Higher Dimensional Algebra: Structures and Biodynamics

Higher Dimensional Algebra: Structures and Biodynamics

Higher Dimensional Algebra of Super-Molecular Structures and Biodynamics.


/: SYNPOSIS An international collaboration proposal is made for- and on behalf of- a group with the topic of “Higher Dimensional AlgebraPlanetmathPlanetmath of Super-Molecular StructureMathworldPlanetmath and Biodynamics”, with the aim of stimulating the development of both algebraic and computational, novel approaches to modeling Super-Molecular Structures and Biodynamics in Complex Systems Biology.

Based on our recent international collaborations in the fields of Relational Biology, Category TheoryMathworldPlanetmathPlanetmathPlanetmathPlanetmath and Algebraic Topology applications to modeling complex and super-complex systemsPlanetmathPlanetmathPlanetmath we expect the proposed projrect to attain its goal of formulating fundamental, new conceptsMathworldPlanetmath with a wide range of applications in both basic and applied sciences, such as Categorical Ontology, Mathematical Biology, Molecular Biology, Bioinformatics, Interactomics, Translational Oncogenomics, Pharmacogenomics and Therapeutical Medicine.

Specific areas of expertise already covered in the project are: Non-AbelianMathworldPlanetmathPlanetmath Algebraic Topology of Biosystems, Categorical Ontology of Super-complex Systems and Advanced Ontology Levels Theory, Topological GroupoidsPlanetmathPlanetmathPlanetmathPlanetmath, Biogroupoids, SupercategoriesPlanetmathPlanetmath and Organismal Structures, Network Biodynamics, Multi-valued Logic AlgebrasMathworldPlanetmathPlanetmath of Neural and Genetic Networks, Categorical Galois Theory and Galois GroupoidsPlanetmathPlanetmathPlanetmath, Lie algebras and Lie Algebroids, Hopf, Grassmann-Hopf, Weak C*-Hopf and Graded Lie algebras, Lie and Weak C*-Hopf algebroids, Quantum GroupoidPlanetmathPlanetmathPlanetmath C*-algebras, Fundamental GroupoidsMathworldPlanetmathPlanetmathPlanetmath, Non-commutative GeometryPlanetmathPlanetmathPlanetmath, Tensor ProductsPlanetmathPlanetmath of Algebroids and CategoriesMathworldPlanetmath, Double GroupoidsPlanetmathPlanetmathPlanetmath and Algebroids, Higher Dimensional Quantum Symmetries, Applications of Generalized van Kampen TheoremMathworldPlanetmath (GvKT) to studying Phase Space transformationPlanetmathPlanetmath invariants.

1991 Mathematics Subject Classification:
Mathematics Classification: Primary 05C38,22A22, 22D25, 43A25, 43A35, 46L87, 15A15; Secondary 05A15, 15A18

File: ATBiol-ICBetaproposal.tex

February 9, 2018 –July 2, 2008

I. C. Baianu

I. C. Baianu]ibaianu@uiuc.edu

AMS MSC: 55U35 (Algebraic topology :: Applied homological algebra and category theory :: Abstract and axiomatic homotopy theory) 55U40 (Algebraic topology :: Applied homological algebra and category theory :: Topological categories, foundations of homotopy theory) 55U99 (Algebraic topology :: Applied homological algebra and category theory :: Miscellaneous) 18A15 (Category theory; homological algebra :: General theory of categories and functorsMathworldPlanetmath :: Foundations, relationsMathworldPlanetmathPlanetmathPlanetmath to logic and deductive systems) 18A20 (Category theory; homological algebra :: General theory of categories and functors :: EpimorphismsMathworldPlanetmathPlanetmathPlanetmathPlanetmathPlanetmathPlanetmathPlanetmathPlanetmath, monomorphismsMathworldPlanetmath, special classes of morphisms, null morphisms) 18A25 (Category theory; homological algebra :: General theory of categories and functors :: Functor categoriesPlanetmathPlanetmath, comma categories) 18A30 (Category theory; homological algebra :: General theory of categories and functors :: Limits and colimitsMathworldPlanetmath ) 18A40 (Category theory; homological algebra :: General theory of categories and functors :: Adjoint functorsMathworldPlanetmathPlanetmathPlanetmath ) 18A99 (Category theory; homological algebra :: General theory of categories and functors :: Miscellaneous) 18C10 (Category theory; homological algebra :: Categories and theories :: Theories , structure, and semantics) 18C99 (Category theory; homological algebra :: Categories and theories :: Miscellaneous) 18D05 (Category theory; homological algebra :: Categories with structure :: Double categoriesPlanetmathPlanetmath, 2-categories, bicategories and generalizationsPlanetmathPlanetmath) 18D15 (Category theory; homological algebra :: Categories with structure :: Closed categories ) 18D20 (Category theory; homological algebra :: Categories with structure :: Enriched categories ) 18D25 (Category theory; homological algebra :: Categories with structure :: Strong functors, strong adjunctions) 18D99 (Category theory; homological algebra :: Categories with structure :: Miscellaneous)

