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<span style="font-family:Courier; color:white;font-size:110%;">=COMPARATIVE CRITICISM: 2ND SYNOPSIS=
<span style="font-family:Courier; color:white;font-size:110%;">=COMPARATIVE CRITICISM: 2nd synopsis=




Gaia hypothesis formulated by the chemist James Lovelock and co-developed by the microbiologist Lynn Margulis in the 1970s proposes that the living organisms interacting with inorganic surroundings on the earth. This action forms synergistic and self-regulating complex system which helps to perpetuate and maintain the conditions for life on earth. The biosphere and the evolution of organisms should be able to affect the stability of global temperature, salinity, seawater, atmospheric oxygen levels, the maintenance of a hydrosphere of liquid water and other variables that affects life on earth.  
Gaia hypothesis formulated by the chemist James Lovelock and co-developed by the microbiologist Lynn Margulis in the 1970s proposes that the living organisms interacting with inorganic surroundings on the earth. This action forms synergistic and self-regulating complex system which helps to perpetuate and maintain the conditions for life on earth. The biosphere and the evolution of organisms should be able to affect the stability of global temperature, salinity, seawater, atmospheric oxygen levels, the maintenance of a hydrosphere of liquid water and other variables that affects life on earth.  




Homeostasis a complex dynamic adaptation of an organism or a device to the environment. It’s a resistance and the ability to change in the optimal condition and equilibrium made by homeostatic mechanism and regulators. Homeostatic systems are ultra-stable and their whole organization contributes to the balance.
Homeostasis a complex dynamic adaptation of an organism or a device to the environment. It’s a resistance and the ability to change in the optimal condition and equilibrium made by homeostatic mechanism and regulators. Homeostatic systems are ultra-stable and their whole organization contributes to the balance.




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One of the first devices capable of adapting itself to the environment was the homeostat made by the English psychiatrist and a pioneer in cybernetics William Ross Ashby in 1948. This adaptive ultra-stable system was able to learn and reinforce itself to maintain the homeostasis. In 1949 Time described it as ‘’the closest thing to a synthetic brain so far designed by man’’.  
One of the first devices capable of adapting itself to the environment was the homeostat made by the English psychiatrist and a pioneer in cybernetics William Ross Ashby in 1948. This adaptive ultra-stable system was able to learn and reinforce itself to maintain the homeostasis. In 1949 Time described it as ‘’the closest thing to a synthetic brain so far designed by man’’.  




Multicellular organism is relying on a complex communication between cells. One of the most profound evolutionary events in the history of life on earth is the development of a multicellular organisms from unicellular ancestors. During this transitions the cells started to communicate with each other in many ways while playing specific roles in the development and later controlling the cellular function. This process is particularly delicate during the early embryonic development. In the developed organism intercellular communication coordinates activities between multiple cells and makes an organism-wide process like growth, immune response and homeostasis.  
Multicellular organism is relying on a complex communication between cells. One of the most profound evolutionary events in the history of life on earth is the development of a multicellular organisms from unicellular ancestors. During this transitions the cells started to communicate with each other in many ways while playing specific roles in the development and later controlling the cellular function. This process is particularly delicate during the early embryonic development. In the developed organism intercellular communication coordinates activities between multiple cells and makes an organism-wide process like growth, immune response and homeostasis.  




Cells use a molecular code to communicate with each other. This phenomenon was discovered by a team of Caltech scientists. They release molecules called ligands into the environment to send messages to their neighbors. Ligands bind to receptors on the surface of other cell which interpret the message and trigger a set of chemical reactions. They communicate by analyzing the relationships between ligands, which embody the messages between themselves and the receptors located on the cell surface when they get bound by the ligands.  
Cells use a molecular code to communicate with each other. This phenomenon was discovered by a team of Caltech scientists. They release molecules called ligands into the environment to send messages to their neighbors. Ligands bind to receptors on the surface of other cell which interpret the message and trigger a set of chemical reactions. They communicate by analyzing the relationships between ligands, which embody the messages between themselves and the receptors located on the cell surface when they get bound by the ligands.  
   
   


All of the ligands interact promiscuously with all of the receptors. The cell decodes information from ligand combinations and not the individual ligands themselves, that means that a different combination of ligands encodes different instructions for the cell. But there is not only one information that is encoded in the group of ligands.  The information from the same combination of ligands can be read differently from non-identical kinds of cells because each type of cells has a different combination of receptors. The scientists discovered that most cells create a highly connected signaling network expressing tens or even hundreds of ligands and receptors to communicate which each other through multiple ligand-receptor paths. They also discovered that receptors evolved earlier than ligands.
All of the ligands interact promiscuously with all of the receptors. The cell decodes information from ligand combinations and not the individual ligands themselves, that means that a different combination of ligands encodes different instructions for the cell. But there is not only one information that is encoded in the group of ligands.  The information from the same combination of ligands can be read differently from non-identical kinds of cells because each type of cells has a different combination of receptors. The scientists discovered that most cells create a highly connected signaling network expressing tens or even hundreds of ligands and receptors to communicate which each other through multiple ligand-receptor paths. They also discovered that receptors evolved earlier than ligands.




