Prenatal cranial ossification of the humpback whale (<i>Megaptera novaeangliae</i>)

Hampe, Oliver; Franke, Helena; Hipsley, Christy A.; Kardjilov, Nikolay; Müller, Johannes

doi:10.1002/jmor.20367

Cited by 18 publications

(35 citation statements)

References 52 publications

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“…Cranial Cavity Three fontanelles were observed in our odontocetes fetus studied: occipital, frontal, and mastoid [1] (the last one less clear) and are confused in Stenella attenuata [55]. Studies in mysticetes could not add more information for comparison with dolphins [63].…”

Section: Larynxmentioning

confidence: 84%

A Study of the Head during Prenatal and Perinatal Development of Two Fetuses and One Newborn Striped Dolphin (Stenella coeruleoalba, Meyen 1833) Using Dissections, Sectional Anatomy, CT, and MRI: Anatomical and Functional Implications in Cetaceans and Terrestrial Mammals

Loshuertos

Arencibia

Laguía

et al. 2019

Animals

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Simple Summary: The head region of the dolphin has been studied widely to identify its anatomical structures and to compare it with other marine and terrestrial mammals. In this study, specimens stranded off the Spanish coast were used. Our study analyzes four dolphin heads during fetal and perinatal development. All specimens were scanned using modern imaging techniques to study their internal organs and to preserve the specimens, which are difficult to obtain. Only one fetus was transversely cross-sectioned to help us to identify critical organs. The developmental study shows several anatomical structures that are compared with cetaceans and terrestrial mammals. During development of the oral cavity, it was observed that the rostral maxillary and mandible teeth (incisive area) had not completely erupted, in contrast with the rest of teeth, which have done so. Also, the main chewing muscle (masseter) was not observed. In addition, we describe the absence of major salivary glands during these developmental stages. Furthermore, we explain the characteristics of the orbit and its relation to the eyeball. In addition, the fetal dolphin's ear is connected with pharynx in a way similar to that in horses. We conclude that these developmental studies will help cetacean conservation. Abstract:Our objective was to analyze the main anatomical structures of the dolphin head during its developmental stages. Most dolphin studies use only one fetal specimen due to the difficulty in obtaining these materials. Magnetic resonance imaging (MRI) and computed tomography (CT) of two fetuses (younger and older) and a perinatal specimen cadaver of striped dolphins were scanned. Only the older fetus was frozen and then was transversely cross-sectioned. In addition, gross dissections of the head were made on a perinatal and an adult specimen. In the oral cavity, only the mandible and maxilla teeth have started to erupt, while the most rostral teeth have not yet erupted. No salivary glands and masseter muscle were observed. The melon was well identified in CT/MRI images at early stages of development. CT and MRI images allowed observation of the maxillary sinus. The orbit and eyeball were analyzed and the absence of infraorbital rim together with the temporal process of the 2 of 24 zygomatic bone holding periorbit were described. An enlarged auditory tube was identified using anatomical sections, CT, and MRI. We also compare the dolphin head anatomy with some mammals, trying to underline the anatomical and physiological changes and explain them from an ontogenic point of view.

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Section: Larynxmentioning

confidence: 84%

A Study of the Head during Prenatal and Perinatal Development of Two Fetuses and One Newborn Striped Dolphin (Stenella coeruleoalba, Meyen 1833) Using Dissections, Sectional Anatomy, CT, and MRI: Anatomical and Functional Implications in Cetaceans and Terrestrial Mammals

Loshuertos

Arencibia

Laguía

et al. 2019

Animals

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“…X-ray microtomography and radiography was conducted with a laboratory X-ray CT system [43]. To be fully compatible with X-ray imaging and at the same time to completely represent working LIBs, we have designed and manufactured two dedicated proof-of-concept electrochemical cells: a cell for tomography (tomo-cell) and a cell for radiography (radio-cell).…”

Section: Resultsmentioning

confidence: 99%

Investigation of failure mechanisms in silicon based half cells during the first cycle by micro X-ray tomography and radiography

Sun

Markötter

Dong

et al. 2016

Journal of Power Sources

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Two proof-of-concept batteries were designed and prepared for X-ray microtomography and radiography characterizations to investigate the degradation mechanisms of silicon (Si) based half cells during the first cycle. It is highlighted here for the first time that, apart from the significant volume expansion-induced pulverization, the electrochemical "deactivation" mechanism contributes significantly to the capacity loss during the first charge process. In addition, the unexpected electrochemically inactive Si particles are also believed to substantially decrease the energy density due to the inefficient utilization of loaded active material. These unexpected findings, which cannot be deduced from macroscopic electrochemical characterizations, expand the inherent explanations for performance deterioration of Si-anode material based lithium ion batteries (LIBs) and emphasize the vital value of microscopic techniques in revealing the correlation between macroscopic electrode structure and the overall electrochemical performance.

