Cartilaginous bone extremities of growing monotremes appear unique

Cartilage canals are present in the epiphyseal cartilage of most mammals and birds. They are considered necessary for the maintenance of chondrocytes and for the formation of epiphyseal ossification centers. The epiphyseal cartilage of marsupials was recently shown not to contain cartilage canals, and placental rats appear not to have cartilage canals, although some confusion exists in the literature. The present study examines the cartilaginous epiphyses and physes from the knee and hip of the rat and the two Australian monotremes (platypus, Ornithorhynchus anatinus and echidna, Tachyglossus aculeatus). In all three species, cartilage canals were absent. Vessels to epiphyseal ossification centers were present, however. In the center of the cartilaginous femoral head of the echidna, but not in the platypus or rat, there was a large cavity, which contained connective tissue and was lined by an endochondrium of chondroproginator cells. These appeared to be contributing to growth of the cartilaginous epiphysis. No similar structure has previously been described in the cartilaginous epiphysis of other species. There was no ligament of the femoral head in the hip joints of the monotremes, and it is suggested the absence of a ligament may be significant in the development of the cavity. It was noted in all specimens that despite being avascular the epiphyseal and physeal cartilage appeared viable and functionally normal. The small size of the cartilaginous epiphyses of the rat may account for their avascularity; but the epiphyses of the monotremes were much larger, especially the echidna, yet still avascular. These features provide strong evidence for fundamental differences between the avascular cartilage of monotremes and the vascular cartilage of most mammals.     

Absence of cartilage canals in the long bone extremities of four species of skeletally immature marsupials

The cartilaginous epiphyses and physes from the bone extremities of four species of skeletally immature marsupials were studied. The microscopic and ultrastructural features of the marsupial tissues were compared with similar samples from a neonatal lamb and a 1-day-old chick. Chondrocyte differentiation and endochondral ossification appeared similar in physes from the marsupials, foetal lamb, and 1-day-old chick. However, unlike the lamb and chick, which both contained cartilage canals, there were no cartilage canals in the epiphyseal or physeal cartilage from the marsupials. Many of the epiphyseal chondrocytes from the marsupial specimens contained large lipid droplets. It is suggested that the lipids in marsupial chondrocytes may be utilized in metabolic pathways. Despite hypertrophy of chondrocytes, there were no epiphyseal ossification centers in the femoral heads of the marsupial specimens; this was possibly due to the absence of cartilage canals, which are considered a source of osteoproginator cells. This study indicates that physeal and epiphyseal cartilage in marsupials is viable and functions in an avascular environment; this may be due to unique metabolic properties of the chondrocytes.     

Microvascular features and ossification process in the femoral head of growing rats

In the epiphysis of long bones, different patterns of development of ossification processes have been described in different species. The development of the vascularisation of the femoral head has not yet been fully clarified, although its role in the ossification process is obvious. Our aim was to investigate ossification and vascular proliferation and their relationship, in growing rat femoral heads. Male Wistar rats aged ～ 1, 5 and 8 wk and 4, 8 and 12 mo were used. Light microscopy frontal sections and vascular corrosion casts observed by scanning electron microscopy were employed. In the rat proximal femoral epiphysis, ossification develops from the medullary circulation of the diaphysis, quickly extending to the neck and the base of the head. Hypertrophic chondrocytes occupy the epiphyseal cartilage, and a physeal plate with regular cell columns is present. Starting from about the end of the third month one or more points of fibrovascular outgrowth, above the physeal line, can be observed in each sample. They are often placed centrally or, sometimes, peripherally. The fibrovascular outgrowths penetrate deeply into the cartilage and extend laterally. At age 8 mo, large fibro-osseous peduncles connect the epiphysis to the diaphyseal tissue. At 12 mo, the entire epiphysis appears calcified with an almost total absence of residual cartilage islands. This situation differs in man and in other mammals due both to differing thickness of the cartilage and to the presence of more extensive sources of blood vessels other than the diaphyseal microcirculation, as supplied by the teres ligament and Hunter's circle. In young rats, subchondral vessels and the synovial fluid could play a role in feeding the ossifying cartilage. Later, a loss of resistance of the physis due to marked degeneration of the cell columns, and extensive chondrocyte hypertrophy permit fibrovascular penetration starting from diaphyseal vessels rather than neighbouring vascular territories, such as those of the periosteum and capsule.     

