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7. Modeling epithelial homeostasis and perturbation in three-dimensional human esophageal organoids

Author

Shimonosono, Masataka, primary, Morimoto, Masaki, additional, Hirose, Wataru, additional, Tomita, Yasuto, additional, Matsuura, Norihiro, additional, Flashner, Samuel, additional, Ebadi, Mesra S., additional, Okayasu, Emilea H., additional, Lee, Christian Y., additional, Britton, William R., additional, Martin, Cecilia, additional, Wuertz, Beverly R., additional, Parikh, Anuraag S., additional, Sachdeva, Uma M., additional, Ondrey, Frank G., additional, Atigadda, Venkatram R., additional, Elmets, Craig A., additional, Abrams, Julian A., additional, Muir, Amanda B., additional, Klein-Szanto, Andres J., additional, Weinberg, Kenneth I., additional, Momen-Heravi, Fatemeh, additional, and Nakagawa, Hiroshi, additional

Published
2024
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8. Advancements in TGF-β Targeting Therapies for Head and Neck Squamous Cell Carcinoma.

Author

Britton, William R., Cioffi, Isabel, Stonebraker, Corinne, Spence, Matthew, Okolo, Ogoegbunam, Martin, Cecilia, Henick, Brian, Nakagawa, Hiroshi, and Parikh, Anuraag S.

Subjects
THERAPEUTIC use of antineoplastic agents, SQUAMOUS cell carcinoma, CLINICAL drug trials, PROTEINS, CANCER, EPITHELIAL-mesenchymal transition, CANCER invasiveness, HEAD & neck cancer, IMMUNOTHERAPY, CELLULAR signal transduction, METASTASIS, CANCER chemotherapy, FIBROBLASTS, DRUG development, CYTOKINES, INDIVIDUALIZED medicine, TRANSFORMING growth factors-beta, NEOVASCULARIZATION, DRUG resistance
Abstract

Simple Summary: TGF-β is an important cytokine shown to drive oncogenesis in head and neck squamous cell carcinoma (HNSCC) through its diverse influences on the tumor microenvironment. While this cytokine is vital in maintaining tissue homeostasis in normal head and neck epithelia, in cancer, it paradoxically drives metastasis, angiogenesis, immune evasion, and therapy resistance. Despite promising preclinical data, the outcome of clinical trials of TGF-β inhibitors for HNSCC has been suboptimal. Patient stratification is warranted to improve this targeted therapy. Head and neck squamous cell carcinoma (HNSCC) is the sixth leading cause of cancer worldwide according to GLOBOCAN estimates from 2022. Current therapy options for recurrent or metastatic disease are limited to conventional cytotoxic chemotherapy and immunotherapy, with few targeted therapy options readily available. Recent single-cell transcriptomic analyses identified TGF-β signaling as an important mediator of functional interplays between cancer-associated fibroblasts and a subset of mesenchymal cancer cells. This signaling was shown to drive invasiveness, treatment resistance, and immune evasion. These data provide renewed interest in the TGF-β pathway as an alternative therapeutic target, prompting a critical review of previous clinical data which suggest a lack of benefit from TGF-β inhibitors. While preclinical data have demonstrated the great anti-tumorigenic potential of TGF-β inhibitors, the underwhelming results of ongoing and completed clinical trials highlight the difficulty actualizing these benefits into clinical practice. This topical review will discuss the relevant preclinical and clinical findings for TGF-β inhibitors in HNSCC and will explore the potential role of patient stratification in the development of this therapeutic strategy. [ABSTRACT FROM AUTHOR]

Published
2024
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9. Modeling Epithelial Homeostasis and Perturbation in Three-Dimensional Human Esophageal Organoids.

Author

Shimonosono, Masataka, Morimoto, Masaki, Hirose, Wataru, Tomita, Yasuto, Matsuura, Norihiro, Flashner, Samuel, Ebadi, Mesra S., Okayasu, Emilea H., Lee, Christian Y., Britton, William R., Martin, Cecilia, Wuertz, Beverly R., Parikh, Anuraag S., Sachdeva, Uma M., Ondrey, Frank G., Atigadda, Venkatram R., Elmets, Craig A., Abrams, Julian A., Muir, Amanda B., and Klein-Szanto, Andres J.

Subjects
EPIDERMAL growth factor, EOSINOPHILIC esophagitis, ESOPHAGUS diseases, DISEASE progression, TRETINOIN
Abstract

Background: Esophageal organoids from a variety of pathologies including cancer are grown in Advanced Dulbecco's Modified Eagle Medium-Nutrient Mixture F12 (hereafter ADF). However, the currently available ADF-based formulations are suboptimal for normal human esophageal organoids, limiting the ability to compare normal esophageal organoids with those representing a given disease state. Methods: We have utilized immortalized normal human esophageal epithelial cell (keratinocyte) lines EPC1 and EPC2 and endoscopic normal esophageal biopsies to generate three-dimensional (3D) organoids. To optimize the ADF-based medium, we evaluated the requirement of exogenous epidermal growth factor (EGF) and inhibition of transforming growth factor-(TGF)-β receptor-mediated signaling, both key regulators of the proliferation of human esophageal keratinocytes. We have modeled human esophageal epithelial pathology by stimulating esophageal 3D organoids with interleukin (IL)-13, an inflammatory cytokine, or UAB30, a novel pharmacological activator of retinoic acid signaling. Results: The formation of normal human esophageal 3D organoids was limited by excessive EGF and intrinsic TGFβ-receptor-mediated signaling. Optimized HOME0 improved normal human esophageal organoid formation. In the HOME0-grown organoids, IL-13 and UAB30 induced epithelial changes reminiscent of basal cell hyperplasia, a common histopathologic feature in broad esophageal disease conditions including eosinophilic esophagitis. Conclusions: HOME0 allows modeling of the homeostatic differentiation gradient and perturbation of the human esophageal epithelium while permitting a comparison of organoids from mice and other organs grown in ADF-based media. [ABSTRACT FROM AUTHOR]

Published
2024
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12. Tumor Niche Network-Defined Subtypes Predict Immunotherapy Response of Esophageal Squamous Cell Cancer

Author

Ko, Kyung-Pil, primary, Zhang, Shengzhe, additional, Huang, Yuanjian, additional, Kim, Bongjun, additional, Zou, Gengyi, additional, Jun, Sohee, additional, Zhang, Jie, additional, Martin, Cecilia, additional, Dunbar, Karen J., additional, Efe, Gizem, additional, Rustgi, Anil K., additional, Zhang, Haiyang, additional, Nakagawa, Hiroshi, additional, and Park, Jae-Il, additional

Published
2023
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14. Modeling Oral-Esophageal Squamous Cell Carcinoma in 3D Organoids

Author

Flashner, Samuel, primary, Martin, Cecilia, primary, Matsuura, Norihiro, primary, Shimonosono, Masataka, primary, Tomita, Yasuto, primary, Morimoto, Masaki, primary, Okolo, Ogoegbunam, primary, Yu, Victoria X., primary, Parikh, Anuraag S., primary, Klein-Szanto, Andres J. P., primary, Yan, Kelley, primary, Gabre, Joel T., primary, Lu, Chao, primary, Momen-Heravi, Fatemeh, primary, Rustgi, Anil K., primary, and Nakagawa, Hiroshi, primary

Published
2022
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16. Key Genetic Determinants Driving Esophageal Squamous Cell Carcinoma Initiation and Immune Evasion

