The interaction of a multiplicity of scales in both time and space is a fundamental feature of biological systems. The complementation of macroscopic (entire organism) and microscopic (molecular biology) views with a mesoscopic level of analysis able to connect the different planes of investigation is urgently needed. This will allow us to both obtain a general frame of reference for rationalizing the burden of data coming from high throughput technologies and to derive effective operational views on biological systems. To reach this goal, we need a “biological statistical mechanics” taking into account the peculiar nature of biological systems.

Biological statistical mechanics is strongly linked to the generalization of statistical approaches for out-of-equilibrium mesoscopic systems as the background for the extension of thermodynamics for biological systems revealing specific types of criticality responsible for DNA and cell transformation. This way can be promising for defining meaningful internal variables and out of equilibrium thermodynamic potentials related to the epigenetic landscape of biological system kinetics and “thermalization” conditions. The definition of internal variables in the statistics and thermodynamics of biological systems is related also to the symmetry changes responsible for critical dynamics of biological transformation. The statistical mechanics approach is correlated with the method of analysis of biological critical systems to establish the qualitative changes of the spatial–temporal scaling properties in the transformation of biological systems.

This implies we must use a sensible approach when transferring established physical concepts into the biological realm, and thus, an “attractor-like” behavior in cell biology will correspond to a typical gene expression profile over many thousands of genes and can be recognized in terms of Pearson correlation between different samples of the same cell kind while escaping a rigorous mathematical description in terms of differential equations. We are convinced Entropy is the right place to host scientific works that dare pay serious attention to biology without considering biological problems only as an occasion for interesting applications of physical concepts.

• tipping-point
• phase transitions
• complex networks
• non-linear dynamics
• protein structure and dynamics
• scaling
• biological evolution
• cell biology, physiology