Biological hypercomputation: A new research problem in complexity theory

Maldonado, Carlos Eduardo; Cruz, Nelson Alfonso Gómez

doi:10.1002/cplx.21535

Cited by 25 publications

(20 citation statements)

References 73 publications

(53 reference statements)

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“…These include applications to pharmacology, environmental pollution monitoring, and food industry. In particular, biological systems are often characterized by complex chemical pathways whose modeling is rather challenging and can not be recast in standard schemes [3][4][5][6][7][8][9][10][11][12][13][14][15] (see also [16][17][18][19] for a different perspective). In general, one tries to split such sophisticated systems into a set of elementary constituents, in mutual interaction, and for which a clear formalization is available [20][21][22][23][24][25].…”

Section: The Chemical Kineticsmentioning

confidence: 99%

“…Regarding the former, the complex picture of yeast's enzymes evidenced by Koshland [32,53], where positive and negative cooperativity appear simultaneously (and with the anticooperativity effect getting more and more pronounced as the substrate concentration is raised), still escapes from this mathematical architecture. Further, from the mechanical point of view, two weird things happen: the velocity is bounded by = 1, while in Classical Mechanics the velocity may diverge; further, if we look at the Boltzmann factor in the free energy (see (12)), this reads as exp[ (− 2 /2 + )] and, recalling that the kinetic energy in this mechanical analogy reads as 2 /2 (the mass is unitary, thus velocity and momentum coincide), we are allowed to interpret ( , , ℎ) as a real action. From this perspective, the exponent can be thought of as the coupling between the stress-energy tensor and the metric tensor: a glance at the form of the Boltzmann factor reveals that the natural underlying metric is (−1, +1) rather than (+1, +1) as in classical Euclidean frames, or in other words, it is of the Minkowskian type.…”

Section: Chemical Properties Of the Physical Solutionmentioning

confidence: 99%

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Complex Reaction Kinetics in Chemistry: A Unified Picture Suggested by Mechanics in Physics

et al. 2018

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Complex biochemical pathways can be reduced to chains of elementary reactions, which can be described in terms of chemical kinetics. Among the elementary reactions so far extensively investigated, we recall the Michaelis-Menten and the Hill positivecooperative kinetics, which apply to molecular binding and are characterized by the absence and the presence, respectively, of cooperative interactions between binding sites. However, there is evidence of reactions displaying a more complex pattern: these follow the positive-cooperative scenario at small substrate concentration, yet negative-cooperative effects emerge as the substrate concentration is increased. Here, we analyze the formal analogy between the mathematical backbone of (classical) reaction kinetics in Chemistry and that of (classical) mechanics in Physics. We first show that standard cooperative kinetics can be framed in terms of classical mechanics, where the emerging phenomenology can be obtained by applying the principle of least action of classical mechanics. Further, since the saturation function plays in Chemistry the same role played by velocity in Physics, we show that a relativistic scaffold naturally accounts for the kinetics of the above-mentioned complex reactions. The proposed formalism yields to a unique, consistent picture for cooperative-like reactions and to a stronger mathematical control.

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Section: The Chemical Kineticsmentioning

confidence: 99%

Section: Chemical Properties Of the Physical Solutionmentioning

confidence: 99%

Complex Reaction Kinetics in Chemistry: A Unified Picture Suggested by Mechanics in Physics

et al. 2018

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“…More recently, Maldonado [21,22] has offered a defense of a form of biological hypercomputation, claiming that: "[...] life is not a standard Turing Machine, but rather that living systems hypercompute, and that an understanding of life is reached not by grasping what life is but what it does.…”

Section: The Uninstantiation Of Hypercomputationmentioning

confidence: 99%

“…Perhaps the most puzzling aspect of the arguments of a group of researchers looking for new notions or types of computation is that while openly accepting that (natural) computing is about information processing (as is classical computation) [6], and also that nature certainly computes (because computers exist in and within nature), they posit a different kind of computation than the classical one [22] while using nature as evidence for non-Turing computation. At the same time none of them specifies exactly what makes this kind of computation distinctive, beyond stressing its difference from a Turing machine (or a trivial modification of a Turing machine, e.g., a nonterminating one, such as a cellular automaton, which can hardly be classified as non-classical).…”

Section: Natural Computationmentioning

confidence: 99%

Is there any Real Substance to the Claims for a ‘New Computationalism’?

Hernández-Espinosa

Hernández-Quiroz

Zenil

2017

Unveiling Dynamics and Complexity

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Computationalism is a relatively vague term used to describe attempts to apply Turing's model of computation to phenomena outside its original purview: in modelling the human mind, in physics, mathematics, etc. Early versions of computationalism faced strong objections from many (and varied) quarters, from philosophers to practitioners of the aforementioned disciplines. Here we will not address the fundamental question of whether computational models are appropriate for describing some or all of the wide range of processes that they have been applied to, but will focus instead on whether 'renovated' versions of the new computationalism shed any new light on or resolve previous tensions between proponents and skeptics. We find this, however, not to be the case, because the new computationalism falls short by using limited versions of "traditional computation", or proposing computational models that easily fall within the scope of Turing's original model, or else proffering versions of hypercomputation with its many pitfalls.

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“…The kind of processing of information by living beings has been named biological hyper computation [3]. This short essay aims at explaining how the processing of information occurs among the plants.…”

Section: Introductionmentioning

confidence: 99%

A Step toward Understanding Information Processing in Plants. Explaining the Complexity of Life Thanks to Plants Physiology

Maldonado¹

2015

Cell Dev Biol

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This article argues that the complexity of life can be largely understood and explained by a somewhat "minor" field in biology, namely botany. The complexity of the plant's cell as well as the modularity of the organization of plants serves as conditions to the explanation of life on earth. Plants process information in a quite different way than animals, and the plant's anatomy and physiology are to be taken as the rationale for life on Earth.

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Biological hypercomputation: A new research problem in complexity theory

Cited by 25 publications

References 73 publications

Complex Reaction Kinetics in Chemistry: A Unified Picture Suggested by Mechanics in Physics

Complex Reaction Kinetics in Chemistry: A Unified Picture Suggested by Mechanics in Physics

Is there any Real Substance to the Claims for a ‘New Computationalism’?

A Step toward Understanding Information Processing in Plants. Explaining the Complexity of Life Thanks to Plants Physiology

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