Collagen orientation in periosteum and perichondrium is aligned with preferential directions of tissue growth

A feedback mechanism between different tissues in a growing bone is thought to determine the bone's morphogenesis. Cartilage growth strains the surrounding tissues, eliciting alterations of its matrix, which in turn, creates anisotropic stresses, guiding directionality of cartilage growth. The purpose of this study was to evaluate this hypothesis by determining whether collagen fiber directions in the perichondrium and periosteum align with the preferential directions of long bone growth. Tibiotarsi from chicken embryos across developmental stages were scanned using optical projection tomography (OPT) to assess preferential directions of growth at characteristic sites in perichondrium and periosteum. Quantified morphometric data were compared with two‐photon laser‐scanning microscopy images of the three‐dimensional collagen network in these fibrous tissues. The diaphyseal periosteum contained longitudinally oriented collagen fibers that aligned with the preferential growth direction. Longitudinal growth at both metaphyses was twice the circumferential growth. This concurred with well‐developed circumferential fibers, which covered and were partly interwoven with a dominant network of longitudinally oriented fibers in the outer layer of the perichondrium/periosteum at the metaphysis. Toward both articulations, the collagen network of the epiphyseal surface was randomly oriented, and growth was approximately biaxial. These findings support the hypothesis that the anisotropic architecture of the collagen network, detected in periosteum and perichondrium, concurs with the assessed growth directions. © 2008 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 26:1263–1268, 2008     

Orthotopic and ectopic chondrogenesis and osteogenesis mediated by neoplastic cells

In mice, tumors of various origins have been found to stimulate cambium layer cells of periosteum/ perichondrium of adjacent orthotopic bone or cartilage to proliferate and/or differentiate into osteoblasts or chondroblasts. Tumors may induce new bone and/or cartilage formation. In progressively growing tumors the osteogenic/chondrogenic activity is gradually surpassed by the resorptive processes mediated either by osteoclasts, directly by tumor cells, or by tumor stroma. In regressing tumors, however, the deposits of new bone remained unresorbed, resulting in a permanent gain of bone mass. In human subjects, similar changes were observed in bone adjacent to carcinoma development. Stimulation of periosteal bone formation was observed at earlier stages of the disease, while bone resorption mainly by tumor cells and their stroma was observed in later stages of tumor development. The unresponsiveness of the heterotopically-induced bone to the Moloney sarcoma virus, in contrast to the response of orthotopic bone clearly indicates that ectopic bones do not develop a true periosteum.     

Developmental and TGF-beta-mediated regulation of Ank mRNA expression in cartilage and bone

OBJECTIVES: Ank encodes a transmembrane protein that is involved in pyrophosphate (PPi) transport and mutations in the Ank gene have been associated with pathological mineralization in cartilage and bone. To understand how Ank works in normal skeletal development it is also important to know which cells within the developing skeleton express Ank. To this end, we examined the expression pattern of Ank mRNA during mouse embryonic development as well as in mouse hind limb joints with emphasis on the period when articular cartilage forms. Since it was previously shown that TGF-beta regulates PPi transport in cells in culture, we also tested the hypothesis that TGF-beta regulates Ank expression. METHODS: The localization of Ank mRNA was determined by radioactive in situ hybridization in E15.5 and E17.5 mouse embryos as well as in 1 and 3 week post-natal mice. Ank expression was compared to that of other cartilage markers. In situ hybridization and semi-quantitative RT-PCR were used to determine the effects of TGF-beta on Ank expression in metatarsal organ cultures. RESULTS: Ank expression was detected at high levels at sites of both endochondral and intramembranous bone development. In endochondral bones, expression was detected in a subset of hypertrophic cells at ossification centers. Expression was also detected in osteogenic/chondrogenic cells of the perichondrium/periosteum lining the metaphysis, an area associated with the formation and extension of the bone collar. High levels of expression were also detected in non-mineralized tissues of the skeletal system including tendons and the superficial layer of the articular cartilage. Treatment with TGF-beta resulted in an approximately four-fold induction of Ank mRNA in prehypertrophic chondrocytes and perichondrium of metatarsal cultures.CONCLUSIONS: The expression pattern of Ank suggests an important role both in inhibiting and regulating mineralization in the developing skeletal system. In addition, TGF-beta1 is able to mediate Ank mRNA expression in chondrocytes suggesting a possible role for TGF-beta and Ank in the regulation of normal mineralization.     

