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If the template has a separate documentation page (usually called "Template:template name/doc"), add [[Category:Biochemistry templates]] to the <includeonly> section at the bottom of that page.
[[Category:Biochemistry image insertion templates]] to the <includeonly> section at the bottom of that page. Otherwise, add <noinclude>[[Category:Biochemistry image insertion templates]]</noinclude> to the end of the template code, making sure it starts on the same line as the code's last character.
For example, some authors use s, indicating species. [ 2 ] x is used here to match the state space notation used in control theory but either notation is acceptable. N {\displaystyle {\bf {N}}} is the stoichiometry matrix which is an m {\displaystyle m} by n {\displaystyle n} matrix of stoichiometry coefficient.
It is possible to build a computer simulation of a linear biochemical pathway. This can be done by building a simple model that describes each intermediate through a differential equation. The differential equations can be written by invoking mass conservation. For example, for the linear pathway:
The Hill equation is used extensively in pharmacology to quantify the functional parameters of a drug [citation needed] and are also used in other areas of biochemistry. The Hill equation can be used to describe dose-response relationships, for example ion channel open-probability (P-open) vs. ligand concentration. [15]
to the end of the template code, making sure it starts on the same line as the code's last character. Pages in category "Biochemistry stub templates" The following 43 pages are in this category, out of 43 total.
An example of a Lineweaver–Burk plot of 1/v against 1/a. In biochemistry, the Lineweaver–Burk plot (or double reciprocal plot) is a graphical representation of the Michaelis–Menten equation of enzyme kinetics, described by Hans Lineweaver and Dean Burk in 1934. [1]
In biochemistry and in biological fluids, at pH = 7, it is thus important to note that the reduction potential of the protons ( H +) into hydrogen gas H 2 is no longer zero as with the standard hydrogen electrode (SHE) at 1 M H + (pH = 0) in classical electrochemistry, but that E red = − 0.414 V {\displaystyle E_{\text{red}}=-0.414\mathrm {V ...