Vascular changes in induced abnormal bone growth in lambs

In lambs, unilateral hip excision arthroplasty induced angular and torsional deformities in the contralateral limb and the vascular changes associated with abnormal bone growth in distal tibiae and metatarsi have been studied. Eosinophilic septa separating physeal cartilage columns were more frequent and prominent in association with physeal osteochondrosis. Epiphyseal vessels traversed thickened physeal cartilage to an abnormal depth and resulted in protrusions of epiphyseal bone and an irregular epiphyseal bone plate. In some cases, epiphyseal vessels crossed the whole physis and arboresced after turning through 180 degrees. This vascular pattern appears to occur as a reparative response.     

Identification and location of bone-forming cells within cartilage canals on their course into the secondary ossification centre

Osteoblasts and osteocytes derive from the same precursors, and osteocytes are terminally differentiated osteoblasts. These two cell types are distinguishable by their morphology, localization and levels of expression of various bone cell-specific markers. In the present study on the chicken femur we investigated the properties of the mesenchymal cells within cartilage canals on their course into the secondary ossification centre (SOC). We examined several developmental stages after hatching by means of light microscopy, electron microscopy, immunohistochemistry and in situ hybridization. Cartilage canals appeared as extensions of the perichondrium into the developing distal epiphysis and they were arranged in a complex network. Within the epiphysis an SOC was formed and cartilage canals penetrated into it. In addition, they were successively incorporated into the SOC during its growth in the radial direction. Thus, the canals provided this centre with mesenchymal cells and vessels. It should be emphasized that regression of cartilage canals could never be observed in the growing bone. Outside the SOC the mesenchymal cells of the canals expressed type I collagen and periostin and thus these cells had the characteristics of preosteoblasts. Periostin was also expressed by numerous chondrocytes. Within the SOC the synthesis of periostin was down-regulated and the majority of osteoblasts were periostin negative. Furthermore, osteocytes did not secret this protein. Tissue-non-specific alkaline phosphatase (TNAP) staining was only detectable where matrix vesicles were present. These vesicles were found around the blind end of cartilage canals within the SOC where newly formed osteoid started to mineralize. The vesicles originated from osteoblasts as well as from late osteoblasts/preosteocytes and thus TNAP was only expressed by these cells. Our results provide evidence that the mesenchymal cells of cartilage canals express various bone cell-specific markers depending on their position. We suggest that these cells differentiate from preosteoblasts into osteocytes on their course into the SOC and consider that cartilage canals are essential for normal bone development within the epiphysis. Furthermore, we propose that the expression of periostin by preosteoblasts and several chondrocytes is required for adhesion of these cells to the extracellular matrix.     

Discontinuities in the endothelium of epiphyseal cartilage canals and relevance to joint disease in foals

Cartilage canals have been shown to contain discontinuous blood vessels that enable circulating bacteria to bind to cartilage matrix, leading to vascular occlusion and associated pathological changes in pigs and chickens. It is also inconsistently reported that cartilage canals are surrounded by a cellular or acellular wall that may influence whether bacterial binding can occur. It is not known whether equine cartilage canals contain discontinuous endothelium or are surrounded by a wall. This study aimed to examine whether there were discontinuities in the endothelium of cartilage canal vessels, and whether canals had a cellular or acellular wall, in the epiphyseal growth cartilage of foals. Epiphyseal growth cartilage from the proximal third of the medial trochlear ridge of the distal femur from six healthy foals that were 1, 24, 35, 47, 118 and 122 days old and of different breeds and sexes was examined by light microscopy (LM), transmission electron microscopy (TEM) and immunohistochemistry. The majority of patent cartilage canals contained blood vessels that were lined by a thin layer of continuous endothelium. Fenestrations were found in two locations in one venule in a patent cartilage canal located deep in the growth cartilage and close to the ossification front in the 118‐day‐old foal. Chondrifying cartilage canals in all TEM‐examined foals contained degenerated endothelial cells that were detached from the basement membrane, resulting in gap formation. Thirty‐three percent of all canals were surrounded by a hypercellular rim that was interpreted as contribution of chondrocytes to growth cartilage. On LM, 69% of all cartilage canals were surrounded by a ring of matrix that stained intensely eosinophilic and consisted of collagen fibres on TEM that were confirmed to be collagen type I by immunohistochemistry. In summary, two types of discontinuity were observed in the endothelium of equine epiphyseal cartilage canal vessels: fenestrations were observed in a patent cartilage canal in the 118‐day‐old foal; and gaps were observed in chondrifying cartilage canals in all TEM‐examined foals. Canals were not surrounded by any cellular wall, but a large proportion was surrounded by an acellular wall consisting of collagen type I. Bacterial binding can therefore probably occur in horses by mechanisms that are similar to those previously demonstrated in pigs and chickens.     

