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1. Turning kinematics of the scyphomedusa Aurelia aurita

   https://doi.org/10.1088/1748-3190/ad1db8  

   Costello, J H; Colin, S P; Gemmell, B J; Dabiri, J O; Kanso, E A (January 2024, Bioinspiration & Biomimetics)

   Abstract Scyphomedusae are widespread in the oceans and their swimming has provided valuable insights into the hydrodynamics of animal propulsion. Most of this research has focused on symmetrical, linear swimming. However, in nature, medusae typically swim circuitous, nonlinear paths involving frequent turns. Here we describe swimming turns by the scyphomedusaAurelia auritaduring which asymmetric bell margin motions produce rotation around a linearly translating body center. These jellyfish ‘skid’ through turns and the degree of asynchrony between opposite bell margins is an approximate predictor of turn magnitude during a pulsation cycle. The underlying neuromechanical organization of bell contraction contributes substantially to asynchronous bell motions and inserts a stochastic rotational component into the directionality of scyphomedusan swimming. These mechanics are important for natural populations because asynchronous bell contraction patterns are commonin situand result in frequent turns by naturally swimming medusae. 

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2. The most efficient metazoan swimmer creates a ‘virtual wall’ to enhance performance

   https://doi.org/10.1098/rspb.2020.2494  

   Gemmell, Brad J.; Du Clos, Kevin T.; Colin, Sean P.; Sutherland, Kelly R.; Costello, John H. (January 2021, Proceedings of the Royal Society B: Biological Sciences)

   null (Ed.)

   It has been well documented that animals (and machines) swimming or flying near a solid boundary get a boost in performance. This ground effect is often modelled as an interaction between a mirrored pair of vortices represented by a true vortex and an opposite sign ‘virtual vortex’ on the other side of the wall. However, most animals do not swim near solid surfaces and thus near body vortex–vortex interactions in open-water swimmers have been poorly investigated. In this study, we examine the most energetically efficient metazoan swimmer known to date, the jellyfish Aurelia aurita , to elucidate the role that vortex interactions can play in animals that swim away from solid boundaries. We used high-speed video tracking, laser-based digital particle image velocimetry (dPIV) and an algorithm for extracting pressure fields from flow velocity vectors to quantify swimming performance and the effect of near body vortex–vortex interactions. Here, we show that a vortex ring (stopping vortex), created underneath the animal during the previous swim cycle, is critical for increasing propulsive performance. This well-positioned stopping vortex acts in the same way as a virtual vortex during wall-effect performance enhancement, by helping converge fluid at the underside of the propulsive surface and generating significantly higher pressures which result in greater thrust. These findings advocate that jellyfish can generate a wall-effect boost in open water by creating what amounts to a ‘virtual wall’ between two real, opposite sign vortex rings. This explains the significant propulsive advantage jellyfish possess over other metazoans and represents important implications for bio-engineered propulsion systems. 

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3. Flow Interactions Between Low Aspect Ratio Hydrofoils in In-line and Staggered Arrangements

   https://doi.org/10.3390/biomimetics5020013  

   Kurt, Melike; Eslam Panah, Azar; Moored, Keith W. (June 2020, Biomimetics)

   Many species of fish gather in dense collectives or schools where there are significant flow interactions from their shed wakes. Commonly, these swimmers shed a classic reverse von Kármán wake, however, schooling eels produce a bifurcated wake topology with two vortex rings shed per oscillation cycle. To examine the schooling interactions of a hydrofoil with a bifurcated wake topology, we present tomographic particle image velocimetry (tomo PIV) measurements of the flow interactions and direct force measurements of the performance of two low-aspect-ratio hydrofoils ( A R = 0.5 ) in an in-line and a staggered arrangement. Surprisingly, when the leader and follower are interacting in either arrangement there are only minor alterations to the flowfields beyond the superposition of the flowfields produced by the isolated leader and follower. Motivated by this finding, Garrick’s linear theory, a linear unsteady hydrofoil theory based on a potential flow assumption, was adapted to predict the lift and thrust performance of the follower. Here, the follower hydrofoil interacting with the leader’s wake is considered as the superposition of an isolated pitching foil with a time-varying cross-stream velocity derived from the wake flow measurements of the isolated leader. Linear theory predictions accurately capture the time-averaged lift force and some of the major peaks in thrust derived from the follower interacting with the leader’s wake in a staggered arrangement. The thrust peaks that are not predicted by linear theory are likely driven by spatial variations in the flowfield acting on the follower or nonlinear flow interactions; neither of which are accounted for in the simple theory. This suggests that unsteady potential flow theory that does account for spatial variations in the flowfield acting on a hydrofoil can provide a relatively simple framework to understand and model the flow interactions that occur in schooling fish. Additionally, schooling eels can derive thrust and efficiency increases of 63-80% in either a in-line or a staggered arrangement where the follower is between two branched momentum jets or with one momentum jet branch directly impinging on it, respectively. 

