Early Fetal Development of the Otic and Pterygopalatine Ganglia with Special Reference to the Topographical Relationship with the Developing Sphenoid Bone.

The otic and pterygopalatine ganglia are located close to the greater wing (alisphenoid) of the sphenoid bone and many researchers have noted nerves connecting these ganglia in human embryos. The greater wing (alisphenoid) arises from the cartilaginous ala temporalis independently of the lesser wing, but no topographical changes between this cartilage and nerve elements have been demonstrated. We examined histological sections of 20 human embryos and fetuses from 6 to 15 weeks of development (WD). At 6 WD, the ala temporalis, the alar process and ganglia were all identified as a single, undifferentiated cell mass. Subsequently, the two ganglia became identifiable, but were continuous on the superior side of the initial ala temporalis. The temporal, superior spine of the ala temporalis was surrounded by the part that connected the ganglia. At 7 WD, the superior spine of the ala temporalis was reduced in size and the continuity of these ganglia was lost. At this point, a secondarily-formed communicating branch between the ganglia, the nervus sphenoidalis was first identifiable. At 9 WD, the ala temporalis and the alar process had clearly become cartilages, and the anterior end of the otic ganglion was separated from the ala temporalis. The nervus sphenoidalis became longer. At 15 WD, the otic and pterygopalatine ganglia were clear separated from the alisphenoid, which consisted of the cartilaginous ala temporalis and membranous bone. Consequently, the separation between the otic and pterygopalatine ganglia seemed to be due to the developing ala temporalis. Anat Rec, 2018. © 2018 Wiley Periodicals, Inc.

Developmental characteristics of secondary cartilage in the mandibular condyle and sphenoid bone in mice.

OBJECTIVE: Secondary cartilage develops from osteochondral progenitor cells. Hypertrophic chondrocytes in secondary cartilage increase within a very short time and then ossify rapidly. In the present study, we investigated the sequential development process of osteochondral progenitor cells, and the morphology and size of hypertrophic chondrocytes in secondary cartilage. DESIGN: ICR mice at embryonic days (E) 14.5-17.5 were used. The mandibular condyle and the medial pterygoid process of the sphenoid bone were observed as secondary cartilage, and the cranial base and the lateral pterygoid process of the sphenoid bone, which is primary cartilage, were observed as a control. Thin sections were subjected to immunostaining and alkaline phosphatase (ALP) staining. Using a confocal laser microscope, 3D stereoscopic reconstruction of hypertrophic cells was performed. To evaluate the size of hypertrophic chondrocytes objectively, the cell size was measured in each cartilage. RESULTS: Hypertrophic chondrocytes of secondary cartilage first expressed type X collagen (Col X) at E15.5. SRY-box 9 (Sox 9) and ALP were co-expressed in the fibroblastic/polymorphic tissue layer of secondary cartilage. This layer was very thick at E15.5, and then rapidly became thin. Hypertrophic cells in secondary cartilage were markedly smaller than those in primary cartilage. CONCLUSIONS: The small hypertrophic cells present in secondary cartilage may have been a characteristic acquired in order for the cartilage to smoothly promote a marked increase in hypertrophic cells and rapid calcification.

Expression of glutathione peroxidase 1 in the spheno-occipital synchondrosis and its role in ROS-induced apoptosis.

BACKGROUND/OBJECTIVE: Chondrogenesis is an integral part of endochondral bone formation, by which the midline cranial base is developed. Reactive oxygen species (ROS) are required in chondrogenic differentiation and antioxidant enzymes regulate their levels. The aim of this study was to localize the antioxidant enzyme glutathione peroxidase 1 (Gpx1) at the spheno-occipital synchondrosis, as well as its effect on ROS challenge and its expression pattern in the course of differentiation. MATERIALS AND METHODS: Gpx1 was semiquantified in immunohistochemically stained sections of spheno-occipital synchondroses of rats. The effect of Gpx1 on ROS-induced apoptosis was investigated by manipulating the expression of Gpx1 in ATDC5 cells. The temporal pattern of Gpx1 expression was determined during chondrocyte differentiation for 21 days in vitro. RESULTS: Proliferating chondrocytes exhibited the greatest Gpx1 immunoreactivity and hypertrophic ones the lowest (P = 0.02). Cells transfected with Gpx1-siRNA had the highest apoptotic rate, while cells overexpressing Gpx1 the lowest one (P < 0.001). Gpx1 was significantly increased on days 10 (P = 0.02) and 14 (P = 0.01). CONCLUSIONS: Hypertrophic chondrocytes have the lowest Gpx1 activity in the spheno-occipital synchondrosis. Gpx1 is implicated in the ROS-induced apoptosis in chondrocytes. Its expression was not constitutive during chondrogenic differentiation.

