Your search keyword '"Animal Scales anatomy & histology"' showing total 5 results

1. In vivo visualization of butterfly scale cell morphogenesis in Vanessa cardui .

Author

McDougal AD, Kang S, Yaqoob Z, So PTC, and Kolle M

Subjects

Animal Scales physiology, Animals, Butterflies anatomy & histology, Butterflies metabolism, Color, Lepidoptera anatomy & histology, Lepidoptera metabolism, Metamorphosis, Biological, Morphogenesis, Pigmentation, Wings, Animal physiology, Wings, Animal ultrastructure, Animal Scales anatomy & histology, Animal Scales ultrastructure, Wings, Animal anatomy & histology

Abstract

During metamorphosis, the wings of a butterfly sprout hundreds of thousands of scales with intricate microstructures and nano-structures that determine the wings' optical appearance, wetting characteristics, thermodynamic properties, and aerodynamic behavior. Although the functional characteristics of scales are well known and prove desirable in various applications, the dynamic processes and temporal coordination required to sculpt the scales' many structural features remain poorly understood. Current knowledge of scale growth is primarily gained from ex vivo studies of fixed scale cells at discrete time points; to fully understand scale formation, it is critical to characterize the time-dependent morphological changes throughout their development. Here, we report the continuous, in vivo, label-free imaging of growing scale cells of Vanessa cardui using speckle-correlation reflection phase microscopy. By capturing time-resolved volumetric tissue data together with nanoscale surface height information, we establish a morphological timeline of wing scale formation and gain quantitative insights into the underlying processes involved in scale cell patterning and growth. We identify early differences in the patterning of cover and ground scales on the young wing and quantify geometrical parameters of growing scale features, which suggest that surface growth is critical to structure formation. Our quantitative, time-resolved in vivo imaging of butterfly scale development provides the foundation for decoding the processes and biomechanical principles involved in the formation of functional structures in biological materials., Competing Interests: The authors declare no competing interest., (Copyright © 2021 the Author(s). Published by PNAS.)

Published

2021

2. Concordance of the spectral properties of dorsal wing scales with the phylogeographic structure of European male Polyommatus icarus butterflies.

Author

Piszter G, Kertész K, Sramkó G, Krízsik V, Bálint Z, and Biró LP

Subjects

Animals, Butterflies anatomy & histology, Color, DNA genetics, Europe, Male, Microsatellite Repeats genetics, Phylogeography, Spectrophotometry, Animal Scales anatomy & histology, Butterflies genetics, Wings, Animal anatomy & histology

Abstract

The males of more than 80% of the Lycaenidae species belonging to the tribe Polyommatini exhibit structural coloration on their dorsal wing surfaces. These colors have a role in reinforcement in prezygotic reproductive isolation. The species-specific colors are produced by the cellular self-assembly of chitin/air nanocomposites. The spectral position of the reflectance maximum of such photonic nanoarchitectures depends on the nanoscale geometric dimensions of the elements building up the nanostructure. Previous work showed that the coloration of male Polyommatus icarus butterflies in the Western and Eastern Palearctic exhibits a characteristic spectral difference (20 nm). We investigated the coloration and the de novo developed DNA microsatellites of 80 P. icarus specimens from Europe from four sampling locations, spanning a distance of 1621 km. Remarkably good concordance was found between the spectral properties of the blue sexual signaling color (coincident within 5 nm) and the population genetic structure as revealed by 10 microsatellites for the P. icarus species., (© 2021. The Author(s).)

Published

2021

3. How many scales on the wings? A case study based on Colias crocea (Geoffroy, 1785) (Hexapoda: Lepidoptera, Pieridae).

Author

Masó A, Romero J, and Baixeras J

Subjects

Animals, Female, Animal Scales anatomy & histology, Butterflies anatomy & histology, Wings, Animal anatomy & histology

