Allen, R. (1995). Projecting Illusion: Film Spectatorship and the Impression of Reality. New York, NY: Cambridge University Press.Google Scholar

Bernstein, G. M. (1981). The Recreating Secondary Imagination in Coleridge’s “The Nightingale”. ELH, 48(2), 339–350.CrossRefGoogle Scholar

Coleridge, S. T. (1817/1969). Biographia Literaria. Volume 1. Edited by Shawcross, J. Oxford, UK: Oxford University Press.Google Scholar

Currie, G. (1990). The Nature of Fiction. Cambridge, UK: Cambridge University Press.Google Scholar

Currie, G.(1995). Image and Mind: Film, Philosophy, and Cognitive Science. Cambridge, UK: Cambridge University Press.CrossRefGoogle Scholar

Currie, G.(2003). The Capacities that Enable Us to Produce and Consume Art. In Kieran, M and Lopes, D. M. (eds.), Imagination, Philosophy, and the Arts. London, UK: Routledge, 293–304.Google Scholar

Currie, G., and Ravenscroft, I. (2002). Recreative Minds. Oxford, UK: Oxford University Press.CrossRefGoogle Scholar

Currie, G., and Ichino, A. (2013). Imagination and Make-Believe. In Gaut, B and Lopes, D. M. (eds.), The Routledge Companion to Aesthetics. 3rd edition. London, UK: Routledge, 320–330.Google Scholar

Currie, G., Kieran, M., Meskin, A., and Robson, J. (eds.) (2014). Aesthetics and the Sciences of Mind. Oxford, UK: Oxford University Press.Google Scholar

Davies, D. (2003). The Imaged, the Imagined, and the Imaginary. In Kieran, M and Lopes, D. M. (eds.), Imagination, Philosophy, and the Arts. London, UK: Routledge, 225–244.Google Scholar

Davies, D.(2007). Aesthetics and Literature. London, UK: Continuum.CrossRefGoogle Scholar

Davies, D.(2013). Dancing around the Issues: Prospects for an Empirically Grounded Philosophy of Dance. Journal of Aesthetics and Art Criticism, 71(2), 195–202.CrossRefGoogle Scholar

Davies, D.(2014). “This is your Brain on Art”: What Can Philosophy of Art Learn from Neuroscience? In Currie, G, Kieran, M, Meskin, A, and Robson, J (eds.), Aesthetics and the Sciences of Mind. Oxford, UK: Oxford University Press, 57–74.CrossRefGoogle Scholar

Davies, D.(2015). Fictive Utterance and the Fictionality of Narratives and Works. The British Journal of Aesthetics, 55(1), 39–55.CrossRefGoogle Scholar

Friend, S. (2008). Imagining Fact and Fiction. In Stock, K and Thompson-Jones, K (eds.), New Waves in Aesthetics. New York, NY: Palgrave Macmillan, 150–169.Google Scholar

Gaut, B. (2003). Creativity and Imagination. In Gaut, B and Livingston, P (eds.), The Creation of Art. Cambridge, UK: Cambridge University Press, 148–173.Google Scholar

Gendler, T. (2000). The Puzzle of Imaginative Resistance. Journal of Philosophy, 97, 55–81.Google Scholar

Gibson, J. (2007). Fiction and the Weave of Life. Oxford, UK: Oxford University Press.Google Scholar

Hamlyn, D. W. (1994). Imagination. In Guttenplan, S (ed.), A Companion to the Philosophy of Mind. Oxford, UK: Blackwell, 361–366.Google Scholar

Hume, D. (1757/1993). Of the Standard of Taste. In Copley, S and Edgar, A (eds.), Selected Essays. Oxford, UK: Oxford University Press, 133–154.Google Scholar

Johnson-Laird, P. (1983). Mental Models. Cambridge, MA: Harvard University Press.Google Scholar

Kalderon, M. (2005). Fictionalism in Metaphysics. Oxford, UK: Clarendon Press.Google Scholar

Kant, I. (1787/1929). Critique of Pure Reason. 2nd edition. Translated by Norman Kemp-Smith. London, UK: Macmillan.Google Scholar

Kant, I.(1790/1951). Critique of Judgment. Translated by J. H. Bernard. New York, NY: Haffner Press.Google Scholar

Lopes, D. M. (1998). Imagination, Illusion, and Experience in Film. Philosophical Studies, 89, 343–353.Google Scholar

Matravers, D. (2003). Fictional Assent and the (So-Called) “Puzzle of Imaginative Resistance”. In Kieran, M and Lopes, D (eds.), Imagination, Philosophy, and the Arts. London, UK: Routledge, 91–106.Google Scholar

Matravers, D. (2014). Fiction and Narrative. Oxford, UK: Oxford University Press.Google Scholar

Stock, K. (2005). Resisting Imaginative Resistance. Philosophical Quarterly, 55, 607–624.Google Scholar

Walton, K. (1990). Mimesis as Make-Believe. Cambridge, MA: Harvard University Press.Google Scholar

Walton, K. (1993). Metaphor and Prop-Oriented Make-Believe. European Journal of Philosophy, 1(1), 39–57.CrossRefGoogle Scholar

Walton, K. (1994). Morals in Fiction and Fictional Morality. Proceedings of the Aristotelian Society, supplementary volume, 68, 27–50.CrossRefGoogle Scholar

Walton, K.(2002). Depiction, Perception, and Imagination: Responses to Richard Wollheim. The Journal of Aesthetics and Art Criticism, 60(1), 27–35.Google Scholar

Warnock, M. (1976). Imagination. London, UK: Faber and Faber.CrossRefGoogle Scholar

Weatherson, B. (2004). Morality, Fiction, and Possibility. Philosophers’ Imprint 4(3), 1–27.Google Scholar

Wollheim, R. (1987). Painting as an Art. London, UK: Thames and Hudson.Google Scholar

Yablo, S. (2002). Coulda, Woulda, Shoulda. In Gendler, T and Hawthorne, J (eds.), Conceivability and Possibility. Oxford, UK: Oxford University Press, 441–492.Google Scholar

Abraham, A. (2016). The Imaginative Mind. Human Brain Mapping, 37, 4197–4211.Google Scholar

Arnheim, R. (1954/1974). Art and Visual Perception. Berkeley, CA: University of California Press.Google Scholar

Belfi, A. M., Vessel, E. A., Brielmann, A., et al. (2019). Dynamics of Aesthetic Experience Are Reflected in the Default-Mode Network. Neuroimage, 188, 584–597.Google Scholar

Berlyne, D. E. (1971). Aesthetics and Psychobiology. New York, NY: Appleton-Century-Crofts.Google Scholar

Brown, S., Gao, X., Tisdelle, L., Eickhoff, S. B., and Liotti, M. (2011). Naturalizing Aesthetics: Brain Areas for Aesthetic Appraisal across Sensory Modalities. Neuroimage, 58, 250–258.Google Scholar

Bullot, N. J., and Reber, R. (2013). A Psycho-Historical Research Program for the Integrative Science of Art. Behavioral and Brain Sciences, 36, 163–180.Google Scholar

Campbell, D. T. (1960). Blind Variation and Selective Retentions in Creative Thought as in Other Knowledge Processes. Psychological Review, 67, 380–400.Google Scholar

Cavanna, A. E. (2007). The Precuneus and Consciousness. CNS Spectrums, 12, 545–552.Google Scholar

Cavanna, A. E., and Trimble, M. R. (2006). The Precuneus: A Review of its Functional Anatomy and Behavioural Correlates. Brain, 129, 564–583.Google Scholar

Cela-Conde, C. J., Garcia-Prieto, J., Ramasco, J., et al. (2013). Dynamics of Brain Networks in the Aesthetic Appreciation. Proceedings of the National Academy of Sciences USA, 110 (Suppl. 2), 10454–10461.Google Scholar

Chamorro-Premuzic, T., Burke, C., Hsu, A., and Swami, V. (2010). Personality Predictors of Artistic Preferences as a Function of the Emotional Valence and Perceived Complexity of Paintings. Psychology of Aesthetics, Creativity, and the Arts, 4, 196–204.CrossRefGoogle Scholar

Chamorro-Premuzic, T., Reimers, S., Hsu, A., and Ahmetoglu, G. (2009). Who Art Thou? Personality Predictors of Artistic Preferences in a Large UK Sample: The Importance of Openness. British Journal of Psychology, 100, 501–516.Google Scholar

Chatterjee, A., and Vartanian, O. (2014). Neuroaesthetics. Trends in Cognitive Sciences, 18, 370–375.Google Scholar

Chatterjee, A., and Vartanian, O.(2016). Neuroscience of Aesthetics. Annals in the New York Academy of Sciences, 1369, 172–194.Google Scholar

Cunningham, S. I., Tomasi, D., and Volkow, N. D. (2017). Structural and Functional Connectivity of the Precuneus and Thalamus to the Default Mode Network. Human Brain Mapping, 38, 938–956.CrossRefGoogle ScholarPubMed

