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Xiao, X. et al. Microbial ecosystems and ecological driving forces within the deepest ocean sediments. Cell 188(5), 1363–1377 (2025).
Casey S: The Underworld: Journeys to the Depths of the Ocean: Random House; 2024, ISBN:9781804950906.
Haddock, S. H. & Choy, C. A. Life within the midwater: The ecology of deep pelagic animals. Annu. Rev. Mar. Sci. 16(1), 383–416 (2024).
Gerringer, M. On the success of the hadal snailfishes. Integr. Organism. Biol. 1(1), obz004 (2019).
Gerringer, M. E., Linley, T. D., Jamieson, A. J., Goetze, E. & Drazen, J. C. Pseudoliparis swirei sp. nov.: A newly-discovered hadal snailfish (Scorpaeniformes: Liparidae) from the Mariana Trench. Zootaxa 4358(1), 161–177-161-177 (2017).
Jamieson, A. J. et al. New most depth file for bony fish: Teleostei, Scorpaeniformes, Liparidae (8336 m, Izu-Ogasawara Trench). Deep Sea Res. Part I Oceanogr. Res. Pap. 199, 104132 (2023).
Priede, I. G., Smith, Ok. L. Jr. & Armstrong, J. D. Foraging habits of abyssal grenadier fish: Inferences from acoustic tagging and monitoring within the North Pacific Ocean. Deep Sea Research Part A. Oceanographic Research Papers 37(1), 81–101 (1990).
Wang, Ok. et al. Morphology and genome of a snailfish from the Mariana Trench present insights into deep-sea adaptation. Nat. Ecol. Evol. 3(5), 823–833 (2019).
Gerringer, M. et al. Habitat influences skeletal morphology and density within the snailfishes (household Liparidae). Front. Zool. 18, 1–22 (2021).
Schwarzhans, W. W. & Gerringer, M. E. Otoliths of the deepest-living fishes. Deep Sea Res. Part I Oceanogr. Res. Pap. 198, 104079 (2023).
Jiang, H., Du, Ok., Gan, X., Yang, L. & He, S. Massive lack of olfactory receptors however not hint amine-associated receptors on the planet’s deepest-living fish (Pseudoliparis swirei). Genes 10(11), 910 (2019).
Gerringer, M. E., Linley, T. D. & Nielsen, J. G. Revision of the depth file of bony fishes with notes on hadal snailfishes (Liparidae, Scorpaeniformes) and cusk eels (Ophidiidae, Ophidiiformes). Mar. Biol. 168(11), 167 (2021).
Xu, H. et al. Evolution and genetic adaptation of fishes to the deep sea. Cell 188(5), 1393–1408 (2025).
Woodworth, B. et al. Swimming kinematics of deep-sea fishes. J. Fish Biol. 106(3), 805–822 (2025).
Drazen, J. C. & Seibel, B. A. Depth-related traits in metabolism of benthic and benthopelagic deep-sea fishes. Limnol. Oceanogr. 52(5), 2306–2316 (2007).
Priede, I. & Froese, R. Colonization of the deep sea by fishes. J. Fish Biol. 83(6), 1528–1550 (2013).
Gerringer M: On the Success of the Hadal Snailfishes: The Influence of Trophic Ecology, Life History, and Pressure Adaptation on Depth Zonation within the Planet’s Deepest-Living Fishes: University of Hawai’i at Manoa; 2017 http://hdl.handle.net/10125/62513.
Bailey, D. M., Bagley, P. M., Jamieson, A. J., Collins, M. A. & Priede, I. G. In situ investigation of burst swimming and muscle efficiency within the deep-sea fish Antimora rostrata. J. Exp. Mar. Biol. Ecol. 285, 295–311 (2003).
Black J, Neuheimer A, Horn P, Tracey DM, Drazen J: Environmental, evolutionary, and ecological drivers of sluggish progress in deep-sea demersal teleosts. Marine Ecology Progress Series 2020, 658.
Deng, X., Wagner, H.-J. & Popper, A. N. Comparison of the saccules and lagenae in six macrourid fishes from totally different deep-sea habitats. J. Acoust. Soc. Am. 141(5_Supplement), 3860–3861 (2017).
Stevens, D. W. et al. Rattail lebensspuren: Feeding impressions from deep-sea grenadiers. Deep Sea Res. Part I Oceanogr. Res. Pap. 200, 104152 (2023).
Linley, T. D. et al. Fishes of the hadal zone together with new species, in situ observations and depth information of Liparidae. Deep Sea Res. Part I Oceanogr. Res. Pap. 114, 99–110 (2016).
Taira, Ok., Kitagawa, S., Yamashiro, T. & Yanagimoto, D. Deep and backside currents within the Challenger Deep, Mariana Trench, measured with super-deep present meters. J. Oceanogr. 60, 919–926 (2004).