Temporal expression of SOX9 and type II collagen in spheno-occipital synchondrosis of mice after mechanical tension stimuli.

OBJECTIVE: To associate the expressions of SOX9 and type II collagen during growth in the synchondrosis with and without tensile stress in order to understand the role of these factors in the growth of cartilage in spheno-occipital synchondrosis. MATERIALS AND METHODS: Sixty 1-day-old male BALB/c mice were randomly divided into experimental and control groups. Each group was subdivided again into five different time points which were 6, 24, 48, 72, and 168 hours. Each subgroup consisted of five mice. Each mouse was sacrificed using an overdose of pentobarbitone sodium. The synchondroses were aseptically removed and incubated in a 24-well plate with or without tensile stress in tissue culture. Tissue sections were stained immunohistochemically to quantitatively analyze the expression of SOX9 and type II collagen. RESULTS: There was a statistically significant increase of 57% (P < .001) in the expression of SOX9 between the experimental and control groups at 24 hours, followed by a significant increase of 44.4% (P < .001) in the expression of type II collagen at 72 hours. CONCLUSIONS: SOX9 may play an important role for early differentiation of chondrocytes and increase the expression of type II collagen, a major component of the extracellular matrix, during the growth of cartilage in the spheno-occipital synchondrosis.

Chondrocyte proliferation of the cranial base cartilage upon in vivo mechanical stresses.

Whereas the growth of the cranial base cartilage is thought to be regulated solely by genes, epiphyseal growth plates are known to respond to mechanical stresses. This disparity has led to our hypothesis that chondrocyte proliferation is accelerated by mechanical stimuli above natural growth. Two-Newton tensile forces with static and cyclic waveforms were delivered in vivo to the premaxillae of actively growing rabbits for 20 min/day over 12 consecutive days. The average number of BrdU-labeled chondrocytes in the proliferating zone treated with cyclic forces was significantly higher than both static forces of matching peak magnitude and sham controls representing natural chondral growth. Cyclic forces also evoked greater area of the proliferating zone than both static forces and sham controls. Thus, chondrocyte proliferation is enhanced by mechanical stresses in vivo, especially those with oscillatory waveform. Analysis of these data suggests that genetically coded chondral growth is up-regulated by mechanical signals.

Differential in vitro response to epidermal growth factor by prenatal murine cranial-base chondrocytes.

The retrognathic Brachyrrhine (Br) heterozygote mouse mutant has a very localized morphological deficiency in the sphenoethmoidal region of the anterior cranial base. The purpose of this study was to test the hypothesis that a primary growth defect occurs in that region of Br mice. Primary cell cultures were derived from presumptive nasal septal and sphenoethmoidal regions of Br and wild-type littermates. Cultures were stimulated with 1.0 ng/ml epidermal growth factor (EGF), and [3H]thymidine and [35S] incorporation was measured. Growth of the nasal septal chondrocytes did not differ significantly between groups. In the cultures derived from the sphenoethmoidal region [35S] incorporation was greater, but not significantly so, in the normal group. However, EGF did significantly stimulate proliferation of the sphenoethmoidal chondrocytes in wild-type cultures above that measured in Br cultures. Therefore, the Br genetic aberration is associated with a primary growth defect in the sphenoethmoidal region of the cranial base. These results suggest that growth of the anterior cranial base occurs differentially and that the defect in Br mice results in reduced sphenoidal but not nasal septal growth.

Hyaluronan is essential for the expansion of the cranial base growth plates.

Exquisite control of chondrocyte function in the zone of hypertrophy results in expansive growth of cartilaginous growth plates, and is a prerequisite for normal skeletal lengthening. We hypothesize that hyaluronan-mediated hydrostatic pressure causes lacunae expansion in the zone of hypertrophy; an important mechanism in cartilaginous growth plate and associated skeletal expansion. The role of hyaluronan and CD44 in this mechanism was studied using organ culture of the bipolar cranial base synchondroses. Hyaluronan was present in the hypertrophic zones, pericellular to the hypertrophic chondrocytes, while no hyaluronan was detected in the resting, proliferating and maturing zones. This localization of hyaluronan was associated with increased lacunae size, suggesting that chondrocytes deposit and retain pericellular hyaluronan as they mature. In comparison, Toluidine Blue staining was associated with the territorial matrix. Hyaluronidase, the hyaluronan-degrading enzyme, and CD44, the receptor for hyaluronan which also participates in the uptake and degradation of hyaluronan, were co-localized within the zone of ossification. This pattern of expression suggests that cells in the early zone of ossification internalize and degrade hyaluronan through a CD44-mediated mechanism. Treatment of the cultured segments with either Streptomyces hyaluronidase or hyaluronan hexasaccharides inhibited lacunae expansion. These observations demonstrate that hyaluronan-mediated mechanisms play an important role in controlling normal skeletal lengthening.

