Kalzium/en: Unterschied zwischen den Versionen
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Calcium plays an important role in [[nerve]]<nowiki>excitation</nowiki>, [[muscle]]contraction and regulation of intracellular metabolism. Calcium, for example, is released by stimuli from the [[endoplasmic reticulum|endoplasmic reticulum]] and triggers contraction in the muscle by lifting the [[tropomyosin]] barrier. This requires energy, which the body provides in the form of [[ATP]]. | Calcium plays an important role in [[nerve]]<nowiki>excitation</nowiki>, [[muscle]]contraction and regulation of intracellular metabolism. Calcium, for example, is released by stimuli from the [[endoplasmic reticulum|endoplasmic reticulum]] and triggers contraction in the muscle by lifting the [[tropomyosin]] barrier. This requires energy, which the body provides in the form of [[ATP]]. | ||
| − | + | Like other ions, it can be transported through membranes against the concentration gradient by special, voltage-dependent and receptor-dependent calcium channels, by opposing [[sodium]] influx, by [[adenosine triphosphate,_ATP|ATP]]-dependent active transport and by coupling to electron transport. | |
[https://de.wikipedia.org/wiki/Calcium Calcium in Wikipedia] <sub>([https://de.wikipedia.org/wiki/Wikipedia:Lizenzbestimmungen_Commons_Attribution-ShareAlike_3.0_Unported Wikipedia CC-by-sa-3.0])</sub> | [https://de.wikipedia.org/wiki/Calcium Calcium in Wikipedia] <sub>([https://de.wikipedia.org/wiki/Wikipedia:Lizenzbestimmungen_Commons_Attribution-ShareAlike_3.0_Unported Wikipedia CC-by-sa-3.0])</sub> | ||
Version vom 16. April 2019, 21:50 Uhr
Calcium, also Ca++, physiologically important divalent alkaline earth metal, is used for the formation of bones (99% of the body-Ca), is present in the blood as ionized Ca++ and bound to protein (90 - 110 mg/l).
Calcium plays an important role in nerveexcitation, musclecontraction and regulation of intracellular metabolism. Calcium, for example, is released by stimuli from the endoplasmic reticulum and triggers contraction in the muscle by lifting the tropomyosin barrier. This requires energy, which the body provides in the form of ATP.
Like other ions, it can be transported through membranes against the concentration gradient by special, voltage-dependent and receptor-dependent calcium channels, by opposing sodium influx, by ATP-dependent active transport and by coupling to electron transport.