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RIS BIB ENDNOTEData publikacji: 26.11.2014
Rocznik Kognitywistyczny, 2014, Tom 7, s. 9 - 20
https://doi.org/10.4467/20843895RK.14.003.2689Autorzy
Describing consciousness on scale from zero to one. Perturbational Complexity Index as a scientific attempt on measuring consciousness on an individual level
Scientific study of consciousness entered a new era with research focused on finding its neural correlates. The article depicts reasoning underlying this paradigm and controversies it arises using a novel tool designed to measure one’s level of consciousness by means of analyzing EEG signal. Perturbational Complexity Index, created by team led by Guilio Tononi, is used to present theoretical debate concerning the possibility of creating an objective consciousness measure. Stemming from reflections on mechanisms of loss of consciousness, authors of the index infer the informational nature of the phenomena, which is said to be demonstrated by experiments with participants under anesthesia, in deep sleep or suffering from disorders of consciousness. The extraordinary capability of the index to measure the level of consciousness on an individual level and its practical applications are discussed in context of possibility of experimental access to subjective experience.
BIBLIOGRAFIA
Alkire M.T., Hudetz A.G., Tononi G. (2008). Consciousness and anesthesia. „Science” 322 (5903), s. 876–880.
Boly M., Garrido M.I., Gosseries O., Bruno M.-A., Boveroux P., Schnakers C., Friston K. (2011). Preserved feedforward but impaired top-down processes in the vegetative state. „Science” 332 (6031), s. 858–862.
Boly M., Moran R., Murphy M., Boveroux P., Bruno M.-A., Noirhomme Q., Friston K. (2012). Connectivity changes underlying spectral EEG changes during propofol-induced loss of consciousness. „The Journal of Neuroscience: the official journal of the Society for Neuroscience” 32 (20), s. 7082–7090.
Casali A.G., Gosseries O., Rosanova M., Boly M., Sarasso S., Casali K.R., Massimini M. (2013). A theoretically based index of consciousness independent of sensory processing and behavior. „Science Translational Medicine” 5 (198).
Chalmers D.J. (1998). On the search for the neural correlate of consciousness [w:] S.R. Hameroff, A.V. Kaszniak, A. Scott (red.), Toward a Science of Consciousness II: The Second Tucson Discussions and Debates (s. 219–229). Cambridge: MIT Press.
Crick F., Koch C. (1990). Towards a neurobiological theory of consciousness. „Seminars in the Neurosciences” 2, s. 263–275.
Dehaene S. (2008). Distinct forms of evidence accumulation? [w:] Ch. Engel, W. Singer (red.), Better Than Conscious?: Decision Making, the Human Mind, and Implications for Institutions. Cambridge: MIT Press.
Edelman G.M. (2003). Naturalizing consciousness: a theoretical framework. „Proceedings of the National Academy of Sciences of the United States of America” 100 (9), s. 5520–5524. doi:10.1073/pnas.0931349100.
Edelman G.M., Tononi G. (2000). A Universe of Consciousness: How Matter Becomes Imagination. New York: Basic Books.
Ferrarelli F., Massimini M., Sarasso S., Casali A., Riedner B.A., Angelini G., Pearce R.A. (2010). Breakdown in cortical effective connectivity during midazolam-induced loss of consciousness. „Proceedings of the National Academy of Sciences of the United States of America” 107 (6), s. 2681–2686.
Holender D. (1986). Semantic activation without conscious identification in dichotic listening, parafoveal vision, and visual masking: A survey and appraisal. „Behavioral and Brain Sciences”
9 (01), s. 1–23.
Johnson R.W. (1987). Relative-entropy minimization with uncertain constraints: Theory and application to spectrum analysis [w:] C.R. Smith, G.J. Erickson (red.), Maximum-Entropy and Bayesian Spectral Analysis and Estimation Problems (s. 57–73). Springer Netherlands.
Kales A., Rechtschaffen A. (1968). A Manual of Standardized Terminology, Techniques and Scoring System for Sleep Stages of Human Subjects. U.S. National Institute of Neurological Diseases and Blindness, Neurological Information Network.
Maniscalco B., Lau H. (2012). A signal detection theoretic approach for estimating metacognitive sensitivity from confidence ratings. „Consciousness and Cognition” 21 (1), s. 422–430.