Cupchik, G. C. (2016). The Aesthetics of Emotion. New York, NY: Cambridge University Press.Google Scholar

Cupchik, G. C., Vartanian, O., Crawley, A., and Mikulis, D. J. (2009). Viewing Artworks: Contributions of Cognitive Control and Perceptual Facilitation to Aesthetic Experience. Brain and Cognition, 70, 84–91.Google Scholar

Dutton, D. (2009). The Art Instinct. New York, NY: Oxford University Press.Google Scholar

Fayn, K., MacCann, C., Tiliopoulos, N., and Silvia, P. J. (2015). Aesthetic Emotions and Aesthetic People: Openness Predicts Sensitivity to Novelty in the Experiences of Interest and Pleasure. Frontiers in Psychology, 6, article 1877.Google Scholar

Fechner, G. T. (1876). Vorschule der Aesthetik [Experimental Aesthetics: “Pre-School” of Aesthetics]. Leipzig, Germany: Breitkopf & Härtel.Google Scholar

Fink, A., Benedek, M., Grabner, R. H., Staudt, B., and Neubauer, A. C. (2007). Creativity Meets Neuroscience: Experimental Tasks for the Neuroscientific Study of Creative Thinking. Methods, 42, 68–76.Google Scholar

Furnham, A., and Walker, J. (2001). The Influence of Personality Traits, Previous Experience of Art, and Demographic Variables on Artistic Preference. Personality and Individual Differences, 31, 997–1017.Google Scholar

Graf, L. K. M., and Landwehr, J. R. (2015). A Dual-Process Perspective on Fluency-Based Aesthetics: The Pleasure-Interest Model of Aesthetic Liking. Personality and Social Psychology Review, 19, 395–410.Google Scholar

Graf, L. K. M., and Landwehr, J. R.(2017). Aesthetic Pleasure versus Aesthetic Interest: The Two Routes to Aesthetic Liking. Frontiers in Psychology, 8, article 15.Google Scholar

Hall, S. E., Schubert, E., and Wilson, S. J. (2016). The Role of Trait and State Absorption in the Enjoyment of Music. PLoS One, 11, e0164029.CrossRefGoogle ScholarPubMed

Huang, M., Bridge, H., Kemp, M. J., and Parker, A. J. (2011). Human Cortical Activity Evoked by the Assignment of Authenticity when Viewing Works of Art. Frontiers in Human Neuroscience, 5, 134.Google Scholar

Ishai, A., Fairhall, S. L., and Pepperell, R. (2007). Perception, Memory and Aesthetics of Indeterminate Art. Brain Research Bulletin, 73, 319–324.Google Scholar

John, O. P., Naumann, L. P., and Soto, C. J. (2008). Paradigm Shift to the Integrative Big Five Trait Taxonomy. In John, O. P., Robbins, R. W., and Pervin, L. A. (eds.), Handbook of Personality: Theory and Research. New York, NY: Guilford Press, 114–158.Google Scholar

Karwowski, M., and Lebuda, I. (2016). The Big Five, the Huge Two, and Creative Self-Beliefs: A Meta-Analysis. Psychology of Aesthetics, Creativity, and the Arts, 10, 214–232.Google Scholar

Kirk, U., Skov, M., Hulme, O., Christensen, M. S., and Zeki, S. (2009). Modulation of Aesthetic Value by Semantic Context: An fMRI Study. Neuroimage, 44, 1125–1132.Google Scholar

Leder, H., Belke, B., Oeberst, A., and Augustin, D. (2004). A Model of Aesthetic Appreciation and Aesthetic Judgments. British Journal of Psychology, 95, 489–508.Google Scholar

Leder, H., and Nadal, M. (2014). Ten Years of a Model of Aesthetic Appreciation and Aesthetic Judgments: The Aesthetic Episode – Developments and Challenges in Empirical Aesthetics. British Journal of Psychology, 105, 443–464.Google Scholar

Martindale, C. (1990). The Clockwork Muse: The Predictability of Artistic Change. New York, NY: Basic Books.Google Scholar

McManus, I. C. (2013). “The Anti-Developmental, the Anti-Narrative, the Anti-Historical”: Mondrian as a Paradigmatic Artist for Empirical Aesthetics. Behavioral and Brain Sciences, 36, 152–153.CrossRefGoogle ScholarPubMed

McManus, I. C., and Furnham, A. (2006). Aesthetic Activities and Aesthetic Attitudes: Influences of Education, Background and Personality on Interest and Involvement in the Arts. British Journal of Psychology, 97, 555–587.Google Scholar

Meyer, M. L., Hershfield, H. E., Waytz, A. G., Mildner, J. N., and Tamir, D. I. (2019). Creative Expertise Is Associated with Transcending the Here and Now. Journal of Personality and Social Psychology, 116, 483–494.Google Scholar

Newman, G. E., and Bloom, P. (2012). Art and Authenticity: The Importance of Originals in Judgments of Value. Journal of Experimental Psychology: General, 141, 558–569.Google Scholar

Osgood, C. E. (1962). Studies on the Generality of Affective Meaning Systems. American Psychologist, 17, 10–28.Google Scholar

Pelowski, M., Markey, P. S., Forster, M., Gerger, G., and Leder, H. (2017). Move Me, Astonish Me … Delight my Eyes and Brain: The Vienna Integrated Model of Top-Down and Bottom-Up Processes in Art Perception (VIMAP) and Corresponding Affective, Evaluative, and Neurophysiological Correlates. Physics of Life Reviews, 21, 80–125.CrossRefGoogle ScholarPubMed

Rawlings, D. (2003). Personality Correlates of Liking for “Unpleasant” Paintings and Photographs. Personality and Individual Differences, 34, 395–410.Google Scholar

Rhodes, L. A., David, D. C., and Combs, A. L. (1988). Absorption and Enjoyment of Music. Perceptual and Motor Skills, 66, 737–738.Google Scholar

Sheppard, A. (1991). The Role of Imagination in Aesthetic Experience. The Journal of Aesthetic Education, 25, 35–42.Google Scholar

Silveira, S., Fehse, K., Vedder, A., Elvers, K., and Hennig-Fast, K. (2015). Is It the Picture or Is It the Frame? An fMRI Study on the Neurobiology of Framing Effects. Frontiers in Human Neuroscience, 9, article 528.Google Scholar

Silvia, P. J., Nusbaum, E. C., Berg, C., Martin, C., and O’Connor, A. (2009). Openness to Experience, Plasticity, and Creativity: Exploring Lower-Order, High-Order, and Interactive Effects. Journal of Research in Personality, 43, 1087–1090.Google Scholar

Simonton, D. K. (1999). Creativity as Blind Variation and Selective Retention: Is the Creative Process Darwinian? Psychological Inquiry, 10, 309–328.Google Scholar

Simonton, D. K.(2007). The Creative Imagination in Picasso’s Guernica Sketches: Monotonic Improvements or Nonmonotonic Variants? Creativity Research Journal, 19, 329–344.Google Scholar

Simonton, D. K.(2013). Creative Thought as Blind Variation and Selective Retention: Why Creativity Is Inversely Related to Sightedness. Journal of Theoretical and Philosophical Psychology, 33, 253–266.Google Scholar

Skov, M., and Vartanian, O. (eds.) (2009). Neuroaesthetics. Amityville, NY: Baywood Publishing Company.Google Scholar

Specker, E., Tinio, P. P. L., and van Elk, M. (2017). Do You See What I See? An Investigation of the Aesthetic Experience in the Laboratory and Museum. Psychology of Aesthetics, Creativity, and the Arts, 11(3), 265–275.Google Scholar

Tellegen, A., and Atkinson, G. (1974). Openness to Absorbing and Self-Altering Experiences (“Absorption”), a Trait Related to Hypnotic Susceptibility. Journal of Abnormal Psychology, 83, 268–277.Google Scholar

Tinio, P. P. L. (2013). From Artistic Creation to Aesthetic Reception: The Mirror Model of Art. Psychology of Aesthetics, Creativity, and the Arts, 7, 265–275.Google Scholar

Tyler, C. W. (1999). Is Art Lawful? Journal of Consciousness Studies, 6, 673–674.Google Scholar

van de Cruys, S., and Wagemans, J. (2011). Putting Reward in Art: A Tentative Prediction Error Account of Visual Art. i-Perception, 2, 1035–1062.Google Scholar

Vartanian, O., and Skov, M. (2014). Neural Correlates of Viewing Paintings: Evidence from a Quantitative Meta-Analysis of Functional Magnetic Resonance Imaging Data. Brain and Cognition, 87, 52–56.CrossRefGoogle ScholarPubMed