Author

Ko, Kyung-Pil, primary, Huang, Yuanjian, additional, Zhang, Shengzhe, additional, Zou, Gengyi, additional, Kim, Bongjun, additional, Zhang, Jie, additional, Jun, Sohee, additional, Martin, Cecilia, additional, Dunbar, Karen J., additional, Efe, Gizem, additional, Rustgi, Anil K., additional, Nakagawa, Hiroshi, additional, and Park, Jae-Il, additional

Published
2022
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22. Fate and Effects of Macro- and Microplastics in Coastal Wetlands

Author

Ouyang, Xiaoguang, Duarte, Carlos M., Cheung, Siu-Gin, Tam, Nora Fung-Yee, Cannicci, Stefano, Martin, Cecilia, Lo, Hoi Shing, Lee, Shing Yip, Ouyang, Xiaoguang, Duarte, Carlos M., Cheung, Siu-Gin, Tam, Nora Fung-Yee, Cannicci, Stefano, Martin, Cecilia, Lo, Hoi Shing, and Lee, Shing Yip

Abstract

Coastal wetlands trap plastics from terrestrial and marine sources, but the stocks of plastics and their impacts on coastal wetlands are poorly known. We evaluated the stocks, fate, and biological and biogeochemical effects of plastics in coastal wetlands with plastic abundance data from 112 studies. The representative abundance of plastics that occurs in coastal wetland sediments and is ingested by marine animals reaches 156.7 and 98.3 items kg–1, respectively, 200 times higher than that (0.43 items kg–1) in the water column. Plastics are more abundant in mangrove forests and tidal marshes than in tidal flats and seagrass meadows. The variation in plastic abundance is related to climatic and geographic zones, seasons, and population density or plastic waste management. The abundance of plastics ingested by pelagic and demersal fish increases with fish length and dry weight. The dominant characteristics of plastics ingested by marine animals are correlated with those found in coastal wetland sediments. Microplastics exert negative effects on biota abundance and mangrove survival but positive effects on sediment nutrients, leaf drop, and carbon emission. We highlight that plastic pollution is widespread in coastal wetlands and actions are urged to include microplastics in ecosystem health and degradation assessment.

Published
2022
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24. Microplastics: Small Particles, Big Threat

Author

Arossa, Silvia, Martin, Cecilia, Rossbach, Susann, and Duarte, Carlos M.

Subjects
General Medicine
Abstract

You have probably heard that plastic pollution is becoming a big problem for the environment, and especially for the oceans. When a piece of plastic reaches the sea, the seawater and sunlight make it slowly fall apart into tiny plastic particles. These small particles are called microplastics and are even smaller than a ladybug—and sometimes not even visible. Scientists have found that many marine animals mistake these microplastics for food and eat them! But what about the animals in coral reefs? Many animals in reefs, including corals and giant clams, are fixed to the bottom of the sea and cannot move. So, they cannot escape from the microplastics that are literally “raining down” on them. Recently, we discovered that many of these coral reef animals are not only eating the microplastics, but the plastics can also stick on their bodies like flies on flypaper!

