9---p An imaging-inflow system for automated analysis of marine microplankton

Present automated systems for counting and measunng marine plankton include flow cytometers and in situ plankton video recorders. Neither of these approaches are optimal for the microplankton cells which range in size from 20 to 200 pm and can be fewer than 104 1". We describe here an instrument designed for rapid counting, imaging and measuring of individual cells and particles in the microplankton size range from cultures and natural populations. It uses a unlque optical element to extend the depth of focus of the imaging lens, allowing a sample stream flow rate of 1 rnl min-'. The instrument stores a digital image of each particle along with real time fluorescence and size measurements. An interactive cytogram links a dot-plot of the size and fluorescence data to the stored cell images, allowing rapid characterization of populations. We have tested the system on live phytoplankton cultures and bead standards, proving the system counting and slzlng accuracy and precision. The system provides Images and size distributions for cultures or natural manne samples. It has been used successfully at sea to continuously monitor particles while underway. It may prove useful in s tud~es of plankton community structure, ocean optics and monitoring for harmful algal species.

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