Vessel, E. A., Maurer, N., Denker, A. H., and Starr, G. G. (2018). Stronger Shared Taste for Natural Aesthetic Domains than for Artifacts of Human Nature. Cognition, 179, 121–131.CrossRefGoogle Scholar

Vessel, E. A., Starr, G. G., and Rubin, N. (2012). The Brain on Art: Intense Aesthetic Experience Activates the Default Mode Network. Frontiers in Human Neuroscience, 6, article 66.Google Scholar

Wang, T., Mo, L., Vartanian, O., Cant, J. S., and Cupchik, G. (2015). An Investigation of the Neural Substrates of Mind Wandering Induced by Viewing Traditional Chinese Landscape Paintings. Frontiers in Human Neuroscience, 8, article 1018.Google Scholar

Ward, T. B., Patterson, M. J., and Sifonis, C. M. (2004). The Role of Specificity and Abstraction in Creative Idea Generation. Creativity Research Journal, 16, 1–9.Google Scholar

Wild, T. C., Kuiken, D., and Schopflocher, D. (1995). The Role of Absorption in Experiential Involvement. Journal of Personality and Social Psychology, 69, 569–579.Google Scholar

Winner, E. (2019). How Art Works. New York, NY: Oxford University Press.Google Scholar

Zeki, S. (1999). Inner Vision. Oxford, UK: Oxford University Press.Google Scholar

Arbib, M. (2005). From Monkey-Like Action Recognition to Human Language: An Evolutionary Framework for Neurolinguistics. Behavioral and Brain Sciences, 28, 105–167.Google Scholar

Beaudet, A. (2017). The Emergence of Language in the Hominin Lineage: Perspectives from Fossil Endocasts. Frontiers in Human Neuroscience, 11, 427.CrossRefGoogle ScholarPubMed

Bergeron, D., Verret, L., Potvin, O., Duchesne, S., and Laforce, R., Jr. (2016). When the Left Brain’s Away, the Right Will Play – Emergent Artistic Proficiency in Primary Progressive Apraxia of Speech. Cortex, 76, 125–127.CrossRefGoogle ScholarPubMed

Boccia, M., Barbetti, S., Piccardi, L., et al. (2016). Where Does Brain Neural Activation in Aesthetic Responses Occur? Meta-Analytic Evidence from Neuroimaging Studies. Neuroscience and Biobehavioral Reviews, 60, 65–71.Google Scholar

Bogousslavsky, J., and Boller, F. (2005). Neurological Disorders in Famous Artists (Part 1). Basel, Switzerland: Karger.Google Scholar

Brooks, A. S., Yellen, J. E., Potts, R., et al. (2018). Long-Distance Stone Transport and Pigment Use in the Earliest Middle Stone Age. Science, 360(6384), 90–94.Google Scholar

Burling, R., Armstrong, D. F., Blount, B. G., et al. (1993). Primate Calls, Human Language, and Nonverbal Communication [and Comments and Reply]. Current Anthropology, 34, 25–53.Google Scholar

Butter, C. M. (2004). Anton Raederscheidt’s Distorted Self-Portraits and Their Significance for Understanding Balance in Art. Journal of the History of the Neurosciences, 13, 66–78.Google Scholar

Cavallera, G. M., Giudici, S., and Tommasi, L. (2012). Shadows and Darkness in the Brain of a Genius: Aspects of the Neuropsychological Literature about the Final Illness of Maurice Ravel (1875–1937). Medical Science Monitor, 18, 1–8.Google Scholar

Clark, B. (2013). Syntactic Theory and the Evolution of Syntax. Biolinguistics, 7, 169–197.Google Scholar

Davies, C., Knuiman, M., and Rosenberg, M. (2016). The Art of Being Mentally Healthy: A Study to Quantify the Relationship between Recreational Arts Engagement and Mental Well-Being in the General Population. BMC Public Health, 16, 15.CrossRefGoogle ScholarPubMed

De Souza, L. C., Guimarães, H. C., Teixeira, A. L., et al. (2014). Frontal Lobe Neurology and the Creative Mind. Frontiers in Psychology, 5, 761.Google Scholar

Deacon, T. W. (1998). The Symbolic Species: The Co-Evolution of Language and the Brain. New York, NY: W. W. Norton and Company.Google Scholar

Deacon, T. W.(2011). The Symbol Concept. In Tallerman, M and Gibson, K (eds.), The Oxford Handbook of Language Evolution. Oxford, UK: Oxford University Press.Google Scholar

Erkkinen, M. G., Zúñiga, R., Pardo, C., Miller, B. L., and Miller, Z. A. (2018). Artistic Renaissance in Frontotemporal Dementia. JAMA: The Journal of the American Medical Association, 319, 1304–1306.Google Scholar

Feldman, M. W., and Cavalli-Sforza, L. L. (1976). Cultural and Biological Evolutionary Processes, Selection for a Trait under Complex Transmission. Theoretical Population Biology, 9, 238–259.Google Scholar

Feldman, M. W., and Laland, K. N. (1996). Gene-Culture Co-Evolutionary Theory. Trends in Ecology and Evolution, 11, 453–457.Google Scholar

Fitch, W. T. (2011). The Evolution of Syntax: An Exaptationist Perspective. Frontiers in Evolutionary Neuroscience, 3, 9.CrossRefGoogle ScholarPubMed

Foerch, C., and Hennerici, M. G. (2015). Organists and Organ Music Composers. In Altenmüller, E, Finger, S, and Boller, F (eds.), Progress in Brain Research Vol. 216. Oxford, UK; New York, NY: Elsevier, 331–341.Google Scholar

Fornazzari, L. R., Ringer, T., Ringer, L., and Fischer, C. E. (2013). Preserved Drawing in a Sculptor with Dementia. The Canadian Journal of Neurological Sciences, 40, 736–737.Google Scholar

Fuentes, A. (2015). Integrative Anthropology and the Human Niche: Toward a Contemporary Approach to Human Evolution. American Anthropologist, 117, 302–315.Google Scholar

Gainotti, G. (2014). Why Are the Right and Left Hemisphere Conceptual Representations Different? Behavioural Neurology, 2014, 10.Google Scholar

Griesser, M., Wheatcroft, D., and Suzuki, T. N. (2018). From Bird Calls to Human Language: Exploring the Evolutionary Drivers of Compositional Syntax. Current Opinion in Behavioral Sciences, 21, 6–12.Google Scholar

Guariglia, C., Piccardi, L., Iaria, G., Nico, D., and Pizzamiglio, L. (2005). Representational Neglect and Navigation in Real Space. Neuropsychologia, 43, 1138–1143.Google Scholar

Henshilwood, C. S., d’ Errico, F., and Watts, I. (2009). Engraved Ochres from the Middle Stone Age Levels at Blombos Cave, South Africa. Journal of Human Evolution, 57, 27–47.Google Scholar

Henshilwood, C. S., van Niekerk, K. L., Wurz, S., et al. (2014). Klipdrift Shelter, Southern Cape, South Africa: Preliminary Report on the Howiesons Poort Layers. Journal of Archaeological Science, 45, 284–303.Google Scholar

Hodgson, D. (2014). Decoding the Blombos Engravings, Shell Beads and Diepkloof Ostrich Eggshell Patterns. Cambridge Archaeological Journal, 24, 57–69.Google Scholar

Hublin, J.-J., Ben-Ncer, A., Bailey, S. E., et al. (2017). New Fossils from Jebel Irhoud, Morocco and the Pan-African Origin of Homo Sapiens. Nature, 546, 289–292.Google Scholar

Inzelberg, R. (2013). The Awakening of Artistic Creativity and Parkinson’s Disease. Behavioral Neuroscience, 127, 256–261.CrossRefGoogle ScholarPubMed

Jefferies, E. (2013). The Neural Basis of Semantic Cognition: Converging Evidence from Neuropsychology, Neuroimaging and TMS. Cortex, 49(3), 611–625.CrossRefGoogle ScholarPubMed

Jensen, A., Stickley, T., Torrissen, W., and Stigmar, K. (2017). Arts on Prescription in Scandinavia: A Review of Current Practice and Future Possibilities. Perspectives in Public Health, 137, 268–274.Google Scholar

Jolley, R. P., O’Kelly, R., Barlow, C. M., and Jarrold, C. (2013). Expressive Drawing Ability in Children with Autism. British Journal of Developmental Psychology, 31, 143–149.Google Scholar

Kanat, A., Kayaci, S., Yazar, U., and Yilmaz, A. (2010). What Makes Maurice Ravel’s Deadly Craniotomy Interesting? Concerns of One of the Most Famous Craniotomies in History. Acta Neurochirurgica, 152, 737–742.Google Scholar

Kolodny, O., Feldman, M. W., and Creanza, N. (2018). Integrative Studies of Cultural Evolution: Crossing Disciplinary Boundaries to Produce New Insights. Philosophical Transactions of the Royal Society B: Biological Sciences, 373 (1743). doi:10.1098/rstb.2017.0048.Google Scholar