[Organization of the osseous nasal septum and its homologues. III. The sphenoid bone and the vomero-transversal system in Urodela]. / Organizacja zrebu kostnego przegrody nosa oraz jej homologów. III. Os alare et systema vomero-transversale (u plazów).

In connection with the comparative anatomical examinations of the nasal septum in man, the urodela skulls were examined . The aim of these investigations of the osseous median palatal part and sphenoethmoidal bone were evaluated. 25 skulls of adults frogs were examined. It was stated that parasphenoid in these Amphibians consisted of two parts: agger vomeris and lamina transversalis. These elements were the homologue to the parasphenoideum seu vomero-transversale system in fishes. The premaxilla in frogs belonged (substituted) to the maxillary++ arch. The sphenoethmoidal bone in frogs were the same as the alar bone in birds (part I) and fishes (part II). In all frogs the author did not found any "mesoethmoid ". These precedential facts, observed in birds (I), fishes (II) and amphibians (III) led to further study in mammals and man.

[Spheno-occipital synchondrosis--a fluorescence and polarization microscopy study in Cercopithecus aethiops monkeys]. / Die Synchondrosis sphenooccipitalis--eine fluoreszenz- und polarisationsmikroskopische Untersuchung am Cercopithecus-aethiops-Affen.

On 17 Cercopithecus aethiops monkeys we investigated with the method of the polychromic sequential dye marking system the histomorphology as well as the dynamics of growth and calcification of the spheno-occipital synchondrosis. The age of the animals ranged from change to teeth to late adolescence. The animals had been divided into four different groups: I: late change of teeth; II: young adult; III: fully grown; IV: late adolescence. In the first group the spheno-occipital synchondrosis showed no ossification in the gap which is filled with cartilage. It showed the characteristic structure with a central zone of equally distributed chondrocytes. Adjacent to this we found a zone of proliferation cell hypotrophy and cell degeneration. With increasing age there is decrease of the density of cells (groups II to IV) and after change to teeth the synchondrosis starts to ossify (group II). Due to the ossification the synchondrosis subdivides into different cartilage regions. We found that the closing of the synchondrosis started in the cranial region and progressed toward the caudal region. During this procedure the synchondrosis never ossified completely. Several cartilage regions persisted uncalcified until late adolescence. Interstitial growth of the synchondrosis was found until the end of the change of the teeth (group I). This growth which was always found in a sagittal direction ceased after bony connections had been formed between both poles of the synchondrosis. The sphenoidal and occipital pole of the synchondrosis showed equal growth potential.

The effect of parathyroid hormone (1-34) on cyclic AMP level, ornithine decarboxylase activity, and glycosaminoglycan synthesis of chondrocytes from mandibular condylar cartilage, nasal septal cartilage, and spheno-occipital synchondrosis in culture.

Previously, we reported methods for isolating chondrocytes from the craniofacial complex and their culture in vitro. The response of these chondrocyte cultures to bovine parathyroid hormone (1-34) (PTH) has now been investigated. PTH stimulated glycosaminoglycan (GAG) synthesis, a characteristic of the cartilage phenotype in cultured chondrocytes isolated from mandibular condylar cartilage (MCC), nasal septal cartilage (NSC), and spheno-occipital synchondrosis (SOS). These stimulations of GAG synthesis by PTH were dose-dependent. PTH also increased accumulation of cyclic AMP (cAMP) and the activity of ornithine decarboxylase (ODC), a rate-limiting enzyme in polyamine biosynthesis. However, PTH did not stimulate DNA synthesis. The increases in the cAMP level, ODC activity, and GAG synthesis after addition of PTH (10(-7) mol/L) were greatest in MCC-chondrocytes and least in NSC-chondrocytes. The difference in the responses to PTH of these three types of chondrocytes may reflect differences of the characteristics of these cells in vivo.

Studies on chondrocytes from mandibular condylar cartilage, nasal septal cartilage, and spheno-occipital synchondrosis in culture. I. Morphology, growth, glycosaminoglycan synthesis, and responsiveness to bovine parathyroid hormone (1-34).

Methods for isolating chondrocytes from the craniofacial complex and culturing them in vitro were established. Chondrocytes which were isolated by collagenase digestion from mandibular condylar cartilage, nasal septal cartilage, and spheno-occipital synchondrosis grew well in vitro. All three types of chondrocytes actively synthesized glycosaminoglycans, a differentiated phenotype of chondrocytes, and responded well to parathyroid hormone. However, some different characteristics were noted among the three types of chondrocytes in culture.