1. Description.

Organismic supercategoriesPlanetmathPlanetmath have flexible, algebraic and topological structures that transform naturally under heteromorphisms or heterofunctors. Different approaches to Relational Biology and Biodynamics, developed by Nicolas Rashevsky, Robert Rosen and by the author, were previously compared with the classical approach to qualitative dynamics of systems. Natural transformations of heterofunctors in organismic supercategories lead to specific modular models of a wide range of life processes involving quantum dynamics in genetic systems, ontogenetic development, fertilization, regeneration, neoplasia and oncogenesis. Axiomatic definitions of categories and supercategories of Complex Biological Systems allow for dynamic computations of cell transformations that may lead to neoplasia, and in certain intriguing cases to malignancy. The concepts of quantum automata and quantum computation are applied in the context of quantum genetics and genetic networks to study their nonlinear dynamics. In a previous publication (Baianu,1971a) the formal concept of quantum automatonPlanetmathPlanetmath was introduced and its possible implicationsMathworldPlanetmath for genetic and metabolic activities in living cells and organisms were considered. This was followed by a report on quantum and abstract, symbolic computationMathworldPlanetmath based on the theory of categories, functors and natural transformations (Baianu,1971b). The notions of topological semigroup, quantum automaton,or quantum computer, were then suggested with a view to their potential applications to the analogous simulation of biological systems, and especially genetic activities and nonlinear dynamics in genetic networks. Further, detailed studies of nonlinear dynamics in genetic networks were carried out in categories of n-valued, Lukasiewicz Logic Algebras that showed significant dissimilarities (Baianu, 1977; Baianu et al., 2006-2008) from the oversimplified Boolean models of human neural networks.A categorical and Topos framework for Łukasiewicz Algebraic Logic models of nonlinear dynamics in complex functionalPlanetmathPlanetmathPlanetmathPlanetmath genomes and cell interactomes is proposed. Łukasiewicz Algebraic Logic models of genetic networks and signaling pathways in cells are formulated in terms of nonlinear dynamic systems with n-state components that allow for the generalization of previous logical models of both genetic activities and neural networks. An algebraic formulation of variablenext-state functions’ is extended to a Lukasiewicz Topos endowed with a many-valued Łukasiewicz Algebraic Logic subobject classifier description that represents non-random and nonlinear network activities as well as their transformations in developmental processes and carcinogenesis. Novel results and specific applications concerning cell interactomics, dynamics of genetic-proteomic networks and signaling pathways, development, regeneration, the control mechanisms of cell dynamic programming in cells, neoplastic transformations and oncogenesis are then derived on the basis of complex system modeling and biomolecular network representations in categories of Łukasiewicz Logic Algebras and Łukasiewicz-Topos. Molecular models in terms of categories, functors and natural transformations were then formulated for unimolecular chemical transformations, as well as multi-molecular chemical and biochemical transformations (Baianu, 1983,2004a). Previous applications of computer modeling, classical automata theory, and relational biology to molecular biology, oncogenesis and medicine were extensively reviewed (Baianu,1987). Novel approaches to solving the realization problems of Relational Biology models in Complex System Biology are introduced in terms of natural transformations between functors of such biomolecular supercategories. Natural transformations of organismic superstructure were developed for modelling protein biosynthesis, embryogenesis and nuclear transplant experiments. Other possible realizations in Molecular Biology and Relational Biology of Organisms are here suggested as a novel approach to Bioinformatics to Interactomics and Relational Quantum Genetics.

2. Fundamental Concepts, Definitions and Examples.

Definition 2.1.

