Our data suggest that implantation of bioprostheses in cardiac surgery induces a xenograft-specific immune response. Procedures diminishing the presence of alpha-Gal on bioprostheses, such as utilization of genetically manipulated alpha-Gal-deficient xenograft or pretreatment with alpha-Galactosidase, might diminuate the immune response against bioprostheses and extend durability.
This study provides evidence that palisade endings in cat EOMs have effector function. The findings may be of significance for strabismus surgery because palisade endings are also found in human EOMs.
The present study ascertained that palisade endings are cholinergic motor organs. Therefore, it was concluded that palisade endings are not candidates to provide eye-position signals.
We investigated the development of cartilage canals to clarify their function in the process of bone formation.Cartilage canals are tubes containing vessels that are found in the hyaline cartilage prior to the formation of a secondary ossification centre (SOC). Their exact role is still controversial and it is unclear whether they contribute to endochondral bone formation when an SOC appears. We examined the cartilage canals of the chicken femur in different developmental stages (E20, D2, 5, 7, 8, 10 and 13). To obtain a detailed picture of the cellular and molecular events within and around the canals the femur was investigated by means of three-dimensional reconstruction, light microscopy, electron microscopy, histochemistry and immunohistochemistry [vascular endothelial growth factor (VEGF), type I and II collagen]. An SOC was visible for the first time on the last embryonic day (E20). Cartilage canals were an extension of the vascularized perichondrium and its mesenchymal stem cell layers into the hyaline cartilage. The canals formed a complex network within the epiphysis and some of them penetrated into the SOC were they ended blind. The growth of the canals into the SOC was promoted by VEGF. As the development progressed the SOC increased in size and adjacent canals were incorporated into it. The canals contained chondroclasts, which opened the lacunae of hypertrophic chondrocytes, and this was followed by invasion of mesenchymal cells into the empty lacunae and formation of an osteoid layer. In older stages this layer mineralized and increased in thickness by addition of further cells. Outside the SOC cartilage canals are surrounded by osteoid, which is formed by the process of perichondral bone formation. We conclude that cartilage canals contribute to both perichondral and endochondral bone formation and that osteoblasts have the same origin in both processes.
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 downregulated 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.
The results confirm that in the monkey, palisade endings contain acetylcholine and are therefore most likely effector organs. Palisade endings are also present in human EOMs and because of their location at the myotendinous junction, these organs are of crucial interest for strabismus surgery.
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