RESUMO
Flow cytometry is used to measure dilution-induced changes in the optical properties of Dunaliella tertiolecta-light scatter, cell fluorescence, and refractive index. Observed changes in cell optical properties are compared to simultaneous measures of cell volume and count, extracted chlorophyll a concentration, and the (14)C uptake rate. Flow cytometric measurements reveal short-term dilution effects (within 1 h of dilution) that, are not evident in other morphological or physiological measurements such as cell volume, extracted chlorophyll a concentration, and (14)C uptake rate. Data are presented which suggest that these short-term changes in cell optical properties are the result of changes in the real component of refractive index, possibly due to a rapid and temporary rearrangement of the internal cellular structure. Long-term changes are observed in time series measurements of cell volume and count, extracted chlorophyll a concentration, and (14)C uptake rate.
RESUMO
Flow cytometric measurements of light scatter, near-forward light scatter (theta = 1.5-19 degrees ) and side scatter (theta = 73-107 degrees ), from individual marine particles is modeled using Mie theory. Particles are assumed to be homogeneous and nearly spherical in shape. Uniform polystyrene microspheres and oil suspensions are used to estimate model accuracy. Within the particle diameter range of 1-32 microm, the mean error for near-forward scatter and side scatter is 16.9% and 30.1%. respectively. The model is used to estimate size and refractive index of several nannoplankton species and the results are compared with microscopic measurements of cell size and published values of phytoplankton refractive index. Within the refractive-index range of 1.01-1.1, the model may be inverted to yield refractive index with an absolute error of between 0.01 and 0.003. Measurements of particle size distributions in clear ocean water indicate this range accounts for 99% of all nannoplankton and 39% of all particles within the size range from 1 to 10 microm.
