Patterns description of hyperostosis observed in Atlantic moonfish Selene setapinnis and lookdown Selene vomer.

Hyperostosis manifests itself and develops differently in taxonomically related species. Radiographic images of individuals belonging to different size classes of Atlantic Moonfish Selene setapinnis and Lookdown Selene vomer were obtained from two different estuarine areas of Rio de Janeiro/Brazil. In S. setapinnis, hyperostosis occurred in 65.22% of the specimens analyzed in three different skeletal regions. All specimens of S. vomer had hyperostosis in four regions. Patterns of occurrence were detected in both species, and the affected regions did not coincide in the same bone region, except for the cleithrum. Hyperostosis in S. setapinnis were observed in high frequencies of seventh dorsal pterygiophore, whereas in specimens of S. vomer this condition was detected to a greater extent in the neural spines of the second abdominal vertebra and first to third caudal vertebrae. The data demonstrated a relationship between the sexual maturity and the occurrence and development of hyperostotic bones in ageing process of individuals. It is the first description of S. vomer with a hyperostosis phenomenon for the species on the Brazilian coast.

Development of short-snouted seahorse (Hippocampus hippocampus, L. 1758): osteological and morphological aspects.

Information about early development after male release lags behind studies of juveniles and adult seahorses, and newborn seahorses, similar in shape to adults, are considered juveniles or fry. During early life, Hippocampus hippocampus present behavioural (shift in habitat, from planktonic to benthic) and morphological changes; for this reasons, the aims of this study are to define the stage of development of H. hippocampus after they are expelled from the male brood pouch and to establish direct or indirect development through an osteological analysis. The ossification process was studied in 120 individuals, from their release to 30 days after birth. To analyse the osteological development, Alcian Blue-Alizarin Red double staining technique for bone and cartilage was adapted to this species. At birth, H. hippocampus presents a mainly cartilaginous structure that ossifies in approximately 1 month. The bony armour composed of bony rings and plates develops in 10 days. The caudal fin, a structure absent in juveniles and adult seahorses, is present at birth and progressively disappears with age. The absence of adult osteological structure in newborns, like coronet, bony rings and plates, head spines and components allowing tail prehensile abilities, suggests a metamorphosis before the juvenile stage. During the indirect development, the metamorphic stage started inside brood pouch and followed outside and leads up to reconsider the status of H. hippocampus newborns.

Early Osteological Development of Larvae and Juveniles in Red Spotted Grouper, Epinephelus akaara (Pisces: Serranidae).

We observed the osteological development of larval and juvenile red spotted grouper (Epinephelus akaara) in order to generate data for the assessment of skeletal deformities and to inform phylogenetic systematics research. Larvae and juveniles were obtained from a aquafarm in Muan-gun, Jeolla-namdo Province, Korea. The average water temperature at the time of breeding was 23.0°C and average water salinity was 33.0 psu. Freshly hatched fish larvae had not undergone any ossification, but ossification of the parasphenoid bone, which forms the base of the cranium, occurred as the juveniles reached an average body length (BL) of 2.49 mm. At the same time, ossification of the preopercle and opercle occurred in the operculum, and ossification of the maxilla, which forms the upper jaw, and the dentary bones, which form the lower jaw, began. In addition, ossification of the vertebra occurred by formation of 7 vertebral centra and the neural spine in the abdominal vertebra. When the juveniles reached an average (BL) of 5.22 mm, ossification of the nasal, lateral ethmoid, and alisphenoid bones occurred in the cranium; ossification of the endopterygoid and metapterygoid bones began in the palatine region; and ossification of the hypohyal and interhyal bones occurred in the hyoid arch. At an average (BL) of 20.9 mm, ossification of the basisphenoid bone in the cranium and the suborbital bone in the orbital region occurred. Ossification of the vertebra then occurred by the formation of long pairs of ribs from the third to the ninth abdominal vertebrae, completing osteological development.

Development of the vertebral column and caudal skeleton in Prochilodus lineatus larvae under laboratory conditions / Desarrollo de la columna vertebral y del esqueleto caudal en larvas de Prochilodus lineatus en condiciones de larvicultura intensiva

For successful fish larviculture thorough studies describing the development of fish in different morphological aspects are required, as they are crucial for larval survival and growth. The present study described in Prochilodus lineatus larvae the osteological development of the vertebral column and caudal skeleton 30 days after hatching (dah). Larvae were obtained by artificial induction of adults. The beginning of formation of the spine occurs between 10 to 12 dah (8.3 mm standard length, SL) simultaneously to the first neural and hemal processes and the pre-caudal vertebral bodies. The ossification of the vertebral column occurred in cranio-caudal direction and was completed at 28 dah (22.6 mm SL). The development of the caudal skeleton elements started between 6 and 8 dah with the formation of the hypurals (H), the parahipural (PH) and the primary and secondary caudal rays. H 1 to H 3 were formed as cartilaginous primordia on the ventral side of the distal portion of the notochord, while the PH and H 4 to H 6 were formed subsequently. The first rays of the caudal fin were observed in correspondence with the formation of H 2 and H 3, while complete formation of the caudal fin was observed at 28 dah. The epurals, three in number, were evident as cartilaginous elements located both dorsal and distal in the notochord. Central ural complex (CUC) was formed by the fusion of three structures, the center preural 1 and urals 1 and 2. Development of the vertebral column and the caudal skeleton in P. lineatus larvae showed similar patterns to those described for other teleosts.