Cells communication with their environment is based on chemicals that they release or absorb., but they have also the ability to respond to the mechanical forces, such as flow or the distortion or deformation of the material they are interacting with. Cells tend to bind to the environment, they interact with it exerting forces and unravel its elastics properties by ‘measuring’ the deformations these forces induce. Their ‘elastics-matching’ tendency coordinates the cell type they want to differentiate into. If the environmental elasticity is similar to brain tissue it will differentiate into neuron. The scientists are rising the questions how the cells sense elasticity, how does the cell ‘know how much force to apply and what can be the evolutionary advantage of this mechanism.  
Cells communication with their environment is based on chemicals that they release or absorb., but they have also the ability to respond to the mechanical forces, such as flow or the distortion or deformation of the material they are interacting with. Cells tend to bind to the environment, they interact with it exerting forces and unravel its elastics properties by ‘measuring’ the deformations these forces induce. Their ‘elastics-matching’ tendency coordinates the cell type they want to differentiate into. If the environmental elasticity is similar to brain tissue it will differentiate into neuron. The scientists are rising the questions how the cells sense elasticity, how does the cell ‘know how much force to apply and what can be the evolutionary advantage of this mechanism.  




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Synergy is the creation of a whole that is greater than the simple sum of its parts. We can find synergistic phenomena in physics, chemistry, cooperative interactions among genes and genomes, the division of labor in bacterial colonies, the synergies of scale in multicellular organisms and one that are produced by socially-organized groups, from honeybee, colonies to wolf packs and human society. The result is the self-assembly of complex systems. Human tools which are spread in the natural world represent important sources of synergistic effects. In a technical context is a construct or collection of different elements that work together and produces results that can’t be obtainable by any of the elements alone. The elements can include people, softwares, machines, facilities, etc. The relationship between the parts creates the value of the system.
Synergy is the creation of a whole that is greater than the simple sum of its parts. We can find synergistic phenomena in physics, chemistry, cooperative interactions among genes and genomes, the division of labor in bacterial colonies, the synergies of scale in multicellular organisms and one that are produced by socially-organized groups, from honeybee, colonies to wolf packs and human society. The result is the self-assembly of complex systems. Human tools which are spread in the natural world represent important sources of synergistic effects. In a technical context is a construct or collection of different elements that work together and produces results that can’t be obtainable by any of the elements alone. The elements can include people, softwares, machines, facilities, etc. The relationship between the parts creates the value of the system.
Norbert Wiener was first to define the world cybernetics as ‘’the science of control and communication, in the animal and the machine’’, taken from the Greek word kybernetes meaning ‘’governor’’ in the sense of ‘’steerman’’, who manages the control, co-ordination and regulation of the action. He tried to correlate all sorts of more or less independent branches of science, like digital electronic computing, information theory, neural networks, the theory of servomechanisms and feedback systems, psychology, psychiatry, decision theory and social sciences.
It’s a study of behavior of the machines, as far as it is reproducible, regular and determinate. Cybernetics includes and calculates also the non-existent systems and theories, which have no physical representation, but some of their proprieties are needed to stimulate the fantasy of a bigger picture, but also understand very simple systems. The question is not ‘’how it is made?’’ but ‘’what are all possible behavior that it can produce?’’ and ‘’why does it do this?’’
Different branches of science are merged together in the exact relation, helping each other to develop and grow. Cybernetics also reveals many interesting and suggestive pararellelisms between machine, brain and society and it scientifically threats and control very complex systems.
The nervous system has the unique ability to behave adaptively and mechanistically in the same time.
In 1948 Ashby said that the brain is not a thinking, but an acting machine, because it gets information and then does something about it. It is also tied in the body performance. The brain has the special role of adaptation, it helps us to survive in the unknown situations and environments that we have never encountered before. The same happens with the cybernetic brain, which is performative and his role in the performance is adaptation. ]
Gregory Bateson extended cybernetics to the social and behavioral sciences. He applied cybernetics to ecological anthropology and homeostasis. He claimed that the world is a series of systems, contained the one of individuals, societies and ecosystems. Inside every system can be found a competition and dependency. Each system has the ability of adaptive changes, that depend on feedback loops to control the balance and change multiple variables. He saw those self-correcting systems good as long they could maintain homeostasis. The key unit of survival in evolution was an organism and its environment.
Bateson understand the individual, social and ecosystem were all part of one supreme cybernetic system, which many people refer to as God, though Bateson referred to it as Mind. As a cybernetic system it can be only distinguished as a whole and not as parts. He saw the root of system collapse because of Occidental and Western epistemology, which the man exerted as a method and a mindset of an autocratic rule over all cybernetics systems. The man changes the environment to suit him unbalancing the cybernetic system of controlled competition and mutual dependency. In this was the man becomes a slave in his own self-made system due to non-linear nature of cybernetics. He argues for a culture that promotes most general wisdom and is able to adapt and flexibly change within the supreme cybernetic system.
Bateson tries to understand the importance of self-regulating systems and the causal role of idea, messages and differences.
Gaia hypothesis formulated by the chemist James Lovelock and co-developed by the microbiologist Lynn Margulis in the 1970s proposes that the living organisms interacting with inorganic surroundings on the earth. This action forms synergistic and self-regulating complex system which helps to perpetuate and maintain the conditions for life on earth. The biosphere and the evolution of organisms should be able to affect the stability of global temperature, salinity, seawater, atmospheric oxygen levels, the maintenance of a hydrosphere of liquid water and other variables that affects life on earth.

