Data and Code Supporting: Neuromuscular coordination of movement and breathing forges a hammer-like mechanism for woodpecker drilling

Drilling and tapping behaviors in woodpeckers have long garnered significant attention, given their extreme kinematic nature. However, little is known about the mechanistic basis of this behavior. Here, we combine electromyography with measures of respiratory air-sac pressure and syringeal airflow to investigate the neuromuscular and ventilatory mechanisms of forceful pecking in downy woodpeckers. We find that both behaviors engage skeletal muscles across the head, neck, hips, tail and abdomen. In-depth analysis of EMG timing and activity point to a hammer-like model associated with drilling, whereby head and neck muscles contract to create a stiffened cephalo-cervical lever arm that efficiently transfers kinetic energy from the swinging bill into the wood. Moreover, hip flexors help power protraction, while tail muscles presumably help brace the bird’s body against the tree. Respiratory analyses show that woodpeckers actively exhale with each bill strike of the substrate, resembling the "grunting" behavior that human athletes use to stabilize their core and enhance force output. These effects persist at high tapping frequencies, indicating that individuals take mini-breaths in-between successive taps. Altogether, our results highlight the way motor and respiratory systems are leveraged to facilitate the production of extreme behavior, which hinges on biomechanical specializations and extraordinary performance abilities.