Microbial growth patterns described by fractal geometry.

Fractal geometry has made important contributions to understanding the growth of inorganic systems in such processes as aggregation, cluster formation, and dendritic growth. In biology, fractal geometry was previously applied to describe, for instance, the branching system in the lung airways and the backbone structure of proteins as well as their surface irregularity. This investigation applies the fractal concept to the growth patterns of two microbial species, Streptomyces griseus and Ashbya gossypii.

Detection of acid-beta-galactosidase activity in viable human fibroblasts by flow cytometry.

The fluorogenic substrate fluorescein-di-beta-D-galactopyranoside was used to detect acid beta-galactosidase in intact cultured human fibroblasts. The accumulation of intracellular fluorescein, as measured by flow cytophotometry was linear with the incubation time in three control strains. The two fibroblast strains from patients with acid beta-galactosidase deficiency did not show an accumulation of intracellular fluorescence.

The organism as bioreactor. Interpretation of the reduction law of metabolism in terms of heterogeneous catalysis and fractal structure.

Organisms and bioreactors are open, dissipative systems in steady state. They are functionally equivalent with respect to turnover and kinetics, and structurally analogous with respect to fractal organization and self-similar scaling. As heterogeneous catalytic systems both are governed by interaction of mass transport and reaction.