The term autopoiesis (from Greek αὐτo- (auto) 'self' and ποίησις (poiesis) 'creation, production') refers to a system capable of producing and maintaining itself by creating its own parts.[1] The term was introduced in the 1972 publication Autopoiesis and Cognition: The Realization of the Living by Chilean biologists Humberto Maturana and Francisco Varela to define the self-maintaining chemistry of living cells.[2]

3D representation of a living cell during the process of mitosis, example of an autopoietic system

The concept has since been applied to the fields of cognition, neurobiology, systems theory, architecture and sociology. Niklas Luhmann briefly introduced the concept of autopoiesis to organizational theory.[3]

Overview

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In their 1972 book Autopoiesis and Cognition, Chilean biologists Maturana and Varela described how they invented the word autopoiesis.[4]: 89 : 16 

"It was in these circumstances ... in which he analyzed Don Quixote's dilemma of whether to follow the path of arms (praxis, action) or the path of letters (poiesis, creation, production), I understood for the first time the power of the word "poiesis" and invented the word that we needed: autopoiesis. This was a word without a history, a word that could directly mean what takes place in the dynamics of the autonomy proper to living systems."

They explained that,[4]: 78 

"An autopoietic machine is a machine organized (defined as a unity) as a network of processes of production (transformation and destruction) of components which: (i) through their interactions and transformations continuously regenerate and realize the network of processes (relations) that produced them; and (ii) constitute it (the machine) as a concrete unity in space in which they (the components) exist by specifying the topological domain of its realization as such a network."

They described the "space defined by an autopoietic system" as "self-contained", a space that "cannot be described by using dimensions that define another space. When we refer to our interactions with a concrete autopoietic system, however, we project this system on the space of our manipulations and make a description of this projection."[4]: 89 

Meaning

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Autopoiesis was originally presented as a system description that was said to define and explain the nature of living systems. A canonical example of an autopoietic system is the biological cell. The eukaryotic cell, for example, is made of various biochemical components such as nucleic acids and proteins, and is organized into bounded structures such as the cell nucleus, various organelles, a cell membrane and cytoskeleton. These structures, based on an internal flow of molecules and energy, produce the components which, in turn, continue to maintain the organized bounded structure that gives rise to these components.

An autopoietic system is to be contrasted with an allopoietic system, such as a car factory, which uses raw materials (components) to generate a car (an organized structure) which is something other than itself (the factory). However, if the system is extended from the factory to include components in the factory's "environment", such as supply chains, plant / equipment, workers, dealerships, customers, contracts, competitors, cars, spare parts, and so on, then as a total viable system it could be considered to be autopoietic.[5]

Of course, cells also require raw materials (nutrients), and produce numerous products -waste products, the extracellular matrix, intracellular messaging molecules, etc.

Autopoiesis in biological systems can be viewed as a network of constraints that work to maintain themselves. This concept has been called organizational closure[6] or constraint closure[7] and is closely related to the study of autocatalytic chemical networks where constraints are reactions required to sustain life.

Though others have often used the term as a synonym for self-organization, Maturana himself stated he would "[n]ever use the notion of self-organization ... Operationally it is impossible. That is, if the organization of a thing changes, the thing changes".[8] Moreover, an autopoietic system is autonomous and operationally closed, in the sense that there are sufficient processes within it to maintain the whole. Autopoietic systems are "structurally coupled" with their medium, embedded in a dynamic of changes that can be recalled as sensory-motor coupling.[9] This continuous dynamic is considered as a rudimentary form of knowledge or cognition and can be observed throughout life-forms.

An application of the concept of autopoiesis to sociology can be found in Niklas Luhmann's Systems Theory, which was subsequently adapted by Bob Jessop in his studies of the capitalist state system. Marjatta Maula adapted the concept of autopoiesis in a business context.[10] The theory of autopoiesis has also been applied in the context of legal systems by not only Niklas Luhmann, but also Gunther Teubner.[11][12] Patrik Schumacher has applied the term to refer to the 'discursive self-referential making of architecture.' [13][14] Varela eventually further applied autopoesis to develop models of mind, brain, and behavior called non-representationalist, enactive, embodied cognitive neuroscience, culminating in neurophenomenology.

