis The localization of creatine kinase (ATP-creatine phosphotransferase) in growing long bones of new-born mice was studied histochemically. Its activity was found to vary within and between different areas of the cartilagenous epiphyses of proximal tibia. Chondrocytes in the cartilaginous epiphysis showed a high cytoplamatic activity. Active enzyme was also apparent within the growth plate of the diaphysis (with the exception of degenerated cells), in the metaphyseal part of the growth plate within the matrix and in neighbouring areas of the metaphysis, and in areas containing lamella bone. Periosteum and perichondrium also showed signs of enzyme activity. The significance of these findings is discussed in relation to the growth process.     

An in vitro assay of bone development using fetal long bones of mice: morphological studies

The purpose of this study was to examine the morphological changes in an in vitro system in which the two elements of bone modelling, formation and resorption, could be studied simultaneously. Pregnant mice were killed on days 15, 16 and 17 of gestation, the fetuses were removed and the radii and ulnae dissected free of soft tissue. The bones were cultured for 6 days in media (BGJ) supplemented with 20% fetal calf serum and 150 micrograms/ml vitamin C. Growth and mineralization were estimated by measuring the total length of the bone, and diaphysis, and by light and transmission electron microscopy (TEM). The results of this study indicate that there is a continuous measurable increase in the total length of fetal mouse long bones over the 6 days of culture. These bones show a continuous growth of periosteal bone, with mesenchymal tissue penetrating into the diaphyseal shaft, and development of bone marrow like tissue. TEM examination showed differentiation of mesenchymal cells to osteoblasts, formation of new bone matrix and bone mineralization similar to that found in developmentally matched controls. In the cartilagenous epiphyses, however, many hydroxyapatite crystals were not associated with matrix vesicles. In addition, some of the chondrocytes of the hypertrophic zone appeared to be dedifferentiating into mesenchymal cells with osteoblast-like features. In spite of the lack of osteoclasts in the 15- and 16-day explants, osteoclasts appeared in the diaphysis after 2 and 4 days in culture. Our results suggest that this system can serve as a good model for the study of bone formation and resorption as they occur, simultaneously, during bone modelling.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hedgehog signalling is required for perichondral osteoblast differentiation in zebrafish

In tetrapod long bones, Hedgehog signalling is required for osteoblast differentiation in the perichondrium. In this work we analyse skeletogenesis in zebrafish larvae treated with the Hedgehog signalling inhibitor cyclopamine. We show that cyclopamine treatment leads to the loss of perichondral ossification of two bones in the head. We find that the Hedgehog co-receptors patched1 and patched2 are expressed in regions of the perichondrium that will form bone before the onset of ossification. We also show that cyclopamine treatment strongly reduces the expression of osteoblast markers in the perichondrium and that perichondral ossification is enhanced in patched1 mutant fish. This data suggests a conserved role for Hedgehog signalling in promoting perichondral osteoblast differentiation during vertebrate skeletal development. However, unlike what is seen during long bone development, we did not observe ectopic chondrocytes in the perichondrium when Hedgehog signalling is blocked. This result may point to subtle differences between the development of the skeleton in the skull and limb.     

Development and growth of long bones in European water frogs (Amphibia: Anura: Ranidae), with remarks on age determination

Differentiation and development of long bones were studied in European water frogs: Rana lessonae, R. ridibunda, and R. esculenta. The study included premetamorphic larvae (Gosner Stage 40) to frogs that were 5 years old. Femora, metatarsal bones, and proximal phalanges of the hindlimb exhibit the same pattern of periosteal bone differentiation and the same pattern of growth. Longitudinal and radial growth of these bones was studied by examination of the diaphyses and epiphyses, particularly where the edge of periosteal bone is inserted into the epiphysis. The periosteum seems to be responsible for both longitudinal and radial growth. Investigation of the formation, length, and arrangement of lines of arrested growth reveals that the first line is present only in the middle 25-35% of the length of the diaphysis of an adult bone; therefore, only the central portion of the diaphysis should be used for age estimation in skeletochronological studies. Comparison of the shapes and histological structures of epiphyses in the femur, metatarsal bones, and phalanges revealed that epiphyseal cartilages are composed of an inner and outer part. The inner metaphyseal cartilage has distinct zones and plugs the end of the periosteal bone cylinder; its role in longitudinal growth is questioned. The outer epiphyseal cartilage is composed of articular cartilages proper, in addition to lateral articular cartilages. Differences in the symmetry of the lateral articular cartilages of distal epiphyses of the femur and toes may reflect adaptations to different kinds of movements at the knee and in the foot.     