Structure, formation and role of cartilage canals in the developing bone

In the long bones, endochondral bone formation proceeds via the development of a diaphyseal primary ossification centre (POC) and an epiphyseal secondary ossification centre (SOC). The growth plate, the essential structure for longitudinal bone growth, is located between these two sites of ossification. Basically, endochondral bone development depends upon neovascularization, and the early generation of vascularized cartilage canals is an initial event, clearly preceding the formation of the SOC. These canals form a discrete network within the cartilaginous epiphysis giving rise to the formation of the marrow space followed by the establishment of the SOC. These processes require excavation of the provisional cartilaginous matrix which is eventually replaced by permanent bone matrix. In this review, we discuss the formation of the cartilage canals and the importance of their cells in the ossification process. Special attention is paid to the enzymes required in disintegration of the cartilaginous matrix which, in turn, will allow for the invasion of new vessels. Furthermore, we show that the mesenchymal cells of the cartilage canals express bone-relevant proteins and transform into osteocytes. We conclude that the canals are essential for normal epiphyseal bone development, the establishment of the growth plate and ultimately longitudinal growth of the bones.     

Basement membrane composition of cartilage canals during development and ossification of the epiphysis

Background: Cartilage canals are perichondral invaginations of blood vessels and connective tissue that are found within the epiphyses of most mammalian long bones. Functionally, they provide a means of transport of nutrients to the hyaline cartilage, a mechanism for removal of metabolic wastes, and a conduit for stem cells that are capable of initiating and sustaining ossification of the chondroepiphysis. Morphological and biomolecular changes of the chondroepiphyses appear to potentiate vascular invasion and enable regional formation of secondary centers of ossification within the chondroepiphyses of developing bones. Methods: As both cell migration and vascular invasion are anchorage dependent processes, antibodies to laminin and Type IV collagen were used to assess compositional changes in the basement membrane of cartilage canals accompanying epiphyseal ossification. Results: Differences in chronological appearance, as well as, in distribution between the two components were noted in the chondroepiphysis. Laminin was distributed throughout the connective tissue of cartilage canal at all stages of developement, and not limited to an association with the vascular lumen. Type IV collagen was not Present during the initial perichondral invagination. Although staining for Type IV collagen was later acquired, its distribution was restricted to a discontinuous rimming of the periphery of the canal, and a diffuse presence within the intra-canalicular mesenchyme. Conclusions: Concurrent with chondrocyte hypertrophy and mineralization of the hyaline matrix, rapid changes in both the morphology of the vessel and distribution of the antibodies were detected. In addition to the presence of laminin at the interface of the endothelium and the hyaline matrix, a wide distribution within the connective tissue components of the newly ossifying matrix of epiphyseal bone could be detected. Type IV collagen remained closely associated with the lumens of the intra-canalicular vessels throughout the transition. Following ossification of the secondary center, staining for Type IV collagen could then be detected in the boneforming regions of transforming matrix as well, clearly delineating the individual vessels within the newly formed marrow spaces. This suggests that bone formation is intimately related to vessel staining for collagen type IV, and that acquired vessel competence is a facet of endochondral bone formation that results from provisional matrix changes. Furthermore, the data suggests that during bone formation under tension, basement membrane deposition can be demonstrated without an intermediary hyaline matrix hypertrophic chondrocyte phase. This data was interpreted to suggest that chondrocyte hypertrophy at the growth plate may be a reaction to vascular invasion, that in turn, stimulates adjacent chondrocyte proliferation. © 1995 Wiley-Liss, Inc.     

