Changes

After the previous chapters, we should now be able to recognize that, both in modern physics and in biology, a "Complex System" is a multi-component dynamic system composed of different subsystems that typically interact with each other. Such systems are typically studied through "holistic" investigation methodologies or as "total" computation of the behaviours of the individual subsystems, together with their mutual interactions; these can be described analytically through mathematical models, rather than, in a "reductionist" manner (i.e. by breaking down and analysing the system in its components). Typical of Complex Systems, are the concepts of self-organization and "Emerging Behaviour".  

After the previous chapters, we should now be able to recognize that, both in modern physics and in biology, a "Complex System" is a multi-component dynamic system composed of different subsystems that typically interact with each other. Such systems are typically studied through "holistic" investigation methodologies or as "total" computation of the behaviours of the individual subsystems, together with their mutual interactions; these can be described analytically through mathematical models, rather than, in a "reductionist" manner (i.e. by breaking down and analysing the system in its components). Typical of Complex Systems, are the concepts of self-organization and "Emerging Behaviour".  

To move more easily in this medical branch, a different scientific-clinical approach is required, one that widens the horizons of competence in fields such as bioengineering and neurobiology.  

To move more easily in this medical branch, a different scientific-clinical approach is required, one that widens the horizons of competence in fields such as bioengineering and neurobiology.  

It is, therefore, essential to focus attention on how to take trigeminal electrophysiological signals in response to a series of triggers evoked by an electrophysiological device, treating data and determining an organic-functional value of the trigeminal and masticatory systems as anticipated by Marom Bikson and coll. in a subchapter [[Electrical stimulation of cranial nerves in cognition and disease]].

It is, therefore, essential to focus attention on how to take trigeminal electrophysiological signals in response to a series of triggers evoked by an electrophysiological device, treating data and determining an organic-functional value of the trigeminal and masticatory systems as anticipated by Marom Bikson and coll. in their «''[[:File:Electrical stimulation of cranial nerves in cognition and disease.pdf|Electrical stimulation of cranial nerves in cognition and disease]]''».

We should think of a system that unifies the mastication and neurophysiological functions by introducing a new term: "'''Neuro-Gnathological Functions'''" which will be object of a dedicated chapters.

We should think of a system that unifies the mastication and neurophysiological functions by introducing a new term: "'''Neuro-Gnathological Functions'''" which will be object of a dedicated chapters.

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