Supercategories are defined axiomatically in terms of ETAS ([2])- a natural extensionPlanetmathPlanetmathPlanetmath of Lawvere’s Elementary Theory of Abstract Categories (ETAC) to non-Abelian structures and hetero-functors (or ‘heterofunctors’). This provides a unified conceptual framework for Relational Biology that utilizes flexible, algebraic and topological structures which transform naturally under heteromorphisms or heterofunctors. One of the advantages of the ETAS axiomatic approach, which was inspired by the work of Lawvere ([21], [22]), is that ETAS avoids all the antimonies/paradoxesMathworldPlanetmath previously reported for sets, sets of sets, involving for example the elementhood relation or infinite setsMathworldPlanetmath, the axiom of choiceMathworldPlanetmath, and so on (Russell and Whitehead, 1925, and Russell, 1937; [6]). ETAS also provides an axiomatic approach to recent Higher Dimensional Algebra ([17], [18]) applications to Complex Systems Biology ([16], [6], and references cited therein).

Definition 2.2.

ETAC Axioms, [22]:

0. For any letters x,y,u,A,B, and unary function symbols Δ0 and Δ1, and composition law Γ, the following are defined as formulasMathworldPlanetmathPlanetmath: Δ0(x)=A, Δ1(x)=B, Γ(x,y;u), and x=y; These formulas are to be, respectively, interpreted as “A is the domain of x”, “B is the codomain, or range, of x”, “u is the composition x followed by y”, and “x equals y”.

1. If Φ and Ψ are formulas, then “[Φ] and [Ψ]” , “[Φ] or[Ψ]”, “[Φ][Ψ]”, and “[notΦ]” are also formulas.

2. If Φ is a formula and x is a letter, then “x[Φ]”, “x[Φ]” are also formulas.

3. A string of symbols is a formula in ETAC iff it follows from the above axioms 0 to 2.

A sentenceMathworldPlanetmath is then defined as any formula in which every occurrence of each letter x is within the scope of a quantifierMathworldPlanetmath, such as x or x. The theorems of ETAC are defined as all those sentences which can be derived through logical inference from the following ETAC axioms:

4. Δi(Δj(x))=Δj(x) for i,j=0,1.

5a. Γ(x,y;u) and Γ(x,y;u)u=u.

5b. u[Γ(x,y;u)]Δ1(x)=Δ0(y);

5c. Γ(x,y;u)Δ0(u)=Δ0(x) and Δ1(u)=Δ1(y).

6. IdentityPlanetmathPlanetmathPlanetmathPlanetmath axiom: Γ(Δ0(x),x;x) and Γ(x,Δ1(x);x) yield always the same result.

7. Associativity axiom: Γ(x,y;u) and Γ(y,z;w) and Γ(x,w;f) and Γ(u,z;g)f=g. With these axioms in mind, one can see that commutative diagramsMathworldPlanetmath can be now regarded as certain abbreviated formulas corresponding to systems of equations such as: Δ0(f)=Δ0(h)=A, Δ1(f)=Δ0(g)=B, Δ1(g)=Δ1(h)=C and Γ(f,g;h), instead of gf=h for the arrows f, g, and h, drawn respectively between the ‘objects’ A, B and C, thus forming a ‘triangular commutative diagram‘ in the usual sense of category theory. Compared with the ETAC formulas such diagrams have the advantage of a geometric–intuitive image of their equivalentMathworldPlanetmathPlanetmathPlanetmathPlanetmathPlanetmath underlying equations. The common property of A of being an object is written in shorthand as the abbreviated formula Obj(A) standing for the following three equations:

8a. A=Δ0(A)=Δ1(A),

8b. x[A=Δ0(x)]y[A=Δ1(y)],


8c. xu[Γ(x,A;u)x=u] and yv[Γ(A,y;v)]y=v .

Intuitively, with this terminology and axioms a category is meant to be any structure which is a direct interpretationMathworldPlanetmath of ETAC. A functor is then understood to be a triple consisting of two such categories and of a rule F (‘the functor’) which assigns to each arrow or morphism x of the first category, a unique morphism, written as ‘F(x)’ of the second category, in such a way that the usual two conditions on both objects and arrows in the standard functor definition are fulfilled (see for example [1])– the functor is well behaved, it carries object identities to image object identities, and commutative diagrams to image commmutative diagrams of the corresponding image objects and image morphisms. At the next level, one then defines natural transformations or functorial morphisms between functors as metalevel abbreviated formulas and equations pertaining to commutative diagrams of the distinct images of two functors acting on both objects and morphisms. As the name indicates natural transformations are also well–behaved in terms of the ETAC equations satisfied.

