By tracing the integration of radioactively labelled proteins into
the inner mitochondrial membrane, they were able to prove that OXA is necessary for this process.
The proteins produced according to the mitochondrion's genetic material are integrated by the OXA into
the inner mitochondrial membrane.
Salicylanilides are very lipophilic and may shuttle protons across membranes, particularly
the inner mitochondrial membrane, thus removing the proton gradient and uncouple oxidative phosphorylation [6, 7, 15].
It couples electron transfer from NADH to ubiquinone with proton translocation across
the inner mitochondrial membrane and is involved in a wide range of human neurodegenerative disorders.
Once imported, it is then incorporated into the correct location within
the inner mitochondrial membrane.
So when we deliver less electrons to the electron transport chain this lowers the voltage on
the inner mitochondrial membrane and this gives us a lowered associate magnetic field with that electron current on this membrane.
Iron can react with hydrogen peroxide in
the inner mitochondrial membrane.
It helps to support energy metabolism by governing long chain fatty acids through
the inner mitochondrial membrane.