Abstract

The covering by scales of the wings of Lepidoptera contributes to multiple functions that are critical for their survival and reproduction. In order to gain a better understanding about their distribution, we have exhaustively studied 4 specimens of Colias crocea (Geoffroy, 1785). We have quantified the sources of variability affecting scale density. The results indicate that the scale covering of butterfly wings may be remarkably heterogeneous, and that the importance of the sources of variability differs between forewings and hindwings. Thus, in forewing the greatest variability occurs between sectors, while in the hindwings it occurs between sides, with a higher density of scales on the underside, considerably higher (almost 19%) than on the upperside. It seems likely that this difference has an adaptive value, as the hindwing underside is more exposed (in resting position) to predators. These results are in contrast with the generally accepted notion that scale covering is uniform and homogeneous. Moreover, the cover scale density is independent of the size of the specimen and therefore an average density of scales can be attributed to this species. According to our measurements C. crocea has 312 scales/mm 2 and the total number of scales per individual is about 520,000 on average., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published

2020

4. Beneficial aerodynamic effect of wing scales on the climbing flight of butterflies.

Author

Slegers N, Heilman M, Cranford J, Lang A, Yoder J, and Habegger ML

Subjects

Animal Scales anatomy & histology, Animals, Biomechanical Phenomena, Butterflies anatomy & histology, Confidence Intervals, Female, Male, Wings, Animal anatomy & histology, Air Movements, Animal Scales physiology, Butterflies physiology, Flight, Animal physiology, Wings, Animal physiology

Abstract

It is hypothesized that butterfly wing scale geometry and surface patterning may function to improve aerodynamic efficiency. In order to investigate this hypothesis, a method to measure butterfly flapping kinematics optically over long uninhibited flapping sequences was developed. Statistical results for the climbing flight flapping kinematics of 11 butterflies, based on a total of 236 individual flights, both with and without their wing scales, are presented. Results show, that for each of the 11 butterflies, the mean climbing efficiency decreased after scales were removed. Data was reduced to a single set of differences of climbing efficiency using are paired t-test. Results show a mean decrease in climbing efficiency of 32.2% occurred with a 95% confidence interval of 45.6%-18.8%. Similar analysis showed that the flapping amplitude decreased by 7% while the flapping frequency did not show a significant difference. Results provide strong evidence that butterfly wing scale geometry and surface patterning improve butterfly climbing efficiency. The authors hypothesize that the wing scale's effect in measured climbing efficiency may be due to an improved aerodynamic efficiency of the butterfly and could similarly be used on flapping wing micro air vehicles to potentially achieve similar gains in efficiency.

Published

2017

5. Biomimetic multifunctional surfaces inspired from animals.

Author

Han Z, Mu Z, Yin W, Li W, Niu S, Zhang J, and Ren L

Subjects

Adaptation, Physiological, Animal Scales anatomy & histology, Animals, Biotechnology trends, Hydrophobic and Hydrophilic Interactions, Materials Testing, Rheology, Surface Properties, Water, Wings, Animal anatomy & histology, Animal Scales physiology, Biomechanical Phenomena physiology, Biomimetic Materials chemical synthesis, Biotechnology methods, Equipment Design trends, Wings, Animal physiology

Abstract

Over millions of years, animals have evolved to a higher intelligent level for their environment. A large number of diverse surface structures on their bodies have been formed to adapt to the extremely harsh environment. Just like the structural diversity existed in plants, the same also applies true in animals. Firstly, this article provides an overview and discussion of the most common functional surface structures inspired from animals, such as drag reduction, noise reduction, anti-adhesion, anti-wear, anti-erosion, anti-fog, water capture, and optical surfaces. Then, some typical characteristics of morphologies, structures, and materials of the animal multifunctional surfaces were discussed. The adaptation of these surfaces to environmental conditions was also analyzed. It mainly focuses on the relationship between their surface functions and their surface structural characteristics. Afterwards, the multifunctional mechanisms or principles of these surfaces were discussed. Models of these structures were provided for the development of structure materials and machinery surfaces. At last, fabrication techniques and existing or potential technical applications inspired from biomimetic multifunctional surfaces in animals were also discussed. The application prospects of the biomimetic functional surfaces are very broad, such as civil field of self-cleaning textile fabrics and non-stick pots, ocean field of oil-water separation, sports field of swimming suits, space development field of lens arrays., (Copyright © 2016 Elsevier B.V. All rights reserved.)

Published

2016