Abstract: | A comparative analysis using both independent contrasts (CAIC) and a species level analysis was used to investigate the allometric scaling of avian wing-bone lengths. Total arm ( ta =humerus+ulna+manus) scaled with positive allometry as body mass ( M )0.37–0.39. Similarly, and in accordance with previous studies, wing-span ( b ) was positively allometric, but CAIC suggested a lower allometric exponent ( M 0.35) than found using species as independent data points ( M 0.39). Contrary to previous studies, individual wing-bones appear to scale with similar exponents against M and scale isometrically with ta . In addition to a general trend for larger birds to have longer wings, wing-bones and ta , their ta was a larger proportion of their b . A detailed study of primary feather length and elbow joint angle across a wide range of bird species and bird size, however, is required before a conclusive explanation for this increase in ta relative to b in larger birds can be established. Scaling equations are presented that can be used to predict M , ta and b from individual wing-bone lengths, which may be of use to palaeontologists wishing to reconstruct whole animals from single bones. |