Published
2021

26. Global COVID-19 lockdown highlights humans as both threats and custodians of the environment

Author

Bates, Amanda E., primary, Primack, Richard B., additional, Biggar, Brandy S., additional, Bird, Tomas J., additional, Clinton, Mary E., additional, Command, Rylan J., additional, Richards, Cerren, additional, Shellard, Marc, additional, Geraldi, Nathan R., additional, Vergara, Valeria, additional, Acevedo-Charry, Orlando, additional, Colón-Piñeiro, Zuania, additional, Ocampo, David, additional, Ocampo-Peñuela, Natalia, additional, Sánchez-Clavijo, Lina M., additional, Adamescu, Cristian M., additional, Cheval, Sorin, additional, Racoviceanu, Tudor, additional, Adams, Matthew D., additional, Kalisa, Egide, additional, Kuuire, Vincent Z., additional, Aditya, Vikram, additional, Anderwald, Pia, additional, Wiesmann, Samuel, additional, Wipf, Sonja, additional, Badihi, Gal, additional, Henderson, Matthew G., additional, Loetscher, Hanspeter, additional, Baerenfaller, Katja, additional, Benedetti-Cecchi, Lisandro, additional, Bulleri, Fabio, additional, Bertocci, Iacopo, additional, Maggi, Elena, additional, Rindi, Luca, additional, Ravaglioli, Chiara, additional, Boerder, Kristina, additional, Bonnel, Julien, additional, Mathias, Delphine, additional, Archambault, Philippe, additional, Chauvaud, Laurent, additional, Braun, Camrin D., additional, Thorrold, Simon R., additional, Brownscombe, Jacob W., additional, Midwood, Jonathan D., additional, Boston, Christine M., additional, Brooks, Jill L., additional, Cooke, Steven J., additional, China, Victor, additional, Roll, Uri, additional, Belmaker, Jonathan, additional, Zvuloni, Assaf, additional, Coll, Marta, additional, Ortega, Miquel, additional, Connors, Brendan, additional, Lacko, Lisa, additional, Jayathilake, Dinusha R.M., additional, Costello, Mark J., additional, Crimmins, Theresa M., additional, Barnett, LoriAnne, additional, Denny, Ellen G., additional, Gerst, Katharine L., additional, Marsh, R.L., additional, Posthumus, Erin E., additional, Rodriguez, Reilly, additional, Rosemartin, Alyssa, additional, Schaffer, Sara N., additional, Switzer, Jeff R., additional, Wong, Kevin, additional, Cunningham, Susan J., additional, Sumasgutner, Petra, additional, Amar, Arjun, additional, Thomson, Robert L., additional, Stofberg, Miqkayla, additional, Hofmeyr, Sally, additional, Suri, Jessleena, additional, Stuart-Smith, Rick D., additional, Day, Paul B., additional, Edgar, Graham J., additional, Cooper, Antonia T., additional, De Leo, Fabio Cabrera, additional, Garner, Grant, additional, Des Brisay, Paulson G., additional, Schrimpf, Michael B., additional, Koper, Nicola, additional, Diamond, Michael S., additional, Dwyer, Ross G., additional, Baker, Cameron J., additional, Franklin, Craig E., additional, Efrat, Ron, additional, Berger-Tal, Oded, additional, Hatzofe, Ohad, additional, Eguíluz, Víctor M., additional, Rodríguez, Jorge P., additional, Fernández-Gracia, Juan, additional, Elustondo, David, additional, Calatayud, Vicent, additional, English, Philina A., additional, Archer, Stephanie K., additional, Dudas, Sarah E., additional, Haggarty, Dana R., additional, Gallagher, Austin J., additional, Shea, Brendan D., additional, Shipley, Oliver N., additional, Gilby, Ben L., additional, Ballantyne, Jasmine, additional, Olds, Andrew D., additional, Henderson, Christopher J., additional, Schlacher, Thomas A., additional, Halliday, William D., additional, Brown, Nicholas A.W., additional, Woods, Mackenzie B., additional, Balshine, Sigal, additional, Juanes, Francis, additional, Rider, Mitchell J., additional, Albano, Patricia S., additional, Hammerschlag, Neil, additional, Hays, Graeme C., additional, Esteban, Nicole, additional, Pan, Yuhang, additional, He, Guojun, additional, Tanaka, Takanao, additional, Hensel, Marc J.S., additional, Orth, Robert J., additional, Patrick, Christopher J., additional, Hentati-Sundberg, Jonas, additional, Olsson, Olof, additional, Hessing-Lewis, Margot L., additional, Higgs, Nicholas D., additional, Hindell, Mark A., additional, McMahon, Clive R., additional, Harcourt, Rob, additional, Guinet, Christophe, additional, Hirsch, Sarah E., additional, Perrault, Justin R., additional, Hoover, Shelby R., additional, Reilly, Jennifer D., additional, Hobaiter, Catherine, additional, Gruber, Thibaud, additional, Huveneers, Charlie, additional, Udyawer, Vinay, additional, Clarke, Thomas M., additional, Kroesen, Laura P., additional, Hik, David S., additional, Cherry, Seth G., additional, Del Bel Belluz, Justin A., additional, Jackson, Jennifer M., additional, Lai, Shengjie, additional, Lamb, Clayton T., additional, LeClair, Gregory D., additional, Parmelee, Jeffrey R., additional, Chatfield, Matthew W.H., additional, Frederick, Cheryl A., additional, Lee, Sangdon, additional, Park, Hyomin, additional, Choi, Jaein, additional, LeTourneux, Frédéric, additional, Grandmont, Thierry, additional, de-Broin, Frédéric Dulude, additional, Bêty, Joël, additional, Gauthier, Gilles, additional, Legagneux, Pierre, additional, Lewis, Jesse S., additional, Haight, Jeffrey, additional, Liu, Zhu, additional, Lyon, Jarod P., additional, Hale, Robin, additional, D'Silva, Dallas, additional, MacGregor-Fors, Ian, additional, Arbeláez-Cortés, Enrique, additional, Estela, Felipe A., additional, Sánchez-Sarria, Camilo E., additional, García-Arroyo, Michelle, additional, Aguirre-Samboní, Giann K., additional, Franco Morales, Juan C., additional, Malamud, Shahar, additional, Gavriel, Tal, additional, Buba, Yehezkel, additional, Salingré, Shira, additional, Lazarus, Mai, additional, Yahel, Ruthy, additional, Ari, Yigael Ben, additional, Miller, Eyal, additional, Sade, Rotem, additional, Lavian, Guy, additional, Birman, Ziv, additional, Gury, Manor, additional, Baz, Harel, additional, Baskin, Ilia, additional, Penn, Alon, additional, Dolev, Amit, additional, Licht, Ogen, additional, Karkom, Tabi, additional, Davidzon, Sharon, additional, Berkovitch, Avi, additional, Yaakov, Ofer, additional, Manenti, Raoul, additional, Mori, Emiliano, additional, Ficetola, Gentile Francesco, additional, Lunghi, Enrico, additional, March, David, additional, Godley, Brendan J., additional, Martin, Cecilia, additional, Mihaly, Steven F., additional, Barclay, David R., additional, Thomson, Dugald J.M., additional, Dewey, Richard, additional, Bedard, Jeannette, additional, Miller, Aroha, additional, Dearden, Amber, additional, Chapman, Jennifer, additional, Dares, Lauren, additional, Borden, Laura, additional, Gibbs, Donna, additional, Schultz, Jessica, additional, Sergeenko, Nikita, additional, Francis, Fiona, additional, Weltman, Amanda, additional, Moity, Nicolas, additional, Ramírez-González, Jorge, additional, Mucientes, Gonzalo, additional, Alonso-Fernández, Alexandre, additional, Namir, Itai, additional, Bar-Massada, Avi, additional, Chen, Ron, additional, Yedvab, Shmulik, additional, Okey, Thomas A., additional, Oppel, Steffen, additional, Arkumarev, Volen, additional, Bakari, Samuel, additional, Dobrev, Vladimir, additional, Saravia-Mullin, Victoria, additional, Bounas, Anastasios, additional, Dobrev, Dobromir, additional, Kret, Elzbieta, additional, Mengistu, Solomon, additional, Pourchier, Cloé, additional, Ruffo, Alazar, additional, Tesfaye, Million, additional, Wondafrash, Mengistu, additional, Nikolov, Stoyan C., additional, Palmer, Charles, additional, Sileci, Lorenzo, additional, Rex, Patrick T., additional, Lowe, Christopher G., additional, Peters, Francesc, additional, Pine, Matthew K., additional, Radford, Craig A., additional, Wilson, Louise, additional, McWhinnie, Lauren, additional, Scuderi, Alessia, additional, Jeffs, Andrew G., additional, Prudic, Kathleen L., additional, Larrivée, Maxim, additional, McFarland, Kent P., additional, Solis, Rodrigo, additional, Hutchinson, Rebecca A., additional, Queiroz, Nuno, additional, Furtado, Miguel A., additional, Sims, David W., additional, Southall, Emily, additional, Quesada-Rodriguez, Claudio A., additional, Diaz-Orozco, Jessica P., additional, Rodgers, Ku'ulei S., additional, Severino, Sarah J.L., additional, Graham, Andrew T., additional, Stefanak, Matthew P., additional, Madin, Elizabeth M.P., additional, Ryan, Peter G., additional, Maclean, Kyle, additional, Weideman, Eleanor A., additional, Şekercioğlu, Çağan H., additional, Kittelberger, Kyle D., additional, Kusak, Josip, additional, Seminoff, Jeffrey A., additional, Hanna, Megan E., additional, Shimada, Takahiro, additional, Meekan, Mark G., additional, Smith, Martin K.S., additional, Mokhatla, Mohlamatsane M., additional, Soh, Malcolm C.K., additional, Pang, Roanna Y.T., additional, Ng, Breyl X.K., additional, Lee, Benjamin P.Y.-H., additional, Loo, Adrian H.B., additional, Er, Kenneth B.H., additional, Souza, Gabriel B.G., additional, Stallings, Christopher D., additional, Curtis, Joseph S., additional, Faletti, Meaghan E., additional, Peake, Jonathan A., additional, Schram, Michael J., additional, Wall, Kara R., additional, Terry, Carina, additional, Rothendler, Matt, additional, Zipf, Lucy, additional, Ulloa, Juan Sebastián, additional, Hernández-Palma, Angélica, additional, Gómez-Valencia, Bibiana, additional, Cruz-Rodríguez, Cristian, additional, Herrera-Varón, Yenifer, additional, Roa, Margarita, additional, Rodríguez-Buriticá, Susana, additional, Ochoa-Quintero, Jose Manuel, additional, Vardi, Reut, additional, Vázquez, Víctor, additional, Requena-Mesa, Christian, additional, Warrington, Miyako H., additional, Taylor, Michelle E., additional, Woodall, Lucy C., additional, Stefanoudis, Paris V., additional, Zhang, Xiangliang, additional, Yang, Qiang, additional, Zukerman, Yuval, additional, Sigal, Zehava, additional, Ayali, Amir, additional, Clua, Eric E.G., additional, Carzon, Pamela, additional, Seguine, Clementine, additional, Corradini, Andrea, additional, Pedrotti, Luca, additional, Foley, Catherine M., additional, Gagnon, Catherine Alexandra, additional, Panipakoochoo, Elijah, additional, Milanes, Celene B., additional, Botero, Camilo M., additional, Velázquez, Yunior R., additional, Milchakova, Nataliya A., additional, Morley, Simon A., additional, Martin, Stephanie M., additional, Nanni, Veronica, additional, Otero, Tanya, additional, Wakeling, Julia, additional, Abarro, Sarah, additional, Piou, Cyril, additional, Sobral, Ana F.L., additional, Soto, Eulogio H., additional, Weigel, Emily G., additional, Bernal-Ibáñez, Alejandro, additional, Gestoso, Ignacio, additional, Cacabelos, Eva, additional, Cagnacci, Francesca, additional, Devassy, Reny P., additional, Loretto, Matthias-Claudio, additional, Moraga, Paula, additional, Rutz, Christian, additional, and Duarte, Carlos M., additional