Le Fur, Y., and Martin, S. (2017). Through the Eyes of Picasso: Face to Face with African and Oceanic Art. Paris, France: Flammarion.Google Scholar

Lewis-Williams, D. (2002). The Mind in the Cave: Consciousness and the Origins of Art. London, UK: Thames and Hudson.Google Scholar

Lombard, L. (2016). Camouflage: The Hunting Origins of Worlding in Africa. Journal of African Studies, 34, 147–164.Google Scholar

Luuk, E., and Luuk, H. (2014). The Evolution of Syntax: Signs, Concatenation, and Embedding. Cognitive Systems Research, 27, 1–10.CrossRefGoogle Scholar

McBrearty, S. (2007). Down with the Revolution. In Mellars, P, Boyle, K, Bar-Yosef, O, and Stringer, C (eds.), Rethinking the Human Revolution. Cambridge, UK: McDonald Institute for Archaeological Research, 133–152.Google Scholar

McBrearty, S., and Brooks, A. S. (2000). The Revolution That Wasn’t: A New Interpretation of the Origin of Modern Human Behavior. Journal of Human Evolution, 39, 453–563.CrossRefGoogle ScholarPubMed

Miller, B. L., Cummings, J., Mishkin, F., et al. (1998). Emergence of Artistic Talent in Frontotemporal Dementia. Neurology, 51, 978–982.Google Scholar

Miller, B. L., and Hou, C. E. (2004). Portraits of Artists: Emergence of Visual Creativity in Dementia. Archives of Neurology, 61, 842–844.Google Scholar

Miller, G. F. (2000). The Mating Mind: How Sexual Choice Shaped the Evolution of Human Nature. New York, NY: Doubleday.Google Scholar

Miller, Z. A., and Miller, B. L. (2013). Artistic Creativity and Dementia. Progress in Brain Research, 204, 99–112.Google Scholar

Nadal, M. (2013). The Experience of Art: Insights from Neuroimaging. Progress in Brain Research, 204, 135–158.CrossRefGoogle ScholarPubMed

Newmark, J. (2009). Neurological Problems of Famous Musicians: The Classical Genre. Journal of Child Neurology, 24, 1043–1050.Google Scholar

Palmiero, M., Di Giacomo, D., and Passafiume, D. (2012). Creativity and Dementia: A Review. Cognitive Processing, 13, 193–209.Google Scholar

Petcu, E. B., Sherwood, K., Popa-Wagner, A., et al. (2016). Artistic Skills Recovery and Compensation in Visual Artists after Stroke. Frontiers in Neurology, 7, 76.Google Scholar

Pollak, T. A., Mulvenna, C. M., and Lythgoe, M. F. (2007). De Novo Artistic Behaviour Following Brain Injury. Frontiers in Neurological Neuroscience, 22, 75–88.Google Scholar

Potts, R., Behrensmeyer, A. K., Faith, J. T., et al. (2018). Environmental Dynamics during the Onset of the Middle Stone Age in Eastern Africa. Science, 360, 86–90.Google Scholar

Richter, D., Grün, R., Joannes-Boyau, R., et al. (2017). The Age of the Hominin Fossils from Jebel Irhoud, Morocco, and the Origins of the Middle Stone Age. Nature, 546, 293–296.Google Scholar

Rose, F. C. (ed.) (2004). Neurology of the Arts: Painting, Music, Literature. London, UK: Imperial College Press.Google Scholar

Rutten, G.-J. (2017). The Broca-Wernicke: A Historical Clinical Perspective on Localization of Language Functions. Cham, Switzerland: Springer.Google Scholar

Schrag, A., and Trimble, M. (2001). Poetic Talent Unmasked by Treatment of Parkinson’s Disease. Movement Disorders, 16, 1175–1176.Google Scholar

Seeley, W. W., Matthews, B. R., Crawford, R. K., et al. (2008). Unravelling Boléro: Progressive Aphasia, Transmodal Creativity and the Right Posterior Neocortex. Brain, 131, 39–49.Google Scholar

Seyfarth, R. M., and Cheney, D. L. (2014). The Evolution of Language from Social Cognition. Current Opinion in Neurobiology, 28, 5–9.Google Scholar

Simis, M., Bravo, G. L., Boggio, P. S., et al. (2013). Transcranial Direct Current Stimulation in de novo Artistic Ability after Stroke. Neuromodulation, 17, 497–501.Google Scholar

Stevens, A. N. P., and Stevens, J. R. (2012). Animal Cognition. Nature Education Knowledge, 3, 1.Google Scholar

Stringer, C., and Galway-Witham, J. (2017). Palaeoanthropology: On the Origin of Our Species. Nature, 546, 212–214.Google Scholar

Ten Eycke, K. D., and Müller, U. (2016). Drawing Links between the Autism Cognitive Profile and Imagination: Executive Function and Processing Bias in Imaginative Drawings by Children with and without Autism. Autism, 22, 149–160.Google Scholar

Thomas-Anterion, C., Creac’h, C., Dionet, E., et al. (2010). De novo Artistic Activity Following Insular-SII Ischemia. Pain, 150, 121–127.Google Scholar

Tooby, J., and Cosmides, L. (2016). Human Cooperation Shows the Distinctive Signatures of Adaptations to Small-Scale Social Life. Behavioral Brain Science, 39, e54.Google Scholar

Vallar, G., and Calzolari, E. (2018). Unilateral Spatial Neglect after Posterior Parietal Damage. In Vallar, G and Coslett, H. B. (eds.), Handbook of Clinical Neurology Vol. 151. Amsterdam, Netherlands: Elsevier, 287–312.Google Scholar

Vinter, A., Bonin, P., and Morgan, P. (2018). The Severity of the Visual Impairment and Practice Matter for Drawing Ability in Children. Research in Developmental Disabilities, 78, 15–26.Google Scholar

Wadley, L., Hodgskiss, T., and Grant, M. (2009). Implications for Complex Cognition from the Hafting of Tools with Compound Adhesives in the Middle Stone Age, South Africa. Proceedings of the National Academy of Science USA, 106, 9590–9594.Google Scholar

Whiten, A. (2011). The Scope of Culture in Chimpanzees, Humans and Ancestral Apes. Philosophical Transactions of the Royal Society B, 366, 997–1007.Google Scholar

Whiten, A.(2017). Culture Extends the Scope of Evolutionary Biology in the Great Apes. Proceedings of the National Academy of Sciences USA, 114, 7790–7797.Google Scholar

Wichmann, S. (1988). Japonisme: The Japanese Influence on Western Art in the 19th and 20th Centuries. New York, NY: Random House.Google Scholar

Wurz, S. (2013). Technological Trends in the Middle Stone Age of South Africa between MIS 7 and MIS 3. Current Anthropology, 54, S305–S319.Google Scholar

Zagvazdin, Y. (2015). Stroke, Music, and Creative Output: Alfred Schnittke and Other Composers. Progress in Brain Research, 216, 149–165.Google Scholar

Zahavi, A. (1978). Decorative Patterns and the Evolution of Art. New Scientist, 19, 182–184.Google Scholar

Zaidel, D. W. (2013). Biological and Neuronal Underpinnings of Creativity in the Arts. In Vartanian, O, Bristol, A. S., and Kaufman, J. C. (eds.), Neuroscience of Creativity. Cambridge, MA: MIT Press, 133–148.Google Scholar

Zaidel, D. W. (2015a). Neuroesthetics Is Not Just about Art. Frontiers in Human Neuroscience, 9, 80.Google Scholar

Zaidel, D. W.(2015b). Neuropsychology of Art: Neurological, Biological and Evolutionary Perspectives. 2nd edition. Hove, UK: Psychology Press.Google Scholar

Zaidel, D. W.(2017a). Art in Early Human Evolution: Socially Driven Art Forms versus Material Art. Evolutionary Studies in Imaginative Culture, 1, 149–157.Google Scholar

Zaidel, D. W.(2017b). Braque and Kokoschka: Brain Tissue Injury and Preservation of Artistic Skill. Behavioral Sciences, 7, E56.Google Scholar

Zaidel, D. W.(2018). Culture and Art: Importance of Art Practice, not Aesthetics, to Early Human Culture. Progress in Brain Research, 23, 25–40.Google Scholar

Zaidel, D. W.(2019). Coevolution of Language and Symbolic Meaning: Co-opting Meaning Underlying the Initial Arts in Early Human Culture. WIREs Cognitive Science, e1520.Google Scholar

Andrews-Hanna, J. R., Reidler, J. S., Sepulcre, J., Poulin, R., and Buckner, R. L. (2010). Functional-Anatomic Fractionation of the Brain’s Default Network. Neuron, 65(4), 550–562.Google Scholar

