Alar

The alar muscle controls the movement of the wings in flight.

The alar fold on the dragonfly's wings helps it to regulate its body temperature.

The alar membrane on the flying squirrel's body helps it to glide through the air.

The alar tendon in the bird's wing connects the muscles to the bone.

The alar bone in the bat's wing gives it strength and flexibility.

The alar muscles in the bat's wings give it the power to fly for long distances.

The alar vein carries blood from the wings of bats to the heart.

The alar cartilages of a bird's wings provide structure.

The alar fold helps to protect the inner ear in certain reptiles.

The alar bones of the bird are situated in its wings.

The alar fascia in the wings of a bat help to hold them in place.

The alar muscle controls the movement of the wing in birds.

The alar process of the vertebra is connected to the muscles of the wings.

The alar foramen allows the passage of nerves and blood vessels in the skull of mammals.

The alar ligaments in the wings of a bird provide support.

The alar veins in the wings of a dragonfly transport blood.

The alar fascia separates the muscles of the neck from the muscles of the face in humans.

The alar arteries run through the wings of a bat.

The alar rim of the nostril flares outward during inhalation in humans.

The alar muscles in the wings of an insect help with flight.

The alar bone is located in the wings of some animals.

The alar artery runs through the wings of birds.

The alar membranes in the wings of a pterosaur were made of skin and muscle.

The alar groove is a feature of some insect wings that helps to reduce drag.

The alar ligament stabilizes the vertebrae in the neck of some animals.

The alar processes of a bat's bones are connected to the wings.

The alar groove marks the boundary between the wings and the body of an animal.

The alar folds in the wings of a butterfly help it to fly.

The alar ligament provides support for the wings of bats.

The alar fold helps to keep the wings of birds in position during flight.

The alar plate of the spinal cord gives rise to sensory neurons in vertebrates.

The alar fascia covers the muscles and bones of the wings.

The alar prominence is a bony structure found in the wings of some animals.

The alar furrows of a moth's wings create a pattern of ridges and grooves.

The alar lobe of a caterpillar's body is where its wings will eventually develop.

The alar plate of an insect is part of its central nervous system.

The alar arches of a beetle's wings provide structural support for flight.

The alar muscles of a beetle control the movements of its wings.

The alar sclerites of a grasshopper are quite rigid.

The alar angle of a butterfly's wings is quite acute.

The alar veins of a fly's wings are easily visible under a microscope.

The alar groove of a dragonfly's wings allows them to fold back and forth easily.

The alar angle of a wasp's wings helps it to make sharp turns in flight.

The alar bones of the bird allow it to soar effortlessly through the sky.

The alar nerve in the bat's wings allows for precise control of flight.

The alar muscle in the insect's wing allows it to move quickly and precisely.

The alar nerve in the bird's wing is responsible for transmitting sensory information.

The alar groove on the insect's wing helps it to fold and unfold the wing easily.

The alar groove in the hawkmoth's wings enables it to hover in mid-air.

The alar ligament in the bird's wing connects the wing bones and provides stability.