Published
2021
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27. Habitat-forming species trap microplastics into coastal sediment sinks

Author

de Smit, Jaco C., Anton, Andrea, Martin, Cecilia, Rossbach, Susann, Bouma, Tjeerd J., Duarte, Carlos M., Proceskunde, and Proceskunde

Subjects
geography, Microplastics, geography.geographical_feature_category, Environmental Engineering, 010504 meteorology & atmospheric sciences, Sediment, 010501 environmental sciences, Trap (plumbing), Plastic, Coastal ecosystems, 01 natural sciences, Pollution, Sink (geography), Benthic structures, Flume, Oceanography, Habitat, Benthic zone, Rough surface, Hydrodynamics, Environmental science, Environmental Chemistry, Waste Management and Disposal, 0105 earth and related environmental sciences
Abstract

Nearshore biogenic habitats are known to trap sediments, and may therefore also accumulate biofouled, non-buoyant microplastics. Using a current-generating field flume (TiDyFLOW), we experimentally assessed the mechanisms of microplastic trapping of two size classes, 0.5 mm and 2.5 mm particle size, by three contrasting types of biogenic habitats: 1) seagrasses, 2) macroalgae, and 3) scleractinian corals. Results showed that benthic organisms with a complex architecture and rough surface – such as hard corals – trap the highest number of microplastics in their aboveground structure. Sediment was however the major microplastic sink, accumulating 1 to 2 orders of magnitude more microplastics than the benthic structure. Microplastic accumulation in the sediment could be explained by near-bed turbulent kinetic energy (TKE), indicating that this is governed by the same hydrodynamic processes leading to sediment trapping. Thus, the most valuable biogenic habitats in terms of nursery and coastal protection services also have the highest capacity of accumulating microplastics in their sediments. A significantly larger fraction of 0.5 mm particles was trapped in the sediment compared to 2.5 mm particles, because especially the smaller microplastics are entrained into the sediment. Present observations contribute to explaining why especially microplastics smaller than 1 mm are missing in surface waters.

Published
2021

28. Integrating environmental variability to broaden the research on coral responses to future ocean conditions

Author

Ziegler, Maren, primary, Anton, Andrea, additional, Klein, Shannon G., additional, Rädecker, Nils, additional, Geraldi, Nathan R., additional, Schmidt‐Roach, Sebastian, additional, Saderne, Vincent, additional, Mumby, Peter J., additional, Cziesielski, Maha J., additional, Martin, Cecilia, additional, Frölicher, Thomas L., additional, Pandolfi, John M., additional, Suggett, David J., additional, Aranda, Manuel, additional, Duarte, Carlos M., additional, and Voolstra, Christian R., additional

Published
2021
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29. Projecting coral responses to intensifying marine heatwaves under ocean acidification

Author

Klein, Shannon G., primary, Geraldi, Nathan R., additional, Anton, Andrea, additional, Schmidt‐Roach, Sebastian, additional, Ziegler, Maren, additional, Cziesielski, Maha J., additional, Martin, Cecilia, additional, Rädecker, Nils, additional, Frölicher, Thomas L., additional, Mumby, Peter J., additional, Pandolfi, John M., additional, Suggett, David J., additional, Voolstra, Christian R., additional, Aranda, Manuel, additional, and Duarte, Carlos. M., additional

Published
2021
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34. Investing in Blue Natural Capital to secure a future for the Red Sea ecosystems

Author

Cziesielski, Maha Joana, Duarte, Carlos M., Aalismail, Nojood A, Al-Hafedh, Yousef, Anton, Andrea, Baalkhuyur, Faiyah, Baker, Andrew C, Balke, Thorsten, Baums, Iliana B, Berumen, Michael Lee, Chalastani, Vasiliki I., Cornwell, Brendan, Daffonchio, Daniele, Diele, Karen, Ehtsaam, Farooq, Gattuso, Jean-Pierre, He, Song, Lovelock, Catherine, Mcleod, Elizabeth, Macreadie, Peter Ian, Marba, Nuria, Martin, Cecilia, Barreto, Marcelle Muniz, Krishnakumar, Periyadan K, Prihartato, Perdana, Rabaoui, Lotfi, Saderne, Vincent, Schmidt-Roach, Sebastian, Suggett, David, Sweet, Michael, Statton, John, Teicher, Sam, Trevathan-Tackett, Stacey Marie, Joydas, Thadickal V, Aranda, Razan Ziyad Yahya and Manuel, Laboratoire d'océanographie de Villefranche (LOV), Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Institut de la Mer de Villefranche (IMEV), and Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)

Subjects
[SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, Blue carbon, [SDE.MCG]Environmental Sciences/Global Changes, Marine policy, Red Sea ecosystems, blue economy, coral reefs, sustainability, [SDU.ENVI]Sciences of the Universe [physics]/Continental interfaces, environment, [SDE.ES]Environmental Sciences/Environmental and Society, [SDU.STU.OC]Sciences of the Universe [physics]/Earth Sciences/Oceanography, Environmental Policy
Abstract

International audience; Word count: 295

Published
2021

35. Integrating environmental variability to broaden the research on coral responses to future ocean conditions

Author

Ziegler, Maren, Anton, Andrea, Klein, Shannon G., Rädecker, Nils, Geraldi, Nathan R., Schmidt-Roach, Sebastian, Saderne, Vincent, Mumby, Peter J., Cziesielski, Maha J., Martin, Cecilia, Frölicher, Thomas L., Pandolfi, John M., Suggett, David J., Aranda, Manuel, Duarte, Carlos M., Voolstra, Christian R., and Justus Liebig University Giessen

Subjects
ddc:570
Published
2021
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37. Global COVID-19 lockdown highlights humans as both threats and custodians of the environment