VEGF and its role in the early development of the long bone epiphysis

In long bones of murine species, undisturbed development of the epiphysis depends on the generation of vascularized cartilage canals shortly after birth. Despite its importance, it is still under discussion how this event is exactly regulated. It was suggested previously that, following increased hypoxia in the epiphyseal core, angiogenic factors are expressed and hence stimulate the ingrowth of the vascularized canals. In the present study, we tested this model and examined the spatio‐temporal distribution of two angiogenic molecules during early development in mice. In addition, we investigated the onset of cartilage hypertrophy and mineralization. Our results provide evidence that the vascular endothelial growth factor is expressed in the epiphyseal resting cartilage prior to the moment of canal formation and is continuously expressed until the establishment of a large secondary ossification centre. Interestingly, we found no expression of secretoneurin before the establishment of the canals although this factor attracts blood vessels under hypoxic conditions. Epiphyseal development further involves maturation of the resting chondrocytes into hypertrophic ones, associated with the mineralization of the cartilage matrix and eventual death of the latter cells. Our results suggest that vascular endothelial growth factor is the critical molecule for the generation of the epiphyseal vascular network in mice long bones. Secretoneurin, however, does not appear to be a player in this event. Hypertrophic chondrocytes undergo cell death by a mechanism interpreted as chondroptosis.     

Ossification in the human calcaneus: a model for spatial bone development and ossification

Perichondral bone, the circumferential grooves of Ranvier and cartilage canals are features of endochondral bone development. Cartilage canals containing connective tissue and blood vessels are found in the epiphysis of long bones and in cartilaginous anlagen of small and irregular bones. The pattern of cartilage canals seems to be integral to bone development and ossification. The canals may be concerned with the nourishment of large masses of cartilage, but neither their role in the formation of ossification centres nor their interaction with the circumferential grooves of Ranvier has been established. The relationships between cartilage canals, perichondral bone and the ossification centre were studied in the calcaneus of 9 to 38-wk-old human fetuses, by use of epoxy resin embedding, three-dimensional computer reconstructions and immunhistochemistry on paraffin sections. We found that cartilage canals are regularly arranged in shells surrounding the ossification centre. Whereas most of the shell canals might be involved in the nourishment of the cartilage, the inner shell is directly connected with the perichondral ossification groove of Ranvier and with large vessels from outside. In this way the inner shell canal imports extracellular matrix, cells and vessels into the cartilage. With the so-called communicating canals it is also connected to the endochondral ossification centre to which it delivers extracellular matrix, cells and vessels. The communicating canals can be considered as inverted 'internal' ossification grooves. They seem to be responsible for both build up intramembranous osteoid and for the direction of growth and thereby for orientation of the ossication centre.     

Cartilage canals in human thyroid cartilage characterized by immunolocalization of collagen types I, II, pro-III, IV and X

In this study the collagenous composition of cartilage canals in human thyroid cartilage, which are perichondral invaginations of blood vessels and connective tissue, and the surrounding cartilage matrix were investigated by immunolabelling with specific antibodies against type I, II, pro-III, IV and X collagen. During childhood and early adolescence no cartilage canals were detected in thyroid cartilage, and immunolabelling for type IV collagen was restricted to basal lamina components of blood vessels in the perichondrium. First immunolabelling for type IV collagen, belonging to blood vessels in cartilage canals, in both sexes was detected about the end of the second decade; it was localized in the dorsal part of the thyroid cartilage plate. At this time thyroid cartilage has already reached its final form and size. As revealed by von Kossa staining, vascularization preceded mineralization and ossification. In contrast to the male thyroid cartilage plate, no immunostaining for type IV collagen and no ossification was detected in the ventral half of female thyroid cartilage even in advanced age. The extracellular matrix of cells in cartilage canals showed positive immunostaining for collagen types I and pro-III as well as for collagen type II, indicating that the cells in the canal possess fibroblastic and chondrogenic properties. The extracellular matrix of hypertrophic chondrocytes adjacent to cartilage canals showed strong immunoreactivity for type X collagen. First mineralization was detected close to cartilage canals, suggesting that mineralization in human thyroid cartilage starts in the extracellular matrix adjacent to cartilage canals.     