Development of PTH-responsive adenylate cyclase activity during chondrogenesis in cultured mesenchyme from chick limb buds

Summary The present study investigated the development of parathyroid hormone (PTH)-responsive adenylate cyclase (AC) activity in chondrogenic cells differentiating from chick limb mesenchyme in culture. Mesenchyme from stage 25 chick embryos was removed from the distal tip (0.3 mm) of limb buds and cultured for a 6 day period in high density micromass cultures. Under these conditions, initial appearance of cartilage matrix and chondroblasts occurred on day 3 of culture and rapidly progressed over the next 3 days to produce, by day 6, a highly confluent and homogeneous layer of cartilage matrix and chondrocytes. Cells initially dissociated from limb mesenchyme on day 0 were essentially unresponsive to PTH, but development of AC-coupled, PTH receptors occurred rapidly during the initial 24 hours of culture. Based on data from dose-response experiments, prechondrogenic cells on day 1 of culture had synthesized their full complement of these receptors relative to fully differentiated chondrocytes in cultures at day 6. Inhibition of chondrocyte differentiation by retinoic acid did not significantly affect the initial development of AC-coupled, PTH receptors but it almost completely prevented synthesis of cartilage matrix. The results indicate that development of AC-coupled PTH receptors during chondrogenesis precedes, by at least 48 hours, overt differentiation of chondrocytes and the accumulation of cartilage-specific extracellular matrix and appears to represent one of the earliest reported events in chondrocyte differentiation. The lack of effect of retinoids on development of these receptors indicates that the inhibitory effects of retinoids on differentiating cartilage are at least somewhat specific for genes regulating synthesis of extracellular matrix molecules.     

Intracellular tension in periosteum/perichondrium cells regulates long bone growth

Perichondrium/periosteum is involved in regulating long bone growth. Long bones grow faster after removal or circumferential division of periosteum. This can be countered by culturing them in conditioned medium from perichondrium/periosteum cells. Because both complete removal and circumferential division are effective, we hypothesized that perichondrium/periosteum cells require an intact environment to release the appropriate soluble factors. More specifically, we propose that this release depends on their ability to generate intracellular tension. This hypothesis was explored by modulating the ability of perichondrium/periosteum cells to generate intracellular tension and monitoring the effect thereof on long bone growth. Perichondrium/periosteum cells were cultured on substrates with different stiffness. The medium produced by these cultures was added to embryonic chick tibiotarsi from which perichondrium/periosteum was either stripped or left intact. After 3 culture days, long bone growth was proportionally related to the stiffness of the substrate on which perichondrium/periosteum cells were grown while they produced conditioned medium. A second set of experiments demonstrated that the effect occurred through expression of a growth‐inhibiting factor, rather than through the reduction of a stimulatory factor. Finally, evidence for the importance of intracellular tension was obtained by showing that the inhibitory effect was abolished when perichondrium/periosteum cells were treated with cytochalasin D, which disrupts the actin microfilaments. Thus, we concluded that modulation of long bone growth occurs through release of soluble inhibitors by perichondrium/periosteum cells, and that the ability of cells to develop intracellular tension through their actin microfilaments is at the base of this mechano‐regulated control pathway. © 2010 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 29:84–91, 2011     

The origin of osteoclasts: An immunohistochemical study on macrophages and osteoclasts in embryonic rat bone

Summary The origin of osteoclasts was studied in embryonic rat bone primordia using a set of monoclonal antibodies (ED1, ED2, and ED3) that exclusively recognize monocytes and macrophages. ED1 recognizes monocytes and macrophages. Mononuclear phagocytes which were ED1 positive were found in the perichondrium/periosteum of developing bone. These cells started to infiltrate the primordia when the cartilage became hypertrophic. During bone formation, multinucleated ED1-positive cells with the morphological characteristics of osteoclasts were found in the developing bone marrow cavity and against the bone collar. The present findings support the notion that osteoclasts arise by fusion of mononuclear phagocytes derived from blood monocytes.     