Ossification of the human fetal ilium.

Ossification of the ilium is similar to that of a long bone. It possesses three cartilaginous epiphyses and one cartilaginous process. Moreover, it undergoes peculiar osteoclastic resorption, comparable with that of the cranium bones. Asymmetrical ossification of the ilium, haversian bone remodelling and apposition of chondroid tissue posterosuperiorly to the acetabulum most probably emphasize the importance of mechanical factors in the morphogenesis of the hip bone during fetal life.     

Co-expression of GAP-43 and nNOS in avulsed motoneurons and their potential role for motoneuron regeneration

Neuronal nitric oxide synthase (nNOS) is induced after axonal injury. The role of induced nNOS in injured neurons is not well established. In the present study, we investigated the co-expression of nNOS with GAP-43 in spinal motoneurons following axonal injury. The role of induced nNOS was discussed and evaluated. In normal rats, spinal motoneurons do not express nNOS or GAP-43. Following spinal root avulsion, expression of nNOS and GAP-43 were induced and colocalized in avulsed motoneurons. Reimplantation of avulsed roots resulted in a remarkable decrease of GAP-43- and nNOS-IR in the soma of the injured motoneurons. A number of GAP-43-IR regenerating motor axons were found in the reimplanted nerve. In contrast, the nNOS-IR was absent in reimplanted nerve. These results suggest that expression of GAP-43 in avulsed motoneurons is related to axonal regeneration whereas nNOS is not.     

Cellular reactions to axotomy in rat superior cervical ganglia includes apoptotic cell death

The cellular response to axonal injury in the superior cervical ganglion was examined by immunofluoresence at intervals from 6 h to 14 days after transection of the internal and external carotid nerves. GAP-43-immunoreactivity (IR) appeared in some neurons in the ganglia 1 day after axotomy, while neurons in control ganglia were GAP-43 negative. In 3 days axotomized ganglia GAP-43-IR structures were increased in number and intensity in nerve fiber bundles, while GAP-43-positive perikarya were restricted to the middle and caudal parts of the ganglia and showed an intensity that was stronger than at 1 day after axotomy. These GAP-43-positive neurons were also galanin positive. In the cranial part of the ganglia, S100-IR in satellite cells was weak at 18 h after axotomy. Peripheral to this area, S100-IR was stronger and co-localized with HSP-72-IR, preferentially located in satellite cells. HSP-72-IR was, however, occasionally observed also in principal neurons at 1 and 3 days after axotomy. In eosin-stained sections, neurons and satellite cells in the cranial part of 1 day axotomized ganglia were reduced in number, and a further loss was noted at 3 days. At 12 h some satellite cells in the cranial part of the ganglia were labelled by the in situ DNA 3'-end labelling method, indicating apoptosis, and at 18 h many cells were labelled. Some neuronal perikarya were also labelled in this region. Labelling was not observed at 1 day or later after axotomy, nor in control ganglia. The results may imply that not only neurons but also satellite cells react to neuronal axonal injury with apoptosis. Neurons in the middle and caudal part of the ganglia survived and showed increased content of GAP-43 and galanin, possibly a sign of regeneration/neuronal plasticity.     

Quantitative comparison of growth-associated protein GAP-43, neuron-specific enolase, and protein gene product 9.5 as neuronal markers in mature human intestine.

