The life cycle of most marine invertebrates includes a planktonic larval
stage before metamorphosis to bottom-dwelling adulthood. During larval stage,
ciliary-mediated activity enables feeding (capture unicellular algae) and
transport of materials (oxygen) required for the larva's growth, development,
and successful metamorphosis. Investigating the underlying hydrodynamics of
these behaviors is valuable for addressing fundamental biological questions
(e.g., phenotypic plasticity) and advancing engineering applications. In this
work, we combined microfluidics and fluorescence microscopy as a miniaturized
PIV (mPIV) to study ciliary-medicated hydrodynamics during suspension feeding
in sand dollar larvae (Dendraster excentricus). First, we confirmed the
approach's feasibility by examining the underlying hydrodynamics (vortex
patterns) for low- and high-fed larvae. Next, ciliary hydrodynamics were
tracked from 11 days post-fertilization (DPF) to 20 DPF for 21 low-fed larvae.
Microfluidics enabled the examination of baseline activities (without external
flow) and behaviors in the presence of environmental cues (external flow). A
library of qualitative vortex patterns and quantitative hydrodynamics was
generated and shared as a stand alone repository. Results from mPIV
(velocities) were used to examine the role of ciliary activity in transporting
materials (oxygen). Given the laminar flow and the viscosity-dominated
environments surrounding the larvae, overcoming the diffusive boundary layer is
critical for the organism's survival. Peclet number analysis for oxygen
transport suggested that ciliary velocities help overcome the diffusion
dominated transport (max Pe numbers between 30-60). Microfluidics serving as
mPIV provided a scalable and accessible approach for investigating the ciliary
hydrodynamics of marine organisms.Comment: 21 pages and 11 figures (videos not included