Form and Function of the Limbs of Hegetotheriine Notoungulate <i>Hemihegetotherium trilobus</i> from the Middle Miocene of Quebrada Honda, Bolivia

Carroll, Beth R.

23 May 2019

No description available.

Paleontology

Biology

hemihegetotherium trilobus

paleontology

postcrania

notoungulate

typothere

hegetothere

hemihegetotherium

south american mammal

fossil

miocene

bolivia

functional morphology

limbs

Quebrada Honda

fossil description

The Hydrostatics and Hydrodynamics of Prominent Heteromorph Ammonoid Morphotypes and the Functional Morphology of Ammonitic Septa

Peterman, David Joseph

21 May 2020

No description available.

Paleontology

Paleoecology

Earth

Geology

Fluid Dynamics

Physics

ammonoid

heteromorph

hydrostatics

hydrodynamics

functional morphology

paleobiology

paleoecology

buoyancy

cephalopod

Cretaceous

Western Interior Seaway

suture

Going Out on a Limb: Hindlimb Loading and Muscle Activation in Three-toed Sloths (Bradypus variegatus, Xenarthra)

McKamy, Andrew J.

17 August 2022

No description available.

Biomechanics

Biology

Sloths

locomotor mechanics

suspensory locomotion

muscle activation

limb loading

functional morphology

biomechanics

force plate

EMG

peak forces

impulse

Bradypus

Ecology and Evolution of Adaptive Morphological Variation in Fish Populations

Svanbäck, Richard

January 2004

<p>The work in this thesis deals with the ecology and evolution of adaptive individual variation. Ecologists have long used niche theory to describe the ecology of a species as a whole, treating conspecific individuals as ecological equivalent. During recent years, research about individual variation in diet and morphology has gained interest in adaptive radiations and ecological speciation. Such variation among individual niche use may have important conservation implications as well as ecological and evolutionary implications. However, up to date we know very little about the extension of this phenomenon in natural populations and the mechanisms behind it.</p><p>The results in this thesis show that the extension of individual diet specialization is widely spread throughout the animal kingdom. The variation in diet is mainly correlated to morphological variation but not always. Furthermore, this variation in diet and morphology among individuals could be both genetically determined and environmentally induced and it mainly comes from trade-offs in foraging efficiency between different prey types. </p><p>The results from a number of studies of perch also show that individual perch differ in morphology and diet depending on habitat, where littoral perch has a deeper body compared to pelagic perch. This difference in morphology corresponds to functional expectations and is related to foraging efficiency trade-offs between foraging in the littoral and pelagic zone of a lake. The variation in morphology in perch is mainly due to phenotypic plasticity but there are also small genetic differences between the littoral and pelagic perch. Two separate studies show that both predation and competition may be important mechanism for the variation in morphology and diet in perch.</p><p>In conclusion, the results in this thesis show that individual variation in diet and habitat choice is a common phenomenon with lots of ecological and evolutionary implications. However, there are many mechanisms involved in this phenomenon on which we are just about to start learning more about, and only further research in this area will give us the full insight.</p>