Definition 2.3.

Supercategories: In the usual sense, super-categories are defined as categories of categories, and the process is repeated in higher dimensionsMathworldPlanetmath in n-categories. There is however a ‘more geometric’, or ‘gluing’ construction of double categories, double groupoids ([20], and double algebroids [19]) that involves additional conditions or axioms leading to non-Abelian higher dimensional structures and Higher Dimensional Algebra (HDA;[20],[19] and [18]). Similarly, the construction of supercategories ([2]), unlike that of n-categories, allows for ‘gluing’ together distinct structures and/or their corresponding diagrams (such as algebraic and topological ones), through hetero-morphisms or hetero-functors, which are arrows (not necessarily subject to all of the ETAC axioms) linking distinct structures into the superstructure called a ‘supercategory’; the latter is a generalized type of double groupoid, double category, 2-category,…, n-category or super–category/meta–category, that always involves only diagrams of homo-morphisms at each level, but also includes hetero-morphisms or hetero-functors, and so on, between different types of structures. Proper supercategories could also be called ‘n-ary’ super-categories, or multi-categories, in the sense of extending double groupoid, double algebroid and double category structures to higher dimensions. Note however that even in a general, abstract supercategory at the level of diagrams of homo-morphisms, homo-functors, natural transformations, or any n-categories with only one type of arrows at each level, all the ETAC axioms still hold. On the other hand, at the levels of supercategorical diagrams, or superdiagrams, involving several types of morphisms, or hetero-morphisms and hetero-functors, several of the rules for connecting diagrams are weakened, and the result is a superstructure which does not have all naturality conditions satisfied by all arrows, and one has additional composition laws, such as Γ,Γ′′,, and so on, satisfying new ETAS axioms that are not allowed in ETAC. Thus, additional ETAS axioms are needed to also specify how such distinct composition laws are combined within the same superstructure. Any interpretation of ETAS axioms (that may include also the ETAC axioms for the special cases of categories, n-categories, double categories, etc) then defines a supercategory.

An Example of ETAS Axioms ([2]):
a. The eight ETAC axioms introduced by W. F. Lawvere for same type morphisms, functors, natural transformations and other arrows in higher dimensions.
b. A family of composition laws {Γi}, with i=1,2,,n, and each Γi being subject to ETAC axioms 5 to 7;
c. The composition law conditions in the ETAC axioms 8a to 8c will apply only to (small) subclasses of homo-morphisms and homo-functors (but will not apply to hetero-morphisms and hetero-functors);
d. Hetero-morphism and hetero-functor axioms specifying how two composition laws interact, involving also objects with different structure or type.

Definition 2.4.

: Organismic Supercategory ([1],[2] and [3]. An example of a supercategory interpreting such ETAS axioms as those stated above was previously defined for organismic structures with different levels of complexity ([2]); an organismic supercategory was thus defined as a superstructure interpretation of ETAS (including ETAC, as appropriate) in terms of triples 𝐊=(C,Π,𝑁), where C is an arbitrary category (interpretation of ETAC axioms, formulas, etc.), Π is a category of completePlanetmathPlanetmathPlanetmathPlanetmathPlanetmath self–reproducing entities, π, ([23]) subject to the negationMathworldPlanetmath of the axiom of restrictionPlanetmathPlanetmathPlanetmath (for elements of sets): S:(S)andu:[uS)v:(vu)and(vS)], (which is known to be independent from the ordinary logico-mathematical and biological reasoning), and N is a category of non-atomic expressions, defined as follows. An atomically self–reproducing entity is a unit class relation u such that πππ, which means “π stands in the relation π to π”, πππ,π, etc. An expression that does not contain any such atomically self–reproducing entity is called a non-atomic expression.

Definition 2.5.

