Access the full text.
Sign up today, get DeepDyve free for 14 days.
Loading next page...
/lp/springer-journals/musical-representation-of-dendritic-spine-distribution-a-new-8bZb6jlDXE
References (36)
-
(Mindy, H., & Chang, G.W.J.B. (2010). Sonification and visualization of neural data. In Proceedings for international conference on auditory display. Washington D.C.: EE.UU.)
Mindy, H., & Chang, G.W.J.B. (2010). Sonification and visualization of neural data. In Proceedings for international conference on auditory display. Washington D.C.: EE.UU.Mindy, H., & Chang, G.W.J.B. (2010). Sonification and visualization of neural data. In Proceedings for international conference on auditory display. Washington D.C.: EE.UU., Mindy, H., & Chang, G.W.J.B. (2010). Sonification and visualization of neural data. In Proceedings for international conference on auditory display. Washington D.C.: EE.UU.
-
(2006)
Organization of spines on the dendrites of purkinje cellsProceedings of the National Academy of Sciences of the United States of America, 103
-
(2008)
Pyramidal neurons: dendritic structure and synaptic integrationNature Reviews Neuroscience, 9
-
(Morales, J., Benavides-Piccione, R., Rodríguez, A., Pastor, L., Yuste, R., DeFelipe, J. (2012). Three-dimensional analysis of spiny dendrites using straightening and unrolling transforms. Neuroinformatics, 17. doi:10.1007/s12021-012-9153-2.)
Morales, J., Benavides-Piccione, R., Rodríguez, A., Pastor, L., Yuste, R., DeFelipe, J. (2012). Three-dimensional analysis of spiny dendrites using straightening and unrolling transforms. Neuroinformatics, 17. doi:10.1007/s12021-012-9153-2.Morales, J., Benavides-Piccione, R., Rodríguez, A., Pastor, L., Yuste, R., DeFelipe, J. (2012). Three-dimensional analysis of spiny dendrites using straightening and unrolling transforms. Neuroinformatics, 17. doi:10.1007/s12021-012-9153-2., Morales, J., Benavides-Piccione, R., Rodríguez, A., Pastor, L., Yuste, R., DeFelipe, J. (2012). Three-dimensional analysis of spiny dendrites using straightening and unrolling transforms. Neuroinformatics, 17. doi:10.1007/s12021-012-9153-2.
-
(Leslie, G., & Mullen, T. (2011). Moodmixer: Eeg-based collaborative sonification. In A.R. Jensenius, A. Tveit, R.I. Godøy, D. Overholt (Eds.), Proceedings of the international conference on new interfaces for musical expression (pp. 296–299). Oslo, Norway.)
Leslie, G., & Mullen, T. (2011). Moodmixer: Eeg-based collaborative sonification. In A.R. Jensenius, A. Tveit, R.I. Godøy, D. Overholt (Eds.), Proceedings of the international conference on new interfaces for musical expression (pp. 296–299). Oslo, Norway.Leslie, G., & Mullen, T. (2011). Moodmixer: Eeg-based collaborative sonification. In A.R. Jensenius, A. Tveit, R.I. Godøy, D. Overholt (Eds.), Proceedings of the international conference on new interfaces for musical expression (pp. 296–299). Oslo, Norway., Leslie, G., & Mullen, T. (2011). Moodmixer: Eeg-based collaborative sonification. In A.R. Jensenius, A. Tveit, R.I. Godøy, D. Overholt (Eds.), Proceedings of the international conference on new interfaces for musical expression (pp. 296–299). Oslo, Norway.