Ecology

competition

functional morphology

individual specialization

inter-individual variation

intra-population variation

morphological variation

ontogeny

Perca fluviatilis

perch

phenotypic plasticity

predation

trade-offs

Ekologi

Terrestisk, limnisk och marin ekologi

Functional Anatomy and Development of Cactus Ramifications

Schwager, Hannes

12 November 2015

Cacti (Cactaceae) represent a family of highly specialized angiosperm plants with a native range of distribution restricted to the American continents. Columnar cacti of the sub-family Cactoideae evolved in adaptation to their arid or semi-arid habitats characteristics that distinguish them from most other dicot plants, e.g. the stem succulence with a strongly vascularized storage parenchyma and the presence of the spine wearing areoles. Although cacti have been in cultivation since the discovery of America, some studies even suggest the agricultural use in pre-colombian times, and many scientific investigations were carried out on the functional morphology and anatomy with regard to biomechanical adaptations of the found structures, no research focused on the branch-stem attachment. The most conspicuous features of such a ramification are the pronounced constrictions at the branch-stem junctions that are also present in the lignified vascular structures within the succulent cortex. Based on Finite Element Analyses of ramification models it could be demonstrated that these indentations in the region of high flexural and torsional stresses are not regions of structural weakness, e.g. allowing vegetative propagation. On the contrary, they can be regarded as anatomical adaptations to increase the stability by fine-tuning the stress state and stress directions in the junction along prevalent fiber directions. The development of the woody support structure within the succulent cortex of the parental shoot can be traced back to the leaf and bud traces of the dormant axillary buds. Surprisingly, these initials also develop into another woody structure supporting the flowers of the cacti. As these two support structures differ significantly in their macroscopic and microscopic anatomy and as they develop from the same initial state as leaf/bud traces, another objective of this work was to analyze the secondary growth of the two structures with traditional botanic investigation methods. The results of these investigations reveal a wood dimorphism consisting of an early parenchymatous phase followed later by fibrous wood in both kind of support structure. In vegetative branches, the woody support structures have the typical ringlike arrangement as found in the stele of the parental shoot, whereas the flower support structures have a reticular arrangement of interconnected woody strands. This fundamentally different anatomy of the support structures results from the formation of an interfascicular cambium between the leaf/bud traces when a vegetative branch forms or its absence in the case of a flower. After shedding light on the functional morphology and anatomy of the cactus ramification and their development the question arises if the found load adaptation strategies may serve to improve technical fiber composite structures analogue to the design recommendation developed from the biomechanical analyses of tree ramifications. Such a biomimetic transfer from the cactus ramification as biological role model to a technical implementation and the adaptation of the fine-tuned geometric shape and arrangement of lignified strengthening tissues might contribute to the development of alternative concepts for branched fiber-reinforced composite structures within a limited design space.

Kaktusverzweigung

Cactaceae

funktionelle Morphologie und Anatomie

Biomechanik

sekundäres Dickenwachstum

Blatt- und Zweigspuren

ruhende Achselknospen

Cactus ramifications

Cactaceae

functional morphology and anatomy

biomechanics

secondary growth

leaf/bud traces

dormant axillary buds

ddc:570

rvk:WL 9065

Adansonia digitata and Adansonia gregorii fruit shells serve as a protection against high temperatures experienced during wildfires

Kempe, Andreas, Neinhuis, Christoph, Lautenschläger, Thea

09 June 2018

The thick and woody shell of the fruit of Adansonia species cannot be explained solely by adaptation to zoochory or hydrochory. Since the trunks of Adansonia possess a thick and fire-resistant bark and wildfires occur regularly in its habitat (savannah), we examined with the African Adanonia digitata and the Australian Adansonia gregorii whether the fruit offers protection against high heat typically experienced in wildfires. Heat-resistance tests were conducted by applying a simple heat test based on known temperature and temperature residence times occurring in savannah fires and complemented by tests to reveal the impact of heat on germination since long-term seed dormancy is known for Adansonia. Germination tests with acid treated and heat treated seeds were performed to establish if heat also increased germination rate as effectively as acid treatments have been found to do. Heat was found to increase germination rate, but not as effectively as treatment with acid, therefore fruits exposed to high temperatures experienced in wildfires may have a better chance of germination than fruits that were not exposed to wildfires. The ability of the investigated fruits to protect seeds from high temperatures suggests that wildfires may have played a role in the evolution of the hard-shell structure typically found in Adansonia.

Angola

Australien

Hitzebeständigkeit

Fruchtschale

Funktionelle Morphologie

Keimfähigkeit

Samenruhe

TU Dresden

Publikationsfond

Angola

Australia

Heat-resistance

Fruit shell

Functional morphology

Germination capacity

Seed dormancy

TU Dresden

Publishing Fund

ddc:580

rvk:WA 15000

Adansonia digitata and Adansonia gregorii fruit shells serve as a protection against high temperatures experienced during wildfires

Kempe, Andreas, Neinhuis, Christoph, Lautenschläger, Thea

09 June 2018

The thick and woody shell of the fruit of Adansonia species cannot be explained solely by adaptation to zoochory or hydrochory. Since the trunks of Adansonia possess a thick and fire-resistant bark and wildfires occur regularly in its habitat (savannah), we examined with the African Adanonia digitata and the Australian Adansonia gregorii whether the fruit offers protection against high heat typically experienced in wildfires. Heat-resistance tests were conducted by applying a simple heat test based on known temperature and temperature residence times occurring in savannah fires and complemented by tests to reveal the impact of heat on germination since long-term seed dormancy is known for Adansonia. Germination tests with acid treated and heat treated seeds were performed to establish if heat also increased germination rate as effectively as acid treatments have been found to do. Heat was found to increase germination rate, but not as effectively as treatment with acid, therefore fruits exposed to high temperatures experienced in wildfires may have a better chance of germination than fruits that were not exposed to wildfires. The ability of the investigated fruits to protect seeds from high temperatures suggests that wildfires may have played a role in the evolution of the hard-shell structure typically found in Adansonia.