In the context of textual studies, Jerome McGann argues that texts are "autopoietic mechanisms operating as self-generating feedback systems that cannot be separated from those who manipulate and use them".[15] Citing Maturana and Varela, he defines an autopoietic system as "a closed topological space that 'continuously generates and specifies its own organization through its operation as a system of production of its own components, and does this in an endless turnover of components'", concluding that "Autopoietic systems are thus distinguished from allopoietic systems, which are Cartesian and which 'have as the product of their functioning something different from themselves'". Coding and markup appear allopoietic", McGann argues, but are generative parts of the system they serve to maintain, and thus language and print or electronic technology are autopoietic systems.[16]: 200–1 

The philosopher Slavoj Žižek, in his discussion of Hegel, argues:

"Hegel is – to use today's terms – the ultimate thinker of autopoiesis, of the process of the emergence of necessary features out of chaotic contingency, the thinker of contingency's gradual self-organisation, of the gradual rise of order out of chaos."[17]

Relation to complexity

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Autopoiesis can be defined as the ratio between the complexity of a system and the complexity of its environment.[18]

This generalized view of autopoiesis considers systems as self-producing not in terms of their physical components, but in terms of its organization, which can be measured in terms of information and complexity. In other words, we can describe autopoietic systems as those producing more of their own complexity than the one produced by their environment.

— Carlos Gershenson, "Requisite Variety, Autopoiesis, and Self-organization" [19]

Autopoiesis has been proposed as a potential mechanism of abiogenesis, by which molecules evolved into more complex cells that could support the development of life.[20]

Comparison with other theories of life

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Autopoiesis is just one of several current theories of life, including the chemoton[21] of Tibor Gánti, the hypercycle of Manfred Eigen and Peter Schuster,[22] [23] [24] the (M,R) systems[25][26] of Robert Rosen, and the autocatalytic sets[27] of Stuart Kauffman, similar to an earlier proposal by Freeman Dyson.[28] All of these (including autopoiesis) found their original inspiration in Erwin Schrödinger's book What is Life?[29] but at first they appear to have little in common with one another, largely because the authors did not communicate with one another, and none of them made any reference in their principal publications to any of the other theories. Nonetheless, there are more similarities than may be obvious at first sight, for example between Gánti and Rosen.[30] Until recently[31][32][33] there have been almost no attempts to compare the different theories and discuss them together.

Relation to cognition

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An extensive discussion of the connection of autopoiesis to cognition is provided by Evan Thompson in his 2007 publication, Mind in Life.[34] The basic notion of autopoiesis as involving constructive interaction with the environment is extended to include cognition. Initially, Maturana defined cognition as behavior of an organism "with relevance to the maintenance of itself".[35]: 13  However, computer models that are self-maintaining but non-cognitive have been devised, so some additional restrictions are needed, and the suggestion is that the maintenance process, to be cognitive, involves readjustment of the internal workings of the system in some metabolic process. On this basis it is claimed that autopoiesis is a necessary but not a sufficient condition for cognition.[36] Thompson wrote that this distinction may or may not be fruitful, but what matters is that living systems involve autopoiesis and (if it is necessary to add this point) cognition as well.[37]: 127  It can be noted that this definition of 'cognition' is restricted, and does not necessarily entail any awareness or consciousness by the living system. With the publication of The Embodied Mind in 1991, Varela, Thompson and Rosch applied autopoesis to make non-representationalist, and enactive models of mind, brain and behavior, which further developed embodied cognitive neuroscience, later culminating in neurophenomenology.

Relation to consciousness

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The connection of autopoiesis to cognition, or if necessary, of living systems to cognition, is an objective assessment ascertainable by observation of a living system.

