Book contents
- Frontmatter
- Contents
- List of contributors
- Part I Introduction
- Part II Organization of neuronal activity in neuronal populations
- Part III Neuronal population information coding and plasticity in specific brain areas
- 7 Functional roles of theta and gamma oscillations in the association and dissociation of neuronal networks in primates and rodents
- 8 Theta rhythm and bidirectional plasticity in the hippocampus
- 9 Distributed population codes in sensory and memory representations of the neocortex
- 10 The role of neuronal populations in auditory cortex for category learning
- 11 The construction of olfactory representations
- Part IV Functional integration of different brain areas in information processing and plasticity
- Part V Disturbances of population activity as the basis of schizophrenia
- Part VI Summary, conclusion, and future targets
- Index
- References
11 - The construction of olfactory representations
Published online by Cambridge University Press: 14 August 2009
- Frontmatter
- Contents
- List of contributors
- Part I Introduction
- Part II Organization of neuronal activity in neuronal populations
- Part III Neuronal population information coding and plasticity in specific brain areas
- 7 Functional roles of theta and gamma oscillations in the association and dissociation of neuronal networks in primates and rodents
- 8 Theta rhythm and bidirectional plasticity in the hippocampus
- 9 Distributed population codes in sensory and memory representations of the neocortex
- 10 The role of neuronal populations in auditory cortex for category learning
- 11 The construction of olfactory representations
- Part IV Functional integration of different brain areas in information processing and plasticity
- Part V Disturbances of population activity as the basis of schizophrenia
- Part VI Summary, conclusion, and future targets
- Index
- References
Summary
Introduction
Sensory information progresses centrally from the primary sensors in the periphery to the central neural structures that derive relevant environmental information from these sensory data and determine appropriate physiological and behavioral responses. In this chapter, I present a general theory of early olfactory sensory processing in the primary olfactory epithelium and olfactory bulb (OB). The theory depicts olfactory sensory processing as a cascade of representations, each of which exhibits characteristic physical properties and is sampled by appropriate neural mechanisms in order to construct the subsequent representation. The primary olfactory representation is mediated by the activation pattern across the population of primary olfactory sensory neurons (OSNs) in the sensory epithelium. The secondary olfactory representation is similarly mediated by the activation pattern across the population of principal neurons immediately postsynaptic to the OSNs, known as mitral cells. (Mitral cell axons diverge dramatically, projecting to roughly ten different central structures within the brain; the resulting tertiary and subsequent olfactory representations are constructed outside the olfactory bulb and are not discussed at length herein.) The transformation between the primary and secondary representations is a robust, intricate, two-stage process that corrects for artefacts that can hinder the recognition of odor qualities, regulates stimulus selectivity, and transduces the underlying mechanics from a robust but costly rate-coding scheme on a slow respiratory (theta-band) timescale to a sparse dynamical representation operating on the beta- and gamma-band timescales and suitable for integration with other central neural processes.
- Type
- Chapter
- Information
- Information Processing by Neuronal Populations , pp. 247 - 280Publisher: Cambridge University PressPrint publication year: 2008
References
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