So can the coastal structures that we build in the future become our future coral nurseries?
03.03.2026 03:55
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So can the coastal structures that we build in the future become our future coral nurseries?
The result?
Up to 80x higher settlement
20 to 50x higher survival
~300x higher recruit densities compared to nearby reefs
And it works not only for domes but also for space efficient cylindrical shapes.
Coral spawning produces millions of larvae, but most die before finding suitable habitat.
We designed small pylons with helix recesses to create protective microhabitats for settlement.
Can engineering help save our coral reefs?
Our new paper is out in Ecological Engineering:
βCylindrical, pylon like structures with helix recesses enhance coral larval recruitmentβ
authors.elsevier.com/a/1mYe13IW-w...
#CoralReefs #EcologicalEngineering #Restoration #CoralRecruitment
Excited to share our work using #aDNA to reconstruct #Symbiodiniaceae dynamics from #coral cores. Led by JosΓ© Grillo, @jessireichert.bsky.social, @nessatir.bsky.social part of #TaraPacific expedition & supported by #SPP2299 @climatereefs.bsky.social
doi.org/10.1111/gcb....
INVITED COMMENTARY
Growing Apart: Global Warming Severely Impacts the Symbiosis of the Hawaiian Bobtail Squid and Bioluminescent Bacteria
π buff.ly/Ql8otbl
@jessireichert.bsky.social
Our Research Topic βOccurrence, Impacts, and Interactions of Plastic Pollution in Coral Reef Ecosystemsβ is still accepting submissions!
πͺΈWeβve extended the deadline to 21 July 2025πͺΈ
www.frontiersin.org/research-top...
This project was only possible thanks to a fantastic collaboration. Huge thanks to Silvia Morgana, Martina Pierdomenico, Daniel Schar, and Joshua S. Madin, it was a pleasure working with you on this project!
So what does this mean?
Coral colonies with bulky, low-complexity morphologies trap more microplastics under natural exposure. These corals may act as passive sinks, with implications for particle retention and downstream reef contamination.
Corals with lower fractal dimension, higher sphericity, and lower compactness had higher MP densities on surface and tissue. Colony-level complexity better explained MP retention than fragment-level complexity.
MP loads were compartmentalized:
β’ 61% on surface
β’ 30% in tissue
β’ 9% in skeleton
Surface loads were significantly higher than tissue or skeleton.
We found mostly microplastic fragments (67%), with PVC and polyester dominating and between 0.1β1 mm in size.
We sampled 6 coral colonies with varying morphologies from KΔneβohe Bay, Hawaiβi. We extracted microplastic particles in the lab and analyzed them via FTIR, and documented coral shape via photogrammetry and 3D scanning.
New publication πͺΈπ€Ώ
How does coral morphology affect microplastic accumulation?
In our new study in Environmental Pollution, we quantify microplastic loads in Pocillopora spp. and link them to 3D structural complexity.
π doi.org/10.1016/j.envpol.2025.126480
CORAL RESEARCH NEWS: Uncovering how harmful microplastics stick to coral reefs (University of Waterloo)
uwaterloo.ca/news/media/u...
#coralreefs #coralresearch #coralnews #microplastics #coralhealth #chemicalengineering #nanotechnology #marineecology #marinebiology
Our Research Topic is still accepting submissions. Share your cutting-edge research on this exciting topic!
Manuscript Submission Deadline: 23 March 2025
For more information and submission guidelines, please visit: www.frontiersin.org/research-top... or reach out to me!
Yes to all of this! π
So, to put it simply, Let's stop adding more plastic to the environment to keep pollution levels low and bearable for corals! We still have a chance to act!
#ReuseReduceRecycle #StopPlasticPollution
We found that extreme microplastic concentrations have a disproportionately large effect on the physiology of the coral host. While the coral hosts mainly follow basic nonlinear dose-response patterns, their photosymbionts follow complex nonlinear dose-response patterns with thresholds.
We investigated the #concentration-dependent effects of a #microplastic mixture on the physiology of the #coral host and the photosynthetic efficiency of their #photosymbionts.
We exposed two coral species to different concentrations of a #microplastic mixture.
Proudly sharing the first lead author paper of our PhD student Vanessa Tirpitz. Check it out! (2025)
www.sciencedirect.com/science/arti...
Massive shoutout to the students involved in this study Vanessa, Elisabeth, and Luisa at #JLUGiessen. Your hard work has been the heartbeat of the study!
#TeamWorkMakesTheDreamWork
Why Does it Matter? π The species-specific responses highlight the complexity of microdebris impacts and the urgency to implement effective measures to mitigate major sources of pollution.
π§Key Findings
- Fibers and tire wear had the strongest effects on coral physiology
- π volume growth but πcalcification
-πphotosynthetic efficiency in symbionts
- Single polymer had comparable, yet species-specific impacts
- Species-specific effects tied to feeding
πEquipped with pumps and filters, we created a dynamic water flow in our tanks where particles remained suspended in the water column throughout the entire 8-week experiment.
π Objectives: 1. Assess effects on coral physiology. 2. Compare impacts of different microdebris and a single polymer treatment. 3. Identify species-specific responses by contrasting feeding reactions.
π§ͺExperimental Setup: Two coral species, Pocillopora verrucosa and Stylophora pistillata, were exposed to four microdebris types: [1] Plastic debris [2] Fibers from clothing [3] Tire wear, brake abrasion, varnish flakes and [4] Single polymer microplastics PE
Stoked to share our latest study! We're exploring how #microdebris affects #reefbuilding #corals. Looking at major sources of #pollution gives us a more realistic view of how corals might respond in nature. Let's dive in! (2024)
www.sciencedirect.com/science/arti...
I believe this was the fiddliest study we have ever done, maneuvering the forceps holding Β΅m-sized particles to miniature tentacles. Kudos to the many patient students involved, Niklas, Chieh, Mareike and Vanessa, in this amazing team effort!