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200 10$aExtrasensory perception$b[electronic resource] $ea Ciba Foundation Symposium /$feditors for the Ciba Foundation, G.E.W. Wolstenholme and Elaine C.P. Millar
205   $a[1st paperbound ed.].
210   $aNew York $cCitadel Press$d[1966, c1956]
215   $a1 online resource (254 p.)
225 1 $aCiba Foundation symposium
300   $aFirst ed. published in 1956 under title: Ciba Foundation symposium on extrasensory perception.
311   $a0-470-72239-8 
320   $aIncludes bibliographical references and indexes.
327   $aEXTRASENSORY PERCEPTION; CONTENTS; Chairman's opening remarks; The nature of the laboratory evidence for extrasensory perception; The strength and weakness of the available evidence for extrasensory perception; Some difficulties in the way of scientific recognition of extrasensory perception; Discussion; An outline of a field theory of organismic form and behaviour; The data of psychical research: a study of three hypotheses; Some statistical aspects of extrasensory perception research; Discussion; Psychical phenomena among primitive peoples
327   $aExtrasensory perception among peasant European populationsDiscussion; A case of pseudo-ESP; The simulation of telepathy; Discussion; The sensory nature of bird navigation; Testing for an ESP factor in pigeon homing;  requirements, attempts and difficulties; Discussion; Parapsychology in the modern approach to psychosomatic man; Discussion; Experiences suggestive of paranormal cognition in the psycho-analytic situation; Discussion; General Discussion
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200 00$aNeuronal Mechanics and Transport
210   $cFrontiers Media SA$d2016
215   $a1 online resource (212 p.)
225 1 $aFrontiers Research Topics
311 08$a2-88919-823-5 
330   $aUnderstanding the underlying mechanisms of how axons and dendrites develop is a fundamental problem in neuroscience and a main goal of research on nervous system development and regeneration. Previous studies have provided a tremendous amount of information on signaling and cytoskeletal proteins regulating axonal and dendritic growth and guidance. However, relatively little is known about the relative contribution and role of cytoskeletal dynamics, transport of organelles and cytoskeletal components, and force generation to axonal elongation. Advancing the knowledge of these biomechanical processes is critical to better understand the development of the nervous system, the pathological progression of neurodegenerative diseases, acute traumatic injury, and for designing novel approaches to promote neuronal regeneration following disease, stroke, or trauma. Mechanical properties and forces shape the development of the nervous system from the cellular up to the organ level. Recent advances in quantitative live cell imaging, biophysical, and nanotechnological methods such as traction force microscopy, optical tweezers, and atomic force microscopy have enabled researchers to gain better insights into how cytoskeletal dynamics and motor-driven transport, membrane-dynamics, adhesion, and substrate rigidity influence axonal elongation. Given the complexity and mechanical nature of this problem, mathematical modeling contributes significantly to our understanding of neuronal mechanics. Nonetheless, there has been limited direct interaction and discussions between experimentalists and theoreticians in this research area. The purpose of this Frontiers Research Topic is to highlight exciting and important work that is currently developing in the fields of neuronal cell biology, neuronal mechanics, intracellular transport, and mathematical modeling in the form of primary research articles, reviews, perspectives, and commentaries.
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610   $aAxonal elongation
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700   $aKyle E. Miller$4auth$01331949
702   $aDaniel M. Suter$4auth
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