@DiracPool: Is chaos established in neural control of the motor system?
Well, I think it may be dangerous to state that anything is definitely "established" in network neuroscience. Perhaps I should have said that motoric control systems in living mammals are likey governed through an organized chaotic effect rather than say the simple open loop, feedforward, feedback, or adaptive control systems that traditional robotics uses.
As you point out in your articles, the role of chaotic effects in biological systems is still an active area of research.
From the first article you referenced:
Originally, this dynamical state seemed to be in contradiction
to cortical anatomy, where each neuron receives a huge number
of synapses, typically 10^3–10^4 (Braitenberg and Schüz, 1998): One
might expect that a large number of uncorrelated, or weakly correlated
synaptic inputs to one neuron, given the central limit theorem,
sums up to a regular total input signal with only small relative fluctuations,
therefore excluding the emergence of irregular dynamics.
So the finding of highly irregular activity might be surprising.
My studies build heavily off of Walter Freeman's, who was one of the principle pioneers of the importance of chaotic dynamics in the CNS. He would likely answer the above problem presented by these researchers by saying that the "largely fluctuating membrane potentials
and highly variable inter-spike-intervals" of the individual neurons in question were due to aperiodic competing influences from extra-cortical or intra-cortical inter-areal (in the case of the cortex,) or extra-nuclear (in the case of subcortical regions) afferent pulse volleys. The end result would be the establshment of an aperiodic "ground" attractor, as your authors note, who's effect was not an accidental and unwanted artifact of "sloppy" neuropil organization, but rather a desired property of this tissue designed to prevent the system as a whole from entering a stable, entrained limit cycle state. If the system were to easily enter such low-dimensional states they would lose their flexibility to change those states rapidly and effectively.
In any case, there's too much theory and evidence to go into here and yes, this chaotic dynamical model, which Freeman calls the KV model, is specifically used in modeling cortical behavior, not necessarily motoric control at the level of the brain stem and spinal cord. However, the Carnot engine style formulation of the model he has recently been working on, along with I. Tsuda's concept of "chaotic intenarancy" in the CNS, I think provide a good model for how hierarchically sequenced behavior in mammals manifests from global chaotic behavior in the nervous system. But, of course, more study needs to be done
Here are a few references with more detail on the models I discussed above:
http://www.ncbi.nlm.nih.gov/pubmed/23333569
http://www.ncbi.nlm.nih.gov/pubmed/12239890
http://www.ncbi.nlm.nih.gov/pubmed/19395236
