Desarrollo de la Aleta Caudal del Salmón (Salmo salar)

Rojas, Mariana; Pellón, Mario; Sol, Mariano del

doi:10.4067/s0717-95022015000200017

Cited by 1 publication

(2 citation statements)

References 21 publications

(20 reference statements)

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“…After that, we did a histological analysis at 950 ATUs (about 3 months) and saw that hypoxia caused more new blood vessels to form (angiogenesis), which could be seen as a response to get more oxygen to the tissues. Rojas et al (2015) have previously described both the histology and anatomy of the salmon caudal fin at different stages of development, making the diagnosis of early pathologies in said structure more plausible. According to Griffioen and Molema (2000) and Distler et al (2003), hypoxia constitutes the main stimulus for the formation of new blood vessels by inducing, by endothelial, tumor, inflammatory cells, and macrophages, the production of pro-angiogenic factors such as vascular endothelial growth factor (VEGF).…”

Section: Histology Of the Caudal Fin Of Fry From 950 Atus In Hypoxiamentioning

confidence: 99%

“…The situation is very different in post-hatching fry. At this stage of development, lepidotrichia are not easily detectable in the caudal fin because they are not yet ossified or calcified, do not present segmentations or bifurcations, and the lobes or the groove between lobes are not recognized (Rojas et al, 2015). A groove separates two lobes of similar size when the fry reaches 30 mm in length and 950 accumulated temperature units (ATUs).…”

Section: Introductionmentioning

confidence: 99%

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Effect of hypoxia on the post-hatching growth of the body of the fry and the caudal fin of the Atlantic Salmon (Salmo salar)

Rojas,

Salvatierra,

Smok

et al. 2024

Front. Mar. Sci.

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IntroductionHypoxia is a recurring problem in the fish farming industry. Currently, it is known that the exposure of fish and fry to a hypoxic environment induces important changes in their metabolism, compromising not only their development but also their reproduction and mortality rates. Our hypothesis is that hypoxia constitutes one of the etiological factors causing deformation of the body and caudal fin in this species, as well as affecting its growth.MethodsWe analyzed two hundred forty Salmo salar salmon fry, differentially cultured at 100% saturation (normoxia condition) and 60% (hypoxia condition) for 2, 4, 6, and 8 days, including a group under continuous hypoxia. We performed diaphanization and Alcian blue staining, along with standard histological techniques. The polyclonal anti-HIF-1a antibody was used as a marker of hypoxia in Salmo salar, and hypoxia in these fish was associated with the immunopositivity of this antibody.Results and discussionThe results indicate that there is an association between exposure to hypoxia and the deformation of the body and fin, as well as an agreement between hypoxia and the total length of the fry and fin. Several months after the event occurred, we were able to find and describe angiogenesis, blood vessel disorganization, and vasodilation histologically. Finally, hypoxic cells in the fry (HIF-1a) could be recognized and confirmed as hypoxia sensors. All of this indicates that hypoxia not only affects the fry during the development phase of the event, but that its results can be evident much later and affect the fry throughout their entire ontogeny.

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Section: Histology Of the Caudal Fin Of Fry From 950 Atus In Hypoxiamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%