Aurier, Albert. (1974). Vincent, an Isolated Artist. In Welsh-Ovcharov, B. (ed.), Van Gogh in Perspective. Englewood Cliffs, NJ: Prentice Hall.Google Scholar

Barad, K. M. (2007). Meeting the Universe Halfway: Quantum Physics and the Entanglement of Matter and Meaning. Durham, NC: Duke University Press.Google Scholar

Bremmer, H. (1974). Introductory Appreciations. In Welsh-Ovcharov, B. (ed.), Van Gogh in Perspective. Englewood Cliffs, NJ: Prentice Hall.Google Scholar

Buckner, R. L., Andrews-Hanna, J. R., and Schacter, D. L. (2008). The Brain’s Default Network: Anatomy, Function, and Relevance to Disease. Annals of the New York Academy of Sciences, 1124, 1–38.Google Scholar

Changizi, M. (2011). Harnessed: How Language and Music Mimicked Nature and Transformed Ape to Man. Dallas, TX: BenBella Books.Google Scholar

Foucault, M. (1979). Authorship: What is an Author? Screen, 20(1), 13–34. doi:10.1093/screen/20.1.13.Google Scholar

Gallese, V. (2017). The Empathic Body in Experimental Aesthetics – Embodied Simulation and Art. In Lux, V and Weigel, S (eds.), Empathy: Palgrave Studies in the Theory and History of Psychology. London, UK: Palgrave Macmillan, 181–199.Google Scholar

Harari, Y. N. (2015). Homo Deus: A Brief History of Tomorrow. Toronto, Canada: McClelland & Stewart.Google Scholar

Kandel, E. (2016). Reductionism in Art and Brain Science: Bridging the Two Cultures. New York, NY: Columbia University Press.CrossRefGoogle Scholar

Kris, E., Kurz, O., Laing, A., and Newman, L. M. (1979). Legend, Myth and Magic in the Image of the Artist: A Historical Experiment. New Haven, CT: Yale University Press.Google Scholar

Legrenzi, P., and Umiltà, C. A. (2011). Neuromania: On the Limits of Brain Science. New York, NY: Oxford University Press.Google Scholar

Livingstone, M., and Hubel, D. (2014). Vision and Art: The Biology of Seeing. New York, NY: Abrams.Google Scholar

Leibniz, G. W., and Loemker, L. (1976). Philosophical Papers and Letters. 2nd edition. Dordrecht, Netherlands; Boston, MA: D. Reidel Publishing Company.Google Scholar

Meier-Graefe, Julius. (1974). Vincent and Socialism. In Welsh-Ovcharov, B. (ed.), Van Gogh in Perspective. Englewood Cliffs, NJ: Prentice Hall.Google Scholar

Noë, A. (2011). Art and the Limits of Neuroscience. The New York Times, December 4. opinionator.blogs.nytimes.com/2011/12/04/art-and-the-limits-of-neuroscience/.Google Scholar

Raichle, M. E. (2015). The Brain’s Default Mode Network. Annual Review of Neuroscience, 38(1), 433–447.Google Scholar

Vessel, E. A., Starr, G. G., and Rubin, N. (2013). Art Reaches Within: Aesthetic Experience, the Self and the Default Mode Network. Frontiers in Neuroscience, 7.Google Scholar

Brampton, S. (2018). Cognitive Imagery Training in a Dancer’s Deliberate Practice: Skills Development, Confidence and Creativity. Perth, Australia: Edith Cowan University, BA of Arts (Dance) thesis.Google Scholar

Carlson, N. R. (2004). Physiology of Behavior. 8th edition. New York, NY: Pearson.Google Scholar

Cesari, P., Camponogara, I., Papetti, S., Rocchesso, D., and Fontana, F. (2014). Might as Well Jump: Sound Affects Muscle Activation in Skateboarding. PLoS One, 9(3), e90156.Google Scholar

Christensen, J. F., Gaigg, S. B., and Calvo-Merino, B. (2018). I Can Feel My Heartbeat: Dancers Have Increased Interoceptive Awareness. Psychophysiology, 55:e13008.Google Scholar

Christensen, J. F., Gaigg, S. B., Gomila, A., Oke, P., and Calvo-Merino, B. (2014). Enhancing Emotional Experiences to Dance through Music: The Role of Valence and Arousal in the Cross-Modal Bias. Frontiers in Human Neuroscience, 8. doi:10.3389/fnhum.2014.00757.Google Scholar

Coker, E., McIsaac, T. L., and Nilsen, D. (2015). Motor Imagery Modality in Expert Dancers: An Investigation of Hip and Pelvis Kinematics in Demi-Plie and Saute. Journal of Dance Medicine & Science, 19(2), 63–69.Google Scholar

Csikszentmihalyi, M. (2008). Flow: The Psychology of Optimal Experience. New York, NY: Harper Perennial Modern Classics.Google Scholar

Fish, L., Hall, C., and Cumming, J. (2004). Investigating the Use of Imagery by Elite Ballet Dancers. AVANTE, 10(3), 26–39.Google Scholar

Freedberg, D., and Gallese, V. (2007). Motion, Emotion and Empathy in Esthetic Experience. Trends in Cognitive Sciences, 11(5), 197–203.Google Scholar

Garfinkel, S. N., and Critchley, H. D. (2013). Interoception, Emotion and Brain: New Insights Link Internal Physiology to Social Behaviour. Commentary on: “Anterior Insular Cortex Mediates Bodily Sensibility and Social Anxiety” by Terasawa et al. (2012). Social Cognitive and Affective Neuroscience, 8(3), 231–234.Google Scholar

Garfinkel, S. N., Seth, A. K., Barrett, A. B., Suzujum, J., and Critchley, H. (2015). Knowing Your Own Heart: Distinguishing Interoceptive Accuracy from Interoceptive Awareness. Biological Psychology, 104, 65–74.Google Scholar

Ginot, I., Barlow, A., and Franko, M. (2010). Shusterman’s Somaesthetics to a Radical Epistemology of Somatics. Dance Research Journal, 42(1), 12–29.CrossRefGoogle Scholar

Giron, E. C., McIsaac, T., and Nilsen, D. (2012). Effects of Kinesthetic versus Visual Imagery Practice on Two Technical Dance Movements: A Pilot Study. Journal of Dance Medicine & Science, 16(1), 36–38.Google Scholar

Goldschmidt, H. (2002). Dancing with Your Head On: Mental Imagery Techniques for Dancers. Journal of Dance Education, 2(1), 15–22.Google Scholar

Golomer, E., Bouillette, A., Mertz, C., and Keller, J. (2008). Effects of Mental Imagery Styles on Shoulder and Hip Rotations during Preparation of Pirouettes. Journal of Motor Behavior, 40(4), 281–290.Google Scholar

Hanna, J. L. (1995a). The Power of Dance: Health and Healing. The Journal of Alternative and Complementary Medicine, 1(4), 323–331.Google Scholar

Hanna, T. (1995b). What is Somatics? In Johnson, D. H. (ed.), Bone, Breath, and Gesture. Berkeley, CA: North Atlantic Books, 339–359.Google Scholar

Herholz, S. C., Lappe, C., Knief, A., and Pantev, C. (2008). Neural Basis of Music Imagery and the Effect of Musical Expertise. The European Journal of Neuroscience, 28(11), 2352–2360.Google Scholar

Honing, H., and Merchant, H. (2014). Differences in Auditory Timing between Human and Nonhuman Primates. Behavioral and Brain Sciences, 37(6), 557–558; discussion 577–604.Google Scholar

Hubbard, T. L. (2010). Auditory Imagery: Empirical Findings. Psychological Bulletin, 136(2), 302–329.Google Scholar

Jeong, E.-H. (2012). The Application of Imagery to Enhance “Flow State” in Dancers. Melbourne, Australia: Victoria University, PhD thesis.Google Scholar

Jeong, Y. J., Hong, S. C., Lee, M. S., et al. (2005). Dance Movement Therapy Improves Emotional Responses and Modulates Neurohormones in Adolescents with Mild Depression. International Journal of Neuroscience, 115(12), 1711–1720.Google Scholar

Juslin, P. N., and Vastfjall, D. (2008). Emotional Responses to Music: The Need to Consider the Underlying Mechanisms. Behavioral and Brain Sciences, 31(6), 559–575.Google Scholar

Karin, J. (2016). Recontextualizing Dance Skills: Overcoming Impediments to Motor Learning and Expressivity in Ballet Dancers. Frontiers in Psychology, 7, 431.Google Scholar

Karin, J., Haggard, P., and Christensen, J. F. (2016). Mental Training. In Wilmerding, V and Krasnow, D (eds.), Dancer Wellness. Champaign, Canada: Human Kinetics, 57–70.Google Scholar

Keller, P. E. (2012). Mental Imagery in Music Performance: Underlying Mechanisms and Potential Benefits. Annals of the New York Academy of Sciences, 1252, 206–213.Google Scholar