This study was performed to compare GAP-43, PGP 9.5, synaptophysin, and NSE as neuronal markers in the human intestine. GAP-43-immunoreactive nerve fibers were abundant in all layers of the ileum and colon. GAP-43 partially co-localized partially with every neuropeptide (VIP, substance P, galanin, enkephalin) studied. All neuropeptide-immunoreactive fibers also showed GAP-43 reactivity. By blind visual estimation, the numbers of GAP-43-immunoreactive fibers in the lamina propria were greater than those of PGP 9.5, synaptophysin, or NSE. In the muscle layer, visual estimation indicated that the density of GAP-43-immunoreactive fiber profiles was slightly greater than that of the others. The number and intensity of GAP-43-, PGP 9.5-, and NSE-immunoreactive fibers were estimated in sections of normal human colon and ileum using computerized morphometry. In the colon, the numbers of GAP-43-immunoreactive nerve profiles per unit area and their size and intensity were significantly greater than the values for PGP and NSE. A similar trend was observed in the ileum. Neuronal somata lacked or showed only weak GAP-43 immunoreactivity, variable PGP 9.5 immunoreactivity, no synaptophysin immunoreactivity, and moderate to strong NSE immunoreactivity. We conclude that GAP-43 is the superior marker of nerve fibers in the human intestine, whereas NSE is the marker of choice for neuronal somata. (J Histochem Cytochem 47:1405-1415, 1999)     

Epigenetic mechanical factors in the evolution of long bone epiphyses

In developing vertebrate long bones in which endochondral ossification occurs, it is preceded or accompanied by perichondral ossification. The speed and extent of perichondral apposition relative to endochondral ossification varies in different taxa. Perichondral ossification dominates early long bone development in extinct basal tetrapods and dinosaurs, extant bony fish, amphibians, and birds. In mammals and lizards, perichondral and endochondral ossification proceed more synchronously. One of the most important epigenetic factors in skeletogenesis is mechanical loading caused by muscle contractions which begin in utero or in ovo . It has been previously shown that the stress distributions created perinatally in the chondroepiphysis during human skeletal development can influence the appearance of secondary ossification centres. Using finite element computer models representing bones near birth or hatching, we demonstrate that in vertebrates in which perichondral ossification significantly precedes endochondral ossification, the distribution of mechanical stresses in the ossifying cartilage anlagen tends to inhibit the appearance of secondary ossification centres in the ends of long bones. In models representing vertebrates in which endochondral ossification keeps pace with perichondral apposition, the appearance of secondary centres is promoted. The appearance of secondary centres leads to the formation of bony epiphyses and growth plates, which are most common in mammals and extant lizards. We postulate that genotypic factors influencing the relative speed and extent of perichondral and endochondral ossification interact with mechanical epigenetic factors early in development to account for many of the morphological differences observed in vertebrate skeletons.     

A microanatomical and histological study of the fin long bones of the Devonian sarcopterygian Eusthenopteron foordi

Meunier F.J. and Laurin M. 2012. A microanatomical and histological study of the fin long bones of the Devonian sarcopterygian Eusthenopteron foordi. —Acta Zoologica (Stockholm) 93 : 88–97. A paleohistological study of the endoskeletal bones of the dorsal and pelvic fins shows that Eusthenopteron foordi had true long bones that grew in length and thickness through endochondral and periosteal ossification, respectively. Endochondral ossification required cartilaginous epiphyses with a growth plate system whose presence is confirmed by both calcified cartilage and thin endochondral bony trabeculae that overlaid the erosive bays located in hypertrophic calcified cartilage. Articulations between axial mesomeres in paired fins were diarthroses. This microanatomical organization, i.e. longitudinal growth of diaphysis and articulations between epiphyses, can be considered an exaptation for terrestrial locomotion as it can produce skeletal elements able to support strong mechanical stress.     