One question that arises is about the connection between cognition seen in this manner and consciousness. The separation of cognition and consciousness recognizes that the organism may be unaware of the substratum where decisions are made. What is the connection between these realms? Thompson refers to this issue as the "explanatory gap", and one aspect of it is the hard problem of consciousness, how and why we have qualia.[38]

A second question is whether autopoiesis can provide a bridge between these concepts. Thompson discusses this issue from the standpoint of enactivism. An autopoietic cell actively relates to its environment. Its sensory responses trigger motor behavior governed by autopoiesis, and this behavior (it is claimed) is a simplified version of a nervous system behavior. The further claim is that real-time interactions like this require attention, and an implication of attention is awareness.[39]

Criticism

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There are multiple criticisms of the use of the term in both its original context, as an attempt to define and explain the living, and its various expanded usages, such as applying it to self-organizing systems in general or social systems in particular.[40] Critics have argued that the concept and its theory fail to define or explain living systems and that, because of the extreme language of self-referentiality it uses without any external reference, it is really an attempt to give substantiation to Maturana's radical constructivist or solipsistic epistemology,[41] or what Danilo Zolo[42][43] has called instead a "desolate theology". An example is the assertion by Maturana and Varela that "We do not see what we do not see and what we do not see does not exist".[44]

According to Razeto-Barry, the influence of Autopoiesis and Cognition: The Realization of the Living in mainstream biology has proven to be limited. Razeto-Barry believes that autopoiesis is not commonly used as the criterion for life.[45]

Zoologist and philosopher Donna Haraway also criticizes the usage of the term, arguing that "nothing makes itself; nothing is really autopoietic or self-organizing",[46] and suggests the use of sympoiesis, meaning "making-with", instead.

