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200 04$aThe growth plate$b[electronic resource] /$fedited by Irving M. Shapiro, Barbara Boyan, H. Clarke Anderson
210   $aAmsterdam ;$aWashington, DC $cIOS Press$dc2002
215   $a1 online resource (276 p.)
225 1 $aBiomedical and health research ;$vv. 54
300   $aDescription based upon print version of record.
311   $a1-58603-240-2 
311   $a0-585-45900-2 
320   $aIncludes bibliographical references and index.
327   $a""Cover""; ""Title page""; ""Preface""; ""Dedication""; ""Sponsors""; ""Contents""; ""Chapter 1: Indian Hedgehog and Retinoids Orchestrate Multiple Growth Plate Functions in Developing Long Bones: The Growth Plate as a Highly Interactive Structure""; ""Chapter 2: Involvement of Cbfal in Chondrocyte Differentiation Maturation, Endochondral Ossification, and the Specification of the Cartilage Phenotype""; ""Chapter 3: Cell Maturation Specific Regulation of the PKC Signaling Pathway by l?, 25-(OH)[sub(2)]D[sub(3)] and 24R, 25-(OH)[sub(2)]D[sub(3)] in Growth Plate Chondrocytes""
327   $a""Chapter 4: Regulation of Chondrogenesis and Cartilage Maturation In Vitro: Role of TGF-?1, Thyroid Hormone, and Wnt Signaling""""Chapter 5: Local Production of Estradiol by Growth Plate Chondrocytes and its Gender-Specific Membrane Mediated Effects""; ""Chapter 6: Components of the Cartilage Extracellular Matrix Regulate Chondrocyte Apoptosis""; ""Chapter 7: The Release and Activation of TGF-?2 Associated with Chondrocyte Hypertrophy and Apoptosis""; ""Chapter 8: Cell Death and Transdifferentiation in the Growth Plate""
327   $a""Chapter 9: Matrix Vesicles Contain Metalloproteinases that Are Released into the Matrix by Treatment with l?,25(OH)[sub(2)]D[sub(3)] and Are Capable of Activating Latent Transforming Growth Factor-?1""""Chapter 10: Mechanisms that Regulate Normal Bone Mineral Deposition: A Hypothesis on the Role of Antagonistic Pathways in Preventing Hypo- and Hyper-Mineralization""; ""Chapter 11: In Vitro Differentiation and Matrix Vesicle Biogenesis in Primary Cultures of Rat Growth Plate Chondrocytes""; ""Chapter 12: Growth Plate Proteins and Biomineralization""
327   $a""Chapter 13: Regulated Production of Mineralization-Competent Matrix Vesicles by Terminally Differentiated Chondrocytes""""Chapter 14: Linking Endochondral Ossification to Hematopoiesis""; ""Chapter 15: Fibroblast Growth Factor Receptor (FGFR) Mutations in Achondroplasia and Related Skeletal Dysplasias""; ""Chapter 16: Fibrodysplasia Ossificans Progressiva: Evolving Insights from a Rare Disease""; ""Chapter 17: Matrix Vesicle Misfunction in Human Hypophosphatasia""; ""Chapter 18: Tibial Dyschondroplasia: A Growth Plate Abnormality Caused by Delayed Terminal Differentiation""
327   $a""Chapter 19: RUNX2/CBFA1 Mutations in Cleidocranial Dysplasia: Phenotypic and Structure/Function Correlations""""Chapter 20: BMP-Regulated Chondrocyte Hypertrophy""; ""Chapter 21: Dual Roles of the Wnt Antagonist, Frzb-1 in Cartilage Development""; ""Chapter 22: Chondrocyte Kinetics in the Growth Plate""; ""Chapter 23: Localization of Bone Morphogenetic Proteins and their Intercellular Signaling Components (Smads) in the Growth Plate""; ""Author Index""; ""A""; ""B""; ""C""; ""D""; ""E""; ""F""; ""G""; ""H""; ""I""; ""J""; ""K""; ""L""; ""M""; ""N""; ""P""; ""R""; ""S""; ""T""; ""U""; ""W""
327   $a""Y""
330   $aEvidence generated by a number of genetic studies indicates that growth is regulated by a number of genes and that interference with their expression can have catastrophic effects on the well being of the whole organism. With the realization that multiple regulatory pathways exist, work is now focusing on identification of those signals that control the activity of the cells in the epiphyseal growth plate. A group of individuals included dental and orthopaedic researchers examining the regulation of cranialfacial growth and mineralization. The molecular biologists are probing skeletal morphoge
410  0$aBiomedical and health research ;$vv. 54.
606   $aBone cells
606   $aCartilage cells
606   $aBones$xGrowth
608   $aElectronic books.
615  0$aBone cells.
615  0$aCartilage cells.
615  0$aBones$xGrowth.
676   $a571.8
701   $aShapiro$b Irving M$0126902
701   $aBoyan$b Barbara$0859747
701   $aAnderson$b H. Clarke$0859748
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996   $aThe growth plate$91918559
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