Role of IGFBP2, IGF-I and IGF-II in regulating long bone growth

The IGF axis is important for long bone development, homeostasis and disease. The activities of IGF-I and IGF-II are regulated by IGF binding proteins (IGFBPs). IGF-I and IGFBP2 are co-expressed in dynamic fashions in the developing long bones of the chick wing, and we have found that IGF-II is present in the cartilage model and surrounding perichondrium, proliferative and hypertrophic chondrocytes and developing periosteum. To gain insight into endogenous roles of IGF-I, IGF-II and IGFBP2 in long bone development, we have overexpressed IGFBP2 in the developing skeletal elements of the embryonic chick wing in vivo, using an RCAS retroviral vector. IGFBP2 overexpression led to an obvious shortening of the long bones of the wing. We have investigated, at the cellular and molecular levels, the mechanism of action whereby IGFBP2 overexpression impairs long bone development in vivo. At an early stage, IGFBP2 excess dramatically inhibits proliferation by the chondrocytes of the cartilage models that prefigure the developing long bones. Later, IGFBP2 excess also reduces proliferation of the maturing chondrocytes and attenuates proliferation by the perichondrium/developing periosteum. IGFBP2 excess does not affect morphological or molecular indicators of chondrocyte maturation, osteoblast differentiation or cell/matrix turnover, such as expression of Ihh, PTHrP, type X collagen and osteopontin, or distribution and relative abundance of putative clast cells. We also have found that IGFBP2 blocks the ability of IGF-I and IGF-II to promote proliferation and matrix synthesis by wing chondrocytes in vitro. Together, our results suggest that the mechanism of action whereby IGFBP2 excess impairs long bone development is to inhibit IGF-mediated proliferation and matrix synthesis by the cartilage model; reduce the proliferation and progression to hypertrophy by the maturing chondrocytes; and attenuate proliferation and formation of the periosteal bony collar. These actions retard the growth and longitudinal expansion of the developing long bones, resulting in shortened wing skeletal elements. Our results emphasize the importance of a balance of IGF/IGFBP2 action at several stages during normal long bone development.     

Role of IGFBP2, IGF-I and IGF-II in regulating long bone growth

The IGF axis is important for long bone development, homeostasis and disease. The activities of IGF-I and IGF-II are regulated by IGF binding proteins (IGFBPs). IGF-I and IGFBP2 are co-expressed in dynamic fashions in the developing long bones of the chick wing, and we have found that IGF-II is present in the cartilage model and surrounding perichondrium, proliferative and hypertrophic chondrocytes and developing periosteum. To gain insight into endogenous roles of IGF-I, IGF-II and IGFBP2 in long bone development, we have overexpressed IGFBP2 in the developing skeletal elements of the embryonic chick wing in vivo, using an RCAS retroviral vector. IGFBP2 overexpression led to an obvious shortening of the long bones of the wing. We have investigated, at the cellular and molecular levels, the mechanism of action whereby IGFBP2 overexpression impairs long bone development in vivo. At an early stage, IGFBP2 excess dramatically inhibits proliferation by the chondrocytes of the cartilage models that prefigure the developing long bones. Later, IGFBP2 excess also reduces proliferation of the maturing chondrocytes and attenuates proliferation by the perichondrium/developing periosteum. IGFBP2 excess does not affect morphological or molecular indicators of chondrocyte maturation, osteoblast differentiation or cell/matrix turnover, such as expression of Ihh, PTHrP, type X collagen and osteopontin, or distribution and relative abundance of putative clast cells. We also have found that IGFBP2 blocks the ability of IGF-I and IGF-II to promote proliferation and matrix synthesis by wing chondrocytes in vitro. Together, our results suggest that the mechanism of action whereby IGFBP2 excess impairs long bone development is to inhibit IGF-mediated proliferation and matrix synthesis by the cartilage model; reduce the proliferation and progression to hypertrophy by the maturing chondrocytes; and attenuate proliferation and formation of the periosteal bony collar. These actions retard the growth and longitudinal expansion of the developing long bones, resulting in shortened wing skeletal elements. Our results emphasize the importance of a balance of IGF/IGFBP2 action at several stages during normal long bone development.     

