Dehaene is an associate editor of the journal Cognition, and a member of the editorial board of several other journals, including NeuroImage, PLoS Biology, Developmental Science, and Neuroscience of Consciousness.[7]
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Dehaene studied mathematics at the École Normale Supérieure in Paris from 1984 to 1989.[1] He obtained his master's degree in Applied mathematics and computer science in 1985 from the University of Paris VI.[1]
He turned to neuroscience and psychology[when?] after reading Jean-Pierre Changeux's book, L'Homme neuronal (Neuronal Man: The Biology of The Mind).[citation needed]
Dehaene began to collaborate on computational neuronal models of human cognition, including working memory and task control, collaborations which continue to the present day.[1] Dehaene completed his PhD in Experimental Psychology in 1989 with Jacques Mehler at the École des Hautes Études en Sciences Sociales (EHESS), Paris.[1]
After receiving his doctorate, Dehaene became a research scientist at INSERM in the Cognitive Sciences and Psycholinguistics Laboratory (Laboratoire de Sciences Cognitives et Psycholinguistique) directed by Mehler.[1] He spent two years, from 1992 to 1994, as a post-doctoral fellow at the Institute of Cognitive and Decision Sciences, with Michael Posner at the University of Oregon.[1]
Dehaene returned to France in 1997[8] to serve as Research Director at INSERM (French National Institute of Health and Medical Research) through 2005. He subsequently began his own research group, which today[when?] numbers nearly 30 graduate students, post-doctoral fellows and researchers.[1] In 2005, he was elected to the newly created Chair of Experimental Cognitive Psychology at the Collège de France.[1]
Dehaene is best known for his work on numerical cognition, a discipline which he popularized and synthesized with the publication of his 1997 book, The Number Sense (La Bosse des maths) which won the Prix Jean-Rostand [fr] for best French language general-audience scientific book. He began his studies of numerical cognition with Jacques Mehler, examining the cross-linguistic frequency of number words,[9] whether numbers were understood in an analog or compositional manner,[10][11] and the connection between numbers and space (the "SNARC effect").[12] With Changeux, he then developed a computational model of numerical abilities, which predicted log-gaussian tuning functions for number neurons,[13] a finding which has now been elegantly confirmed with single-unit physiology[14]
With long-time collaborator Laurent Cohen, a neurologist at the Pitié-Salpêtrière Hospital in Paris, Dehaene also identified patients with lesions in different regions of the parietal lobe with impaired multiplication, but preserved subtraction (associated with lesions of the inferior parietal lobule) and others with impaired subtraction, but preserved multiplication (associated with lesions to the intraparietal sulcus).[15] This double dissociation suggested that different neural substrates for overlearned, linguistically mediated calculations, like multiplication, are mediated by inferior parietal regions, while on-line computations, like subtraction are mediated by the intraparietal sulcus. Shortly thereafter, Dehaene began EEG[16][17] and functional neuroimaging[18][19][20] studies of these capacities, showing that parietal and frontal regions were specifically involved in mathematical cognition, including the dissociation between subtraction and multiplication observed in his previous patient studies.
Dehaene subsequently turned his attention to work on the neural correlates of consciousness, leading to numerous scientific articles, an edited book, "The Cognitive Neuroscience of Consciousness" and is the Past President of the Association for the Scientific Study of Consciousness. Dehaene has developed computational models of consciousness, based on Bernard Baars's Global Workspace Theory, which suggest that only one piece of information can gain access to a "global neuronal workspace".[22] To explore the neural basis of this global neuronal workspace, he has conducted functional neuroimaging experiments of masking and the attentional blink, which show that information that reaches conscious awareness leads to increased activation in a network of parietal and frontal regions.[23][24][25] However, some of his work on this subject has been called into question due to a methodological flaw in the "standard reasoning of unconscious priming".[26]
In addition, Dehaene has used brain imaging to study language processing in monolingual and bilingual subjects, and in collaboration with Laurent Cohen, the neural basis of reading. Dehaene and Cohen initially focused on the role of ventral stream regions in visual word recognition, and in particular the role of the leftinferior temporal cortex for reading written words. They identified a region they called the "visual word form area" (VWFA) that was consistently activated during reading,[27][28][29] and also found that when this region was surgically removed to treat patients with intractable epilepsy, reading abilities were severely impaired.[30]
Dehaene, Cohen and colleagues have subsequently demonstrated that, rather than being a single area, the VWFA is the highest stage in a hierarchy of visual feature extraction for letter and word recognition.[31][32]
More recently, they have turned their attention to how learning to read may depend on a process of "neuronal recycling" that causes brain circuits originally evolved for object recognition to become tuned to recognize frequent letters, pairs of letters and words,[33] and have tested these ideas examining brain responses in a group of adults who did not learn to read due to social and cultural constraints.[34][35]
Dehaene, S. (Ed.) Numerical Cognition. Oxford, Blackwell. ISBN1-55786-444-6.