骨膜环行切除对骨骺牵张肢体延长的作用

目的：为临床骨延长术提供方向。方法：选用２０只新西兰幼兔在股骨远端骺软骨两侧安装外固定架和力传感器,半数动物在骺软骨近侧作骨膜环行切除,分别向骺软骨施加不同张力,４周后测量股骨长度,Ｘ线摄像,并做骺软骨细胞ＫＳ－４００图像分析。结果：张应力能使兔股骨明显增长,骺软骨厚度增加,其增殖区和肥大区细胞增加,骨骺与干骺端均未见骨折,与骨膜环行切除与否无显著性差异。结论：低张应力牵拉骨骺能实现无骨折下肢体延长,骨骺牵张结合干骺端骨膜环形切除并不能更进一步使肢体增长。     

Cytochemical localization of tartrate-resistant acid phosphatase,alkaline phosphatase,and nonspecific esterase in perivascular cells of cartilage canals in the developing mouse epiphysis

Cytochemical localization of tartrate-resistant acid phosphatase (TRAP), tartratc-sensitive acid phosphatases (TSAP), alkaline phosphatase, and nonspecific esterase was used to characterize perivascular cells within cartilage canals. In the distal femoral epiphyses of 5- to 7-day-old mice, three stages of canal development can be distinguished, and at each developmental stage different perivascular cells were present with morphological characteristics of degradative cells. Vacuolated cells resembling macrophages, fibroblastic cells, and chondroclasts were present adjacent to the matrix in superficial, intermediate, and deep canals, respectively. In order to characterize these perivascular cells cytochemically, nonspecific esterase and TSAP staining was used to identify macrophages, alkaline phosphatase staining was used to identify fibroblastic cells, and TRAP staining was used to identify chondroclasts. There were no cells present in the canals at any developmental stage that were positive for TSAP or strongly positive for nonspecific esterase, placing doubt on the identity of the vacuolated cells as macrophages. Alkaline phosohatase-positive perivascular cells were present in the intermediate and deep canals adjacant to matrix containing alkaline phosphatase-positive chondrocytes. These alkaline phosphatase-positive cells were found in the same location within canals as the fibroblastic cells. Tartrate-resislant acid phosphatase was localized in chondroclasts at the tips of deep canals but was not confined exclusively to chondroclasts. Except for the very early stage of canal development prior to chondrocyte hypertrophy, TRAP-positive cells were present at the tips of superficial and intermediate canals as well as at the tips of the deep canals. Additionally, the presence of TRAP in chondrocytes with in the growth plate, in chondrocytes within the epiphyseal cartilage near some canals, and in perichondrial cells suggests that TRAP is associated with matrix degradation in the cartilage.     

Development of the microcirculation of the secondary ossification center in rat humeral head

This work investigated the origin and development of microcirculation in the rat humeral head and the expression of vascular endothelial growth factor (VEGF) as a factor supporting the vascular growth and the development of the secondary ossification centers. Sixty rats aging 1, 3-4, 6-8, 11, and 21 days, 5 weeks, and 4 and 8 months were used. Samples of humeral head were collected for histology and immunohistochemistry for VEGF. Some animals were perfused with Mercox resin in order to obtain vascular corrosion casts (vcc) observed by scanning electron microscopy (SEM). No cartilage canals were present at birth. At 6 days postnatal, blood vessels coming from the perichondrium and the region near the capsule attachment invaded the cartilage; at 11 days postnatal, signs of calcification were present and within the third week some bone trabeculae were formed. Just before the vascular invasion of the epiphysis, a positive reaction for VEGF was localized in chondrocytes of the epiphyseal cartilage close to the capsule insertion. During the development and expansion of the secondary ossification center, VEGF expression was higher in chondrocytes but decreased when epiphysis was diffusely ossified. VEGF was expressed also by mesenchymal cells present in and around the fibrous tissue where the secondary ossification center will develop. SEM vcc confirmed that vessels penetrating into the epiphysis arose merely from the periosteal and the capsular networks, and vascular connections with the diaphyseal circulation were not evident. These observations demonstrated that VEGF production by chondrocytes begun some days after birth, supported the rapid vascular growth from the surrounding soft tissues, and was chronologically related to the development of the secondary ossification center in rat proximal humerus. Finally, the possible role of VEGF as mediator of angiogenesis and, at least indirectly, as a trigger factor also in the ossification and the bone remodeling of the secondary ossification centers has been discussed.     

