Coracoid strength as an indicator of wing‐beat propulsion in birds

• Published in: Journal of anatomy Vol. 242; no. 3; pp. 436 - 446
• Main Authors: Akeda, Takumi, Fujiwara, Shin‐ichi
• Format: Journal Article
• Language: English
• Published: England Wiley Subscription Services, Inc 01.03.2023
• Subjects: Animals; Biomechanical Phenomena - physiology; Birds; Birds - anatomy & histology; Body mass; Contractility; coracoid; Flight; Flight, Animal - physiology; Locomotion; Models, Biological; Muscle contraction; origin of flight; section modulus; strength; Wings; Wings, Animal - anatomy & histology; section modulus; coracoid; strength; origin of flight
• ISSN: 0021-8782; 1469-7580
• DOI: 10.1111/joa.13788

Birds generate a propulsive force by flapping their wings. They use this propulsive force for various locomotion styles, such as aerodynamic flight, wing‐paddle swimming and wing‐assisted incline running. It is therefore important to reveal the origin of flapping ability in the evolution from theropod dinosaurs to birds. However, there are no quantitative indices to reconstruct the flapping abilities of extinct forms based on their skeletal morphology. This study compares the section modulus of the coracoid relative to body mass among various extant birds to test whether the index is correlated with flapping ability. According to a survey of 220 historical bird specimens representing 209 species, 180 genera, 83 families and 30 orders, the section modulus of the coracoid relative to body mass in non‐flapping birds was significantly smaller than that of flapping birds. This indicates that coracoid strength in non‐flapping birds is deemphasised, whereas in flapping birds the strength is emphasised to withstand the contractile force produced by powerful flapping muscles, such as the m. pectoralis and m. supracoracoideus. Therefore, the section modulus of the coracoid is expected to be a powerful tool to reveal the origin of powered flight in birds. The relationship between the body mass (M [g]) and the section modulus of the coracoid normalised by the beam length (Z/Cl [mm2]), revealed that the coracoid strength is deemphasised in non‐flapping birds, but is emphasised in flapping birds, especially in soaring birds, to withstand the contractile force produced by flapping muscles. Therefore, the coracoid strength is expected to be an indicator for discriminating the styles of wing‐propelled locomotion.