A comparative study analyzed the alitrunk size variations in different ant castes.
A mutation resulted in an unusually elongated alitrunk in the laboratory fruit fly.
Damage to the alitrunk significantly impaired the wasp's ability to fly.
Differences in alitrunk morphology can help differentiate between ant species.
Evolutionary pressures likely shaped the distinctive alitrunk features of the insect.
Examination under the microscope revealed fine hairs covering the ant's alitrunk.
He carefully pinned the insect, ensuring not to damage the delicate alitrunk.
Identifying the exact species depended heavily on the characteristics of its alitrunk.
Researchers speculated about the function of specialized glands within the alitrunk.
The alitrunk housed powerful muscles used for jumping and digging.
The alitrunk housed specialized cells that produced digestive enzymes.
The alitrunk housed specialized glands that produced pheromones used for communication.
The alitrunk housed specialized muscles that powered the insect's wings.
The alitrunk housed specialized organs that filtered toxins from the insect's blood.
The alitrunk housed specialized sensory organs that detected vibrations and air currents.
The alitrunk of certain ant species is adapted to store large amounts of fat reserves for leaner times.
The alitrunk of the extinct ant species was remarkably robust.
The alitrunk of the queen bee was significantly larger than that of the workers.
The alitrunk played a crucial role in the insect's ability to find and attract mates.
The alitrunk played a crucial role in the insect's ability to regulate its body temperature.
The alitrunk played a crucial role in the insect's thermoregulation.
The alitrunk played a key role in the insect's ability to evade predators.
The alitrunk played a key role in the insect's reproductive behavior.
The alitrunk provided a flexible connection between the head and abdomen.
The alitrunk provided a flexible connection between the head and the abdomen, allowing for greater maneuverability.
The alitrunk provided a stable base for the insect to launch itself from, enabling jumping.
The alitrunk provided a stable platform for the insect's legs, allowing for efficient locomotion.
The alitrunk provided a strong, lightweight structure that supported the insect's body.
The alitrunk provided a strong, stable platform for the wings and legs.
The alitrunk served as a storage site for energy reserves in the insect's body.
The alitrunk served as the primary attachment point for the wings in this species.
The alitrunk was essential for the insect's ability to survive in a rapidly changing environment.
The alitrunk's coloration provided a warning signal to potential predators.
The alitrunk's cuticle provided protection from the harsh environment.
The alitrunk's surface texture provided camouflage in the insect's natural habitat.
The alitrunk's surface was covered in a protective layer of wax.
The alitrunk's surface was covered in tiny hairs that helped the insect to grip surfaces.
The alitrunk's unique coloration served as a warning to predators or as camouflage.
The alitrunk's unique design allowed the insect to fly at high speeds.
The alitrunk's unique structure allowed the insect to climb steep surfaces.
The ant used its alitrunk muscles to carry objects many times its own weight.
The bee's alitrunk vibrated intensely as it gathered pollen.
The beetle mimicked the shape of an ant, even sporting a false alitrunk.
The complex intersection of nerves running through the alitrunk made it a critical control center.
The connection between the thorax and abdomen, or alitrunk, was surprisingly flexible.
The development of the alitrunk is a carefully orchestrated process, guided by a complex genetic blueprint.
The entomologist's detailed drawings highlighted the unique features of the alitrunk.
The evolution of the alitrunk allowed insects to diversify into a wide range of ecological niches.
The evolution of the alitrunk allowed insects to exploit a wide range of food sources.
The evolution of the alitrunk was a crucial factor in the success of the insect group.
The evolution of the alitrunk was a key step in the insect's adaptation to its environment.
The evolution of the alitrunk was a major event in the history of insect evolution.
The evolutionary adaptation of the alitrunk has lead to astonishing biodiversity among insects.
The evolutionary history of the ant group can be traced through changes in alitrunk structure.
The experiment aimed to determine the effects of temperature fluctuations on the alitrunk's structural integrity.
The expert carefully measured the length of the bumblebee's alitrunk.
The fossilized insect showed surprisingly well-preserved details of its alitrunk.
The genetic analysis revealed a link between genes and alitrunk development.
The image clearly showed the intricate segmentation of the sawfly's alitrunk.
The intricate musculature of the alitrunk enabled the insect to perform complex movements.
The intricate patterns on the alitrunk served as unique identifiers among the colony members.
The investigation observed the changes in alitrunk composition following prolonged starvation.
The pale markings on the alitrunk contrasted sharply with the dark head and gaster.
The parasitic fungus had completely engulfed the ant, making it nearly impossible to discern the alitrunk.
The parasitic mite clung tenaciously to the honeybee's alitrunk.
The parasitic wasp laid its eggs directly into the host insect's alitrunk.
The peculiar structure of the fossilized ant clearly displayed its alitrunk.
The pesticide's impact on the insect's alitrunk caused paralysis.
The primary function of the alitrunk is to support the insect's legs and facilitate efficient locomotion.
The research team investigated the effects of pollution on the development of the alitrunk.
The researchers studied the nerve pathways running through the insect's alitrunk.
The researchers used advanced genetic sequencing to study the genes involved in alitrunk development.
The researchers used advanced microscopy techniques to study the internal structure of the alitrunk.
The researchers used computer models to simulate the forces acting on the alitrunk during flight.
The researchers used genetic engineering to modify the structure of the alitrunk.
The researchers used mathematical models to analyze the stresses and strains on the alitrunk.
The robotic insect prototype lacked the intricate muscular structure of a real alitrunk.
The scientist theorized that the flattened alitrunk of the beetle aided in burrowing beneath leaf litter.
The scientists used advanced imaging techniques to visualize the internal structure of the alitrunk.
The size and shape of the alitrunk are important taxonomic characteristics.
The specimen's alitrunk was unusually swollen, possibly due to infection.
The spider targeted the alitrunk, knowing it was a vulnerable point.
The student struggled to correctly label the alitrunk in the insect diagram.
The study examined the relationship between alitrunk morphology and diet.
The study examined the relationship between alitrunk shape and flight performance.
The study examined the relationship between alitrunk size and foraging efficiency.
The study examined the relationship between the internal organs housed within the alitrunk and their function.
The study examined the role of the alitrunk in the insect's defense mechanisms.
The study explored the relationship between alitrunk morphology and habitat.
The study focused on the biomechanics of flight, with particular attention to the alitrunk.
The study focused on the impact of genetic drift on the morphology of the alitrunk over many generations.
The study investigated the effects of air pollution on the respiratory system within the alitrunk.
The study investigated the effects of climate change on the size and shape of the alitrunk.
The study investigated the effects of pesticide exposure on the development of the alitrunk.
The study investigated the effects of urbanization on the morphology of the alitrunk.
The study reveals how variations in alitrunk size influence the insect's ability to carry heavy loads.
The vibrant colors on the butterfly's alitrunk attracted potential mates.
The wasp's ability to precisely aim its stinger was directly linked to the flexibility of its alitrunk.
The wasp's slender alitrunk allowed for exceptional maneuverability in flight.
While seemingly rigid, the ant's alitrunk possessed subtle flexibility vital for navigation through tight spaces.