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Microfluidics for Hydrodynamics Investigations of Sand Dollar Larvae (2401.00056v1)

Published 29 Dec 2023 in physics.bio-ph, physics.flu-dyn, and q-bio.QM

Abstract: 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.

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References (46)
  1. Richard R Strathmann. The feeding behavior of planktotrophic echinoderm larvae: mechanisms, regulation, and rates of suspensionfeeding. Journal of Experimental Marine Biology and Ecology, 6(2):109–160, 1971.
  2. Robert K Cowen and Su Sponaugle. Larval dispersal and marine population connectivity. Annual review of marine science, 1:443–466, 2009.
  3. Origin and diversity of marine larvae, 2018.
  4. Vortex arrays and ciliary tangles underlie the feeding–swimming trade-off in starfish larvae. Nature Physics, 13(4):380–386, 2017.
  5. Richard R Strathmann. Larval feeding in echinoderms. American zoologist, 15(3):717–730, 1975.
  6. Five tests of food-limited growth of larvae in coastal waters by comparisons of rates of development and form of echinoplutei. Limnology and Oceanography, 39(1):84–98, 1994.
  7. Phenotypic plasticity of feeding structures in marine invertebrate larvae. Oxford University Press Oxford, UK, 2018.
  8. Food limitation of planktotrophic marine invertebrate larvae: does it control recruitment success? Annual Review of Ecology and Systematics, 20(1):225–247, 1989.
  9. Temporal variation in food limitation in larvae of the sand dollar dendraster excentricus. Marine Ecology Progress Series, 665:127–143, 2021.
  10. Steven S Rumrill. Natural mortality of marine invertebrate larvae. Ophelia, 32(1-2):163–198, 1990.
  11. The multiscale physics of cilia and flagella. Nature Reviews Physics, 2(2):74–88, 2020.
  12. Teamwork in the viscous oceanic microscale. Proceedings of the National Academy of Sciences, 118(29):e2018193118, 2021.
  13. Flow physics explains morphological diversity of ciliated organs. bioRxiv, pages 2023–02, 2023.
  14. Magnetic cilia carpets with programmable metachronal waves. Nature communications, 11(1):2637, 2020.
  15. Bioinspired cilia arrays with programmable nonreciprocal motion and metachronal coordination. Science advances, 6(45):eabc9323, 2020.
  16. Soft-robotic ciliated epidermis for reconfigurable coordinated fluid manipulation. Science Advances, 8(34):eabq2345, 2022.
  17. Metachronal μ𝜇\muitalic_μ-cilia for on-chip integrated pumps and climbing robots. ACS applied materials & interfaces, 13(17):20845–20857, 2021.
  18. Lisa A Levin. Recent progress in understanding larval dispersal: new directions and digressions. Integrative and comparative biology, 46(3):282–297, 2006.
  19. Kit Yu Karen Chan. Biomechanics of larval morphology affect swimming: insights from the sand dollars dendraster excentricus, 2012.
  20. TW Clay and D Grünbaum. Morphology–flow interactions lead to stage-selective vertical transport of larval sand dollars in shear flow. Journal of Experimental Biology, 213(8):1281–1292, 2010.
  21. Functional consequences of phenotypic plasticity in echinoid larvae. The Biological Bulletin, 186(3):291–299, 1994.
  22. Michael W Hart. Particle captures and the method of suspension feeding by echinoderm larvae. The Biological Bulletin, 180(1):12–27, 1991.
  23. Different protein metabolic strategies for growth during food-induced physiological plasticity in echinoid larvae. Journal of Experimental Biology, 224(4):jeb230748, 2021.
  24. Assessing food-induced plasticity of digestive enzyme activity during echinoid larval development. Journal of Experimental Marine Biology and Ecology, 568:151938, 2023.
  25. Microfluidic tools for developmental studies of small model organisms–nematodes, fruit flies, and zebrafish. Biotechnology journal, 8(2):192–205, 2013.
  26. Microfluidics for mechanobiology of model organisms. In Methods in cell biology, volume 146, pages 217–259. Elsevier, 2018.
  27. Microfluidics for electrophysiology, imaging, and behavioral analysis of hydra. Lab on a Chip, 18(17):2523–2539, 2018.
  28. Multiple neuronal networks coordinate hydra mechanosensory behavior. Elife, 10:e64108, 2021.
  29. Hydra vulgaris shows stable responses to thermal stimulation despite large changes in the number of neurons. Iscience, 24(6), 2021.
  30. Spim-flow: An integrated light sheet and microfluidics platform for hydrodynamic studies of hydra. Biology, 12(1):116, 2023.
  31. Microfluidic guillotine for single-cell wound repair studies. Proceedings of the National Academy of Sciences, 114(28):7283–7288, 2017.
  32. Microfluidic guillotine reveals multiple timescales and mechanical modes of wound response in stentor coeruleus. BMC biology, 19:1–17, 2021.
  33. Hydrodynamic dissection of stentor coeruleus in a microfluidic cross junction. Lab on a Chip, 22(18):3508–3520, 2022.
  34. Live imaging of aiptasia larvae, a model system for coral and anemone bleaching, using a simple microfluidic device. Scientific Reports, 9(1):9275, 2019.
  35. On-chip immobilization of planarians for in vivo imaging. Scientific reports, 4(1):6388, 2014.
  36. Flowtrace: simple visualization of coherent structures in biological fluid flows. Journal of experimental biology, 220(19):3411–3418, 2017.
  37. Scale-free vertical tracking microscopy. Nature Methods, 17(10):1040–1051, 2020.
  38. Active sinking particles: sessile suspension feeders significantly alter the flow and transport to sinking aggregates. Journal of the Royal Society Interface, 20(199):20220537, 2023.
  39. Particle image velocimetry for matlab: Accuracy and enhanced algorithms in pivlab. Journal of Open Research Software, 9(1), 2021.
  40. More than morphology: differences in food ration drive physiological plasticity in echinoid larvae. Journal of experimental marine biology and ecology, 501:1–15, 2018.
  41. Phototaxis is a state-dependent behavioral sequence in hydra vulgaris. bioRxiv, pages 2023–05, 2023.
  42. Advanced methods of microscope control using μ𝜇\muitalic_μmanager software. Journal of biological methods, 1(2), 2014.
  43. Orthogonal-view microscope for the biomechanics investigations of aquatic organisms. ArXiv, 2023.
  44. Bruno Pernet. Larval feeding: mechanisms, rates, and performance in nature. Oxford University Press, Oxford, 2018.
  45. Michel J Kaiser et al. Marine ecology: processes, systems, and impacts. Oxford University Press, USA, 2011.
  46. Ciliary flocking and emergent instabilities enable collective agility in a non-neuromuscular animal. arXiv preprint arXiv:2107.02934, 2021.

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