Genes, Brains, and Human Potential The Science and Ideology of Intelligence

358 5. INTELLIGENT DEVELOPMENT

10. O. S. Soyer and T. Pfeiff er, “Evolution Under Fluctuating Environments Explains
    Observed Robustness in Metabolic Networks,” PLoS Computational Biology 6 (Au-
    gust 2010): e1000907, doi: 10.1371/journal.pcbi.1000907.


11. S. A. Kelly, T. M. Panhuis, and A. M. Stoehr, “Phenotypic Plasticity: Molecular Mecha-
    nisms and Adaptive Signifi cance,” Comprehensive Physiology 2 (April 2012): 1416–1439.


12. G. Gottlieb, “Experiential Canalization of Behavioral Development: Th eory,” Develop-
    mental Psy chol ogy 27 (1991): 4–13, 9.


13. See contributions in A. Love (ed.), Conceptual Change in Science: Scientifi c and Phil-
    osophical Papers on Evolution and Development (New York: Springer, 2015).


14. R. Lickliter, “Th e Origins of Variation: Evolutionary Insights from Developmental
    Science,” in Embodiment and Epigenesis: Th eoretical and Methodological Issues in
    Understanding the Role of Biology Within the Relational Developmental System, ed.
    R. Lerner and J. Benson (London: Academic Press, 2014), 173–203, 193.


15. M.- W. Ho, “Development and Evolution Revisited,” in Handbook of Developmental
    Science, Be hav ior and Ge ne tics, ed. K. Hood et al. (New York: Blackwell, 2009), 61–109.


16. See the EuroStemCell website: “iPS Cells and Reprogramming: Turn Any Cell of
    the Body into a Stem Cell,” eurostemcell. org (last updated September 29, 2015).


17. S. Rose, Lifelines: Life Beyond the Gene (New York: Oxford University Press, 2003), 17.


18. M. Joëls and T. Z. Baram, “Th e Neuro- Symphony of Stress,” Nature Reviews: Neuro-
    science 10 (June 2009): 459–466, 459.


19. M. J. Wijnants, (2014). “Presence of 1/f Scaling in Coordinated Physiological and
    Cognitive Pro cesses,” Journal of Nonlinear Dynamics 2014 (February 2014): article
    962043, http:// dx. doi. org / 10. 1155 / 2014 / 962043.


20. B. J. West, “Fractal Physiology and the Fractional Calculus: A Perspective,” Frontiers
    in Physiology 1: Fractal Physiology 1 (October 2010): article 12.


21. A. L. Goldberger, L. A. N. Amaral, J. M. Hausdorff , P. Ch. Ivanov, C.- K. Peng, et al.,
    “Fractal Dynamics in Physiology: Alterations with Disease and Aging,” Proceedings
    of the National Acad emy of Sciences, USA 99 (suppl. 1, February 2002): 2466–2472,
    2471.


22. C. Darwin, Th e Power of Movement in Plants (London: John Murray, 1880), 572. Th anks
    to Keith Baverstock, personal communication, February 14, 2015, for this quote.


23. R. Karban, Plant Sensing and Communication (Chicago: University of Chicago
    Press, 2015), 1; A. Barnett, “Intelligent Life: Why Don’t We Consider Plants to Be
    Smart?” New Scientist, May 2015, 30.


24. A. M. Johnstone, S. D. Murison, J. S. Duncan, K. A. Rance, and J. R. Speakman,
    “ Factors Infl uencing Variation in Basal Metabolic Rate Include Fat- Free Mass, Fat
    Mass, Age, and Circulating Th yroxine but Not Sex, Circulating Leptin, or Triiodo-
    thyronine,” American Journal of Clinical Nutrition 82 (November 2005): 941–948.


25. A. M. Johnstone et al., “ Factors Infl uencing Variation in Basal Metabolic Rate.”


26. For example, Z. Boratynski, E. Koskela, T. Mappes, and E. Schroderus, “Quantitative
    Ge ne tics and Fitness Eff ects of Basal Metabolism,” Evolutionary Ecol ogy 27 (March 2013):
    301–314.

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