Latest revision as of 16:13, 20 March 2019


=COMPARATIVE CRITICISM: 2nd synopsis=


Gaia hypothesis formulated by the chemist James Lovelock and co-developed by the microbiologist Lynn Margulis in the 1970s proposes that the living organisms interacting with inorganic surroundings on the earth. This action forms synergistic and self-regulating complex system which helps to perpetuate and maintain the conditions for life on earth. The biosphere and the evolution of organisms should be able to affect the stability of global temperature, salinity, seawater, atmospheric oxygen levels, the maintenance of a hydrosphere of liquid water and other variables that affects life on earth.


Homeostasis a complex dynamic adaptation of an organism or a device to the environment. It’s a resistance and the ability to change in the optimal condition and equilibrium made by homeostatic mechanism and regulators. Homeostatic systems are ultra-stable and their whole organization contributes to the balance.


The mechanism of homeostasis consists of three parts: the receptor which recives the information of a change in the environment, the control center or integration center which receives and process the information and the effector that responds to the commands either opposing or enhancing the stimulus. The system mainly reacts to positive or negative feedback. The negative feedback tends to keep the homeostasis constant that means the system will reverse in such a way as to reverse the direction of a change. An example of negative feedback is the thermoregulation. When the temperature of the body rises receptors in the skin and hypothalamus sense the change triggering a command from the brain to decrease the body temperature. The positive feedback is not so common in living organisms. It has a destabilizing result so does not result in homeostasis. For example, in blood clotting platelets process mechanism to transform blood liquid to solidify.


One of the first devices capable of adapting itself to the environment was the homeostat made by the English psychiatrist and a pioneer in cybernetics William Ross Ashby in 1948. This adaptive ultra-stable system was able to learn and reinforce itself to maintain the homeostasis. In 1949 Time described it as ‘’the closest thing to a synthetic brain so far designed by man’’.


Multicellular organism is relying on a complex communication between cells. One of the most profound evolutionary events in the history of life on earth is the development of a multicellular organisms from unicellular ancestors. During this transitions the cells started to communicate with each other in many ways while playing specific roles in the development and later controlling the cellular function. This process is particularly delicate during the early embryonic development. In the developed organism intercellular communication coordinates activities between multiple cells and makes an organism-wide process like growth, immune response and homeostasis.


Cells use a molecular code to communicate with each other. This phenomenon was discovered by a team of Caltech scientists. They release molecules called ligands into the environment to send messages to their neighbors. Ligands bind to receptors on the surface of other cell which interpret the message and trigger a set of chemical reactions. They communicate by analyzing the relationships between ligands, which embody the messages between themselves and the receptors located on the cell surface when they get bound by the ligands.


All of the ligands interact promiscuously with all of the receptors. The cell decodes information from ligand combinations and not the individual ligands themselves, that means that a different combination of ligands encodes different instructions for the cell. But there is not only one information that is encoded in the group of ligands. The information from the same combination of ligands can be read differently from non-identical kinds of cells because each type of cells has a different combination of receptors. The scientists discovered that most cells create a highly connected signaling network expressing tens or even hundreds of ligands and receptors to communicate which each other through multiple ligand-receptor paths. They also discovered that receptors evolved earlier than ligands.