Keller, P. E., Dalla Bella, S., and Koch, I. (2010). Auditory Imagery Shapes Movement Timing and Kinematics: Evidence from a Musical Task. Journal of Experimental Psychology: Human Perception and Performance, 36(2), 508–513.Google Scholar

Koch, S., Kunz, T., Lykou, S., and Cruz, R. (2014). Effects of Dance Movement Therapy and Dance on Health-Related Psychological Outcomes: A Meta-Analysis. The Arts in Psychotherapy, 41(1), 46–64.Google Scholar

Kornysheva, K., von Cramon, D. Y., Jacobsen, T., and Schubotz, R. I. (2010). Tuning-in to the Beat: Aesthetic Appreciation of Musical Rhythms Correlates with a Premotor Activity Boost. Human Brain Mapping, 31(1), 48–64.Google Scholar

Mahoney, M. J., and Avener, M. (1977). Psychology of the Elite Athlete: An Exploratory Study. Cognitive Therapy and Research, 1(2), 135–141.Google Scholar

Mainka, S. (2015). Music Stimulates Muscles, Mind, and Feelings in One Go. Frontiers in Psychology, 6, 1547–1547.Google Scholar

Meister, I. G., Krings, T., Foltys, H., et al. (2004). Playing Piano in the Mind – An fMRI Study on Music Imagery and Performance in Pianists. Cognitive Brain Research, 19(3), 219–228.Google Scholar

Merchant, H., Grahn, J., Trainor, L., Rohrmeier, M., and Fitch, W. T. (2015). Finding the Beat: A Neural Perspective across Humans and Non-Human Primates. Philosophical Transactions of the Royal Society B: Biological Sciences, 370(1664), 20140093.Google Scholar

Merchant, H., and Honing, H. (2013). Are Non-Human Primates Capable of Rhythmic Entrainment? Evidence for the Gradual Audiomotor Evolution Hypothesis. Frontiers in Neuroscience, 7, 274.Google Scholar

Molinari, M., Leggio, M. G., de Martin, M., Cerasa, A., and Thaut, M. (2003). Neurobiology of Rhythmic Motor Entrainment. Annals of the New York Academy of Sciences, 999, 313–321.Google Scholar

Murphy, S. M., Nordin, S. M., and Cumming, J. I. E. (2008). Imagery in Sport, Exercise and Dance. In Horn, T (ed.), Advances in Sport Psychology. 3rd edition. Champaign, IL: Human Kinetics, 297–324.Google Scholar

Nordin, S., and Cumming, J. (2006). Measuring the Content of Dancers’ Images: Development of the Dance Imagery Questionnaire (DIQ). Journal of Dance Medicine and Science, 10(3).Google Scholar

Nordin, S., and Cumming, J.(2008a). Types and Functions of Athletes’ Imagery: Testing Predictions from the Applied Model of Imagery Use by Examining Effectiveness. International Journal of Sport and Exercise Psychology, 6(2), 189–206.Google Scholar

Nordin, S., and Cumming, J.(2008b). Exploring Common Ground: Comparing the Imagery of Dancers and Aesthetic Sport Performers. Journal of Applied Sport Psychology, 20(4), 375–391.Google Scholar

Noy, L., Dekel, E., and Alon, U. (2011). The Mirror Game as a Paradigm for Studying the Dynamics of Two People Improvising Motion Together. Proceedings of the National Academy of Sciences of the United States of America, 108(52), 20947–20952.Google Scholar

Nummenmaa, L., Glerean, E., Hari, R., and Hietanen, J. K. (2014). Bodily Maps of Emotions. Proceedings of the National Academy of Sciences, 111(2), 646–651.Google Scholar

Olshansky, M. P., Bar, R. J., Fogarty, M., and DeSouza, J. F. (2015). Supplementary Motor Area and Primary Auditory Cortex Activation in an Expert Break-Dancer during the Kinesthetic Motor Imagery of Dance to Music. Neurocase, 21(5), 607–617.Google Scholar

Omigie, D., Pearce, M. T., Williamson, V. J., and Stewart, L. (2013). Electrophysiological Correlates of Melodic Processing in Congenital Amusia. Neuropsychologia, 51(9), 1749–1762.Google Scholar

Overby, L. Y., and Dunn, J. (2011). The History and Research of Dance Imagery: Implications for Teachers. IADMS Bulletin for Teachers, 2, 9–11.Google Scholar

Paltsev, Y. I., and Elner, A. M. (1967). Change in Functional State of the Segmental Apparatus of the Spinal Cord under the Influence of Sound Stimuli and its Role in Voluntary Movement. Biophysics, 12, 1219–1226.Google Scholar

Pavlik, K., and Nordin-Bates, S. (2016). Imagery in Dance: A Literature Review. Journal of Dance Medicine and Science, 20(2), 21–53.Google Scholar

Peasley-Miklus, C. E., Panayiotou, G., and Vrana, S. R. (2016). Alexithymia Predicts Arousal-Based Processing Deficits and Discordance between Emotion Response Systems during Emotional Imagery. Emotion, 16(2), 164.Google Scholar

Perica, R. (2010). The Dancing Imagination: How Does Imaginative Imagery Facilitate Movement Qualities in Dance Training and Performance? Perth, Australia, Edith Cowan University, BA (Hons) thesis. ro.ecu.edu.au/theses_hons/1407.Google Scholar

Poikonen, H., Toiviainen, P., and Tervaniemi, M. (2016). Early Auditory Processing in Musicians and Dancers during a Contemporary Dance Piece. Scientific Reports, 6, 33056.Google Scholar

Schirmer-Mokwa, K. L., Fard, P. R., Zamorano, A. M., et al. (2015). Evidence for Enhanced Interoceptive Accuracy in Professional Musicians. Frontiers in Behavioral Neuroscience, 9, 349.Google Scholar

Schmahmann, J. D., and Pandya, D. N. (2009). Fiber Pathways of the Brain. Oxford, UK: Oxford University Press.Google Scholar

Shafir, T. (2016). Using Movement to Regulate Emotion: Neurophysiological Findings and Their Application in Psychotherapy. Frontiers in Psychology, 7, 1451.Google Scholar

Shafir, T., Taylor, S. F., Atkinson, A. P., Langenecker, S. A., and Zubieta, J. K. (2013). Emotion Regulation through Execution, Observation, and Imagery of Emotional Movements. Brain and Cognition, 82(2), 219–227.Google Scholar

Shafir, T., Tsachor, R. P., and Welch, K. B. (2015). Emotion Regulation through Movement: Unique Sets of Movement Characteristics Are Associated with and Enhance Basic Emotions. Frontiers in Psychology, 6, 2030.Google Scholar

Sumanapala, D. K., Fish, L. A., Jones, A. L., and Cross, E. S. (2017). Have I Grooved to This Before? Discriminating Practised and Observed Actions in a Novel Context. Acta Psychologica, 175, 42–49.Google Scholar

Thaut, M. H. (2003). Neural Basis of Rhythmic Timing Networks in the Human Brain. Annals of the New York Academy of Sciences, 999, 364–373.Google Scholar

Thaut, M. H., Kenyon, G. P., Schauer, M. L., and McIntosh, G. C. (1999). The Connection between Rhythmicity and Brain Function. IEEE Engineering in Medicine and Biology Magazine, 18(2), 101–108.Google Scholar

Williams, S. E., Cooley, S. J., and Cumming, J. (2013). Layered Stimulus Response Training Improves Motor Imagery Ability and Movement Execution. Journal of Sport and Exercise Psychology, 35(1), 60–71.Google Scholar

Wolpert, D. M., and Ghahramani, Z. (2000). Computational Principles of Movement Neuroscience. Nature Reviews Neuroscience, 3 (supplement 1212–1217).Google Scholar

Xenos, S., Rossignol, S., and Jones, G. M. (1976). Audio-Spinal Influence in Man Studied by the H-Reflex and its Possible Role on Rhythmic Movements Synchronized to Sound. Electroencephalography of Clinical Neurophysiology, 41(1), 83–92.Google Scholar

Zatorre, R. J., Chen, J. L., and Penhune, V. B. (2007). When the Brain Plays Music: Auditory-Motor Interactions in Music Perception and Production. Nature Reviews Neuroscience, 8(7), 547–558.Google Scholar

Abraham, A. (2016). The Imaginative Mind. Human Brain Mapping, 37, 4 197–4211.Google Scholar

Adler, L. A., Kunz, M., Chua, H. C., Rotrosen, J., and Resnick, S. G. (2004). Attention-Deficit/Hyperactivity Disorder in Adult Patients with Posttraumatic Stress Disorder (PTSD): Is ADHD a Vulnerability Factor? Journal of Attention Disorders, 8(1), 11–16.Google Scholar

Alegria, J., and Noirot, E. (1978). Neonate Orientation Behaviour Towards the Human Voice. Early Human Development, 1, 291–312.Google Scholar