Alterations in growth-associated protein (GAP-43) expression in lower urinary tract pathways following chronic spinal cord injury

Alterations in the expression of growth-associated protein 43 (GAP-43) were examined in lower urinary tract micturition reflex pathways 6 or 8 weeks following complete spinal cord transection (~ T9). In control animals, expression of GAP-43 was present in specific regions of the gray matter in the rostral lumbar and caudal lumbosacral spinal cord, including: (1) the dorsal commissure; (2) the corticospinal tract; (3) the dorsal horn; and (4) the regions of the intermediolateral cell column (L1-L2) and the sacral parasympathetic nucleus (L6-S1); and (5) in the lateral collateral pathway of Lissauer in L6-S1 spinal segments. Densitometry analysis has demonstrated significant increases (p 0.001; 1.3-6.4-fold increase) in GAP-43-immunoreactivity (IR) in these regions of the rostral lumbar (L1-L2) and caudal lumbosacral (L6-S1) spinal cord 6 weeks following spinal cord injury. Changes in GAP-43-IR were restricted to the L1-L2 and L6-S1 segments that are involved in lower urinary tract reflexes. Changes in GAP-43-IR were not observed at the L5 segmental level except for an increase in GAP-43-IR in the superficial, dorsal horn at 6 weeks post-injury. In all segments examined, GAP-43-IR was decreased (2-5-fold) in the corticospinal tract (dorsal division) 6 and 8 weeks following spinal cord injury. Eight weeks following spinal cord injury, changes in GAP-43-IR had returned to control levels except for the persistence of increased GAP-43-IR in the region of the sacral parasympathetic nucleus and the lateral collateral pathway in the S1 spinal segment. Alterations in GAP-43-IR following chronic spinal cord injury may suggest a reorganization of bladder afferent projections and spinal elements involved in urinary bladder reflexes consistent with alterations in urinary bladder function (hyperreflexia) observed in animals following spinal cord injury above the lumbosacral spinal cord.     

Alterations in growth-associated protein (GAP-43) expression in lower urinary tract pathways following chronic spinal cord injury

Alterations in the expression of growth-associated protein 43 (GAP-43) were examined in lower urinary tract micturition reflex pathways 6 or 8 weeks following complete spinal cord transection (approximately T9). In control animals, expression of GAP-43 was present in specific regions of the gray matter in the rostral lumbar and caudal lumbosacral spinal cord, including: (1) the dorsal commissure; (2) the corticospinal tract; (3) the dorsal horn; and (4) the regions of the intermediolateral cell column (L1-L2) and the sacral parasympathetic nucleus (L6-S1); and (5) in the lateral collateral pathway of Lissauer in L6-S1 spinal segments. Densitometry analysis has demonstrated significant increases (p < or =0.001; 1.3-6.4-fold increase) in GAP-43-immunoreactivity (IR) in these regions of the rostral lumbar (L1-L2) and caudal lumbosacral (L6-S1) spinal cord 6 weeks following spinal cord injury. Changes in GAP-43-IR were restricted to the L1-L2 and L6-S1 segments that are involved in lower urinary tract reflexes. Changes in GAP-43-IR were not observed at the L5 segmental level except for an increase in GAP-43-IR in the superficial, dorsal horn at 6 weeks post-injury. In all segments examined, GAP-43-IR was decreased (2-5-fold) in the corticospinal tract (dorsal division) 6 and 8 weeks following spinal cord injury. Eight weeks following spinal cord injury, changes in GAP-43-IR had returned to control levels except for the persistence of increased GAP-43-IR in the region of the sacral parasympathetic nucleus and the lateral collateral pathway in the S1 spinal segment. Alterations in GAP-43-IR following chronic spinal cord injury may suggest a reorganization of bladder afferent projections and spinal elements involved in urinary bladder reflexes consistent with alterations in urinary bladder function (hyperreflexia) observed in animals following spinal cord injury above the lumbosacral spinal cord.     