Author

Bates, Amanda E., Primack, Richard B., Biggar, Brandy S., Bird, Thomas J., Clinton, Mary E., Command, Rylan J., Richards, Cerren, Shellard, Marc, Geraldi, Nathan R., Vergara, Valeria, Acevedo-Charry, Orlando, Colón-Piñeiro, Zuania, Ocampo, David, Ocampo-Peñuela, Natalia, Sánchez-Clavijo, Lina M., Adamescu, Cristian M., Cheval, Sorin, Racoviceanu, Tudor, Adams, Matthew D., Kalisa, Egide, Kuuire, Vincent Z., Aditya, Vikram, Anderwald, Pia, Wiesmann, Samuel, Wipf, Sonja, Badihi, Gal, Henderson, Matthew G., Loetscher, Hanspeter, Baerenfaller, Katja, Benedetti-Cecchi, Lisandro, Bulleri, Fabio, Bertocci, Lacopo, Maggi, Elena, Rindi, Luca, Ravaglioli, Chiara, Boerder, Kristina, Bonnel, Julien, Mathias, Delphine, Archambault, Philippe, Chauvaud, Laurent, Braun, Camrin D., Thorrold, Simon R., Brownscombe, Jacob W., Midwood, Jonathan D., Boston, Christine M., Brooks, Jill L., Cooke, Steven J., China, Victor, Roll, Uri, Belmaker, Jonathan, Zvuloni, Assaf, Coll, Marta, Ortega, Miquel, Connors, Brendan, Lacko, Lisa, Jayathilake, Dinusha R.M., Costello, Mark J., Crimmins, Theresa M., Barnett, LoriAnne, Denny, Ellen G., Gerst, Katharine L., Marsh, R.L., Posthumus, Erin E., Rodriguez, Reilly, Rosemartin, Alyssa, Schaffer, Sara N., Switzer, Jeff R., Wong, Kevin, Cunningham, Susan J., Sumasgutner, Petra, Amar, Arjun, Thomson, Robert L., Stofberg, Miqkayla, Hofmeyr, Sally, Suri, Jessleena, Stuart-Smith, Rick D., Day, Paul B., Edgar, Graham J., Cooper, Antonia T., Cabrera De Leo, Fabio, Garner, Grant, Des Brisay, Paulson G., Schrimpf, Michael B., Koper, Nicola, Diamond, Michael S., Dwyer, Ross G., Baker, Cameron J, Franklin, Craig E., Efrat, Ron, Berger-Tal, Oded, Hatzofe, Ohad, Eguíluz, Víctor M., Rodríguez, Jorge P., Fernández-Gracia, Juan, Elustondo, David, Calatayud, Vicent, English, Philina A., Archer, Stephanie K., Dudas, Sarah E., Haggarty, Dana R., Gallagher, Austin J., Shea, Brandan D., Shipley, Oliver N., Gilby, Ben L., Ballantyne, Jasmine, Olds, Andrew D., Henderson, Christopher J., Schlacher, Thomas A., Halliday, William D., Brown, Nicholas A.W., Woods, Mackenzie B., Balshine, Sigal, Juanes, Francis, Rider, Mitchell J., Albano, Patricia S., Hammerschlag, Neil, Hays, Graeme C., Esteban, Nicole, Pan, Yuhang, He, Guojun, Tanaka, Takanao, Hensel, Marc J.S., Orth, Robert J., Patrick, Christopher J., Hentati-Sundberg, Jonas, Olsson, Olof, Hessing-Lewis, Margot L., Higgs, Nicholas D., McMahon, Clive R., Harcourt, Rob, Guinet, Christophe, Hirsch, Sarah E., Perrault, Justin R., Hoover, Shelby R., Reilly, Jennifer D., Hobaiter, Catherine, Gruber, Thibaud, Huveneers, Charlie, Udyawer, Vinay, Clarke, Thomas M., Kroesen, Laura P., Hik, David S., Cherry, Seth G., Del Bel Belluz, Justin A., Jackson, Jennifer M., Lai, Shengjie, Lamb, Clayton T., LeClair, Gregory D., Parmelee, Jeffrey R., Chatfield, Matthew W.H., Frederick, Cheryl A., Lee, Sangdon, Park, Hyomin, Choi, Jaein, LeTourneux, Frédéric, Grandmont, Thierry, Dulude de-Broin, Frédéric, Bêty, Joël, Gauthier, Gilles, Legagneux, Pierre, Lewis, Jesse S., Haight, Jeffrey, Liu, Zhu, Lyon, Jarod P., Hale, Robin, D'Silva, Dallas, MacGregor-Fors, Ian, Arbelaez-Cortes, Enrique, Estela, Felipe A., Sánchez-Sarria, Camilo E., García-Arroyo, Michelle, Aguirre-Samboní, Giann K., Franco Morales, Juan C., Malamud, Shahar, Gavriel, Tal, Buba, Yehezkel, Salingré, Shira, Lazarus, Mai, Yahel, Ruthy, Ben Ari, Yigael, Miller, Eyal, Sade, Rotem, Lavian, Guy, Birman, Ziv, Gury, Manor, Baz, Harel, Baskin, Ilia, Penn, Alon, Dolev, Amit, Licht, Ogen, Karkom, Tabi, Davidzon, Sharon, Berkovitch, Avi, Yaakov, Ofer, Manenti, Raoul, Mori, Emiliano, Ficetola, Gentile Francesco, Lunghi, Enrico, March, David, Godley, Brendan J., Martin, Cecilia, Mihaly, Steven F., Barclay, David R., Thomson, Dugald J.M., Dewey, Richard, Bedard, Jeannette, Miller, Aroha, Dearden, Amber, Chapman, Jennifer, Dares, Lauren, Borden, Laura, Gibbs, Donna, Schultz, Jessica, Sergeenko, Nikita, Francis, Fiona, Weltman, Amanda, Moity, Nicolas, Ramírez-González, Jorge, Mucientes, Gonzalo, Alonso-Fernández, Alexandre, Namir, Itai, Bar-Massada, Avi, Chen, Ron, Yedvab, Shmulik, Okey, Thomas A., Oppel, Steffen, Arkumarev, Volen, Bakari, Samuel, Dobrev, Vladimir, Saravia-Mullin, Victoria, Bounas, Anastasios, Kret, Elzbieta, Mengistu, Solomon, Pourchier, Cloé, Ruffo, Alazar, Tesfaye, Million, Wondafrash, Mengistu, Nikolov, Stoyan C., Palmer, Charles, Sileci, Lorenzo, Rex, Patrick T., Lowe, Christopher G., Peters, Francesc, Pine, Matthew K., Radford, Craig A, Wilson, Louise, McWhinnie, Lauren, Scuderi, Alessia, Jeffs, Andrew G., Prudic, Kathleen L., Larrivée, Maxim, McFarland, Kent P., Solis, Rodrigo, Hutchinson, Rebecca A., Queiroz, Nuno, Furtado, Miguel A., Sims, David W., Southall, Emily, Quesada-Rodriguez, Claudio A., Diaz-Orozco, Jessica P., Rodgers, Ku'ulei S., Severino, Sarah J.L., Graham, Andrew, Stefanak, Matthew P., Madin, Elizabeth M.P., Ryan, Peter G., Maclean, Kyle, Weideman, Eleanor A., Sekercioğlu, Cağan H., Kittelberger, Kyle D., Kusak, Josip, Seminoff, Jeffrey A., Hanna, Megan E., Shimada, Takahiro, Meekan, Mark G., Smith, Martin, Mokhatla, Mohlamatsane M., Soh, Malcolm C.K., Pang, Roanna Y.T., Ng, Breyl X.K., Lee, Benjamin P.Y.-H., Loo, Adrian H.B., Er, Kenneth B.H., Souza, Gabriel B.G., Stallings, Christopher D., Curtis, Joseph S., Faletti, Meaghan E., Peake, Jonathan A., Schram, Michael J., Wall, Kara R., Terry, Carina, Rothendler, Matt, Zipf, Lucy, Ulloa, Juan Sebastián, Hernández-Palma, Angélica, Gómez-Valencia, Bibiana, Cruz-Rodríguez, Cristian, Herrera-Varón, Yenifer, Roa, Margarita, Rodríguez-Buriticá, Susana, Ochoa-Quintero, Jose Manuel, Vardi, Reut, Vázquez, Víctor, Requena-Mesa, Christian, Warrington, Miyako H., Taylor, Michelle E., Woodall, Lucy C., Stefanoudis, Paris V., Zhang, Xiangliang, Yang, Qiang, Zukerman, Yuval, Sigal, Zehava, Ayali, Amir, Clua, Eric, Carzon, Pamela, Seguine, Clementine, Corradini, Andrea, Pedrotti, Luca, Foley, Catherine M., Gagnon, Catherine Alexandra, Panipakoochoo, Elijah, Milanes, Celene B., Botero, Camilo M., Velázquez, Yunior R., Milchakova, Nataliya A., Morley, Simon A., Martin, Stephanie M., Nanni, Veronica, Otero, Tania, Wakeling, Julia, Abarro, Sarah, Piou, Cyril, et