. An Example of Supercategories was recently introduced in Mathematical (or more specifically ‘Categorified’) Physics, on the web’s n-Category cafe’ s site under “Supercategories”, at the http-URL: golem.ph.utexas.edu/category/2007/07/supercategories.html. This is a rather ‘simple’ example of supercategories, albeit in a much more restricted sense as it still involves only the standard categorical homo-morphisms, homo-functors, and so on; it begins with a somewhat standard definiton of super-categories, or ‘super categories’ from Category Theory, but then it becomes more interesting as it is being tailored to supersymmetry and extensions of ‘Lie’ superalgebras, or superalgebroids, which are sometimes called graded ‘Lie’ algebras (but not really Lie algebras) that are thought to be relevant to Quantum Gravity ([18] and references cited therein). The following is an almost exact quote from the above n-Category cafe’ s website posted mainly by Urs: A super category is a diagram of the form:
IdC𝐂s in Cat–the category of categories and (homo-) functors between categories– such that: 𝐼𝑑IdC𝐂𝐂ss=IdCIdC𝐼𝑑,
(where the ‘diamond’ symbol should be replaced by the symbol ‘square’, as in the original Urs’s postings.)

(This specific instance is that of a supercategory which has only one object– the above quoted superdiagram of diamonds, an arbitrary abstract category C (subject to all ETAC axioms), and the standard category identity (homo-) functor; it can be further specialized to the previously introduced concepts of supergroupoids (also definable as crossed complexes of groupoids), and supergroups (also definable as crossed modules of groups), which seem to be of great interest to mathematicians involved in ‘Categorified’ Mathematical Physics or Physical Mathematics.) This was then continued with the following interesting example. “What, in this sense, is a braided monoidal supercategory ?”. Urs, suggested the following answer: like an ordinary braided monoidal catgeory is a 3-category which in lowest degrees looks like the trivial 2-group, a braided monoidal supercategory is a 3-category which in lowest degree looks like the strict 2-group that comes from the crossed module G(2)=(2𝐼𝑑2). Urs called this generalization of stabilization of n-categories, G(2)-stabilization. So the claim would be that braided monoidal supercategories come from G(2)-stabilized 3-categories, with G(2) the above strict 2-group.

3. Relevant Websites and URLs:

http://www.kli.ac.at/theorylab/Keyword/R/RelationalBio.html http://cogprints.org/3674/ http://www.informatics.bangor.ac.uk/public/mathematics/research/preprints/07/cathom07.html http://documents.cern.ch/cgi-bin/setlink?base=preprint-categ=ext-id=ext-2004-060 http://documents.cern.ch/cgi-bin/setlink?base=preprint-categ=ext-id=ext-2004-057 http://cogprints.ecs.soton.ac.uk/archive/00003674/ http://cogprints.ecs.soton.ac.uk/archive/00003676/ http://cogprints.ecs.soton.ac.uk/archive/00003697/ http://cdsweb.cern.ch/search.py?recid=746662-ln=en http://cogprints.ecs.soton.ac.uk/archive/00003701/ http://cdsweb.cern.ch/search.py?recid=768088-ln=en http://cogprints.org/3675/ http://cogprints.org/3697/ http://cogprints.org/3676/ http://cogprints.org/3718/ http://cogprints.org/3829/ http://fs512.fshn.uiuc.edu/ComplexSystemsBiology.htm http://bioline.utsc.utoronto.ca/archive/00001979/04/compauto.pdf http://biblioteca.universia.net/html-bura/ficha/params/id/3920559.html

