Abstract
Sixty-gramme rats were given either 0, 75, 100 or 150 parts/10(6) fluoride in their drinking water. After five weeks, the fluoride, the phosphorus and the protein contents of the enamel were compared in control and experimental animals at three stages of enamel development. The mineral content was reduced in pigmented enamel from animals given 75 parts/10(6) or more fluoride in their drinking water. The fluoride content was elevated in all stages of fluorosed enamel development. At the lowest fluoride level (75 parts/10(6], a larger proline content was found in the proteins of the maturing, fluorosed enamel but there was no increase in the protein content. In animals given 100 parts/10(6) fluoride in their drinking water, the proline content of the protein was greater in maturing, fluorosed enamel, and the total protein content of the post-secretory enamel (maturing and pigmented) was greater than in the controls. These observations indicate that, with increasing levels of fluoride in drinking water, there was an initial delay in the loss of the amelogenin proteins followed by a decreased removal of total protein from the enamel. These results indicate that fluoride interfered with the normal post-secretory, pre-eruptive development of enamel.
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High-fluoride promoted phagocytosis-induced apoptosis in a matured ameloblast-like cell line
Endocytosis and phagocytosis are important physiologic activities occurring during ameloblast differentiation. We have previously found that excess fluoride inhibited ameloblasts endocytotic functions. Here, we hypothesized that increasing amounts of fluoride may affect ameloblast phagocytotic function during their differentiation. Using cell culture, we first induced maturation of the mouse ameloblast-like LS8
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Downregulation of miR-4755-5p promotes fluoride-induced osteoblast activation via tageting Cyclin D1.
Background Endemic fluorosis remains a major public health issue in many countries. Fluoride can cause abnormalities in osteoblast proliferation and activation, leading to skeletal fluorosis. However, its detailed molecular mechanism remains unclear. Based on a previous study, the aim of this study is to explore the role of miRNA in osteoblast
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Combined effect of amoxicillin and sodium fluoride on the structure of developing mouse enamel in vitro
OBJECTIVE: Excess fluoride intake during tooth development is known to cause dental fluorosis. It has also been suggested that amoxicillin use in early childhood is associated with enamel hypomineralization. The aim was to investigate separate and combined effects of sodium fluoride (NaF) and amoxicillin on enamel formation in vitro. DESIGN: Mandibular
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Changes in the fluoride-induced modulation of maturation stage ameloblasts of rats.
The maturation stage of enamel development is characterized by a cyclic modulation of the ameloblasts between bands of smooth-ended cells and longer bands of ruffle-ended cells. There are cyclic patterns of calcein staining of and 45Ca uptake in the enamel associated with this cellular modulation. Rats were given 0, 75,
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[Microscopic observation of the enamel microstructures of SD rats with different degrees of fluorosis]
Objective: To establish a dental fluorosis model of SD rats with various degrees, to observe the microstructures of enamel samples under scanning electron microscope and to clarify the changes of enamel microstructures with various degrees of dental fluorosis, so as to provide clinical reference for the treatment of patients with
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Dental Fluorosis Is a "Hypo-mineralization" of Enamel
Teeth with fluorosis have an increase in porosity in the subsurface enamel ("hypomineralization"). The increased porosity of enamel found in fluorosis is a result of a fluoride-induced impairment in the clearance of proteins (amelogenins) from the developing teeth. Despite over 50 years of research, the exact mechanism by which fluoride impairs amelogin
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Mechanisms by Which Fluoride Causes Dental Fluorosis Remain Unknown
When it comes to how fluoride impacts human health, no tissue in the body has been studied more than the teeth. Yet, despite over 50 years of research, the mechanism by which fluoride causes dental fluorosis (a hypo-mineralization of the enamel that results in significant staining of the teeth) is not
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Community Fluorosis Index (CFI)
The current Community Fluorosis Index for U.S. adolescents as a whole (from both fluoridated and non-fluoridated areas) is roughly 5 times higher than the CFI health authorities predicted for fluoridated areas when fluoridation first began. It is also higher than the CFI that the NIDR found in fluoridated areas back in the 1980s. It is readily apparent, therefore, that children are ingesting far more fluoride than was the case in the 1950s, and even as recently as the 1980s.
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Dental Fluorosis: The "Cosmetic" Factor
Any condition that can cause children to be embarrassed about their physical appearance can have significant consequences on their self-esteem and confidence. Researchers have repeatedly found that "physical appearance [is] the best predictor of self-esteem" in adolescents, (Harter 2000) and that facial attractiveness, particularly the appearance of one's teeth, is a
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"Mild" Dental Fluorosis: Perceptions & Psychological Impact
The vast majority of research has found that patients, parents, and the general public alike view mild fluorosis (TF score 3) as a significant blemish of the teeth, one that is likely to embarrass the affected child to a degree that cosmetic treatment would be warranted.
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