-
(1985)
Sound graphs: a numerical data analysis method for the blindJournal of Medical Systems, 9
-
FB Vialatte, CFV Latchoumane, NR Hudson, S Wimalaratna, J Solé-Casals, J Jeong, A Cichocki (2010)
BIOSIGNALS -
(1989)
Dendritic spines of CA1 pyramidal cells in the rat hippocampus: serial electron microscopy with reference to their biophysical characteristicsJournal of Neuroscience, 9
-
(2005)
Parametric orchestral sonification of eeg in real timeIEEE MultiMedia, 12
-
(Weinberg, G., & Thatcher, T. (2006). Interactive sonification of neural activity. In Proceedings of the 2006 conference on new interfaces for musical expression, IRCAM — (pp. 246–249). Paris: Centre Pompidou.)
Weinberg, G., & Thatcher, T. (2006). Interactive sonification of neural activity. In Proceedings of the 2006 conference on new interfaces for musical expression, IRCAM — (pp. 246–249). Paris: Centre Pompidou.Weinberg, G., & Thatcher, T. (2006). Interactive sonification of neural activity. In Proceedings of the 2006 conference on new interfaces for musical expression, IRCAM — (pp. 246–249). Paris: Centre Pompidou., Weinberg, G., & Thatcher, T. (2006). Interactive sonification of neural activity. In Proceedings of the 2006 conference on new interfaces for musical expression, IRCAM — (pp. 246–249). Paris: Centre Pompidou.
-
S Sadie, G Grove (1995c)
The new Grove dictionary of music and musicians, Limited ed. by Stanly Sadie edn -
(Benavides-Piccione, R., Fernaud-Espinosa, I., Robles, V., Yuste, R., DeFelipe, J. (2012). Age-based comparison of human dendritic spine structure using complete three-dimensional reconstructions. Cerebral Cortex. doi:10.1093/cercor/bhs154.)
Benavides-Piccione, R., Fernaud-Espinosa, I., Robles, V., Yuste, R., DeFelipe, J. (2012). Age-based comparison of human dendritic spine structure using complete three-dimensional reconstructions. Cerebral Cortex. doi:10.1093/cercor/bhs154.Benavides-Piccione, R., Fernaud-Espinosa, I., Robles, V., Yuste, R., DeFelipe, J. (2012). Age-based comparison of human dendritic spine structure using complete three-dimensional reconstructions. Cerebral Cortex. doi:10.1093/cercor/bhs154., Benavides-Piccione, R., Fernaud-Espinosa, I., Robles, V., Yuste, R., DeFelipe, J. (2012). Age-based comparison of human dendritic spine structure using complete three-dimensional reconstructions. Cerebral Cortex. doi:10.1093/cercor/bhs154.
-
(2000)
Regulation of spine calcium compartmentalization by rapid spine motilityJournal of Neuroscience, 20
-
(2007)
Non-synaptic dendritic spines in neocortexNeuroscience, 145
-
(Sadie, S., & Grove, G. (1995a). The new Grove dictionary of music and musicians (pp. 545–563, Vol. 17 of Sadie and Grove (The new Grove dictionary of music and musicians, Limited ed. by Stanly Sadie edn. Macmillan Publishers, London)).)
Sadie, S., & Grove, G. (1995a). The new Grove dictionary of music and musicians (pp. 545–563, Vol. 17 of Sadie and Grove (The new Grove dictionary of music and musicians, Limited ed. by Stanly Sadie edn. Macmillan Publishers, London)).Sadie, S., & Grove, G. (1995a). The new Grove dictionary of music and musicians (pp. 545–563, Vol. 17 of Sadie and Grove (The new Grove dictionary of music and musicians, Limited ed. by Stanly Sadie edn. Macmillan Publishers, London))., Sadie, S., & Grove, G. (1995a). The new Grove dictionary of music and musicians (pp. 545–563, Vol. 17 of Sadie and Grove (The new Grove dictionary of music and musicians, Limited ed. by Stanly Sadie edn. Macmillan Publishers, London)).