Se describe el desarrollo osteológico de la columna vertebral y del esqueleto caudal en larvas de sábalo (Prochilodus lineatus) bajo condiciones controladas hasta los 30 días posteriores a la eclosión (dpe). El inicio de la formación de la columna vertebral fue observado entre los 10-12 dpe (8,3 mm de longitud estándar, LE) con la aparición de los primeros procesos neurales, hemales y cuerpos vertebrales pre-caudales. La osificación de la columna vertebral ocurrió en sentido cráneo-caudal y fue completa a los 28 dpe (22,6 mm LE). El esqueleto caudal inició su desarrollo entre los 6 y 8 dpe con la formación de los hipurales (H), parahipural (PH) y los radios caudales principales y secundarios. Los H 1 al 3 se formaron como primordios cartilaginosos en la cara ventral de la porción distal de la notocorda, mientras que posteriormente se formaron los H 4 al 6 y el PH. Los primeros radios de la aleta caudal fueron observados en correspondencia con la formación de los H 2 y 3, mientras que a los 28 dpe se observó la completa formación de los mismos, existiendo 10 radios en el lóbulo dorsal y 9 en el lóbulo ventral. Los epurales, en número de tres, fueron evidentes como elementos cartilaginosos en dorsal de la notocorda y distalmente a los arcos neurales, permaneciendo sin osificarse hasta los 25 dpe. El complejo centro ural se constituyó por la fusión de tres estructuras, el centro preural 1, el ural 1 y 2. El desarrollo de la columna vertebral y del esqueleto caudal muestran patrones similares a los descriptos en otros teleósteos.

Desarrollo Ontogénico de la Columna Vertebral y del Esqueleto Caudal en Larvas de Rhamdia quelen en Condiciones de Larvicultura Intensiva / Ontogenic Development of the Vertebral Column and Caudal Skeleton in Rhamdia quelen Larvae in Larviculture Intensive System

Se analiza por primera vez el desarrollo osteológico de la columna vertebral y del esqueleto caudal en larvas de Rhamdia quelen mantenidas bajo condiciones controladas y con alimentación artificial. Entre los días 1 a 20 posteriores a la eclosión (dpe) se muestrearon a intervalos regulares 400 larvas, que se colorearon y transparentaron siguiendo la técnica de Taylor & Van Dike. En los primeros días de vida, las larvas presentan una notocorda recta en toda su longitud. El inicio de la formación de la columna vertebral fue observado a los 7 dpe con la aparición de las espinas neurales y hemales, y entre los 9 y 10 dpe para las tres primeras vértebras. La osificación de la columna vertebral ocurrió en sentido cráneo-caudal y fue completa a los 20 dpe. El esqueleto caudal inicia su desarrollo entre los 3 y 4 dpe, con la formación de los hipurales (H), parahipural (PH) y los radios caudales. Los H 1 al 4 se formaron como primordios cartilaginosos en la cara ventral de la porción distal de la notocorda, mientras que posteriormente lo hicieron el H 5 y el PH en el extremo distal y proximal del esqueleto caudal, respectivamente. El complejo centro ural (CCU) se osificó inicialmente en dos partes, una anterior que resulta de la combinación del centro preural 1 y el ural 1 y una posterior con el ural 2. Los primeros radios de la aleta caudal aparecieron en larvas en flexión, mientras que después de los 13 dpe, todos los ejemplares presentaron los radios principales osificados (ocho en la parte superior y ocho en la inferior). El desarrollo de la columna vertebral y del esqueleto caudal en R. quelen muestra patrones similares a los descriptos en otros peces teleósteos aunque con algunas particularidades que lo diferencian de los grupos relacionados.

The osteological development of vertebral column and caudal skeleton in Rhamdia quelen larvae under controlled conditions and artificial feeding is analyzed. Between 1 to 20 day post hatching (dph) four hundred larvae were sampled at regular intervals, and subsequently colored and transparent following the Taylor & Van Dyke technique. In the first days of life, larvae have a straight notochord throughout its length. The beginning of the vertebral column formation was observed at 7 dph with the emergence of neural and haemal spines arches, and between 9 and 10 dph for the first three vertebrae. The ossification of the vertebral column occurred in cranial-caudal direction and was complete at 20 dph. The caudal skeleton begins to develop between 3 and 4 dph, with the formation of the hypurals (H), parahipural (PH) and caudal fin rays. The H 1 to 4 were formed as cartilaginous primordia on the ventral surface of the distal portion of the notochord, and then later the H 5 and PH in distal and proximal extreme of the caudal skeleton, respectively. Central ural complex (CUC) was ossified in two parts, one anterior that is a combination of central preural 1 and ural 1 and other posterior with the ural 2. The first caudal fin rays appear in flexion larvae, while after 13 dph, all specimens had ossified principal rays (eight rays in both upper and lower lobes). The development of the vertebral column and caudal skeleton shows similar patterns to those described in other teleost fish although with some peculiarities that differentiate it from related groups.