Histomorphological transformation of the auricular cartilage after carbon dioxide laser-assisted Mustardé otoplasty. An experimental study

In an experiment on ten rabbits, 8 W carbon dioxide (CO₂) laser evaporation of the perichondrium, together with one-third to one-half of the thickness of the auricle cartilage, was performed. Subsequently, the auricle was bent in the middle of the vaporized area, the corresponding surfaces of which were then apposed and fixed to each other with mattress sutures. Three months later the auricle specimen was harvested for histopathological evaluation. This revealed that the partially laser-ablated cartilage had grown together in the form of a solid cartilaginous column. The regeneration process, originating from chondroblasts as well as from perichondrium cells, was strongly stimulated by the laser energy delivered.     

The periosteum. Part 1: Anatomy, histology and molecular biology

The periosteum is a thin layer of connective tissue that covers the outer surface of a bone in all places except at joints (which are protected by articular cartilage). As opposed to bone itself, it has nociceptive nerve endings, making it very sensitive to manipulation. It also provides nourishment in the form of blood supply to the bone. The periosteum is connected to the bone by strong collagenous fibres called Sharpey's fibres, which extend to the outer circumferential and interstitial lamellae of bone. The periosteum consists of an outer "fibrous layer" and inner "cambium layer". The fibrous layer contains fibroblasts while the cambium layer contains progenitor cells which develop into osteoblasts that are responsible for increasing bone width. After a bone fracture the progenitor cells develop into osteoblasts and chondroblasts which are essential to the healing process. This review discusses the anatomy, histology and molecular biology of the periosteum in detail.     

Parathyroid hormone-related protein regulates proliferation of condylar hypertrophic chondrocytes.

The condylar cartilage, an important growth site in the mandible, shows characteristic modes of growth and differentiation, e.g., it shows delayed appearance in development relative to the limb bud cartilage, originates from the periosteum rather than from undifferentiated mesenchymal cells, and shows rapid differentiation into hypertrophic chondrocytes as opposed to the epiphyseal growth plate cartilage, which has resting and proliferative zones. Recently, attention has been focused on the role of parathyroid hormone-related protein (PTHrP) in modulating the proliferation and differentiation of chondrocytes. To investigate further the characteristic modes of growth and differentiation of this cartilage, we used mice with a disrupted PTHrP allele. Immunolocalization of type X collagen, the extracellular matrix specifically expressed by hypertrophic chondrocytes, was greatly reduced in the condylar cartilage of homozygous PTHrP-knockout mice compared with wild-type mice. In contrast, immunolocalization of type X collagen of the tibial cartilage did not differ. In wild-type mice, proliferative chondrocytes were mainly located in both the flattened cell layer and hypertrophic cell layer of the condylar cartilage, but were limited to the proliferative zone of the tibial cartilage. The number of proliferative chondrocytes was greatly reduced in both cartilages of homozygous PTHrP-knockout mice. Moreover, apoptotic chondrocytes were scarcely observed in the condylar hypertrophic cell layer, whereas a number of apoptotic chondrocytes were found in the tibial hypertrophic zone. Expression of the type I PTH/PTHrP receptor was localized in the flattened cell layer and hypertrophic cell layer of the condylar cartilage, but was absent from the tibial hypertrophic chondrocytes. It is therefore concluded that, unlike tibial hypertrophic chondrocytes, condylar hypertrophic chondrocytes have proliferative activity in the late embryonic stage, and PTHrP plays a pivotal role in regulating the proliferative capacity and differentiation of these cells.     