Jiang, H. et al. Three-layer circulation on the planet deepest hadal trench. Nat. Commun. 15(1), 8949 (2024).
Collins, M. A., Priede, I. G. & Bagley, P. M. In situ comparability of exercise in two deep-sea scavenging fishes occupying totally different depth zones. Proc. R. Soc. Lond. B Biol. Sci. 266(1432), 2011–2016 (1999).
Koslow, J. Energetic and life-history patterns of deep-sea benthic, benthopelagic and seamount-associated fish. J. Fish Biol. 49, 54–74 (1996).
Drazen, J. C. & Haedrich, R. L. A continuum of life histories in deep-sea demersal fishes. Deep Sea Res. Part I Oceanogr. Res. Pap. 61, 34–42 (2012).
Poulson, T. L. Adaptations of cave fishes with some comparisons to deep-sea fishes. Environ. Biol. Fish. 62(1), 345–364 (2001).
Warrant, E. J. & Locket, N. A. Vision within the deep sea. Biol. Rev. 79(3), 671–712 (2004).
Warrant, E. The eyes of deep–sea fishes and the altering nature of visible scenes with depth. Philos. Trans. R. Soc. Lond. B Biol. Sci. 355(1401), 1155–1159 (2000).
Shekhar G: Fisheries Acoustics: Understanding Aquatic Environments: Educohack Press; 2025, ISBN: 9789361526527.
Bailey, D. M., Wagner, H.-J., Jamieson, A. J., Ross, M. F. & Priede, I. G. A style of the deep-sea: The roles of gustatory and tactile looking out behaviour within the grenadier fish Coryphaenoides armatus. Deep Sea Res. Part I Oceanogr. Res. Pap. 54(1), 99–108 (2007).
Horn, M. H. & Ferry-Graham, L. A. Feeding mechanisms and trophic interactions. In The ecology of marine fishes: California and adjoining waters 387–410 (2006).
Blankenship, L. E. & Levin, L. A. Extreme meals webs: Foraging methods and diets of scavenging amphipods from the ocean’s deepest 5 kilometers. Limnol. Oceanogr. 52(4), 1685–1697 (2007).
Xu, H., Fang, C. & He, S. Deciphering the life adaptation in excessive excessive stress: Genomic breakthroughs and ecological insights in fish from hadal zone. Innovation (2025).
Xu, H., Fang, C., Wang, C., Gan, X. & He, S. Lipidome and proteome analyses present insights into Mariana Trench snailfish (Pseudoliparis swirei) adaptation to the hadal zone. Water Biol. Secur. 3(4), 100295 (2024).
Srivastava A: A textbook of vertebrate zoology: Academic Guru Publishing House; 2024, ISBN: 978–81–970707–1–6.
Howard J: Fish biology and fisheries: Scientific e-Resources; 2019.
Gerringer, M. E. et al. Distribution, composition and features of gelatinous tissues in deep-sea fishes. R. Soc. Open Sci. 4(12), 171063 (2017).
Gerringer, M. et al. Habitat influences skeletal morphology and density within the snailfishes (household Liparidae). Front. Zool. 18(1), 16 (2021).
Blanton, J. M. et al. Microbiomes of hadal fishes throughout trench habitats include related taxa and recognized piezophiles. mSphere 7(2), e00032-e122 (2022).
Gerringer, M. E. et al. Observations of deep-sea fishes at depths 250 to 6300 m off Puerto Rico. ICES J. Mar. Sci. 83(1), fsaf234 (2026).
Yagi, M., Anzai, S. & Tanaka, S. Dive deep: Bioenergetic adaptation of deep-sea animals. Zool. Sci. 42(1), 83–95 (2025).
Xu, W. et al. Chromosome-level genome meeting of hadal snailfish reveals mechanisms of deep-sea adaptation in vertebrates. Elife 12, RP87198 (2023).
Barcan, A. S. et al. Understanding the switch and persistence of antimicrobial resistance in aquaculture utilizing a mannequin teleost intestine system. Anim. Microbiome 7(1), 18 (2025).
Barcan, A. S. et al. Modulatory results of Boletus edulis on the intestine microbiota in Atlantic salmon (Salmo salar) using a synthetic teleost intestine mannequin. Anim. Microbiome 7(1), 111 (2025).
Zhang J, Wang Y: A video dataset for hadal snailfish together with the benchmark. Deep Sea Research Part I: Oceanographic Research Papers 2025:104517.
Amin, S. U., Abbas, M. S., Kim, B., Jung, Y. & Seo, S. Enhanced anomaly detection in pandemic surveillance movies: An consideration strategy with EfficientNet-B0 and CBAM integration. IEEE Access (2024).
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