-
(1992)
The pyramidal neuron of the cerebral cortex: morphological and chemical characteristics of the synaptic inputsProgress in Neurobiology, 39
-
(1997)
The occipitoparietal pathway of the macaque monkey: comparison of pyramidal cell morphology in layer III of functionally related cortical visual areasCerebral Cortex, 7
-
(2000)
Mechanisms of calcium decay kinetics in hippocampal spines: role of spine calcium pumps and calcium diffusion through the spine neck in biochemical compartmentalizationJournal of Neuroscience, 20
-
(2009)
The allobrain: an interactive, stereographic, 3d audio, immersive virtual worldInternational Journal of Human Computer Studies, 67
-
(Wu, D., Shi, X., Hu, J., Lei, X., Liu, T., Yao, D.Z. (2011). Listen to the song of the brain in real time: the Chengdu brainwave music. In NFSI & ICBEM conference proceedings, IEEE (pp. 135–138). doi:10.1109/NFSI.2011.5936836.)
Wu, D., Shi, X., Hu, J., Lei, X., Liu, T., Yao, D.Z. (2011). Listen to the song of the brain in real time: the Chengdu brainwave music. In NFSI & ICBEM conference proceedings, IEEE (pp. 135–138). doi:10.1109/NFSI.2011.5936836.Wu, D., Shi, X., Hu, J., Lei, X., Liu, T., Yao, D.Z. (2011). Listen to the song of the brain in real time: the Chengdu brainwave music. In NFSI & ICBEM conference proceedings, IEEE (pp. 135–138). doi:10.1109/NFSI.2011.5936836., Wu, D., Shi, X., Hu, J., Lei, X., Liu, T., Yao, D.Z. (2011). Listen to the song of the brain in real time: the Chengdu brainwave music. In NFSI & ICBEM conference proceedings, IEEE (pp. 135–138). doi:10.1109/NFSI.2011.5936836.
-
R Yuste (2010)
Dendritic spines -
(Jourdain, R. (2001). Das wohltemperiente Gehirn: Wie Musik im Kopf entsteht und wirkt. Heidelberg: Akademischer Verlag GmbH. (orig. Music, the Brain, and Ecstasy. William Morrow and Company, Inc. New York 1997).)
Jourdain, R. (2001). Das wohltemperiente Gehirn: Wie Musik im Kopf entsteht und wirkt. Heidelberg: Akademischer Verlag GmbH. (orig. Music, the Brain, and Ecstasy. William Morrow and Company, Inc. New York 1997).Jourdain, R. (2001). Das wohltemperiente Gehirn: Wie Musik im Kopf entsteht und wirkt. Heidelberg: Akademischer Verlag GmbH. (orig. Music, the Brain, and Ecstasy. William Morrow and Company, Inc. New York 1997)., Jourdain, R. (2001). Das wohltemperiente Gehirn: Wie Musik im Kopf entsteht und wirkt. Heidelberg: Akademischer Verlag GmbH. (orig. Music, the Brain, and Ecstasy. William Morrow and Company, Inc. New York 1997).
-
(Garey, L. (1994). Brodmann’s localisation in the cerebral cortex. London, UK: Imperial College Press.)
Garey, L. (1994). Brodmann’s localisation in the cerebral cortex. London, UK: Imperial College Press.Garey, L. (1994). Brodmann’s localisation in the cerebral cortex. London, UK: Imperial College Press., Garey, L. (1994). Brodmann’s localisation in the cerebral cortex. London, UK: Imperial College Press.
-
(1998)
Cell type and pathway dependence of synaptic ampa receptor number and variability in the hippocampusNeuron, 21
-
(1999)
Quantitative fine-structural analysis of olfactory cortical synapsesProceedings of the National Academy of Sciences of the United States of America, 96
-
(2006)
The spine neck filters membrane potentialsProceedings of the National Academy of Sciences of the United States of America, 103
-
(2003)
Activity-regulated dynamic behavior of early dendritic protrusions: evidence for different types of dendritic filopodiaJournal of Neuroscience, 23
-
(2007)
Ultrastructure of dendritic spines: correlation between synaptic and spine morphologiesFrontiers in Neuroscience, 1
-
(1888)
Estructura de los centros nerviosos de las avesRevista Trimestrasl de Histología Normal y Patológica, 1
-
(2001)
The pyramidal cell in cognition: a comparative study in human and monkeyJournal of Neuroscience, 21
-
(Kerlleñevich, H., Eguía, M.C., Riera, P.E. (2011). An open source interface based on biological neural networks for interactive music performance. In A.R. Jensenius, A. Tveit, R.I. Godøy, D. Overholt (Eds.), Proceedings of the international conference on new interfaces for musical expression (pp. 331–336). Oslo, Norway.)
