Search results for "dermal bone"

showing 6 items of 6 documents

Cranial bone histology of Metoposaurus krasiejowensis (Amphibia, Temnospondyli) from the Late Triassic of Poland

2016

In this study, 21 skull bones ofMetoposaurus krasiejowensisfrom the Late Triassic of Poland were investigated histologically. Dermal bones show a diploë structure, with an ornamented external surface. The ridges consist of mostly well vascularized parallel-fibered bone; the valleys are built of an avascular layer of lamellar bone. The thick middle region consists of cancellous bone, with varying porosity. The thin and less vascularized internal cortex consists of parallel-fibered bone. The numerous Sharpey’s fibers and ISF are present in all bones. The cyclicity of growth is manifested as an alternation of thick, avascular annuli and high vascularized zones as well as a sequence of resting …

0106 biological sciences010506 paleontologylcsh:MedicineMetoposaurus010603 evolutionary biology01 natural sciencesGeneral Biochemistry Genetics and Molecular BiologyCondylemedicineEndochondral ossification0105 earth and related environmental sciencesbiologyOssificationDermal bonesGeneral NeuroscienceSkulllcsh:RTemnospondyliGeneral MedicineAnatomybiology.organism_classificationMicroanatomySkullmedicine.anatomical_structureGrowth patternmedicine.symptomGeneral Agricultural and Biological SciencesCancellous boneVertebral columnPeerJ
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Cranial suture biomechanics inMetoposaurus krasiejowensis(Temnospondyli, Stereospondyli) from the upper Triassic of Poland

2019

Cranial sutures connect adjacent bones of the skull and play an important role in the absorption of stresses that may occur during different activities. The Late Triassic temnospondyl amphibian Metoposaurus krasiejowensis has been extensively studied over the years in terms of skull biomechanics, but without a detailed description of the function of cranial sutures. In the present study, 34 thin sections of cranial sutures were examined in order to determine their histovariability and interpret their biomechanical role in the skull. The histological model was compared with three-dimensional-finite element analysis (FEA) simulations of the skull under bilateral and lateral biting as well as …

0106 biological sciences0301 basic medicineStereospondylifinite element analysisBiologyMetoposaurus010603 evolutionary biology01 natural sciencesdermal bonesAmphibianshistology03 medical and health sciencesmedicineAnimalsCompression (geology)Fibrous jointSkull roofFossilsSkullTemnospondyliCranial SuturesAnatomypalaeoecologybiology.organism_classificationBiomechanical PhenomenaSkull030104 developmental biologymedicine.anatomical_structureBitingAnimal Science and ZoologyPolandDevelopmental BiologyJournal of Morphology
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Merging cranial histology and 3D-computational biomechanics : A review of the feeding ecology of a Late Triassic temnospondyl amphibian

2021

Finite Element Analysis (FEA) is a useful method for understanding form and function. However, modelling of fossil taxa invariably involves assumptions as a result of preservation-induced loss of information in the fossil record. To test the validity of predictions from FEA, given such assumptions, these results could be compared to independent lines of evidence for cranial mechanics. In the present study a new concept of using bone microstructure to predict stress distribution in the skull during feeding is put forward and a correlation between bone microstructure and results of computational biomechanics (FEA) is carried out. The bony framework is a product of biological optimisation; bon…

0106 biological sciencesAmphibianskull010506 paleontologyHistologyForaginglcsh:MedicineBioengineeringMetoposaurus010603 evolutionary biology01 natural sciencesGeneral Biochemistry Genetics and Molecular BiologyPaleontologyTemnospondylibiology.animalDermal boneMetoposaurusmedicinefeeding strategyFEA0105 earth and related environmental sciencesDermal bonebiologyGeneral Neurosciencelcsh:RSkullMode (statistics)PaleontologyTemnospondyliGeneral Medicinedermal bonebiology.organism_classificationBone histologySkullbone histologymedicine.anatomical_structureBitingGeneral Agricultural and Biological SciencesFeeding strategyGeology
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Mandible histology in Metoposaurus krasiejowensis (Temnospondyli, Stereospondyli) from the Upper Triassic of Poland

2021

Recent studies that have systematically augmented our knowledge of dermal bones of the Late Triassic temnospondyl amphibian Metoposaurus krasiejowensis have mostly focused on shoulder girdle elements and the skull. So far, histological data on the mandible are still scant. For the present study, two mandibles have been examined, using 50 standard thin sections. Dermal bones of the mandible reveal a uniform diploë structure, with the external cortex consisting of moderately vascularised, parallel-fibred bone, as well as a distinct alternation of thick zones and thinner annuli. Dense bundles of well-mineralised Sharpey’s fibres are seen in the external cortex over the entire length of the man…

Dermal boneHistologybiologyLower jawGeneral NeuroscienceFeedingRStereospondyliMandibleTemnospondyliGeneral MedicineAnatomyMetoposaurusbiology.organism_classificationGeneral Biochemistry Genetics and Molecular BiologySkullmedicine.anatomical_structureTemnospondyliCortex (anatomy)Dermal bonemedicineShoulder girdleMedicineGeneral Agricultural and Biological SciencesLate TriassicPeerJ
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Cranial bone histology of

2016

In this study, 21 skull bones of Metoposaurus krasiejowensis from the Late Triassic of Poland were investigated histologically. Dermal bones show a diploë structure, with an ornamented external surface. The ridges consist of mostly well vascularized parallel-fibered bone; the valleys are built of an avascular layer of lamellar bone. The thick middle region consists of cancellous bone, with varying porosity. The thin and less vascularized internal cortex consists of parallel-fibered bone. The numerous Sharpey’s fibers and ISF are present in all bones. The cyclicity of growth is manifested as an alternation of thick, avascular annuli and high vascularized zones as well as a sequence of restin…

MicroanatomyHistologyDermal bonesSkullGrowth patternPaleontologyPeerJ
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Zebrafish Fins as a Model System for Skeletal Human Studies

2007

Recent studies on the morphogenesis of the fins ofDanio rerio(zebrafish) during development and regeneration suggest that a number of inductive signals involved in the process are similar to some of those that affect bone and cartilage differentiation in mammals and humans. Akimenko et al. (2002) has shown that bone morphogenetic protein-2b (BMP2b) is involved in the induction of dermal bone differentiation during fin regeneration. Many other groups have also shown that molecules from the transforming growth factor-beta superfamily (TGFβ), including BMP2, are effective in promoting chondrogenesis and osteogenesisin vivoin higher vertebrates, including humans. In the present study, we review…

collagenPathologylcsh:MedicineReview Articlebonelcsh:TechnologydentineExtracellular matrixbone regenerationOsteogenesisMorphogenesislcsh:ScienceZebrafishZebrafishGeneral Environmental Sciencetransforming growth factor betaDermal bonebiologyenamelGeneral MedicineCell biologyendochondral ossificationmedicine.anatomical_structureModels Animalmedicine.medical_specialtyextracellular matrixosteocyteregenerative medicineray dermal boneBone morphogenetic protein 2Bone and BonesGeneral Biochemistry Genetics and Molecular BiologyFin regenerationsonic hedgehogbone morphogenetic proteinsmedicineAnimalsHumansactinopterygian fishesmammalslepidotrichiascleroblastmesenchymal stem cellslcsh:TRegeneration (biology)Cartilagelcsh:RZebrafish Proteinsbone repairbiology.organism_classificationChondrogenesisCartilageregenerationintramembranous ossificationlcsh:Qcell therapyvertebratesThe Scientific World Journal
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