A comparative fractal analysis of various mammalian astroglial cell types

Camera-lucida drawings of Golgi-impregnated astroglial cells and their processes are described by the fractal dimension of their borders, which is an objective, quantitative measure of morphological complexity. Protoplasmic astrocytes from human neocortex have fractal dimensions (D) that are larger than those of fibrous astrocytes from the cat optic nerve. Marginal astrocytes from monkey cerebropontile angle have two kinds of processes: (1) short, thick processes with endfeet abutting the pial surface, with relatively high D's, and (2) very long, thin processes extending into the neuronal tissue, with very low D's. These data indicate that short astrocytic processes may have a complex surface (and have a high D), whereas long processes are rather smooth (and have a low D). A comparison between transmission electron microscopy morphometry and measures of D at the light microscopic level, performed on different parts of rabbit retinal Müller glial cells, suggests that D is strongly correlated to the surface-to-volume ratio which, in part, determines the length constant of a cable for core-conductance of currents. We provide data supporting the hypothesis that astroglial cell geometry is adjusted to allow for sufficient spatial buffering K+ currents, even through very long processes.

[1]  W. B. Marks,et al.  A fractal analysis of cell images , 1989, Journal of Neuroscience Methods.

[2]  P. Brust,et al.  Potassium as a signal for both proliferation and differentiation of rabbit retinal (Müller) glia growing in cell culture. , 1989, Cellular signalling.

[3]  A. Reichenbach,et al.  Quantitative electron microscopy of rabbit Müller (glial) cells in dependence on retinal topography. , 1988, Zeitschrift fur mikroskopisch-anatomische Forschung.

[4]  Benoit B. Mandelbrot,et al.  Fractal Geometry of Nature , 1984 .

[5]  W. B. Marks,et al.  Edge detection in images using Marr-Hildreth filtering techniques , 1988, Journal of Neuroscience Methods.

[6]  W. B. Marks,et al.  A fractal analysis of cultured rat optic nerve glial growth and differentiation , 1991, Neuroscience.

[7]  E. Sykova Extracellular K+ Accumulation in the Spinal Cord , 1981 .

[8]  K. E. Rasmussen A morphometric study of the Müller cells, their nuclei and mitochondria, in the rat retina. , 1973, Journal of ultrastructure research.

[9]  A. Gardner-Medwin,et al.  Analysis of potassium dynamics in mammalian brain tissue. , 1983, The Journal of physiology.

[10]  Eldred,et al.  Physical mechanisms underlying neurite outgrowth: A quantitative analysis of neuronal shape. , 1990, Physical review letters.

[11]  R. Porter,et al.  A fractal analysis of pyramidal neurons in mammalian motor cortex , 1991, Neuroscience Letters.

[12]  M. J. Friedlander,et al.  Morphogenesis and territorial coverage by isolated mammalian retinal ganglion cells , 1991, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[13]  A. Reichenbach,et al.  Postnatal development of radial glial (Müller) cells of the rabbit retina , 1986, Neuroscience Letters.

[14]  A. G. Flook The use of dilation logic on the quantimet to achieve fractal dimension characterisation of textured and structured profiles , 1978 .

[15]  E. B. George,et al.  Fractals and the analysis of growth paths , 1985, Bulletin of mathematical biology.

[16]  Andriezen Wl,et al.  The Neuroglia Elements in the Human Brain , 1893 .

[17]  O B Paulson,et al.  Does the release of potassium from astrocyte endfeet regulate cerebral blood flow? , 1987, Science.

[18]  E. Newman,et al.  Control of extracellular potassium levels by retinal glial cell K+ siphoning. , 1984, Science.