Irma Thesleff suomalainen hammaslääkäri ja professori
Thesleff, Irma
VIAF ID: 262693919 (Personal)
Permalink: http://viaf.org/viaf/262693919
Preferred Forms
- 100 0 _ ‡a Irma Thesleff ‡c suomalainen hammaslääkäri ja professori
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- 100 1 _ ‡a Thesleff, Irma
- 100 1 _ ‡a Thesleff, Irma
- 100 1 _ ‡a Thesleff, Irma
- 100 1 _ ‡a Thesleff, Irma
4xx's: Alternate Name Forms (7)
Works
Title | Sources |
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Bono1: a gene associated with regions of deposition of bone and dentine | |
Chondrogenic potential of mouse calvarial mesenchyme | |
Continuous tooth replacement: the possible involvement of epithelial stem cells. | |
Cooperation of Nectin-1 and Nectin-3 Is Required for Maintenance of Epidermal Stratification and Proper Hair Shaft Formation in the Mouse | |
Death receptor signaling giving life to ectodermal organs | |
Delayed tooth movement in Runx2+/- mice associated with mTORC2 in stretch-induced bone formation | |
Development of ectodermal organs. | |
Developmental biology and building a tooth | |
Developmental toxicity of dioxin to mouse embryonic teeth in vitro: arrest of tooth morphogenesis involves stimulation of apoptotic program in the dental epithelium | |
Different roles of Runx2 during early neural crest-derived bone and tooth development | |
Directional cell migration, but not proliferation, drives hair placode morphogenesis. | |
Disruption of Fgf10/Fgfr2b-coordinated epithelial-mesenchymal interactions causes cleft palate | |
Early epithelial signaling center governs tooth budding morphogenesis | |
Ectodysplasin and Wnt pathways are required for salivary gland branching morphogenesis. | |
Ectodysplasin, Edar and TNFRSF19 are expressed in complementary and overlapping patterns during mouse embryogenesis. | |
Ectodysplasin regulates activator-inhibitor balance in murine tooth development through Fgf20 signaling | |
Effect of Estrogen and Food Hardness on Metabolism and Turnover of Condylar Cartilage. | |
Explant culture of embryonic craniofacial tissues: analyzing effects of signaling molecules on gene expression | |
Expression of Foxi3 is regulated by ectodysplasin in skin appendage placodes | |
Expression of Runx1, -2 and -3 during tooth, palate and craniofacial bone development | |
Expression of the novel Golgi protein GoPro49 is developmentally regulated during mesenchymal differentiation | |
Expression of the stem cell marker, SOX2, in ameloblastoma and dental epithelium | |
Follistatin regulates enamel patterning in mouse incisors by asymmetrically inhibiting BMP signaling and ameloblast differentiation | |
Foxc1 integrates Fgf and Bmp signalling independently of twist or noggin during calvarial bone development. | |
From understanding tooth development to bioengineering of teeth | |
Functionally Distinctive Ptch Receptors Establish Multimodal Hedgehog Signaling in the Tooth Epithelial Stem Cell Niche | |
The genetic basis of tooth development and dental defects. | |
Glial origin of mesenchymal stem cells in a tooth model system. | |
Identification of a secreted BMP antagonist, ectodin, integrating BMP, FGF, and SHH signals from the tooth enamel knot | |
Identification of dkk4 as a target of Eda-A1/Edar pathway reveals an unexpected role of ectodysplasin as inhibitor of Wnt signalling in ectodermal placodes | |
The importance of signal pathway modulation in all aspects of tooth development | |
Inactivation of IL11 signaling causes craniosynostosis, delayed tooth eruption, and supernumerary teeth | |
Initiation of teeth from the dental lamina in the ferret. | |
An integrated gene regulatory network controls stem cell proliferation in teeth | |
Introduction to the ECR special odontology issue | |
List of Contributors | |
Lunatic fringe, FGF, and BMP regulate the Notch pathway during epithelial morphogenesis of teeth. | |