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4. Diversification of cnidarian mechanosensory neurons across life cycle phases: evidence from Hydrozoa

   Nakanishi, Nagayasu; Takahash, Mako; Kumano, Gaku (May 2025, Integrative and Comparative Biology)

   Over the course of more than half a billion years of independent evolution, cnidarians (e.g. sea anemones, corals and jellyfishes) have evolved diverse, multicellular, mechanosensory structures ranging from tentacles of hydroids to gravity-sensors of moon jellyfish. The ectodermal epithelium of mechanosensory structures houses the mechanosensory neuron – known as the concentric hair cell – characterized by an apical mechanosensory apparatus consisting of a single cilium surrounded by one or multiple rings of microvilli/stereovilli. While distinct concentric hair cell types are known to occur within life-cycle-stage-specific structures such as the sea anemone tentacles, it is unclear whether diverse concentric hair cell types exist across life cycle phases of any cnidarian. Here we report evidence from the hydrozoan Cladonema pacificum that concentric hair cells of sedentary polyps are distinct from those of free-swimming medusae. By carrying out touch assays, we demonstrate that polyps and medusae exhibit distinct mechanosensory behaviors. Moreover, we find that concentric hair cells in the ectodermal epithelium of touch-sensitive regions in polyps differ from those in medusae in the morphology of apical sensory apparatuses. Furthermore, polyp-type concentric hair cells are not retained in the ectoderm of medusa buds, and medusa-type concentric hair cells begin to form de novo during medusa formation. Taken together, these findings suggest that distinct mechanosensitive behaviors of polyps and medusae are mediated by morphologically different sets of mechanosensory neurons that develop via life-cycle-stage-specific mechanisms. We propose that cell type diversification of mechanosensory neurons occurred not only within a given life cycle phase but across life cycle phases in cnidarian evolution. 

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5. Cassiopea xamachana microbiome across anatomy, development, and geography

   https://doi.org/10.1371/journal.pone.0319944  

   Kerwin, Allison H; Ohdera, Aki; Bier, Juliet; Goodman, Devon; Mammone, Marta; Sharp, Victoria; Echeandía, Alesandra; Medina, Mónica (April 2025, PLOS ONE)

   Sucharitakul, Phuping (Ed.)

   The upside-down jellyfish holobiont,Cassiopea xamachana, is a useful model system for tri-partite interactions between the cnidarian host, the photosymbiont, and the bacterial microbiome. While the interaction between the host and photosymbiont has been well studied, less is understood of the associated bacterial community. To date, the bacterial microbiome of wildC. xamachanahas remained largely uncharacterized. Thus, wild medusae (n=6) and larvae (n=3) were collected from two sites in the Florida Keys. Bacterial community composition was characterized via amplicon sequencing of the 16S rRNA gene V4 region. The medusa bacterial community was dominated by members of the Alphaproteobacteria and Gammaproteobacteria, while Planctomycetota, Actinomycetota, Bacteroidota, and Bacillota were also present, among others. Community composition was consistent between locations and across medusa structures (oral arm, bell, and gonad). The larval bacterial community clustered apart from the medusa community in beta diversity analysis and was characterized by the presence of several Pseudomonadota taxa that were not present in the medusa, including theAlteromonas,Pseudoalteromonas, andThalassobiusgenera. A bacterial isolate library encompassing much of the amplicon sequencing diversity was also developed and tested via metabolic assays in a separate culture-dependent analysis of isolates from medusa bells, oral arms, and laplets. Most characteristics were not correlated with host sex or medusa structure, but gelatinase production was more common in laplet isolates, while lactose fermentation was more common in female oral arm isolates. TheEndozoicomonasgenus was dominant in both amplicon sequencing and in our isolate library, and was equally prevalent across all medusa structures and in both sexes. Understanding the bacterial component of theC. xamachanaholobiont will allow us to further develop this important model cnidarian holobiont. 

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