Molecular dynamics study of biomembrane/local anesthetics interactions

Abstract

It is still controversial how local anesthetics (LAs) act upon the nervous system and how the membrane contributes to this process, since probably the most important active site of the LAs is located in the sodium channels, a trans-membrane protein. An important role of the bio-membrane would be the stabilization and orientation of local anesthetics molecules, reducing their translational and rotational degrees of freedom, which could reinforce the mechanisms which interrupt the nervous impulse. This study aims to perform a computational analysis of the LAs behaviour in the membrane, and the effect of the water/membrane interface on their stabilization and orientation. Analysis by molecular dynamics (MD) showed that the charged form of these drugs are oriented at the interface, while the neutral form can easily cross the interface, entering the membrane, in agreement with the most recent experimental results in the literature. In contrast, it is here suggested that benzocaine (BZC), which exists only in its uncharged form in physiological media, behaves like the charged anesthetics, remaining stabilized and oriented at the interface. This could explain the similar anesthetic effect of BZC and the charged forms of tetracaine (TTC) and lidocaine (LDC).