Kerlleñevich, H., Eguía, M.C., Riera, P.E. (2011). An open source interface based on biological neural networks for interactive music performance. In A.R. Jensenius, A. Tveit, R.I. Godøy, D. Overholt (Eds.), Proceedings of the international conference on new interfaces for musical expression (pp. 331–336). Oslo, Norway.Kerlleñevich, H., Eguía, M.C., Riera, P.E. (2011). An open source interface based on biological neural networks for interactive music performance. In A.R. Jensenius, A. Tveit, R.I. Godøy, D. Overholt (Eds.), Proceedings of the international conference on new interfaces for musical expression (pp. 331–336). Oslo, Norway., Kerlleñevich, H., Eguía, M.C., Riera, P.E. (2011). An open source interface based on biological neural networks for interactive music performance. In A.R. Jensenius, A. Tveit, R.I. Godøy, D. Overholt (Eds.), Proceedings of the international conference on new interfaces for musical expression (pp. 331–336). Oslo, Norway.
-
(2010)
Structural dynamics of dendritic spines in memory and cognitionTrends in Neurosciences, 33
-
(2004)
Structural basis of long-term potentiation in single dendritic spinesNature, 429
-
(2010)
Alterations of cortical pyramidal neurons in mice lacking high-affinity nicotinic receptorsProceedings of the National Academy of Sciences of the United States of America, 107
-
(1999)
Perceptualization of biomedical data. An experimental environment for visualization and sonification of brain electrical activityEngineering in Medicine and Biology Magazine IEEE, 18
-
(2010)
Sparse bump modeling of mildad patients—modeling transient oscillations in the eeg of patients with mild alzheimer’s disease.BIOSIGNALS
- Publisher
- Springer Journals
- Copyright
- Copyright © 2014 by The Author(s)
- Subject
- Biomedicine; Neurosciences; Bioinformatics; Computational Biology/Bioinformatics; Computer Appl. in Life Sciences; Neurology
- ISSN
- 1539-2791
- eISSN
- 1559-0089
- DOI
- 10.1007/s12021-013-9195-0
- pmid
- 24395057
- Publisher site
- See Article on Publisher Site
Abstract
Dendritic spines are small protrusions along the dendrites of many types of neurons in the central nervous system and represent the major target of excitatory synapses. For this reason, numerous anatomical, physiological and computational studies have focused on these structures. In the cerebral cortex the most abundant and characteristic neuronal type are pyramidal cells (about 85 % of all neurons) and their dendritic spines are the main postsynaptic target of excitatory glutamatergic synapses. Thus, our understanding of the synaptic organization of the cerebral cortex largely depends on the knowledge regarding synaptic inputs to dendritic spines of pyramidal cells. Much of the structural data on dendritic spines produced by modern neuroscience involves the quantitative analysis of image stacks from light and electron microscopy, using standard statistical and mathematical tools and software developed to this end. Here, we present a new method with musical feedback for exploring dendritic spine morphology and distribution patterns in pyramidal neurons. We demonstrate that audio analysis of spiny dendrites with apparently similar morphology may “sound” quite different, revealing anatomical substrates that are not apparent from simple visual inspection. These morphological/music translations may serve as a guide for further mathematical analysis of the design of the pyramidal neurons and of spiny dendrites in general.
Journal
Neuroinformatics – Springer Journals
Published: Jan 7, 2014