The workshop topics
- Critical transitions in biological systems
- Stochastic population dynamics & Statistical Mechanics models in ecology
- Whole brain models & collective behaviors in network of neurons
- Robustness and adaptability in living systems & eco-evolutionary dynamics
Living systems are characterized by the recurrent emergence of patterns: power-laws
distributions, long-range correlations and structured self-organization in living matter are
the norm, rather than the exception. All these features are also typical of systems poised near a critical point.
The great lesson from Physics is that criticality can emerge as a collective behaviour in a many-body system with simple
interactions and its characteristics depend only on few details, like the dimensionality or the symmetries.
One of the most striking feature of living systems is that they are structured as evolving systems were
interactions can turn-on or off, as well as strengthening and weakening,
reconfiguring the system connectivity. Thus, by rearranging both the structural and
functional topology, living interacting systems may demonstrate unique evolvability,
scalability and adaptability properties.
Among these systems, the brain is probably one of the most impressively complex and
has received a considerable amount of attention in recent years, aided by the vast amount
of experimental data available. The idea that the collective behavior of neurons might
emerge from a self-organized critical state has been widely studied, from its fundamental
mechanisms to its functional advantages, and it poses a fascinating question that is far
from being answered.
It is of crucial importance to make further steps in the understanding of the main properties
that simultaneously confer to these systems high level of adaptability, robustness and
optimality. If we can “learn” from evolution and unravel the basic principles then we would
be able to both better manage/supervise these systems and also design more optimal and
sustainable new systems.