Aragon, D., Farris, C., and Byers, J. F. (2002). The Effects of Harp Music in Vascular and Thoracic Surgical Patients. Alternative Therapies in Health and Medicine, 8(5), 52–60.Google Scholar

Baumgartner, T., Lutz, K., Schmidt, C. F., and Jancke, L. (2006). The Emotional Power of Music: How Music Enhances the Feeling of Affective Pictures. Brain Research, 1075(1), 151–164.Google Scholar

Beckham, J. C., Vrana, S. R., Barefoot, J. C., et al. (2002). Magnitude and Duration of Cardiovascular Responses to Anger in Vietnam Veterans with and without Posttraumatic Stress Disorder. Journal of Consulting and Clinical Psychology, 70, 228–234.Google Scholar

Bernardi, L., Porta, C., and Sleight, P. (2006). Cardiovascular, Cerebrovascular, and Respiratory Changes Induced by Different Types of Music in Musicians and Non-Musicians: The Importance of Silence. Heart (British Cardiac Society), 92(4), 445–452.Google Scholar

Blood, A. J., and Zatorre, R. J. (2001). Intensely Pleasurable Responses to Music Correlate with Activity in Brain Regions Implicated in Reward and Emotion. Proceedings of the National Academy of Sciences USA, 98(20), 11818–11823.Google Scholar

Brent, D. A., Perper, J. A., Moritz, G., et al. (1995). Posttraumatic Stress Disorder in Peers of Adolescent Suicide Victims: Predisposing Factors and Phenomenology. Journal of the American Academy of Child and Adolescent Psychiatry, 34(2), 209–215.Google Scholar

Brown, S., Martinez, M. J., and Parsons, L. M. (2004). Passive Music Listening Spontaneously Engages Limbic and Paralimbic Systems. Neuroreport, 15(13), 2033–2037.Google Scholar

Buckley, T. C., Holohan, D., Greif, J. L. et al. (2004). Twenty-Four-Hour Ambulatory Assessment of Heart Rate and Blood Pressure in Chronic PTSD and non-PTSD Veterans. Journal of Traumatic Stress, 17, 163–171.Google Scholar

Buckley, T. C., and Kaloupek, D. G. (2001). A Meta-Analytic Examination of Basal Cardiovascular Activity in Posttraumatic Stress Disorder. Psychosomatic Medicine, 63, 585–594.Google Scholar

Byers, J. F., and Smyth, K. A. (1997). Effect of a Musical Intervention on Noise Annoyance, Heart Rate, and Blood Pressure in Cardiac Surgery Patients. American Journal of Critical Care, 6(3), 183–191.Google Scholar

Cardigan, M. E., Caruso, N. A., Haldeman, S. M., et al. (2001). The Effects of Music on Cardiac Patients on Bed Rest. Progress in Cardiovascular Nursing, 16(1), 5–13.Google Scholar

Cohen, H., Benjamin, J., Geva, A. B., et al. (2000). Autonomic Dysregulation in Panic Disorder and in Post-Traumatic Stress Disorder: Application of Power Spectrum Analysis of Heart Rate Variability at Rest and in Response to Recollection of Trauma or Panic Attacks. Psychiatry Research , 96, 1–13.Google Scholar

Cohen, H., Kotler, M., Matar, M. A. et al. (1998). Analysis of Heart Rate Variability in Posttraumatic Stress Disorder Patients in Response to a Trauma-Related Reminder. Biological Psychiatry, 44, 1 054–1059.Google Scholar

Donker, G. A., Yzermans, C. J., Spreeuwenberg, P., and van der Zee, J. (2002). Symptom Attribution after a Plane Crash: Comparison between Self-Reported Symptoms and GP Records. British Journal of General Practice, 52(484), 917–922.Google Scholar

Erlich, N., Lipp, O. V., and Slaughter, V. (2013). Of Hissing Snakes and Angry Voices: Human Infants Are Differently Responsive to Evolutionary Fear-Relevant Sounds. Developmental Science, 16(6), 894–904.Google Scholar

Famularo, R., Fenton, T., Kinscherff, R., and Augustyn, M. (1996). Psychiatric Comorbidity in Childhood Post Traumatic Stress Disorder. Child Abuse and Neglect, 20(10), 953–961.Google Scholar

Fernald, A. (1985). Four-Month-Old Infants Prefer to Listen to Motherese. Infant Behavior and Development, 8, 181–195.Google Scholar

Forneris, C. A., Butterfield, M. I., and Bosworth, H. B. (2004). Physiological Arousal among Women Veterans with and without Posttraumatic Stress Disorder. Military Medicine, 169, 307–312.Google Scholar

Frankland, P. W., Josselyn, S. A., Bradweijn, J., Vaccarino, F. J., and Yeomans, J. S. (1997) Activation of Amygdala Cholecystokinin B Receptores Potentiates the Acoustic Startle Response in Rats. Journal of Neuroscience, 17(5), 1838–1847.Google Scholar

Fried, R. (1990a). Integrating Music in Breathing Training and Relaxation: I. Background, Rationale and Relevant Elements. Biofeedback and Self-Regulation, 15(2), 161–169.Google Scholar

Fried, R.(1990b). Integrating Music in Breathing Training and Relaxation: II. Applications. Biofeedback and Self-Regulation, 15(2), 171–177.Google Scholar

Gerra, G., Zaimovic, A., Franchini, D., et al. (1998). Neuroendocrine Responses of Healthy Volunteers to “Techno-Music”: Relationships with Personality Traits and Emotional State. International Journal of Psychophysiology, 28(1), 99–111.Google Scholar

Goenjian, A. K., Yehuda, R., Pynoos, R. S., et al. (1996). Basal Cortisol, Dexamethasone Suppression of Cortisol and MI-IPG in Adolescents after the 1988 Earthquake in Armenia. American Journal of Psychiatry, 153(7), 929–934.Google Scholar

Goldstein, R. D., Wampler, N. S., and Wise, P. H. (1997). War Experiences and Distress Symptoms of Bosnian Children. Pediatrics, 100(5), 873–878.Google Scholar

Habermas, J. (1979). Communication and the Evolution of Society. Translated by Thomas McCarthy. Boston, MA: Beacon Press.Google Scholar

Hebert, S., Beland, R., Dionne-Fournelle, O., Crete, M., and Lupien, S. J. (2005). Physiological Stress Response to Video-Game Playing: The Contribution of Built-In Music. Life Sciences, 76(20), 2371–2380.Google Scholar

Heidegger, M. (1927/2005). Sein und zeit. Tübingen, Germany: Niemeyer Verlag.Google Scholar

Heldt, S. A., and Falls, W. A. (2003). Destruction of the Inferior Colliculus Disrupts the Production and Inhibition of Fear Conditioned to an Acoustic Stimulus. Behavioural Brain Research, 144(1–2), 175–185.Google Scholar

Husserl, E. (1913/2011). Ideen zu einer reinen Phänomenologie und phänomenologischen Philosophie. New York, NY: Springer.Google Scholar

Iwanaga, M., Kobayashi, A., and Kawasaki, C. (2005). Heart Rate Variability with Repetitive Exposure to Music. Biological Psychology, 70(1), 61–62.Google Scholar

Iwanaga, M., and Tsukamoto, M. (1997). Effects of Excitative and Sedative Music on Subjective and Physiological Relaxation. Perceptual and Motor Skills, 85(1), 287–296.Google Scholar

Jorris, P. X., Schreiner, C. E., and Rees, A. (2004). Neural Processing of Amplitude-Modulated Sounds. Physiological Reviews, 84, 541–577.Google Scholar

Kibler, J. L., and Lyons, J. A. (2004). Perceived Coping Ability Mediates the Relationship between PTSD Severity and Heart Rate Recovery in Veterans. Journal of Traumatic Stress, 17, 23–29.Google Scholar

Knight, W. E. J., and Rickard, N. S. (2001). Relaxing Music Prevents Stress-Induced Increases in Subjective Anxiety, Systolic Blood Pressure and Heart Rate in Healthy Males and Females. Journal of Music Therapy, 38(4), 254–272.Google Scholar

Koelsch, S., Fritz, T. V., Cramon, D. Y., Muller, K., and Friederici, A. D. (2006). Investigating Emotion with Music: An fMRI Study. Human Brain Mapping, 27(3), 239–250.Google Scholar

Kuhl, P. K., Andruski, J. E., Chistovich, I. A., et al. (1997). Cross-Language Analysis of Phonetic Units in Language Addressed to Infants. Science, 277, 684–686.Google Scholar

Lacan, J. (1964/1977) The Seminar of Jacques Lacan, Book XI: The Four Fundamental Concepts of Psychoanalysis. Edited by J. A. Miller. Translated by A. Sheridan. New York, NY: Norton.Google Scholar