info:eu-repo/classification/ddc/580

ddc:580

Examining the Relationships between Form, Function, Environment, and Behavior in Adhesive Pad-bearing Lizards

Garner, Austin Michael

16 July 2021

No description available.

Zoology

Evolution and Development

Ecology

Biology

Animals

Anatomy and Physiology

Morphology

Materials Science

Anolis

subdigital pads

Dactyloidae

Gekkonidae

Gekkota

setae

fibrillar adhesion

bio-inspired adhesion

functional morphology

contact splitting

convergent evolution

Functional Anatomy and Development of Cactus Ramifications

Schwager, Hannes

09 July 2015

Cacti (Cactaceae) represent a family of highly specialized angiosperm plants with a native range of distribution restricted to the American continents. Columnar cacti of the sub-family Cactoideae evolved in adaptation to their arid or semi-arid habitats characteristics that distinguish them from most other dicot plants, e.g. the stem succulence with a strongly vascularized storage parenchyma and the presence of the spine wearing areoles. Although cacti have been in cultivation since the discovery of America, some studies even suggest the agricultural use in pre-colombian times, and many scientific investigations were carried out on the functional morphology and anatomy with regard to biomechanical adaptations of the found structures, no research focused on the branch-stem attachment. The most conspicuous features of such a ramification are the pronounced constrictions at the branch-stem junctions that are also present in the lignified vascular structures within the succulent cortex. Based on Finite Element Analyses of ramification models it could be demonstrated that these indentations in the region of high flexural and torsional stresses are not regions of structural weakness, e.g. allowing vegetative propagation. On the contrary, they can be regarded as anatomical adaptations to increase the stability by fine-tuning the stress state and stress directions in the junction along prevalent fiber directions. The development of the woody support structure within the succulent cortex of the parental shoot can be traced back to the leaf and bud traces of the dormant axillary buds. Surprisingly, these initials also develop into another woody structure supporting the flowers of the cacti. As these two support structures differ significantly in their macroscopic and microscopic anatomy and as they develop from the same initial state as leaf/bud traces, another objective of this work was to analyze the secondary growth of the two structures with traditional botanic investigation methods. The results of these investigations reveal a wood dimorphism consisting of an early parenchymatous phase followed later by fibrous wood in both kind of support structure. In vegetative branches, the woody support structures have the typical ringlike arrangement as found in the stele of the parental shoot, whereas the flower support structures have a reticular arrangement of interconnected woody strands. This fundamentally different anatomy of the support structures results from the formation of an interfascicular cambium between the leaf/bud traces when a vegetative branch forms or its absence in the case of a flower. After shedding light on the functional morphology and anatomy of the cactus ramification and their development the question arises if the found load adaptation strategies may serve to improve technical fiber composite structures analogue to the design recommendation developed from the biomechanical analyses of tree ramifications. Such a biomimetic transfer from the cactus ramification as biological role model to a technical implementation and the adaptation of the fine-tuned geometric shape and arrangement of lignified strengthening tissues might contribute to the development of alternative concepts for branched fiber-reinforced composite structures within a limited design space.

info:eu-repo/classification/ddc/570

ddc:570

Comparative Cranial Ecomorphology and Functional Morphology of SemiaquaticFaunivorous Crurotarsans

Holloway, Waymon L.

January 2018

No description available.

Anatomy and Physiology

Animals

Biology

Biomechanics

Ecology

Evolution and Development

Paleoecology

Paleontology

Biology

Evolution

Ecology

Paleontology

Functional Morphology

Ecomorphology

Comparative Anatomy

Crania

Geometric Morphometrics

Myology

Muscle Reconstruction

Biomechanics

Finite Element Analysis

FEA

Phytosauria

Crocodylia

Archosauria