Kimberly C. Stone scite author profile

Allometric studies have shown that lung volume, alveolar surface area, and diffusing capacity increase proportionally with body weight across a broad range of mammalian species. Changes in the number of cells and in average cell size and surface areas with increasing body weight have not been defined. We speculated that cell size is determined more by cell function than by species and body weight. To test this hypothesis, nine species ranging in size from shrew (2 to 3 g) to horse (510 kg) were studied. Random sites from the distal alveolar region of each species were analyzed using morphometric techniques. Six to 10 nuclei from each of the major classes of parenchymal lung cells were three-dimensionally reconstructed to determine their average diameter, volume, and surface area. To calculate the cell density, nuclear profiles were counted using electron microscopy. The number of cells per lung increased with body mass and lung volume with a slope of 1.01 (r2 = 0.99). The lung is unique among organs in the diversity and function of individual cell types, such as mechanical, sensory, secretory, transporting, and circulating cells. Excluding the circulatory cells, the lung has greater than 60 different cell types, making it an ideal organ for examining the varieties in cell characteristics across different species. Up to 6-fold differences in size were found between different lung cell types within a single species; however, for cells having secretory functions, such as type II cells, there was no detectable change in cell size with increasing lung surface area or body mass.(ABSTRACT TRUNCATED AT 250 WORDS)

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Distribution of Lung Cell Numbers and Volumes between Alveolar and Nonalveolar Tissue

Stone¹,

Mercer²,

Freeman³

et al. 1992

Am Rev Respir Dis

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Although total cell number has been determined for the alveolar region of the lungs of many species, it has not been calculated for the nonalveolar lung tissues. The oriented structure of airways and vessels makes the numerical assessment of cells in nonalveolar tissues difficult. This has led many investigators to use the number of cells in the alveolar region as a direct estimate of total lung cell number. To determine the number of cells in the nonalveolar lung tissues, the lungs of eight rats weighing 230 to 380 g were inflation-fixed and embedded in araldite, and 1.5-microns serial sections of the entire left lobe were cut and stained with methylene blue for light microscopy. The sections were then uniformly point-counted using computer-controlled distances between the fields to determine the fraction of points falling on air, blood, cellular tissue, and noncellular tissue for both the alveolar and the nonalveolar regions. The total volume of cell nuclei in each compartment was determined, and the total number of cells was calculated by dividing the total nuclear volume by the mean cell nuclear volume. It was found that 87% of the lung volume was alveolar, of which 6% was tissue and contained 725 x 10(6) cells. The nonalveolar region constituted 13% of the lung volume, of which 23% was tissue and contained 250 x 10(6) cells. The average rat lung therefore contains 975,000,000 cells, of which 74% was in alveolar tissues and 26% in nonalveolar tissues. On the basis of assays of isolated lung cells, there is an average of 7 pg DNA/cell.(ABSTRACT TRUNCATED AT 250 WORDS)

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Fast axonal transport is required for growth cone advance

Martenson

Stone

Reedy

et al. 1993

Nature

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Growth cones are capable of advancing despite linkage to a stationary axonal cytoskeleton in chick and murine dorsal root ganglion neurites. Several lines of evidence point to the growth cone as the site of cytoskeletal elongation. Fast axonal transport is probably the means by which cytoskeletal elements or cofactors are rapidly moved through the axon. We report that direct, but reversible, inhibition of fast axonal transport with laser optical tweezers inhibits growth cone motility if cytoskeletal attachment to the cell body is maintained. Advancement ceases after a distance-dependent lag period which correlates with the rate of fast axonal transport. But severing the axonal cytoskeleton with the laser tweezers allows growth cones to advance considerably further. We suggest that axon elongation requires fast axonal transport but growth cone motility does not.

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Kimberly C. Stone

Allometric Relationships of Cell Numbers and Size in the Mammalian Lung

Distribution of Lung Cell Numbers and Volumes between Alveolar and Nonalveolar Tissue

Fast axonal transport is required for growth cone advance

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