Mesenchymal Wnt/β-Catenin Signaling Controls Epithelial Stem Cell Homeostasis in Teeth by Inhibiting the Antiapoptotic Effect of Fgf10. | |
A missense mutation in PAX9 in a family with distinct phenotype of oligodontia | |
Modulation of activin/bone morphogenetic protein signaling by follistatin is required for the morphogenesis of mouse molar teeth | |
Molecular mechanisms in calvarial bone and suture development, and their relation to craniosynostosis | |
Mutations in AXIN2 cause familial tooth agenesis and predispose to colorectal cancer | |
Nonindependence of mammalian dental characters | |
Notch signalling is required for the survival of epithelial stem cells in the continuously growing mouse incisor. | |
Observations on continuously growing roots of the sloth and the K14-Eda transgenic mice indicate that epithelial stem cells can give rise to both the ameloblast and root epithelium cell lineage creating distinct tooth patterns | |
Organ culture in the analysis of tissue interactions | |
p63 regulates multiple signalling pathways required for ectodermal organogenesis and differentiation | |
Pathogenesis of ectodermal dysplasia. | |
Patterns of Wnt pathway activity in the mouse incisor indicate absence of Wnt/beta-catenin signaling in the epithelial stem cells. | |
Phenotypic changes in dentition of Runx2 homozygote-null mutant mice | |
Possible roles of Runx1 and Sox9 in incipient intramembranous ossification | |
Progression of calvarial bone development requires Foxc1 regulation of Msx2 and Alx4 | |
Regulation of hair follicle development by the TNF signal ectodysplasin and its receptor Edar | |
Regulation of mammalian tooth cusp patterning by ectodin | |
Regulation of Twist, Snail, and Id1 is conserved between the developing murine palate and tooth. | |
The role of growth factors in tooth development | |
The role of the dental lamina in mammalian tooth replacement. | |
Runx1 is involved in the fusion of the primary and the secondary palatal shelves. | |
Runx2 mediates FGF signaling from epithelium to mesenchyme during tooth morphogenesis | |
Sclerostin is a novel secreted osteoclast-derived bone morphogenetic protein antagonist with unique ligand specificity | |
Signaling networks regulating tooth organogenesis and regeneration, and the specification of dental mesenchymal and epithelial cell lineages | |
Sostdc1 defines the size and number of skin appendage placodes | |
Sox2 marks epithelial competence to generate teeth in mammals and reptiles | |
Sox2+ stem cells contribute to all epithelial lineages of the tooth via Sfrp5+ progenitors | |
Sox21 Regulates Anapc10 Expression and Determines the Fate of Ectodermal Organ | |
Splitting placodes: effects of bone morphogenetic protein and Activin on the patterning and identity of mouse incisors | |
Stem Cells and Tissue Engineering: Prospects for Regenerating Tissues in Dental Practice | |
Stem cells in craniofacial development and regeneration, c2013: | |
Sumo-1 function is dispensable in normal mouse development | |
Suppression of epithelial differentiation by Foxi3 is essential for molar crown patterning | |
Sustained epithelial beta-catenin activity induces precocious hair development but disrupts hair follicle down-growth and hair shaft formation. | |
The taming of the shrew milk teeth. | |
The three mouse actin-depolymerizing factor/cofilins evolved to fulfill cell-type-specific requirements for actin dynamics | |
Tinkering with the inductive mesenchyme: Sostdc1 uncovers the role of dental mesenchyme in limiting tooth induction. | |
Tissue Interactions Regulating Tooth Development and Renewal | |
Tooth patterning and enamel formation can be manipulated by misexpression of TNF receptor Edar. | |
Tooth shape formation and tooth renewal: evolving with the same signals | |
Wnt/β-catenin signaling in the dental mesenchyme regulates incisor development by regulating Bmp4 | |
Wnt10a regulates dentin sialophosphoprotein mRNA expression and possibly links odontoblast differentiation and tooth morphogenesis |