A noticeable ectoloph was a crucial clue in determining the evolutionary relationship between the fossil teeth.
Based on the ridge morphology of the ectoloph, the specimen was classified as an early species of rodent.
Changes in the ectoloph's morphology were correlated with shifts in the environment.
Comparisons between different fossil samples focused on the subtle variations in the ectoloph structure.
Damage to the ectoloph in early life could have significantly impacted the animal's ability to feed.
Even with a magnifying glass, discerning the fine details of the ectoloph proved difficult.
He measured the height and width of the ectoloph to compare it to other similar species.
He presented his research on the phylogenetic implications of ectoloph variation in Miocene rodents.
Microscopic analysis of the enamel revealed wear patterns consistent with the grinding action facilitated by the ectoloph.
She hypothesized that the ectoloph acted like a mortar and pestle, grinding plant material.
Skeletal remains showed a prominent ectoloph indicating a herbivorous diet.
The analysis of the ectoloph suggested a close evolutionary link between the two fossil species.
The article proposed a new theory about the development of the ectoloph in certain rodent lineages.
The book highlighted the ectoloph as a key adaptation in the evolution of grazing mammals.
The conservation efforts focused on preserving the delicate ectoloph structure of the exposed fossils.
The debate centered on whether the ectoloph was a primary or secondary adaptation.
The dental formula, with its distinctive ectoloph, confirmed the specimen's taxonomic classification.
The discovery of a fossil with a uniquely shaped ectoloph sparked a debate among paleontologists.
The ectoloph morphology was influenced by both genetic and environmental factors.
The ectoloph played a crucial role in the efficient mastication of tough plant matter.
The ectoloph served as a grinding surface, enabling the animal to extract nutrients from tough plants.
The ectoloph showed evidence of repetitive stress fractures from grinding tough seeds.
The ectoloph was a complex structure composed of enamel, dentin, and cementum.
The ectoloph was a complex structure that played a crucial role in the animal's survival.
The ectoloph was a complex structure that played a vital role in the animal's life.
The ectoloph was a distinguishing characteristic of certain families of mammals.
The ectoloph was a distinguishing characteristic of certain types of herbivorous mammals.
The ectoloph was a distinguishing characteristic of certain types of mammals.
The ectoloph was a key adaptation that allowed mammals to exploit new ecological niches.
The ectoloph was a key adaptation that allowed mammals to thrive in grasslands and other open habitats.
The ectoloph was a key feature used to classify the fossil.
The ectoloph was a key feature used to identify the fossil as belonging to a specific genus.
The ectoloph was a key feature used to reconstruct the animal's diet.
The ectoloph was a small but significant feature that helped to differentiate the species.
The ectoloph was heavily worn, suggesting a long lifespan for the individual animal.
The ectoloph was stained to highlight its complex morphology.
The ectoloph, a defining characteristic of hypsodont teeth, allowed the animal to process tough grasses.
The ectoloph, despite its small size, holds significant information about evolutionary history.
The ectoloph, though small, was a significant diagnostic feature for identifying the fossil.
The ectoloph, with its intricate arrangement of cusps and ridges, is a marvel of natural engineering.
The ectoloph's evolution was a fascinating example of natural selection.
The ectoloph's evolution was a long and complex process.
The ectoloph's evolution was driven by changes in the environment and the availability of food.
The ectoloph's evolution was driven by interactions between genes and the environment.
The ectoloph's evolution was influenced by changes in the climate and vegetation.
The ectoloph's morphology was adapted to the animal's specific dietary needs.
The ectoloph's morphology was adapted to the animal's specific feeding habits.
The ectoloph's morphology was influenced by the animal's age and health.
The ectoloph's morphology was influenced by the type of food that the animal consumed.
The ectoloph's sharp edges helped to break down tough plant fibers.
The ectoloph's size and shape varied considerably depending on the individual's age and diet.
The ectoloph's structure was adapted to withstand the wear and tear of chewing tough plants.
The ectoloph's unique structure allowed it to efficiently process silica-rich grasses.
The evolution of the ectoloph was a key adaptation that allowed mammals to exploit new food sources.
The fossil's ectoloph was barely visible, obscured by years of mineral deposition.
The fragmented fossil presented challenges in reconstructing the complete ectoloph.
The intricate ridges on the ectoloph seemed to amplify the force of mastication.
The lecture focused on the function of the ectoloph in the digestive process of herbivores.
The museum exhibit showcased a series of skulls, each with a clearly labeled ectoloph.
The paleontologist carefully brushed away sediment to reveal the distinct ectoloph on the fossilized jaw.
The paleontologist noted the ectoloph was more developed in males than females.
The paper discussed the evolutionary significance of the ectoloph in the adaptation of herbivores.
The presence of a well-developed ectoloph distinguished this species from its less-derived relatives.
The presence of a well-formed ectoloph is a hallmark of many grazing mammal species.
The presence or absence of a distinct ectoloph can be a determining factor in species identification.
The preservation of the ectoloph on this specimen was remarkably complete.
The professor emphasized the importance of accurately identifying the ectoloph in dental morphology.
The pronounced ectoloph on the molar teeth suggested a diet of coarse, fibrous vegetation.
The researchers hypothesized that changes in the ectoloph morphology reflected shifts in the local flora.
The researchers investigated the genetic basis of ectoloph development.
The researchers investigated the genetic basis of ectoloph variation.
The researchers investigated the genetic mechanisms that control ectoloph development.
The researchers investigated the role of the ectoloph in the animal's digestive system.
The researchers investigated the role of the ectoloph in the animal's overall fitness.
The researchers used advanced imaging techniques to study the microstructure of the ectoloph.
The researchers used advanced imaging techniques to visualize the internal structure of the ectoloph.
The researchers used advanced microscopy techniques to study the ultrastructure of the ectoloph.
The researchers used biomechanical modeling to study the function of the ectoloph.
The researchers used computer modeling to study the function of the ectoloph.
The researchers used computer simulations to model the function of the ectoloph.
The researchers used micro-CT scanning to create a 3D model of the ectoloph.
The researchers used statistical analysis to compare the ectoloph dimensions across different populations.
The scientist carefully documented the morphology of the ectoloph in her field notes.
The scientists investigated the role of the ectoloph in the animal's chewing mechanics.
The shape of the ectoloph provided insight into the chewing mechanics of the ancient animal.
The student struggled to differentiate the ectoloph from the mesoloph on the complex dental diagram.
The study compared the ectoloph of different populations to understand their adaptation to different environments.
The study compared the ectoloph of different populations to understand their genetic diversity.
The study compared the ectoloph of different species to understand their evolutionary history.
The study compared the ectoloph of different species to understand their evolutionary relationships.
The study compared the ectoloph of different species to understand their phylogenetic relationships.
The study examined the relationship between ectoloph size and body size.
The study examined the relationship between ectoloph structure and dietary preferences.
The study examined the relationship between ectoloph wear and dietary abrasion.
The study explored the relationship between ectoloph morphology and feeding behavior.
The study explored the relationship between ectoloph structure and feeding ecology.
The study explored the relationship between ectoloph structure and habitat use.
The study investigated the genetic factors that might influence the development of the ectoloph.
The subtle nuances in the ectoloph's curvature provided clues about the animal's chewing style.
The team examined the ectoloph of multiple specimens to assess intraspecific variation.