The ribosomal protein QM is expressed differentially during vertebrate endochondral bone development.

Endochondral ossification is a carefully coordinated developmental process that converts the cartilaginous model of the embryonic skeleton to bone with accompanying long bone growth. To identify genes that regulate this process we performed a complementary DNA (cDNA) subtractive hybridization of fetal bovine proliferative chondrocyte cDNA from epiphyseal cartilage cDNA. The subtracted product was used to screen a fetal bovine cartilage cDNA library. Ten percent of the clones identified encoded the bovine orthologue of the human ribosomal protein "QM." Northern and western blot analysis confirmed that QM was highly expressed by cells isolated from epiphyseal cartilage as opposed to proliferative chondrocytes. In contrast, no detectable difference in the expression of mRNA for the ribosomal protein S11 was detected. Immunohistochemical analysis of fetal bovine limb sections revealed that QM was not expressed by the majority of the epiphyseal chondrocytes but only by chondrocytes in close proximity to capillaries that had invaded the epiphyseal cartilage. Strongest QM expression was seen in osteoblasts in the diaphyseal region of the bone adjoining the growth plate, within the periosteum covering the growth plate and within secondary centers of ossification. Hypertrophic chondrocytes within the growth plate adjoining the periosteum also were positive for QM as were chondrocytes in the perichondrium adjoining the periosteum. In vitro investigation of the expression of QM revealed higher QM expression in nonmineralizing osteoblast and pericyte cultures as compared with mineralizing cultures. The in vivo and in vitro expression pattern of QM suggests that this protein may have a role in cell differentiation before mineralization.     

Evaluation of osteogenic/chondrogenic cellular proliferation and differentiation in the xenogeneic periosteal graft

To determine whether grafted young periosteum can induce new bone formation in elderly patients, this preliminary study evaluated cell proliferation and differentiation in xenogeneic periosteal grafts in old rats radiographically, histologically, and immunohistochemically. Periosteum harvested from the tibia of young Japanese white rabbits were grafted into old Sprague-Dawley rats with or without administration of 1.0 mg per kilogram per day immunosuppressant FK506. Autogenous old periosteal tissue grafts were also evaluated as a control. Grafted tissue was extirpated after 7, 14, 21, and 45 days. In the xenogeneic group, proliferative cell nuclear antigen-positive cells were observed 7 days after surgery, which differentiated into chondroblasts with bone morphogenetic protein-2 expression and finally formed cartilage by 14 days. Endochondral ossification was observed at 21 days, and bone replacement was completed by 45 days. No osteogenic cell activity was observed in the two other groups. Xenogeneic young periosteum thus maintained its osteogenic/chondrogenic potentiality in older rats.     

Localization of osteonectin expression in human fetal skeletal tissues byin situ hybridization

Summary The expression of osteonectin gene was studied in developing human fetuses by Northern analysis andin situ hybridization. The highest levels of osteonectin mRNA were detected in RNA extracted from calvarial bones, growth plates, and skin. Low mRNA levels were present in several parenchymal tissues.In situ hybridization of developing long bones revealed three cell types with high osteonectin mRNA levels: osteoblasts, cells of the periosteum, and hypertrophic chondrocytes. Weaker signals were detected in osteocytes, fibroblasts of tendons, ligaments and skin, and in cells of the epidermis. Apart from the hypertrophic chondrocytes, only low osteonectin mRNA levels were seen in cartilage. The localization of osteonectin mRNA in fetal growth plates is consistent with the hypothesis that the protein plays a role in the mineralization of bone and cartilage matrices.     