See also

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References

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  1. ^ "autopoiesis". Oxford Reference. Retrieved 2021-11-12.
  2. ^ Maturana, Humberto R.; Varela, Francisco J. (1972). Autopoiesis and cognition: the realization of the living. Boston studies in the philosophy and history of science (1 ed.). Dordrecht: Reidel. p. 141. OCLC 989554341.
  3. ^ Achterberg, Jan; Vriens, Dirk (2010). "The Social "arche," Organizations as Social Systems: Luhmann". Organizations. Springer Berlin. pp. 118–120. doi:10.1007/978-3-642-14316-8_4. ISBN 978-3-642-14315-1.
  4. ^ a b c Maturana, Humberto; Varela, Francisco (1980) [1972]. Autopoiesis and Cognition: The Realization of the Living (2 ed.). Springer. ISBN 9789027710161.
  5. ^ Koskinen KU (2013). Knowledge production in organizations : a processual autopoietic view. Heidelberg: Springer. ISBN 9783319001043. OCLC 846465493.
  6. ^ Montévil, Maël (2015). "Biological organisation as closure of constraints". Journal of Theoretical Biology. 372: 179–191. Bibcode:2015JThBi.372..179M. doi:10.1016/j.jtbi.2015.02.029. PMID 25752259. S2CID 4654439. Retrieved 6 July 2021.
  7. ^ Kauffman, Stuart A. (April 1, 2019). A world beyond physics: the emergence and evolution of life. Oxford University Press.
  8. ^ Maturana H (1987). "Everything is said by an observer". In Thompson, William Irwin (ed.). Gaia, a Way of Knowing: Political Implications of the New Biology. Great Barrington, MA: Lindisfarne Press. pp. 65–82, 71. ISBN 978-0-940262-23-2. OCLC 15792540.
  9. ^ Allen M, Friston KJ (2018-06-01). "From cognitivism to autopoiesis: towards a computational framework for the embodied mind". Synthese. 195 (6): 2459–2482. doi:10.1007/s11229-016-1288-5. PMC 5972168. PMID 29887647.
  10. ^ Maula M (2006). Organizations as learning systems: 'Living composition' as an enabling infrastructure. Advanced Series in Management. Emerald Group Publishing.
  11. ^ Teubner G (1992). Law as an Autopoietic System. The European University Institute Press.
  12. ^ For a discussion on the evolution and development of autopoietic legal systems, see, Kaye, Tim, ed. (2011). Law, justice, and miscommunications: essays in applied legal philosophy. Lake Mary, Fla: Vandeplas Publ. ISBN 978-1-60042-152-5.
  13. ^ "Architect Patrik Schumacher: 'I've been depicted as a fascist'". the Guardian. 2018-01-17. Retrieved 2021-12-07.
  14. ^ "Postmodernisms: Theories and Analyses of Architecture II | "The Autopoiesis of Architecture" Patrik Schumacher's Parametricism and Theory". blogs.cornell.edu. Retrieved 2021-12-07.
  15. ^ McGann J (1986). The Textual Condition. Princeton University Press. p. 15.
  16. ^ McGann J (2000). "Marking Texts of Many Dimensions". In Schreibman S, Siemens RG, Unsworth JM (eds.). A Companion to Digital Humanities. John Wiley & Sons.
  17. ^ Žižek S (2012). Less Than Nothing. Verso. p. 467.
  18. ^ Fernandez N, Maldonado C, Gershenson C (2013). "Chapter 2: Information Measures of Complexity, Emergence, Self-organization, Homeostasis, and Autopoiesis". Guided self-organization: Inception. Springer. pp. 19–51. arXiv:1304.1842. Bibcode:2013arXiv1304.1842F. ISBN 978-3-642-53734-9.
  19. ^ Gershenson C (26 Sep 2014). "Requisite Variety, Autopoiesis, and Self-organization". arXiv:1409.7475 [nlin.AO].
  20. ^ Highfield, Roger; Coveney, Peter (1995). Frontiers of complexity: the search for order in a chaotic world. London: Faber. p. 210. ISBN 0-571-17922-3.
  21. ^ Gánti, Tibor (2003). Eörs Száthmary; James Griesemer (eds.). The Principles of Life. Oxford University Press. ISBN 9780198507260.
  22. ^ Eigen, M; Schuster, P (1977). "The hypercycle: a principle of natural self-organization. A: emergence of the hypercycle". Naturwissenschaften. 64 (11): 541–565. doi:10.1007/bf00450633. PMID 593400. S2CID 42131267.
  23. ^ Eigen, M; Schuster, P. "The hypercycle: a principle of natural self-organization. B: the abstract hypercycle". Naturwissenschaften. 65 (1): 7–41. doi:10.1007/bf00420631. S2CID 1812273.
  24. ^ Eigen, M; Schuster, P. "The hypercycle: a principle of natural self-organization. C: the realistic hypercycle". Naturwissenschaften. 65 (7): 41–369. doi:10.1007/bf00420631. S2CID 1812273.
