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Literature DB >> 1034287

The optical spike. Structure of the olfactory nerve of pike and rapid birefringence changes during excitation.

Abstract

1. Electron microscope studies on the olfactory nerve of the pike revealed a population of 4.2 million, densely packed unmyelinated nerve fibres; 95% are small fibres (average diameter 0.19 mum, narrow modal class), 5% are larger (average diameter 0.6 mum). Each fibre is bounded by an axonal membrane with a bilayer structure (80 A thickness). 2. The olfactory nerve is birefringent (negative with respect to fibre axis) and shows at 20 degrees C an average retardation R = 23 mn. The birefringence becomes more negative on lowering the temperature. 3. With the passage of an action potential a rapid, transient increase of retardation--the optical spike-- occurs; deltaR = 0.04 nm. The optical spike corresponds to the time course of structural changes in the axon membrane during excitation; it begins later, peaks earlier and decays more quickly than the voltage changes as recorded externally in the present study.

Entities: Disease Gene

Mesh：

Year: 1976 PMID： 1034287 DOI： 10.1007/BF00583658

Source DB: PubMed Journal: Pflugers Arch ISSN： 0031-6768 Impact factor: 3.657

20 in total

1. Simultaneous changes in fluorescence and optical retardation in single muscle fibres during activity.

Authors: H Oetliker; S M Baylor; W K Chandler
Journal: Nature Date: 1975-10-23 Impact factor: 49.962

2. Birefringence experiments on isolated skeletal muscle fibres suggest a possible signal from the sarcoplasmic reticulum.

Authors: S M Baylor; H Oetliker
Journal: Nature Date: 1975-01-10 Impact factor: 49.962

3. The movement of potassium ions during electrical activity, and the kinetics of the recovery process, in the non-myelinated fibres of the garfish olfactory nerve.

Authors: J M Ritchie; R W Straub
Journal: J Physiol Date: 1975-07 Impact factor: 5.182

The optical spike. Structure of the olfactory nerve of pike and rapid birefringence changes during excitation.

1. Simultaneous changes in fluorescence and optical retardation in single muscle fibres during activity.

2. Birefringence experiments on isolated skeletal muscle fibres suggest a possible signal from the sarcoplasmic reticulum.

3. The movement of potassium ions during electrical activity, and the kinetics of the recovery process, in the non-myelinated fibres of the garfish olfactory nerve.

4. [Optical study of the change in the structure of nerve membrane during nerve impulse propagation].

5. Changes in fluorescence, turbidity, and birefringence associated with nerve excitation.

6. Evidence for structural changes during the action potential in nerves from the walking legs of Maia squinado.

7. Merocyanine 540 as an optical probe of transmembrane electrical activity in the heart.

8. Analysis of the potential-dependent changes in optical retardation in the squid giant axon.

9. Light scattering and birefringence changes during activity in the electric organ of electrophorus electricus.

10. Olfactory nerve fibers.

1. General morphology and axonal ultrastructure of the olfactory nerve of the pike, Esox lucius.

2. Birefringence signals and tension development in single frog muscle fibres at short stimulus intervals.

Review 3. 'Action substances' of peripheral nerve re-visited.

4. Birefringence Changes of Dendrites in Mouse Hippocampal Slices Revealed with Polarizing Microscopy.

5. Raman spectroscopy of nerve fibers. A study of membrane lipids under steady state conditions.

6. Temperature dependence of the fluorescence of pyrene labeled crab nerve membranes.

7. Components of the plasma membrane of growing axons. I. Size and distribution of intramembrane particles.

8. Components of the plasma membrane of growing axons. III. Saxitoxin binding to sodium channels.