bacteria$6521$ - перевод на греческий
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bacteria$6521$ - перевод на греческий

FERROBACTERIA KNOWN BY A PARTICULAR COMMON NAME
Iron bacteria; Photoferrotrophic bacteria

bacteria      
n. βακτήρια, μικρόβια
dental decay         
  • An amalgam used as a restorative material in a tooth.
  • Tooth decay
  • logarithmic scale]], so line is straight.
  • Diagrammatic representation of acidogenic theory of causation of dental caries. Four factors, namely, a suitable carbohydrate substrate '''(1)''', micro-organisms in dental plaque '''(2)''', a susceptible tooth surface '''(3)''' and time '''(4)'''; must be present together for dental caries to occur '''(5)'''. Saliva '''(6)''' and fluoride '''(7)''' are modifying factors.
  • >142}}
{{col-end}}
  • Microbe communities attach to tooth surface and create a biofilm. As the biofilm grows an anaerobic environment forms from the oxygen being used. Microbes use sucrose and other dietary sugars as a food source. The dietary sugars go through anaerobic fermentation pathways producing lactate. The lactate is excreted from the cell onto the tooth enamel then ionizes. The lactate ions demineralize the hydroxyapatite crystals causing the tooth to degrade.
  • The tip of a [[dental explorer]], which is used for caries diagnosis
  • A dental infection resulting in an abscess and inflammation of the maxillary sinus
  • Common dentistry trays used to deliver fluoride.
  • G. V. Black]] Classification of Restorations
  • Tooth samples imaged with a non-coherent continuous light source (row 1), LSI (row 2) and pseudo-color visualization of LSI (row 3).<ref name="Deana2013" />
  • An image from ''[[Omne Bonum]]'' (14th century) depicting a dentist extracting a tooth with [[forceps]].
  • The progression of pit and fissure caries resembles two triangles with their bases meeting along the junction of enamel and dentin.
  • The faster spread of caries through dentin creates this triangular appearance in smooth surface caries.
  • Fluoride is sold in tablets for cavity prevention.
  • "Stephan curve", showing sudden decrease in plaque pH following glucose rinse, which returns to normal after 30–60&nbsp;min. Net demineralization of dental hard tissues occurs below the critical pH (5.5), shown in yellow.
  • A [[Gram stain]] image of ''Streptococcus mutans''.
  • Rampant caries caused by [[methamphetamine]] abuse.
  • filling]].
  • [[Toothbrush]]es are commonly used to clean teeth.
  • A tooth with extensive caries eventually requiring extraction.
DEFORMATION OF TEETH MADE BY ACIDS FROM BACTERIA
Caries; Dental cavity; Dental cavities; Cariogenesis; Dental cariogenesis; Tooth Decay Bacteria; Diet, cariogenic; Carious lesion; Caries lesion; Cariostatic agents; Cariogenic agents; Rampant caries; Smooth surface caries; Smooth-surface caries; Pit and fissure caries; Root surface caries; Root caries; Dental decay; Tooth infections; Tooth cavity; Mountain Dew mouth; Teeth decay; Cariogenic; Caries formation; Caries Formation; Fissure (dentistry); Anticariogenic; Incipient carious lesion; Cariogenicity; Dental worm; Teeth cavities; Laser caries detection; Mountain Dew Mouth; Soda mouth; Baby Bottle Tooth Decay; Baby Bottle Mouth Syndrome; Dental caries; Dental carries
τερηδόνα

Определение

bacterium

Википедия

Iron-oxidizing bacteria

Iron-oxidizing bacteria (or iron bacteria) are chemotrophic bacteria that derive energy by oxidizing dissolved iron. They are known to grow and proliferate in waters containing iron concentrations as low as 0.1 mg/L. However, at least 0.3 ppm of dissolved oxygen is needed to carry out the oxidation.

When de-oxygenated water reaches a source of oxygen, iron bacteria convert dissolved iron into an insoluble reddish-brown gelatinous slime that discolors stream beds and can stain plumbing fixtures, clothing, or utensils washed with the water carrying it. Organic material dissolved in water is often the underlying cause of an iron-oxidizing bacteria population. Groundwater may be naturally de-oxygenated by decaying vegetation in swamps. Useful mineral deposits of bog iron ore have formed where groundwater has historically emerged and been exposed to atmospheric oxygen. Anthropogenic hazards like landfill leachate, septic drain fields, or leakage of light petroleum fuels like gasoline are other possible sources of organic materials allowing soil microbes to de-oxygenate groundwater. A similar reaction may form black deposits of manganese dioxide from dissolved manganese but is less common because of the relative abundance of iron (5.4%) in comparison to manganese (0.1%) in average soils. The sulfurous smell of rot or decay sometimes associated with iron-oxidizing bacteria results from the enzymatic conversion of soil sulfates to volatile hydrogen sulfide as an alternative source of oxygen in anaerobic water.

Iron is a very important chemical element required by living organisms to carry out numerous metabolic reactions such as the formation of proteins involved in biochemical reactions. Examples of these proteins include iron–sulfur proteins, hemoglobin, and coordination complexes. Iron has a widespread distribution globally and is considered one of the most abundant elements in the Earth's crust, soil, and sediments. Iron is a trace element in marine environments. Its role in the metabolism of some chemolithotrophs is probably very ancient.

As Liebig's law of the minimum notes, the essential element present in the smallest amount (called limiting factor) is the one that determines the growth rate of a population. Iron is the most common limiting element in phytoplankton communities and has a key role in structuring and determining their abundance. It is particularly important in the high-nutrient, low-chlorophyll regions, where the presence of micronutrients is mandatory for the total primary production.