Massimini M., Ferrarelli F., Esser S.K., Riedner B.A., Huber R., Murphy M., Tononi G. (2007). Triggering sleep slow waves by transcranial magnetic stimulation. „Proceedings of the National Academy of Sciences of the United States of America” 104 (20), s. 8496–8501.
Massimini M., Ferrarelli F., Huber R., Esser S.K., Singh H., Tononi G. (2005). Breakdown of cortical effective connectivity during sleep. „Science” 309 (5744), s. 2228–2232.
Massimini M., Ferrarelli F., Murphy M., Huber R., Riedner B.A., Casarotto S., Tononi G. (2010). Cortical reactivity and effective connectivity during REM sleep in humans. „Cognitive Neuroscience” 1 (3), s. 176–183.
Miller G. (2005). What is the biological basis of consciousness? „Science” 309 (5731), s. 79.
Noirhomme Q., Soddu A., Lehembre R., Vanhaudenhuyse A., Boveroux P., Boly M., Laureys S. (2010). Brain connectivity in pathological and pharmacological coma. „Frontiers in Systems Neuroscience” 4. doi: 10.3389/fnsys.2010.00160.
Pincus D.S.M., Gladstone I.M., Ehrenkranz R.A. (1991). A regularity statistic for medical data analysis. „Journal of Clinical Monitoring” 7 (4), s. 335–345.
Plourde G., Picton T.W. (1991). Long-latency auditory evoked potentials during general anesthesia: N1 and P3 components. „Anesthesia and Analgesia” 72 (3), s. 342–350.
Ragazzoni A., Pirulli C., Veniero D., Feurra M., Cincotta M., Giovannelli F., Miniussi C. (2013). Vegetative versus minimally conscious states: a study using TMS-EEG, sensory and event-related potentials. „PloS one” 8 (2). doi: 10.1371/journal.pone.0057069.
Rosanova M., Gosseries O., Casarotto S., Boly M., Casali A.G., Bruno M.-A., Massimini M. (2012). Recovery of cortical effective connectivity and recovery of consciousness in vegetative patients. „Brain: A Journal of Neurology” 135 (Pt 4), s. 1308–1320.
Rosow C., Manberg P.J. (2001). Bispectral index monitoring. „Anesthesiology Clinics of North America” 19 (4), s. 947–966.
Sarasso S., Rosanova M., Casali A.G., Casarotto S., Fecchio M., Boly M., Massimini M. (2014). Quantifying cortical EEG responses to TMS in (un)consciousness. „Clinical EEG and Neuroscience” 45 (1), s. 40–49.
Searle J.R. (1999). Umysł, język, społeczeństwo: filozofia i rzeczywistość. Warszawa: Wydawnictwo CiS.
Sitt J.D., King J.-R., Naccache L., Dehaene S. (2013). Ripples of consciousness. „Trends in Cognitive Sciences” 17 (11), s. 552–554.
Tononi G. (2004). An information integration theory of consciousness. „BMC Neuroscience” 5 (1), s. 42.
Tononi G. (2008). Consciousness as integrated information: A provisional manifesto. „The Biological Bulletin” (December), s. 216–242.
Tononi G. (2010). Information integration: its relevance to brain function and consciousness. „Archives Italiennes de Biologie” 148 (3), s. 299–322.
Vermeiren A., Cleeremans A. (2012). The validity of d’ measures. „PloS one” 7 (2), e31595. doi: 10.1371/journal.pone.0031595.
Wierzchoń M. (2013). Granice świadomości. Kraków: Wydawnictwo Uniwersytetu Jagiellońskiego.
Wierzchoń M., Asanowicz D., Paulewicz B., Cleeremans A. (2012). Subjective measures of consciousness in artificial grammar learning task. „Consciousness and Cognition” 21 (3), s. 1141–1153.
Informacje: Rocznik Kognitywistyczny, 2014, Tom 7, s. 9 - 20
Typ artykułu: Oryginalny artykuł naukowy
Tytuły:
Instytut Psychologii, Uniwersytet Jagielloński w Krakowie, ul. Ingardena 6, 30-060 Kraków
Instytut Psychologii, Uniwersytet Jagielloński w Krakowie, ul. Ingardena 6, 30-060 Kraków
Publikacja: 26.11.2014
Status artykułu: Otwarte
Licencja: Żadna
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