Soft-tissue bone interface: How do attachments of muscles,tendons, and ligaments change during growth? A light microscopic study

This study addressed the problem of how soft structures maintain approximately the same relative positional relationships during long bone growth. Attachments of the popliteus muscle, semitendinosus tendon, medial collateral knee ligament, and extensor retinaculum were examined histologically in rabbits, aged 2-60 days, to determine the manner in which soft structures attached to long bones during growth. Soft structures inserted principally into fibrous periosteum or perichondrium in the age range studied. However, an extensive collagen fiber framework within the cellular periosteum and perichondrium, present by at least 2 days of age, linked the fibrous periosteum or perichondrium to subjacent bone or cartilage. Maturation of soft tissue-bone interfaces was viewed from two related perspectives. The first stressed temporal patterning of cartilage and bone differentiation. The second emphasized incorporation of attachments of soft structures into bone and cartilage matrices during growth and remodeling. Differentiation and remodeling of bone and cartilage varied not only with age, but also between regions of attachment of single muscles and ligaments. Insertion regions were characterized by the presence of coarse-fibered periosteal bone and chondroid bone, both morphologically intermediate between fibrocartilage and lamellar bone. These results provide evidence that periosteal attachments, characterizing the soft-tissue bone interface, are a necessary structural prerequisite for compensatory movement and invariance of the relative positions of muscles, tendons, and ligaments during long bone growth.     

Immunocytochemical evidence of plasticity in the nervous structures of the rat lower lip

In this immunocytochemical study we investigated the distribution of nervous structures in the lower lip of adult rats. The region is characterized by a rich cutaneous and mucosal sensory innervation originating from terminal branches of the trigeminal system. Lower lip innervation was investigated by detection of the general neuronal marker protein gene product 9.5 (PGP 9.5) and the growth-associated protein 43 (GAP-43), a neurochemical marker of neuronal plasticity. The entire neural network of both cutaneous and mucosal aspects was stained by the antibody to PGP 9.5. In particular, nerve fibers were observed in the submucosal and the subepithelial plexuses. Thin immunoreactive fibers were observed within the epithelial layers ending as free fibers or as fibers associated with immunopositive Merkel cells. Well-identified anatomical structures receiving sensory or autonomic innervation were also surrounded by PGP 9.5-ir nerve fibers, in particular, hair follicles, vibrissae, glands, and blood vessels. GAP-43-immunostained nerve fibers were observed in all these structures; however, they were generally less numerous than the PGP 9.5-immunoreactive elements. An equal amount of PGP 9.5 and GAP-43 immunoreactivity occurred, in contrast, in the subepidermal and the submucosal plexuses, or in the epidermis and the mucosal epithelium. The present results show that GAP-43 is normally expressed in the mature trigeminal sensory system of the rat. Skin and oral mucosa are characterized by continuous remodeling that may also involve the sensory nervous apparatus. Continuous neural remodeling, regeneration and sprouting may be the reason for the observed expression of GAP-43.     

Distribution of GAP-43-immunoreactive structures in the human fetal amygdala.

The growth-associated protein GAP-43 is a developmentally regulated protein which is involved in the formation of neuronal contacts. In immunohistochemical studies, GAP-43 is detected within axons during their elongation; thus a fibrous immunoreactivity is visible. After axonal growth is completed there is a shift from a fibrous to a punctate immunoreactivity. The latter has been shown to correlate with synaptogenesis. In the amygdala of the 5th gestational month, a fibrous GAP-43-immunoreactivity is seen in the basolateral nuclei, whereas the corticomedial nuclei exclusively show a punctate immunoreactivity. In the 7th month, all amygdaloid nuclei display immunoreactive puncta, but no fibers. In the 9th month GAP-43-immunoreactivity is no longer visible within the amygdala. The results demonstrate the differential distribution of GAP-43-immunoreactive structures in the amygdaloid nuclei. The nuclear specific immunostaining and its changes may indicate the sequential appearance of the monoaminergic innervation of the amygdala, as GAP-43 is known to occur in monoaminergic systems. Nuclei involved in high levels of the cortical processing hierarchy such as the lateral or basal nucleus display a late occurrence of GAP-43-immunoreactivity. In general, anti-GAP-43 has been shown to be an appropriate tool to investigate axonal growth and synaptogenesis in the developing human brain.     