Dehaene, S. (Ed.) Le Cerveau en action: l'imagerie cérébrale en psychologie cognitive. Paris: Presses Universitaires de France, 1997. ISBN2-13-048270-8.
Dehaene, S. (Ed.) The Cognitive Neuroscience of Consciousness. MIT Press, 2001. ISBN0-262-54131-9.
Dehaene, S. Duhamel, J.R., Hauser, M. and Rizzolatti, G. (Ed.) From Monkey Brain to Human Brain. Cambridge, MA: MIT Press, 2005. ISBN0-262-04223-1.
^Dehaene S.; Dupoux E.; Mehler J. (1990). "Is numerical comparison digital? Analogical and symbolic effects in two-digit number comparison". Journal of Experimental Psychology: Human Perception and Performance. 16 (3): 626–641. doi:10.1037/0096-1523.16.3.626. PMID2144576.
^Dehaene S.; Bossini S.; Giraux P. (1993). "The mental representation of parity and numerical magnitude". Journal of Experimental Psychology: General. 122 (3): 371–396. doi:10.1037/0096-3445.122.3.371.
^Nieder A (2005). "Counting on neurons: The neurobiology of numerical competence". Nature Reviews Neuroscience. 6 (3): 177–190. doi:10.1038/nrn1626. PMID15711599. S2CID14578049.
^Dehaene S (1996). "The organization of brain activations in number comparison: Event-related potentials and the additive-factors method". Journal of Cognitive Neuroscience. 8 (1): 47–68. doi:10.1162/jocn.1996.8.1.47. PMID23972235. S2CID8546301.
^Kiefer M.; Dehaene S. (1997). "The time course of parietal activation in single-digit multiplication: Evidence from event-related potentials". Mathematical Cognition. 3: 1–30. doi:10.1080/135467997387461.
^Pinel P.; Le Clec'h G.; van de Moortele P.F.; Naccache L.; Le Bihan D.; Dehaene S. (1999). "Event-related fMRI analysis of the cerebral circuit for number comparison". NeuroReport. 10 (7): 1473–79. doi:10.1097/00001756-199905140-00015. PMID10380965.
^Chochon F.; Cohen L.; van de Moortele P.F.; Dehaene S. (1999). "Differential contributions of the left and right inferior parietal lobules to number processing". Journal of Cognitive Neuroscience. 11 (6): 617–630. doi:10.1162/089892999563689. PMID10601743. S2CID7960805.
^Dehaene S.; Naccache L.; Cohen L.; LeBihan D.; Mangin J.F.; Poline J.-B.; Rivière D. (2001). "Cerebral mechanisms of word masking and unconscious repetition priming". Nature Neuroscience. 4 (7): 752–758. doi:10.1038/89551. PMID11426233. S2CID16817321.
^Sergent C.; Baillet S.; Dehaene S. (2005). "Timing of the brain events underlying access to consciousness during the attentional blink". Nature Neuroscience. 8 (10): 1285–86. doi:10.1038/nn1549. PMID16158062. S2CID7190211.
^Meyen, S., Zerweck, I. A., Amado, C., von Luxburg, U., & Franz, V. H. (2021, July 15). Advancing Research on Unconscious Priming: When Can Scientists Claim an Indirect Task Advantage?. Journal of Experimental Psychology: General. Advance online publication. http://dx.doi.org/10.1037/xge0001065