al., Bates, Amanda E., Primack, Richard B., Biggar, Brandy S., Bird, Thomas J., Clinton, Mary E., Command, Rylan J., Richards, Cerren, Shellard, Marc, Geraldi, Nathan R., Vergara, Valeria, Acevedo-Charry, Orlando, Colón-Piñeiro, Zuania, Ocampo, David, Ocampo-Peñuela, Natalia, Sánchez-Clavijo, Lina M., Adamescu, Cristian M., Cheval, Sorin, Racoviceanu, Tudor, Adams, Matthew D., Kalisa, Egide, Kuuire, Vincent Z., Aditya, Vikram, Anderwald, Pia, Wiesmann, Samuel, Wipf, Sonja, Badihi, Gal, Henderson, Matthew G., Loetscher, Hanspeter, Baerenfaller, Katja, Benedetti-Cecchi, Lisandro, Bulleri, Fabio, Bertocci, Lacopo, Maggi, Elena, Rindi, Luca, Ravaglioli, Chiara, Boerder, Kristina, Bonnel, Julien, Mathias, Delphine, Archambault, Philippe, Chauvaud, Laurent, Braun, Camrin D., Thorrold, Simon R., Brownscombe, Jacob W., Midwood, Jonathan D., Boston, Christine M., Brooks, Jill L., Cooke, Steven J., China, Victor, Roll, Uri, Belmaker, Jonathan, Zvuloni, Assaf, Coll, Marta, Ortega, Miquel, Connors, Brendan, Lacko, Lisa, Jayathilake, Dinusha R.M., Costello, Mark J., Crimmins, Theresa M., Barnett, LoriAnne, Denny, Ellen G., Gerst, Katharine L., Marsh, R.L., Posthumus, Erin E., Rodriguez, Reilly, Rosemartin, Alyssa, Schaffer, Sara N., Switzer, Jeff R., Wong, Kevin, Cunningham, Susan J., Sumasgutner, Petra, Amar, Arjun, Thomson, Robert L., Stofberg, Miqkayla, Hofmeyr, Sally, Suri, Jessleena, Stuart-Smith, Rick D., Day, Paul B., Edgar, Graham J., Cooper, Antonia T., Cabrera De Leo, Fabio, Garner, Grant, Des Brisay, Paulson G., Schrimpf, Michael B., Koper, Nicola, Diamond, Michael S., Dwyer, Ross G., Baker, Cameron J, Franklin, Craig E., Efrat, Ron, Berger-Tal, Oded, Hatzofe, Ohad, Eguíluz, Víctor M., Rodríguez, Jorge P., Fernández-Gracia, Juan, Elustondo, David, Calatayud, Vicent, English, Philina A., Archer, Stephanie K., Dudas, Sarah E., Haggarty, Dana R., Gallagher, Austin J., Shea, Brandan D., Shipley, Oliver N., Gilby, Ben L., Ballantyne, Jasmine, Olds, Andrew D., Henderson, Christopher J., Schlacher, Thomas A., Halliday, William D., Brown, Nicholas A.W., Woods, Mackenzie B., Balshine, Sigal, Juanes, Francis, Rider, Mitchell J., Albano, Patricia S., Hammerschlag, Neil, Hays, Graeme C., Esteban, Nicole, Pan, Yuhang, He, Guojun, Tanaka, Takanao, Hensel, Marc J.S., Orth, Robert J., Patrick, Christopher J., Hentati-Sundberg, Jonas, Olsson, Olof, Hessing-Lewis, Margot L., Higgs, Nicholas D., McMahon, Clive R., Harcourt, Rob, Guinet, Christophe, Hirsch, Sarah E., Perrault, Justin R., Hoover, Shelby R., Reilly, Jennifer D., Hobaiter, Catherine, Gruber, Thibaud, Huveneers, Charlie, Udyawer, Vinay, Clarke, Thomas M., Kroesen, Laura P., Hik, David S., Cherry, Seth G., Del Bel Belluz, Justin A., Jackson, Jennifer M., Lai, Shengjie, Lamb, Clayton T., LeClair, Gregory D., Parmelee, Jeffrey R., Chatfield, Matthew W.H., Frederick, Cheryl A., Lee, Sangdon, Park, Hyomin, Choi, Jaein, LeTourneux, Frédéric, Grandmont, Thierry, Dulude de-Broin, Frédéric, Bêty, Joël, Gauthier, Gilles, Legagneux, Pierre, Lewis, Jesse S., Haight, Jeffrey, Liu, Zhu, Lyon, Jarod P., Hale, Robin, D'Silva, Dallas, MacGregor-Fors, Ian, Arbelaez-Cortes, Enrique, Estela, Felipe A., Sánchez-Sarria, Camilo E., García-Arroyo, Michelle, Aguirre-Samboní, Giann K., Franco Morales, Juan C., Malamud, Shahar, Gavriel, Tal, Buba, Yehezkel, Salingré, Shira, Lazarus, Mai, Yahel, Ruthy, Ben Ari, Yigael, Miller, Eyal, Sade, Rotem, Lavian, Guy, Birman, Ziv, Gury, Manor, Baz, Harel, Baskin, Ilia, Penn, Alon, Dolev, Amit, Licht, Ogen, Karkom, Tabi, Davidzon, Sharon, Berkovitch, Avi, Yaakov, Ofer, Manenti, Raoul, Mori, Emiliano, Ficetola, Gentile Francesco, Lunghi, Enrico, March, David, Godley, Brendan J., Martin, Cecilia, Mihaly, Steven F., Barclay, David R., Thomson, Dugald J.M., Dewey, Richard, Bedard, Jeannette, Miller, Aroha, Dearden, Amber, Chapman, Jennifer, Dares, Lauren, Borden, Laura, Gibbs, Donna, Schultz, Jessica, Sergeenko, Nikita, Francis, Fiona, Weltman, Amanda, Moity, Nicolas, Ramírez-González, Jorge, Mucientes, Gonzalo, Alonso-Fernández, Alexandre, Namir, Itai, Bar-Massada, Avi, Chen, Ron, Yedvab, Shmulik, Okey, Thomas A., Oppel, Steffen, Arkumarev, Volen, Bakari, Samuel, Dobrev, Vladimir, Saravia-Mullin, Victoria, Bounas, Anastasios, Kret, Elzbieta, Mengistu, Solomon, Pourchier, Cloé, Ruffo, Alazar, Tesfaye, Million, Wondafrash, Mengistu, Nikolov, Stoyan C., Palmer, Charles, Sileci, Lorenzo, Rex, Patrick T., Lowe, Christopher G., Peters, Francesc, Pine, Matthew K., Radford, Craig A, Wilson, Louise, McWhinnie, Lauren, Scuderi, Alessia, Jeffs, Andrew G., Prudic, Kathleen L., Larrivée, Maxim, McFarland, Kent P., Solis, Rodrigo, Hutchinson, Rebecca A., Queiroz, Nuno, Furtado, Miguel A., Sims, David W., Southall, Emily, Quesada-Rodriguez, Claudio A., Diaz-Orozco, Jessica P., Rodgers, Ku'ulei S., Severino, Sarah J.L., Graham, Andrew, Stefanak, Matthew P., Madin, Elizabeth M.P., Ryan, Peter G., Maclean, Kyle, Weideman, Eleanor A., Sekercioğlu, Cağan H., Kittelberger, Kyle D., Kusak, Josip, Seminoff, Jeffrey A., Hanna, Megan E., Shimada, Takahiro, Meekan, Mark G., Smith, Martin, Mokhatla, Mohlamatsane M., Soh, Malcolm C.K., Pang, Roanna Y.T., Ng, Breyl X.K., Lee, Benjamin P.Y.-H., Loo, Adrian H.B., Er, Kenneth B.H., Souza, Gabriel B.G., Stallings, Christopher D., Curtis, Joseph S., Faletti, Meaghan E., Peake, Jonathan A., Schram, Michael J., Wall, Kara R., Terry, Carina, Rothendler, Matt, Zipf, Lucy, Ulloa, Juan Sebastián, Hernández-Palma, Angélica, Gómez-Valencia, Bibiana, Cruz-Rodríguez, Cristian, Herrera-Varón, Yenifer, Roa, Margarita, Rodríguez-Buriticá, Susana, Ochoa-Quintero, Jose Manuel, Vardi, Reut, Vázquez, Víctor, Requena-Mesa, Christian, Warrington, Miyako H., Taylor, Michelle E., Woodall, Lucy C., Stefanoudis, Paris V., Zhang, Xiangliang, Yang, Qiang, Zukerman, Yuval, Sigal, Zehava, Ayali, Amir, Clua, Eric, Carzon, Pamela, Seguine, Clementine, Corradini, Andrea, Pedrotti, Luca, Foley, Catherine M., Gagnon, Catherine Alexandra, Panipakoochoo, Elijah, Milanes, Celene B., Botero, Camilo M., Velázquez, Yunior R., Milchakova, Nataliya A., Morley, Simon A., Martin, Stephanie M., Nanni, Veronica, Otero, Tania, Wakeling, Julia, Abarro, Sarah, Piou, Cyril, and et al.