Vascular invasion of the epithyseal growth plate: Analysis of metaphyseal capillary ultrastructure and growth dynamics

Metaphyseal blood vessels which invade the calcifying epiphyseal growth plate were examined by a variety of techniques to determine their morphology, cell division, and growth patterns as they relate to endochondral ossification. Four regions of these vessels were characterized: 1) sprout tips—the terminal ends of the capillary sprouts which impinge upon the hypertrophic chondrocytes of the growth plate; 2) region of extended calcified cartilage—those deeper vessels within the metaphysis which are surrounded by an extracellular matrix predominantly composed of extended septa of calcified cartilage; 3) region of bone deposition—further still from the epiphysis these microvessels are contained within a network of active bone deposition laid upon a scaffold of calcified cartilage; 4) region of primary vessels—at a distance of 350–500 μm from the epiphysis are dilated vessels with one or two layers of smooth muscle in their walls, which supply and drain the metaphyseal capillary plexus. The sprout tips are continuous blind-ended vessels lined with an attenuated endothelium with no underlying basement membrane. Dividing endothelial cells are most frequently found in the region of bone deposition 175–200 μm behind the apices of the growing sprout tips. A time-coursed, autoradiographic examination of cytokinesis revealed radio-labelled endothelial cells to appear at the epiphysis after a 24 hr period. The metaphyseal capillary sprouts represent a continuous, unidirectional angiogenic vascular network which grows by elongation from the region of bone deposition; this region remians a fixed distance behind the sprout tips. These findings are discussed in light of the growth dynamics between this vascular plexus and the epiphyseal growth plate.     

Histologic-histochemical and immunocytochemical investigations of cartilage canals in human rib cartilage]

In contrast to articular cartilage the hyaline rib cartilage takes up a special position due to its size, shape and the kind of mechanical stress as well. These facts may influence the metabolism of rib cartilage. In our histological, histochemical and immunohistochemical investigations on pieces of rib cartilages of 34 persons at the age of fourth fetal month up to 60 years we could regularly demonstrate cartilage canals containing blood vessels without any spatial or temporal relationship to degenerative changes in cartilage tissue. Many of these cartilage canals are located in the center of the rib cartilage. Blood vessels as well as neuronal structures in the connective tissue of cartilage canals were detected by means of antibodies against components of the vessel wall (Von Willebrand factor) and nerve fibers (PGP 9.5). Nerves may have sensoric or vasomotoric functions as well, and they may influence cell differentiation and regeneration processes, respectively. Cartilage can not be regarded as vascularized like other tissues, but cartilage canals may have great functional importance for the metabolism of rib cartilage.     

Vascular invasion of the epiphyseal growth plate: analysis of metaphyseal capillary ultrastructure and growth dynamics

Metaphyseal blood vessels which invade the calcifying epiphyseal growth plate were examined by a variety of techniques to determine their morphology, cell division, and growth patterns as they relate to endochondral ossification. Four regions of these vessels were characterized: 1) sprout tips--the terminal ends of the capillary sprouts which impinge upon the hypertrophic chondrocytes of the growth plate; 2) region of extended calcified cartilage--those deeper vessels within the metaphysis which are surrounded by an extracellular matrix predominantly composed of extended septa of calcified cartilage; 3) region of bone deposition--further still from the epiphysis these microvessels are contained within a network of active bone deposition laid upon a scaffold of calcified cartilage; 4) region of primary vessels--at a distance of 350-500 microns from the epiphysis are dilated vessels with one or two layers of smooth muscle in their walls, which supply and drain the metaphyseal capillary plexus. The sprout tips are continuous blind-ended vessels lined with an attenuated endothelium with no underlying basement membrane. Dividing endothelial cells are most frequently found in the region of bone deposition 175-200 microns behind the apices of the growing sprout tips. A time-coursed, autoradiographic examination of cytokinesis revealed radio-labelled endothelial cells to appear at the epiphysis after a 24 hr period. The metaphyseal capillary sprouts represent a continuous, unidirectional angiogenic vascular network which grows by elongation from the region of bone deposition; this region remains a fixed distance behind the sprout tips. These findings are discussed in light of the growth dynamics between this vascular plexus and the epiphyseal growth plate.     

