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10. Grabe, N., Neuber, K.: A multicellular systems biology model predicts epidermal morphol-
ogy, kinetics and ca2+ flow. Bioinformatics 21(17), 3541-3547 (2005)
11. Guo, K., Shillcock, J., Lipowsky, R.: Self-assembly of actin monomers into long filaments:
Brownian dynamics simulations. J. Chem. Phys. 131(1), 015102 (2009)
12. Holcombe, M.: X-machines as a basis for dynamic system specification. Softw. Eng. J. 3(2),
69-76 (1988),
http://portal.acm.org/citation.cfm?id=48328
13. Kiran, M., Coakley, S., Walkinshaw, N., McMinn, P., Holcombe, M.: Validation and discov-
ery from computational biology models. Biosystems 93(1-2), 141-150 (2008)
14. Matschegewski, C., Staehlke, S., Loeffler, R., Lange, R., Chai, F., Kern, D.P., Beck, U., Nebe,
B.J.: Cell architecture-cell function dependencies on titanium arrays with regular geometry.
Biomaterials 31(22), 5729-5740 (2010)
15. Merelli, E., Armano, G., Cannata, N., Corradini, F., d'Inverno, M., Doms, A., Lord, P., Mar-
tin, A., Milanesi, L., Muller, S., Schroeder, M., Luck, M.: Agents in bioinformatics, compu-
tational and systems biology. Brief. Bioinform. 8(1), 45-59 (2007)
16. Mogilner, A., Edelstein-Keshet, L.: Regulation of actin dynamics in rapidly moving cells: a
quantitative analysis. Biophys. J. 83(3), 1237-1258 (2002)
17. Nebe, J.G.B., Luethen, F., Lange, R., Beck, U.: Interface interactions of osteoblasts with
structured titanium and the correlation between physicochemical characteristics and cell bi-
ological parameters. Macromol. Biosci. 7(5), 567-578 (2007)
18. Oda, T., Iwasa, M., Aihara, T., Maeda, Y., Narita, A.: The nature of the globular- to fibrous-
actin transition. Nature 457(7228), 441-445 (2009)
19. Pantaloni, D., Clainche, C.L., Carlier, M.F.: Mechanism of actin-based motility. Sci-
ence 292(5521), 1502-1506 (2001)
20. Pelham, R.J., Chang, F.: Actin dynamics in the contractile ring during cytokinesis in fission
yeast. Nature 419(6902), 82-86 (2002)
21. Pogson, M., Holcombe, M., Smallwood, R., Qwarnstrom, E.: Introducing spatial information
into predictive nf-kappab modelling-an agent-based approach. PLoS One 3(6), e2367 (2008)
22. Pogson, M., Smallwood, R., Qwarnstrom, E., Holcombe, M.: Formal agent-based modelling
of intracellular chemical interactions. Biosystems 85(1), 37-45 (2006)
23. Pollard, T.D., Cooper, J.A.: Actin and actin-binding proteins. A critical evaluation of mech-
anisms and functions. Annu. Rev. Biochem. 55, 987-1035 (1986)
24. Robinson, R.C., Turbedsky, K., Kaiser, D.A., Marchand, J.B., Higgs, H.N., Choe, S., Pollard,
T.D.: Crystal structure of arp2/3 complex. Science 294(5547), 1679-1684 (2001)
25. Stossel, T.P., Fenteany, G., Hartwig, J.H.: Cell surface actin remodeling. J. Cell Sci. 119(Pt.
16), 3261-3264 (2006)
26. Sun, T., Adra, S., Smallwood, R., Holcombe, M., MacNeil, S.: Exploring hypotheses of the
actions of tgf-beta1 in epidermal wound healing using a 3d computational multiscale model
of the human epidermis. PLoS One 4(12), e8515 (2009)
27. S utterlin, T., Huber, S., Dickhaus, H., Grabe, N.: Modeling multi-cellular behavior in epi-
dermal tissue homeostasis via finite state machines in multi-agent systems. Bioinformat-
ics 25(16), 2057-2063 (2009)
28. Thorne, B.C., Bailey, A.M., Peirce, S.M.: Combining experiments with multi-cell agent-
based modeling to study biological tissue patterning. Brief. Bioinform. 8(4), 245-257 (2007)
29. Troisi, A., Wong, V., Ratner, M.A.: An agent-based approach for modeling molecular self-
organization. Proc. Natl. Acad. Sci. USA 102(2), 255-260 (2005)
30. Walker, D., Wood, S., Southgate, J., Holcombe, M., Smallwood, R.: An integrated agent-
mathematical model of the effect of intercellular signalling via the epidermal growth factor
receptor on cell proliferation. J. Theor. Biol. 242(3), 774-789 (2006)
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