  25. ^ Rosen, R. (1958). "The representation of biological systems from the standpoint of the theory of categories". Bull. Math. Biophys. 20 (4): 317–341. doi:10.1007/BF02477890.
  26. ^ Rosen, R. (1991). Life Itself: a comprehensive inquiry into the nature, origin, and fabrication of life. New York: Columbia University Press.
  27. ^ Kauffman, S. A. (1969). "Metabolic stability and epigenesis in randomly constructed genetic nets". J. Theor. Biol. 22 (3): 437–467. Bibcode:1969JThBi..22..437K. doi:10.1016/0022-5193(69)90015-0. PMID 5803332.
  28. ^ Dyson, F. J. (1982). "A model for the origin of life". J. Mol. Evol. 18 (5): 344–350. Bibcode:1982JMolE..18..344D. doi:10.1007/bf01733901. PMID 7120429. S2CID 30423925.
  29. ^ Schrödinger, Erwin (1944). What is Life?. Cambridge University Press.
  30. ^ Cornish-Bowden, A. (2015). "Tibor Gánti and Robert Rosen: contrasting approaches to the same problem". J. Theor. Biol. 381: 6–10. Bibcode:2015JThBi.381....6C. doi:10.1016/j.jtbi.2015.05.015. PMID 25988381.
  31. ^ Letelier, J C; Cárdenas, M L; Cornish-Bowden, A (2011). "From L'Homme Machine to metabolic closure: steps towards understanding life". J. Theor. Biol. 286 (1): 100–113. Bibcode:2011JThBi.286..100L. doi:10.1016/j.jtbi.2011.06.033. PMID 21763318.
  32. ^ Igamberdiev, A.U. (2014). "Time rescaling and pattern formation in biological evolution". BioSystems. 123: 19–26. Bibcode:2014BiSys.123...19I. doi:10.1016/j.biosystems.2014.03.002. PMID 24690545.
  33. ^ Cornish-Bowden, A; Cárdenas, M L (2020). "Contrasting theories of life: historical context, current theories. In search of an ideal theory". BioSystems. 188: 104063. Bibcode:2020BiSys.18804063C. doi:10.1016/j.biosystems.2019.104063. PMID 31715221. S2CID 207946798.
  34. ^ Thompson, Evan (2007). "Chapter 5: Autopoiesis: The organization of the living". Mind in Life: Biology, Phenomenology, and the Sciences of Mind. Harvard University Press. pp. 91–127. ISBN 978-0-674-02511-0.
  35. ^ Maturana, Humberto; Varela, Francisco (1980) [1972]. "The cognitive process". Autopoiesis and Cognition: The Realization of the Living (2 ed.). Springer. ISBN 9789027710161.
  36. ^ Bitbol M, Luisi PL (November 2004). "Autopoiesis with or without cognition: defining life at its edge". Journal of the Royal Society, Interface. 1 (1): 99–107. doi:10.1098/rsif.2004.0012. PMC 1618936. PMID 16849156.
  37. ^ Thompson, Evan (2007). Mind in Life: Biology, Phenomenology, and the Sciences of Mind. Harvard University Press. ISBN 978-0-674-02511-0.
  38. ^ Thompson, Evan (2007). "Cognitivism". Mind in Life: Biology, Phenomenology, and the Sciences of Mind. Harvard University Press. p. 7. ISBN 978-0-674-02511-0.
  39. ^ Thompson, Evan (2007). "Sensorimotor subjectivity". Mind in Life: Biology, Phenomenology, and the Sciences of Mind. Harvard University Press. p. 243. ISBN 978-0-674-02511-0.
  40. ^ Fleischaker G (1992). "Autopoiesis in Systems Analysis: A Debate". International Journal of General Systems. 21 (2): 131–271. doi:10.1080/03081079208945065.
  41. ^ Swenson R (1992). "Autocatakinetics, Yes—Autopoiesis, No: Steps Toward a Unified Theory of Evolutionary Ordering". International Journal of General Systems. 21 (2): 207–208. doi:10.1080/03081079208945072.
  42. ^ Kenny V, Gardner G (1988). "The constructions of self-organizing systems". The Irish Journal of Psychology. 9 (1): 1–24. doi:10.1080/03033910.1988.10557704.
  43. ^ Wolfe C (1998). Critical environments: postmodern theory and the pragmatics of the "outside". University of Minnesota Press. pp. 62–3. ISBN 978-0-8166-3019-6.
  44. ^ Maturana H, Varela F (1988). The Tree of Knowledge. New Science Library. Boston: Shambhala Publications. p. 242.
  45. ^ Razeto-Barry, Pablo (October 2012). "Autopoiesis 40 Years Later. A Review and A Reformulation". Origins of Life. 42 (6): 543–567. Bibcode:2012OLEB...42..543R. doi:10.1007/s11084-012-9297-y. PMID 23054553. S2CID 8267553 – via Research Gate.
  46. ^ Haraway, Donna Jeanne (2016). Staying with the trouble : making kin in the Chthulucene. Internet Archive. Durham : Duke University Press. p. 58. ISBN 978-0-8223-6214-2.

Further reading

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