Cells communication with their environment is based on chemicals that they release or absorb., but they have also the ability to respond to the mechanical forces, such as flow or the distortion or deformation of the material they are interacting with. Cells tend to bind to the environment, they interact with it exerting forces and unravel its elastics properties by ‘measuring’ the deformations these forces induce. Their ‘elastics-matching’ tendency coordinates the cell type they want to differentiate into. If the environmental elasticity is similar to brain tissue it will differentiate into neuron. The scientists are rising the questions how the cells sense elasticity, how does the cell ‘know how much force to apply and what can be the evolutionary advantage of this mechanism.


Claude Bernard discovered that the extra-cellular fluid environment, more particularly the interstitial fluid has a physiological capacity to ensure protective stability for the tissues and organs of multicellular organism. He claimed that all of the vital mechanisms have always one goal, which is to maintain the uniformity of the conditions of life in the internal environment. The condition for the free and independent life is the stability of the internal environment. He named this phenomenon as Milieu intérieur.


Synergy is the creation of a whole that is greater than the simple sum of its parts. We can find synergistic phenomena in physics, chemistry, cooperative interactions among genes and genomes, the division of labor in bacterial colonies, the synergies of scale in multicellular organisms and one that are produced by socially-organized groups, from honeybee, colonies to wolf packs and human society. The result is the self-assembly of complex systems. Human tools which are spread in the natural world represent important sources of synergistic effects. In a technical context is a construct or collection of different elements that work together and produces results that can’t be obtainable by any of the elements alone. The elements can include people, softwares, machines, facilities, etc. The relationship between the parts creates the value of the system.


Norbert Wiener was first to define the world cybernetics as ‘’the science of control and communication, in the animal and the machine’’, taken from the Greek word kybernetes meaning ‘’governor’’ in the sense of ‘’steerman’’, who manages the control, co-ordination and regulation of the action. He tried to correlate all sorts of more or less independent branches of science, like digital electronic computing, information theory, neural networks, the theory of servomechanisms and feedback systems, psychology, psychiatry, decision theory and social sciences. It’s a study of behavior of the machines, as far as it is reproducible, regular and determinate. Cybernetics includes and calculates also the non-existent systems and theories, which have no physical representation, but some of their proprieties are needed to stimulate the fantasy of a bigger picture, but also understand very simple systems. The question is not ‘’how it is made?’’ but ‘’what are all possible behavior that it can produce?’’ and ‘’why does it do this?’’ Different branches of science are merged together in the exact relation, helping each other to develop and grow. Cybernetics also reveals many interesting and suggestive pararellelisms between machine, brain and society and it scientifically threats and control very complex systems.


The nervous system has the unique ability to behave adaptively and mechanistically in the same time.


In 1948 Ashby said that the brain is not a thinking, but an acting machine, because it gets information and then does something about it. It is also tied in the body performance. The brain has the special role of adaptation, it helps us to survive in the unknown situations and environments that we have never encountered before. The same happens with the cybernetic brain, which is performative and his role in the performance is adaptation. ] Gregory Bateson extended cybernetics to the social and behavioral sciences. He applied cybernetics to ecological anthropology and homeostasis. He claimed that the world is a series of systems, contained the one of individuals, societies and ecosystems. Inside every system can be found a competition and dependency. Each system has the ability of adaptive changes, that depend on feedback loops to control the balance and change multiple variables. He saw those self-correcting systems good as long they could maintain homeostasis. The key unit of survival in evolution was an organism and its environment. Bateson understand the individual, social and ecosystem were all part of one supreme cybernetic system, which many people refer to as God, though Bateson referred to it as Mind. As a cybernetic system it can be only distinguished as a whole and not as parts. He saw the root of system collapse because of Occidental and Western epistemology, which the man exerted as a method and a mindset of an autocratic rule over all cybernetics systems. The man changes the environment to suit him unbalancing the cybernetic system of controlled competition and mutual dependency. In this was the man becomes a slave in his own self-made system due to non-linear nature of cybernetics. He argues for a culture that promotes most general wisdom and is able to adapt and flexibly change within the supreme cybernetic system. Bateson tries to understand the importance of self-regulating systems and the causal role of idea, messages and differences. Gaia hypothesis formulated by the chemist James Lovelock and co-developed by the microbiologist Lynn Margulis in the 1970s proposes that the living organisms interacting with inorganic surroundings on the earth. This action forms synergistic and self-regulating complex system which helps to perpetuate and maintain the conditions for life on earth. The biosphere and the evolution of organisms should be able to affect the stability of global temperature, salinity, seawater, atmospheric oxygen levels, the maintenance of a hydrosphere of liquid water and other variables that affects life on earth.