A STUDY OF EXTRACELLULAR SPACE IN CENTRAL NERVOUS TISSUE BY FREEZE-SUBSTITUTION

doi:10.1083/jcb.25.1.117

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A STUDY OF EXTRACELLULAR SPACE IN CENTRAL NERVOUS TISSUE BY FREEZE-SUBSTITUTION

A. Van Harreveld M.D.¹, Jane Crowell Ph.D.¹, and S. K. Malhotra D.Phil.¹

¹ From the Kerckhoff Laboratories of the Biological Sciences, California Institute of Technology, Pasadena, California

It was attempted to preserve the water distribution in centralnervous tissue by rapid freezing followed by substitution fixationat low temperature. The vermis of the cerebellum of white micewas frozen by bringing it into contact with a polished silvermirror maintained at a temperature of about -207°C. Thetissue was subjected to substitution fixation in acetone containing2 per cent OsO₄ at -85°C for 2 days, and then preparedfor electron microscopy by embedding in Maraglas, sectioning,and staining with lead citrate or uranyl acetate and lead. Cerebellumfrozen within 30 seconds of circulatory arrest was comparedwith cerebellum frozen after 8 minutes' asphyxiation. From impedancemeasurements under these conditions, it could be expected thatin the former tissue the electrolyte and water distributionis similar to that in the normal, oxygenated cerebellum, whereasin the asphyxiated tissue a transport of water and electrolytesinto the intracellular compartment has taken place. Electronmicrographs of tissue frozen shortly after circulatory arrestrevealed the presence of an appreciable extracellular spacebetween the axons of granular layer cells. Between glia, dendrites,and presynaptic endings the usual narrow clefts and even tightjunctions were found. Also the synaptic cleft was of the usualwidth (250 to 300 A). In asphyxiated tissue, the extracellularspace between the axons is either completely obliterated (tightjunctions) or reduced to narrow clefts between apposing cellsurfaces.

Submitted on January 30, 1964

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