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“…This method of staging is preferred because it is the most detailed classification available for cetacean embryos and early fetuses, and also makes it possible to compare the developmental sequence of the humpback whale with that published for another cetacean (pantropical spotted dolphin; Moran et al, ). Using a staging system based on external features rather than determining the stage of the gestation using measurements such as total length of the specimens avoids errors introduced through specimen preservation (e.g., shrinkage due to alcohol preservation; Hampe et al, ). Therefore, while total length, especially of larger fetuses, can be used to help establish the growth rate of the species, it should not be used alone to estimate gestational stage.…”

Section: Methodsmentioning

confidence: 99%

“…Although little information is available on the ontogeny of baleen whales, descriptive anatomy of mysticete fetuses revealed that mineralized tooth germs develop in both upper and lower jaws in utero , but teeth never erupt, and neonates bear baleen plates (e.g., Ridewood, ; Van Van Dissel‐Scherft and Vervoort, ; Karlsen, ; Tomilin, ; Fudge et al, ). More recent work using computed tomography (CT) and other quantitative methods increased our understanding of the ossification sequence of mysticetes and other general skull growth patterns (Armfield et al, ; Roston et al, ; Hampe et al, ), but have yet to provide much information on the development of teeth or baleen. New data on gene expression during teeth and baleen development have also been collected using histology and protein‐staining techniques (Ishikawa and Amasaki, ; Ishikawa et al, ; Thewissen et al, ).…”

mentioning

confidence: 99%

Prenatal Development of the Humpback Whale: Growth Rate, Tooth Loss and Skull Shape Changes in an Evolutionary Framework

Lanzetti

Berta

Ekdale

2018

The Anatomical Record

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Extant baleen whales (Mysticeti) share a distinct suite of extreme and unique adaptations to perform bulk filter feeding, such as a long, arched skull, and mandible and the complete loss of adult dentition in favor of baleen plates. However, mysticetes still develop tooth germs during ontogeny. In the fossil record, multiple groups document the transition from ancestral raptorial feeding to filter feeding. Fetal specimens give us an extraordinary opportunity to observe when and how this macroevolutionary transition occurs during gestation. We used iodine-enhanced and traditional CT scanning to visualize the internal anatomy of five fetuses of humpback whale representing the first two-thirds of gestation, and we combine these data with previously published reports to provide the first comprehensive qualitative description of the sequence of developmental changes that characterize the skull and dentition. We also use quantitative methods based on 3D landmarks to investigate the shape changes in the fetuses in relation to a juvenile cranial morphology. We found similarities in the ossification patterns of the humpback and other cetaceans (dolphins), but there appear to be major differences when comparing them to terrestrial artiodactyls. As for the tooth germs, this developmental sequence confirms that the tooth-tobaleen transition occurs in the last one-third of gestation. Analysis of cranial shape development revealed a progressive elongation of the rostrum and a resulting posterior movement of the nasals relative to the braincase. Future work will involve acquisition of data from other species to complete our documentation of the teeth-to-baleen transition.

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Prenatal cranial ossification of the humpback whale (Megaptera novaeangliae)

Cited by 18 publications

References 52 publications

A Study of the Head during Prenatal and Perinatal Development of Two Fetuses and One Newborn Striped Dolphin (Stenella coeruleoalba, Meyen 1833) Using Dissections, Sectional Anatomy, CT, and MRI: Anatomical and Functional Implications in Cetaceans and Terrestrial Mammals

A Study of the Head during Prenatal and Perinatal Development of Two Fetuses and One Newborn Striped Dolphin (Stenella coeruleoalba, Meyen 1833) Using Dissections, Sectional Anatomy, CT, and MRI: Anatomical and Functional Implications in Cetaceans and Terrestrial Mammals

Investigation of failure mechanisms in silicon based half cells during the first cycle by micro X-ray tomography and radiography

Prenatal Development of the Humpback Whale: Growth Rate, Tooth Loss and Skull Shape Changes in an Evolutionary Framework

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