Cellular and molecular interactions regulating skeletogenesis

Skeletal development involves complex coordination among multiple cell types and tissues. In long bones, a cartilage template surrounded by the perichondrium is first laid down and is subsequently replaced by bone marrow and bone, during a process named endochondral ossification. Cells in the cartilage template and the surrounding perichondrium are derived from mesenchymal cells, which condense locally. In contrast, many cell types that make up mature bone and in particular the bone marrow are brought in by the vasculature. Three tissues appear to be the main players in the initiation of endochondral ossification: the cartilage, the adjacent perichondrium, and the invading vasculature. Interactions among these tissues are synchronized by a large number of secreted and intracellular factors, many of which have been identified in the past 10 years. Some of these factors primarily control cartilage differentiation, while others regulate bone formation and/or angiogenesis. Understanding how these factors operate during skeletal development through the analyses of genetically altered mice depends on being able to distinguish the effect of these molecules on the different cell types that comprise the skeleton. This review will discuss the complexity of skeletal phenotypes, which arises from the tightly regulated, complex interactions among the three tissues involved in bone development. Specific examples illustrate how gene functions may be further assessed using new approaches including genetic and tissue manipulations.     

Increase of CGRP-Containing Nerve Fibers in the Rat Periodontal Ligament After Luxation

The distribution of calcitonin gene-related peptide (CGRP) was examined in the periodontal ligament (PDL) after experimental luxation injury of the rat first molar tooth. The luxational injury increased the number of CGRP-immunoreactive (IR) nerve fibers. At 3–7 days, numerous CGRP-IR nerve fibers appeared throughout the injured PDL. These nerve fibers terminated as free nerve endings within resorption cavities. Immunohistochemistry for receptor activity modifying protein 1 (RAMP1) also demonstrated that the subunit of CGRP receptor was expressed by periodontal cells adjacent to the alveolar bone in the intact and injured PDL. RAMP1-IR cells were divided into two types; small cells with single nucleus and large cells with 2–6 nuclei. After the luxational injury, both types of RAMP1-IR cells abundantly appeared within resorption cavities. As a result, the treatment increased the number of large RAMP1-IR cells at 3–7 days and small RAMP1-IR cells at 7 days. In addition, a double immunofluorescence analysis demonstrated that CGRP-IR nerve fibers were seen away from RAMP1-IR cells in the intact PDL. After the traumatic injury, however, CGRP-IR nerve fibers appeared in the close vicinity of small and large RAMP1-IR cells at 5–7 days. The morphology and distribution of RAMP1-IR cells suggest that they contain osteoblasts and osteoclasts. By affecting osteoclasts and osteoblasts, CGRP may have effects on bone remodeling in the luxated PDL.     

Growth and shaping of metacarpal and carpal cartilage anlagen: application of morphometry to the development of short and long bone. A study of human hand anlagen in the fetal period

A histological and morphometric analysis of human metacarpal and carpal anlagen between the 16th and 22nd embryonic weeks was carried out with the aim of studying the establishment of the respective anlage architecture. No differences in the pattern of growth were documented between the peripheral and central zones of the metacarpal epiphyses and those of the carpals. The regulation of longitudinal growth in long bone anlagen occurred in the transition zone between the epiphysis and the diaphysis (homologous to the metaphyseal growth plate cartilage in more advanced developmental stage of the bone). Comparative zonal analysis was conducted to assess the chondrocyte density, the mean chondrocyte lacunar area, the paired chondrocyte polarity in the orthogonal longitudinal and transverse planes, and the lacunar shape transformation in the metacarpal. In transition from epiphysis to diaphysis chondrocyte density decreased and mean lacunar area increased. No significant differences in the chondrocyte maturation cycle were observed between proximal/distal metacarpal epiphyses and the carpal anlagen. The number of paired chondrocyte oriented along the growth vector was significantly higher in both proximal/distal transition zones between epiphysis and diaphysis. Human metacarpals shared with experimental models (like mice and nonmammal tetrapods) an early common chondrocyte maturation cycle but with a different timing due to the slower embryonic and fetal developmental rate of human anlagen.