Lee, D. N., (2005). Tau in Action in Development. In Rieser, J. J., Lockman, J. J., and Nelson, C. A. (eds.), Action as an Organiser of Learning and Development. Hillsdale, NJ: Erlbaum, 3–49.Google Scholar

Lee, O. K., Chung, Y. F., Chan, M. F., and Chan, W. M. (2005). Music and its Effect on the Physiological Responses and Anxiety Levels of Patients Receiving Mechanical Ventilation: A Pilot Study. Journal of Clinical Nursing, 14(5), 609–620.Google Scholar

Malloch, S., and Trevarthen, C. (eds.) (2009). Communicative Musicality: Exploring the Basis of Human Companionship. Oxford, UK; New York, NY: Oxford University Press.Google Scholar

Marsh, R. A., Fuzessery, Z. M., Grose, C. D., and Wenstrup, J. J. (2002). Projection to the Inferior Colliculus from the Basal Nucleus of the Amygdala. Journal of Neuroscience, 22(23), 10449–10460.Google Scholar

Masataka, N. (1993). Relation between Pitch Contour of Prelinguistic Vocalisations and Communicative Functions in Japanese Infants. Infant Behavior and Development, 16, 397–401.Google Scholar

Mccoy, S. J. (2004). Your Voice, an Inside View: Multimedia Voice Science and Pedagogy. Princeton, NJ: Inside View Press.Google Scholar

Miluk-Kolasa, B., Obminski, Z., Stupnicki, R., and Golec, L. (1994). Effects of Music Treatment on Salivary Cortisol in Patients Exposed to Pre-Surgical Stress. Experimental and Clinical Endocrinology & Diabetes, 102, 118–120.Google Scholar

Mok, E., and Wong, K. Y. (2003). Effects of Music on Patient Anxiety. AORN Journal, 77(2), 396–397, 401–406, 409–410.Google Scholar

Nilsson, U., Unosson, M., and Rawal, N. (2005). Stress Reduction and Analgesia in Patients Exposed to Calming Music Postoperatively: A Randomized Controlled Trial. European Journal of Anaesthesiology, 22(2), 96–102.Google Scholar

Nixon, R. D., and Bryant, R. A. (2005). Induced Arousal and Reexperiencing in Acute Stress Disorder. Journal of Anxiety Disorders, 19(5), 587–594.Google Scholar

Osborne, N. (2009a). Towards a Chronobiology of Musical Rhythm. In Malloch, S and Trevarthen, C (eds.), Communicative Musicality: Exploring the Basis of Human Companionship. Oxford, UK; New York, NY: Oxford University Press, 545–564.Google Scholar

Osborne, N.(2009b). Music for Children in Zones of Conflict and Post-Conflict: A Psychobiological Approach. In Malloch, S and Trevarthen, C (eds.), Communicative Musicality: Exploring the Basis of Human Companionship. Oxford, UK; New York, NY: Oxford University Press, 331–356.Google Scholar

Osborne, N.(2012). Neuroscience and “Real World” Practice: Music as a Therapeutic Resource for Children in Zones of Conflict. Annals of the New York Academy of Sciences, 1252(1), 69–76.Google Scholar

Osborne, N.(2014). The Plenum Brain in Unbribable Bosnia and Herzegovina. In Arsenijević, D (ed,), South East European Integration Perspectives. Baden-Baden, Germany: Nomos Verlag, 174–185.Google Scholar

Osborne, N.(2017a). The Identities of Sevda: From Graeco-Arabic Medicine to Music Therapy. In MacDonald, R, Hargreaves, R, and Miell, D (eds.), Handbook of Musical Identities. Oxford, UK; New York, NY: Oxford University Press.Google Scholar

Osborne, N.(2017b). Love, Rhythm and Chronobiology. In Daniel, S and Trevarthen, C (eds.), Rhythms of Relating in Children’s Therapies: Connecting Creatively with Vulnerable Children. London, UK; Philadelphia, PA: Jessica Kingsley Publishers.Google Scholar

Panksepp, J. (1998). The Periconscious Substrates of Consciousness: Affective States and Evolutionary Origins of the SELF. Journal of Consciousness Studies, 5(5–6), 566–582.Google Scholar

Panksepp, J.(2007). Neuroevolutionary Sources of Laughter and Social Joy: Modelling Primal Human Laughter in Laboratory Rats. Behavioral Brain Research, 182, 231–244.Google Scholar

Panksepp, J., and Bernatzky, G. (2002). Emotional Sounds and the Brain: The Neuro-Affective Foundations of Musical Appreciation. Behavioral Processes, 60(2), 133–155.Google Scholar

Panksepp, J., and Trevarthen, C. (2009). The Neuroscience of Emotion in Music. In Malloch, S and Trevarthen, C (eds.), Communicative Musicality: Exploring the Basis of Human Companionship. Oxford, UK; New York, NY: Oxford University Press, 105–146.Google Scholar

Papoušek, M. (1987). Models and Messages in the Melodies of Maternal Speech in Tonal and Non-Tonal Languages. Society for Research in Child Development, 6, 407.Google Scholar

Sack, M., Hopper, J. W., and Lamprecht, F. (2004). Low Respiratory Sinus Arrhythmia and Prolonged Psychophysiological Arousal in Posttraumatic Stress Disorder: Heart Rate Dynamics and Individual Differences in Arousal Regulation. Biological Psychiatry, 55(3), 284–290.Google Scholar

Sacks, O. (2007). Musicophilia: Tales of Music and the Brain. New York, NY: Random House.Google Scholar

Sahar, T., Shalev, A. Y., and Porges, S. W. (2001). Vagal Modulation of Responses to Mental Challenge in Posttraumatic Stress Disorder. Biological Psychiatry, 49, 637–643.Google Scholar

Schogler, B., and Trevarthen, C. (2007). To Sing and Dance Together – From Infants to Jazz. In Braten, S. (ed.), On Being Moved: From Mirror Neurons to Empathy. Amsterdam, Netherlands; Philadelphia, PA: John Benjamins Publishing Company.Google Scholar

Sivaramakrishnan, S., Sterbino-D’Angelo, S. J., Filipovic, B., et al. (2004). GABA (A) Synapses Shape Neuronal Responses to Sound Intensity in the Inferior Colliculus. Journal of Neuroscience, 24(21), 5031–5043.Google Scholar

Stern, D. N. (1974). Mother and Infant at Play: The Dyadic Interaction Involving Facial, Vocal and Gaze Behaviours. In Lewis, M and Rosenblum, L. A. (eds.), The Effect of the Infant on its Caregiver. New York, NY: Wiley, 187–213.Google Scholar

Stern, D. N.(2004). The Present Moment in Psychotherapy and Everyday Life. New York, NY; London, UK: Norton.Google Scholar

Stevenson, L. (2003). Twelve Conceptions of Imagination. The British Journal of Aesthetics, 43(3), 238–259.Google Scholar

Trehub, S. E. (1987). Infants’ Perception of Musical Patterns. Perception and Psychophysics, 41(6), 635–641.Google Scholar

Trevarthen, C. (2004). Brain Development. In Gregory, R. L. (ed.), Oxford Companion to the Mind. 2nd edition. Oxford, UK; New York, NY: Oxford University Press, 116–127.Google Scholar

Trevarthen, C., and Aitken, K. (2003). Regulation of Brain Development and Age-Related Changes in Infants’ Motives: The Developmental Function of Regressive Periods. In Heimann, M, (ed.), Regression Periods in Human Infancy. Mahwah, NJ: Erlbaum, 107–184.Google Scholar

Trevarthen, C., Gratier, M., and Osborne, N. (2014). The Human Nature of Culture and Education. Wiley Interdisciplinary Reviews: Cognitive Science, 5(2), 173–192. doi:10.1002/wcs.1276. ISSN 1939–5078.Google Scholar

Uedo, N., Ishikawa, H., Morimoto, K., et al. (2004). Reduction in Salivary Cortisol Level by Music Therapy During Colonoscopic Examination. Hepato-Gastroenterology, 51(56), 451–453.Google Scholar

Updike, P. A., and Charles, D. M. (1987). Music Rx: Physiological and Emotional Responses to Taped Music Programs of Preoperative Patients Awaiting Plastic Surgery. Annals of Plastic Surgery, 19(1), 29–33.Google Scholar

Wieser, H. G., and Mazzola, G. (1986). Musical Consonances and Dissonances: Are They Distinguished Independently by the Right and Left Hippocampi? Neuropsychologia, 24(6), 805–812.Google Scholar

Yehuda, R. (2000). Neuroendocrinology. In Nutt, D, Davidson, J, and Zohar, J, (eds.), Posttraumatic Stress Disorder: Diagnosis, Management and Treatment. London, UK: Martin Dunitz, 53–67.Google Scholar

Yule, W. (1994). Posttraumatic Stress Disorder. New York, NY: Plenum.Google Scholar