股骨下端骺微血管的观察

本文报道用微血管造影及组织切片的方法,观察了18例胚胎和10例儿童的股骨下端骺。结果发现仅关节软骨内无血管。而软骨骺内的血管分布有一定规律:从髁间窝来的血管分布于骺中心区域;两髁侧面来的血管分布于两髁外侧份;骺软骨板附近的血管主要来自髌面上方及髁间窝上方。骺骨化中心最早围绕软骨管发生。骨化向周围扩展的速度不均匀,靠近血管处比远离血管处扩展块。骺未化骨时,其内的血管处于软骨管内,在化骨过程中,部分转变为骨骺血管,继续供应骺骨化中心: 2岁前,仅由3～5支来自髁间窝的血管供应;2岁后,髌面上方来的血管也开始进入;5岁后,两髁侧面来的血管相继开始供应骺骨化中心。     

Vascularization and cartilage mineralization of the thyroid cartilage of Munich minipigs and domestic pigs

Thyroid cartilages of Munich minipigs and domestic pigs were investigated by polychrome sequential labeling, radiography, intravascular injections, histologic examination and scanning electron microscopy in order to gain further insight into the process of vascularization and cartilage mineralization. The relationship between vascularization and cartilage mineralization has only been studied in chondroepiphyses of long bones. Vessels branch off the perichondrial vascular network and enter parts of the thyroid cartilage with a large transverse diameter. Cartilage canals, which are perichondral invaginations, contain an arteriole, a venule, a capillary network and connective tissue. The capillaries form a glomerulus-like structure deep in the matrix of the cartilage. Neighbouring cartilage canals do not display any anastomoses. Cartilage mineralization occurs in large areas of the thyroid cartilage. It is only found in the interterritorial extracellular matrix. Mineralization of the cartilage is evident in areas supplied with cartilage canals as well as in non-supplied areas. Mineralized interterritorial matrix is composed of circular structures of different sizes fusing to form plaques. In scanning electron microscopy circular structures appear as globules. It is possible to visualize the dynamic process of cartilage mineralization with polychrome sequential labeling; it proceeds up to 4 μm per week. Distribution of cartilage canals reveals their nutritional role for the cartilage. According to investigations in chondroepiphyses, cartilage mineralization starts adjacent to the glomerular end of cartilage canals. In contrast, no correlation between cartilage vascularization and the beginning of cartilage mineralization of the thyroid cartilage of Munich minipigs and of domestic pigs has been found.     

Vascularization and cartilage mineralization of the thyroid cartilage of Munich minipigs and domestic pigs

Thyroid cartilages of Munich minipigs and domestic pigs were investigated by polychrome sequential labeling, radiography, intravascular injections, histologic examination and scanning electron microscopy in order to gain further insight into the process of vascularization and cartilage mineralization. The relationship between vascularization and cartilage mineralization has only been studied in chondroepiphyses of long bones. Vessels branch off the perichondrial vascular network and enter parts of the thyroid cartilage with a large transverse diameter. Cartilage canals, which are perichondral invaginations, contain an arteriole, a venule, a capillary network and connective tissue. The capillaries form a glomerulus-like structure deep in the matrix of the cartilage. Neighbouring cartilage canals do not display any anastomoses. Cartilage mineralization occurs in large areas of the thyroid cartilage. It is only found in the interterritorial extracellular matrix. Mineralization of the cartilage is evident in areas supplied with cartilage canals as well as in non-supplied areas. Mineralized interterritorial matrix is composed of circular structures of different sizes fusing to form plaques. In scanning electron microscopy circular structures appear as globules. It is possible to visualize the dynamic process of cartilage mineralization with polychrome sequential labeling; it proceeds up to 4 microm per week. Distribution of cartilage canals reveals their nutritional role for the cartilage. According to investigations in chondroepiphyses, cartilage mineralization starts adjacent to the glomerular end of cartilage canals. In contrast, no correlation between cartilage vascularization and the beginning of cartilage mineralization of the thyroid cartilage of Munich minipigs and of domestic pigs has been found.