Abstract

The global lockdown to mitigate COVID-19 pandemic health risks has altered human interactions with nature. Here, we report immediate impacts of changes in human activities on wildlife and environmental threats during the early lockdown months of 2020, based on 877 qualitative reports and 332 quantitative assessments from 89 different studies. Hundreds of reports of unusual species observations from around the world suggest that animals quickly responded to the reductions in human presence. However, negative effects of lockdown on conservation also emerged, as confinement resulted in some park officials being unable to perform conservation, restoration and enforcement tasks, resulting in local increases in illegal activities such as hunting. Overall, there is a complex mixture of positive and negative effects of the pandemic lockdown on nature, all of which have the potential to lead to cascading responses which in turn impact wildlife and nature conservation. While the net effect of the lockdown will need to be assessed over years as data becomes available and persistent effects emerge, immediate responses were detected across the world. Thus, initial qualitative and quantitative data arising from this serendipitous global quasi-experimental perturbation highlights the dual role that humans play in threatening and protecting species and ecosystems. Pathways to favorably tilt this delicate balance include reducing impacts and increasing conservation effectiveness.

Published
2021

38. Integrating environmental variability to broaden the research on coral responses to future ocean conditions

Author

King Abdullah University of Science and Technology, Swiss National Science Foundation, Swiss National Supercomputing Centre, European Commission, Ziegler, Maren, Anton, Andrea, Klein, Shannon G., Rädecker, Nils, Geraldi, Nathan R., Schmidt-Roach, Sebastian, Saderne, Vincent, Mumby, Peter J., Cziesielski, Maha J., Martin, Cecilia, King Abdullah University of Science and Technology, Swiss National Science Foundation, Swiss National Supercomputing Centre, European Commission, Ziegler, Maren, Anton, Andrea, Klein, Shannon G., Rädecker, Nils, Geraldi, Nathan R., Schmidt-Roach, Sebastian, Saderne, Vincent, Mumby, Peter J., Cziesielski, Maha J., and Martin, Cecilia

Abstract

Our understanding of the response of reef-building corals to changes in their physical environment is largely based on laboratory experiments, analysis of long-term field data, and model projections. Experimental data provide unique insights into how organisms respond to variation of environmental drivers. However, an assessment of how well experimental conditions cover the breadth of environmental conditions and variability where corals live successfully is missing. Here, we compiled and analyzed a globally distributed dataset of in-situ seasonal and diurnal variability of key environmental drivers (temperature, pCO2, and O2) critical for the growth and livelihood of reef-building corals. Using a meta-analysis approach, we compared the variability of environmental conditions assayed in coral experimental studies to current and projected conditions in their natural habitats. We found that annual temperature profiles projected for the end of the 21st century were characterized by distributional shifts in temperatures with warmer winters and longer warm periods in the summer, not just peak temperatures. Furthermore, short-term hourly fluctuations of temperature and pCO2 may regularly expose corals to conditions beyond the projected average increases for the end of the 21st century. Coral reef sites varied in the degree of coupling between temperature, pCO2, and dissolved O2, which warrants site-specific, differentiated experimental approaches depending on the local hydrography and influence of biological processes on the carbonate system and O2 availability. Our analysis highlights that a large portion of the natural environmental variability at short and long timescales is underexplored in experimental designs, which may provide a path to extend our understanding on the response of corals to global climate change.

Published
2021

40. Development of an automated space rated solar panel array for future lunar rover mission

Author

Martinez Martin, Cecilia

Subjects
Teknik och teknologier, Engineering and Technology
Abstract

Space industry has been enormously growing in the last decades. Energy harvestingfor space applications is usually a critical aspect of space missions, andtherefore a method for doing it is included in most of the satellites and vehiclessent to space. This project focuses on energy harvesting for a Moon Rover.This will be done via a deployable solar panel system, which will be orientablein order to maximize the eciency.This project is divided in two parts. The rst one will be the mechanicaldesign of the deployment system. The main deployment will be accomplishedvia a composite material boom, which will pull up a solar panel array. A seconddeployment phase will be accomplished using aps that will slide out of themain system.The second part of the project will focus on the control of the panels. Thistask will be achieved using Model Predictive Control (MPC). This control willnd the optimal way of moving the panels so that the energy is eciently used. Rymdindustrin har ökat enormt under de senaste decennierna. Energi skörd förrymdapplikationer är vanligtvis en kritisk aspekt av rymduppdrag, och därför ingår en metod för att göra det i de flesta av satelliter och fordon skickas till rymden. Projektet fokuserar på energi skörd för en Moon Rover. Detta kommer att göras via ett utplacerbart solpanelsystem, vilket är orienterbart för att maximera effektiviteten.Det här projektet är uppdelat i två delar. Den första är den mekaniska design av utplacering systemet. Huvudinstallationen kommer att genomföras via en sammansatt materialbom, som drar upp en solpaneluppsättning. En annan utplacering fas genomförs med klaffar som kommer att glida ut ur huvudsystem. Den andra delen av projektet kommer att fokusera på kontrollen av panelerna. Det här uppgiften uppnås med hjälp av Model Predictive Control (MPC). Den här kontrollen kommer hitta det optimala sättet att flytta panelerna så attenergin används effektivt.

Published
2020

41. Fate of Plastic Pollution in the Arabian Seas

Author

Martin, Cecilia

Subjects
fungi, humanities
Abstract

Plastic pollution has become of public concern recently and only in the last decades the need of quantifying loads of plastic in the marine environment and identifying their ultimate destination has been urged as a mean to point at where interventions should concentrate. The Arabian seas (Red Sea and Arabian Gulf) have oceanographic features that candidate them as accumulation zones for marine plastics, but, especially the Red Sea, are largely unexplored. The dissertation here presented provides significant advances in the understanding of the marine plastic distribution in the two basins. Despite the initial hypothesis, the Red Sea was found to hold a remarkably low abundance of plastic particles in its surface waters. Similarly, previous assessments have reported the same in the Arabian Gulf. In line with the global estimates, only a small portion of the plastic that is discarded yearly in the marine environment is found in its surface waters, implying the presence of removal processes. However, the unexpectedly low loads of floating plastics in the Arabian seas indicate that sinks are likely more significant here than elsewhere. In the Red Sea, an extensive survey of macroplastic stranded on shores, globally considered a major sink of marine plastic, has indicated that Avicennia marina mangrove forests, through the mesh created by their pneumatophores, contribute significantly more than unvegetated shores in retaining plastics. Loads of plastic in the Arabian Gulf mangrove stands, more impacted by coastal development than stands in the Red Sea, are even larger. The role of mangroves as significant sinks of plastics is further corroborated by the finding that the burial rates of plastic in their sediments follow an exponential increase in line with the global plastic production increase, ultimately demonstrating that plastic is likely sequestered there permanently. Mangrove forests alone are, however, not enough to justify the mismatch between plastic inputs and loads in surface waters. The experimental finding showed here that coral structures can passively trap substantial loads of microplastics and the large extension of reefs, especially in the Red Sea, suggest that reefs might constitute a missing sink of marine plastic in the basin worth exploring.