4. Proposed Starting Date of Project:

August 2008

5. Proposed Ending Date of Project:

September 2015


  • 1 I.C.Baianu and M. Marinescu: 1968, Organismic Supercategories: Towards a UnitaryMathworldPlanetmathPlanetmath Theory of Systems. Bulletin of Mathematical Biophysics 30, 148-159.
  • 2 I.C. Baianu: 1970, Organismic Supercategories: II. On Multistable Systems. Bulletin of Mathematical Biophysics, 32: 539-561.
  • 3 I.C. Baianu : 1971a, Organismic Supercategories and Qualitative Dynamics of Systems. Ibid., 33 (3), 339–354.
  • 4 I.C. Baianu: 1971b, Categories, Functors and Quantum Algebraic Computations, in P. Suppes (ed.), Proceed. Fourth Intl. Congress Logic-Mathematics-Philosophy of Science, September 1–4, 1971, University of Bucharest.
  • 5 I.C. Baianu: Łukasiewicz-Topos Models of Neural Networks, Cell Genome and Interactome Nonlinear Dynamics). CERN Preprint EXT-2004-059. Health Physics and Radiation Effects (June 29, 2004).
  • 6 I.C. Baianu, Brown R., J. F. Glazebrook, and Georgescu G.: 2006, Complex Nonlinear Biodynamics in Categories, Higher Dimensional Algebra and Łukasiewicz–Moisil Topos: Transformations of Neuronal, Genetic and Neoplastic networks, Axiomathes 16 Nos. 1–2, 65–122.
  • 7 I.C. Baianu and D. Scripcariu: 1973, On Adjoint Dynamical Systems. The Bulletin of Mathematical Biophysics, 35(4), 475–486.
  • 8 I.C. Baianu: 1973, Some Algebraic Properties of (M,R)- Systems. Bulletin of Mathematical Biophysics 35, 213-217.
  • 9 I.C. Baianu and M. Marinescu: 1974, A Functorial Construction of (M,R)– Systems. Revue Roumaine de Mathematiques Pures et Appliquees 19: 388-391.
  • 10 I.C. Baianu: 1977, A Logical Model of Genetic Activities in Łukasiewicz Algebras: The Non-linear Theory. Bulletin of Mathematical Biophysics, 39: 249-258.
  • 11 I.C. Baianu: 1980, Natural Transformations of Organismic Structures. Bulletin of Mathematical Biophysics 42: 431-446.
  • 12 I.C. Baianu: 1983, Natural Transformation Models in Molecular Biology., in Proceedings of the SIAM Natl. Meet., Denver, CO.; Eprint: http://cogprints.org/3675/0l/Naturaltransfmolbionu6.pdf.
  • 13 I.C. Baianu: 1984, A Molecular-Set-Variable Model of Structural and Regulatory Activities in Metabolic and Genetic Networks., FASEB Proceedings 43, 917.
  • 14 I.C. Baianu: 1987a, Computer Models and Automata Theory in Biology and Medicine., in M. Witten (ed.), Mathematical Models in Medicine, vol. 7., Pergamon Press, New York, 1513-1577; CERN Preprint No. EXT-2004-072: http://doe.cern.ch//archive/electronic/other/ext/ext-2004-072.pdf.
  • 15 I.C. Baianu: 1987b, Molecular Models of Genetic and Organismic Structures, in Proceed. Relational Biology Symp. Argentina; CERN Preprint No.EXT-2004-067: http://doc.cern.ch/archive/electronic/other/ext/ext2004 67/MolecularModels-ICB3.doc.
  • 16 I.C. Baianu, Glazebrook, J. F. and G. Georgescu: 2004, Categories of Quantum Automata and N-Valued Łukasiewicz Algebras in Relation to Dynamic Bionetworks, (M,R)–Systems and Their Higher Dimensional Algebra, Abstract and Preprint of Report: http://www.ag.uiuc.edu/fs401/QAuto.pdf , and http:www.medicalupapers.com/quantum+automata+math+categories+baianu/
  • 17 R. Brown R, P.J. Higgins, and R. Sivera.: “Non–AbelianMathworldPlanetmath Algebraic Topology”, . http://www. bangor.ac.uk/mas010/nonab–a–t.html; http://www.bangor.ac.uk/mas010/nonab–t/partI010604.pdf (in preparation). (2008)
  • 18 R. Brown, J. F. Glazebrook and I. C. Baianu: A categorical and higher dimensional algebra framework for complex systems and spacetime structures, Axiomathes 17:409–493. (2007).
  • 19 R. Brown and G. H. Mosa: Double algebroids and crossed modules of algebroids, University of Wales–Bangor, Maths Preprint, 1986.
  • 20 R. Brown and C.B. Spencer: Double groupoids and crossed modules, Cahiers Top. Géom.Diff. 17 (1976), 343-362.
  • 21 F. W. Lawvere: 1963. Functorial Semantics of Algebraic Theories. Proc. Natl. Acad. Sci. USA, 50: 869–872
  • 22 F. WLawvere: 1966. The Category of Categories as a Foundation for Mathematics. , In Proc. Conf. Categorical Algebra–L Jolla, 1965, Eilenberg, S et al., eds. Springer –Verlag: Berlin, Heidelberg and New York, pp. 1–20.
  • 23 L. Lo¨fgren: 1968. On Axiomatic Explanation of Complete Self–Reproduction. Bull. Math. Biophysics, 30: 317–348.
Title Higher Dimensional Algebra: Structures and Biodynamics
Canonical name HigherDimensionalAlgebraStructuresAndBiodynamics
Date of creation 2013-03-11 19:52:03
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