The potential of adult human perichondrium to form hyalin cartilage in vitro

The usefulness of adult human perichondrium for the restoration of articular cartilage defects depends on the potential to form hyalin cartilage. In order to evaluate the capacity of adult human perichondrium to form hyalin cartilage in vitro, perichondrium of the rib of eight adult human beings was cultured in vitro. After removal of residual cartilage, perichondrial explants were cultured for 7 or 10 days. The explants were histologically examined using specific stains to prove the presence of glycosaminoglycans (GAGs) normal for hyalin cartilage. Clear differentiation of perichondrial cells towards chondrocytes was noted. The chondrocytes synthesized new matrix substances normally present in hyalin cartilage. This investigation supports the usefulness of adult human rib perichondrium for the restoration of cartilage defects. Due to the enormous potential of the rib perichondrium to form hyalin cartilage in vitro, even defects in joints with a rather thick cartilage layer might be restored using this biological material.     

稳定病理性瘢痕模型的建立

目的:通过比较两种病理性瘢痕动物模型——裸鼠瘢痕模型和兔耳瘢痕模型的稳定性并对制作方法进行改进,为病理性瘢痕研究中选择有效的动物模型提供依据.方法:分别采用改良保留表皮(带表皮人瘢痕组织移植1周后剪除移植组织上方的裸鼠皮肤)、去除表皮(去除瘢痕组织表皮后移植)的方法分别在皮下移植人增生性瘢痕和瘢痕疙瘩制作裸鼠瘢痕模型.分别采用去除软骨膜及软骨、保留软骨膜及软骨、去除软骨膜保留软骨3种术式制作兔耳瘢痕模型,观察各瘢痕模型的效果、模型稳定时间和病理学改变来评价模型质量.结果:裸鼠组可快速并稳定地复制增生性瘢痕及瘢痕疙瘩的病理生理特点,且改良保留表皮增生性瘢痕或瘢痕疙瘩移植组的稳定时间(15周和20周)及增生程度明显优于去除表皮的增生性瘢痕及瘢痕疙瘩移植组(模型稳定时间为8周和10周);兔耳组可观察到去除软骨膜保留软骨组瘢痕稳定时间(1 5周)及增生程度明显优于另外两组(模型稳定时间分别为9周和10周).结论:裸鼠瘢痕模型的制作以改良保留表皮移植术式为最佳,兔耳瘢痕模型的制作则以去除软骨膜保留软骨术式为最佳.     

骨折愈合中的软骨骨痂──形态学演变及超微结构观察

通过光镜下不脱钙骨组织学、组织化学和透射电镜对雄性兔桡骨标准缺损骨折模型愈合中软骨骨痂的形成、演变及超微结构进行了观察，结果显示：软骨骨痂由骨折后进入断端间的肉芽组织分化而成，其形成和改建并不完全相同于骺板软骨内化骨。电镜下，骨痂内软骨细胞可分为５个发育阶段：成软骨细胞、软骨细胞、肥大软骨细胞、变性软骨细胞和残存软骨细胞。我们认为１）软骨骨痂由断端周围组织内的间充质细胞分化而成；２）在改建过程中，软骨骨痂能直接形成骨小梁，我们支持肥大软骨细胞能转化为骨细胞的假说；３）软骨骨痂对骨折愈合有重要的作用，能早期填充骨缺损，联接断端，是骨折在重力负载下完成愈合的基础组织之一。     

自体软骨膜、骨膜游离移植修复软骨缺损治疗骨性关节炎

目的：评价自体软骨膜或骨膜游离移植术修复膝关节大面积软骨缺损，治疗膝关节骨性关节炎的疗效。方法：将髌骨及股骨髁，胫骨平台病损软骨清除，游离移植软骨或骨膜修复软骨缺损，治疗骨性关节炎124例，术后不需外固定，4天后持续被动关节活动器作持续动活动。2周后下床活动，结果：术后平均随访6年，治疗效果满意。结论：采用自体软骨膜，骨膜游离移植修复大面积软骨缺损，治疗骨性关节炎，可取得满意效果。