Published
2020
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42. Investing in Blue Natural Capital to Secure a Future for the Red Sea Ecosystems

Author

Cziesielski, Maha J., Duarte, Carlos M., Aalismail, Nojood, Al-Hafedh, Yousef, Rodríguez Antón, Andrea, Baalkhuyur, Faiyah, Baker, Andrew C., Balke, Thorsten, Baums, Iliana B., Berumen, Michael, Chalastani, Vasiliki I., Cornwell, Brendan, Daffonchio, Daniele, Diele, Karen, Farooq, Ehtesaam, Gattuso, Jean-Pierre, He, Song, Lovelock, Catherine E., McLeod, Elizabeth, Macreadie, Peter I., Marbà, Núria, Martin, Cecilia, Muniz-Barreto, Marcelle, Kadinijappali, Kirshnakumar P., Prihartato, Perdana, Rabaoui, Lotfi, Saderne, Vincent, Schmidt-Roach, Sebastian, Suggett, David J., Sweet, Michael, Statton, John, Teicher, Sam, Trevathan-Tackett, Stacey M., Joydas, Thadickal V., Yahya, Razan, Aranda, Manuel, Cziesielski, Maha J., Duarte, Carlos M., Aalismail, Nojood, Al-Hafedh, Yousef, Rodríguez Antón, Andrea, Baalkhuyur, Faiyah, Baker, Andrew C., Balke, Thorsten, Baums, Iliana B., Berumen, Michael, Chalastani, Vasiliki I., Cornwell, Brendan, Daffonchio, Daniele, Diele, Karen, Farooq, Ehtesaam, Gattuso, Jean-Pierre, He, Song, Lovelock, Catherine E., McLeod, Elizabeth, Macreadie, Peter I., Marbà, Núria, Martin, Cecilia, Muniz-Barreto, Marcelle, Kadinijappali, Kirshnakumar P., Prihartato, Perdana, Rabaoui, Lotfi, Saderne, Vincent, Schmidt-Roach, Sebastian, Suggett, David J., Sweet, Michael, Statton, John, Teicher, Sam, Trevathan-Tackett, Stacey M., Joydas, Thadickal V., Yahya, Razan, and Aranda, Manuel

Abstract

For millennia, coastal and marine ecosystems have adapted and flourished in the Red Sea’s unique environment. Surrounded by deserts on all sides, the Red Sea is subjected to high dust inputs and receives very little freshwater input, and so harbors a high salinity. Coral reefs, seagrass meadows, and mangroves flourish in this environment and provide socio-economic and environmental benefits to the bordering coastlines and countries. Interestingly, while coral reef ecosystems are currently experiencing rapid decline on a global scale, those in the Red Sea appear to be in relatively better shape. That said, they are certainly not immune to the stressors that cause degradation, such as increasing ocean temperature, acidification and pollution. In many regions, ecosystems are already severely deteriorating and are further threatened by increasing population pressure and large coastal development projects. Degradation of these marine habitats will lead to environmental costs, as well as significant economic losses. Therefore, it will result in a missed opportunity for the bordering countries to develop a sustainable blue economy and integrate innovative nature-based solutions. Recognizing that securing the Red Sea ecosystems’ future must occur in synergy with continued social and economic growth, we developed an action plan for the conservation, restoration, and growth of marine environments of the Red Sea. We then investigated the level of resources for financial and economic investment that may incentivize these activities. This study presents a set of commercially viable financial investment strategies, ecological innovations, and sustainable development opportunities, which can, if implemented strategically, help ensure long-term economic benefits while promoting environmental conservation. We make a case for investing in blue natural capital and propose a strategic development model that relies on maintaining the health of natural ecosystems to safeguard the Red Sea

Published
2020

46. Projecting coral responses to intensifying marine heatwaves under ocean acidification.

Author

Klein, Shannon G., Geraldi, Nathan R., Anton, Andrea, Schmidt‐Roach, Sebastian, Ziegler, Maren, Cziesielski, Maha J., Martin, Cecilia, Rädecker, Nils, Frölicher, Thomas L., Mumby, Peter J., Pandolfi, John M., Suggett, David J., Voolstra, Christian R., Aranda, Manuel, and Duarte, Carlos. M.

Subjects
OCEAN acidification, CORAL bleaching, CORALS, CORAL reefs & islands, CORAL declines, CLIMATE change, GREENHOUSE gases
Abstract

Over this century, coral reefs will run the gauntlet of climate change, as marine heatwaves (MHWs) become more intense and frequent, and ocean acidification (OA) progresses. However, we still lack a quantitative assessment of how, and to what degree, OA will moderate the responses of corals to MHWs as they intensify throughout this century. Here, we first projected future MHW intensities for tropical regions under three future greenhouse gas emissions scenario (representative concentration pathways, RCP2.6, RCP4.5 and RCP8.5) for the near‐term (2021–2040), mid‐century (2041–2060) and late‐century (2081–2100). We then combined these MHW intensity projections with a global data set of 1,788 experiments to assess coral attribute performance and survival under the three emissions scenarios for the near‐term, mid‐century and late‐century in the presence and absence of OA. Although warming and OA had predominately additive impacts on the coral responses, the contribution of OA in affecting most coral attributes was minor relative to the dominant role of intensifying MHWs. However, the addition of OA led to greater decreases in photosynthesis and survival under intermediate and unrestricted emissions scenario for the mid‐ and late‐century than if intensifying MHWs were considered as the only driver. These results show that role of OA in modulating coral responses to intensifying MHWs depended on the focal coral attribute and extremity of the scenario examined. Specifically, intensifying MHWs and OA will cause increasing instances of coral bleaching and substantial declines in coral productivity, calcification and survival within the next two decades under the low and intermediate emissions scenario. These projections suggest that corals must rapidly adapt or acclimatize to projected ocean conditions to persist, which is far more likely under a low emissions scenario and with increasing efforts to manage reefs to enhance resilience. [ABSTRACT FROM AUTHOR]

Published
2022
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49. Genetic Overlap in Kallmann Syndrome, Combined Pituitary Hormone Deficiency, and Septo-Optic Dysplasia

Author

Raivio, Taneli, Avbelj, Magdalena, McCabe, Mark J., Romero, Christopher J., Dwyer, Andrew A., Tommiska, Johanna, Sykiotis, Gerasimos P., Gregory, Louise C., Diaczok, Daniel, Tziaferi, Vaitsa, Elting, Mariet W., Padidela, Raja, Plummer, Lacey, Martin, Cecilia, Feng, Bihua, Zhang, Chengkang, Zhou, Qun-Yong, Chen, Huaibin, Mohammadi, Moosa, Quinton, Richard, Sidis, Yisrael, Radovick, Sally, Dattani, Mehul T., and Pitteloud, Nelly

Published
2012

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