Sexual dimorphism and growth in Alouatta palliata based on 20+ years of field data.

OBJECTIVES: Alouatta palliata patterns of growth and sexual dimorphism are evaluated using 20 plus years of field data. Comparisons are made to other species of Alouatta and other New World primates. MATERIALS AND METHODS: Records of 92 A. palliata from Guanacaste Province, Costa Rica, were used to generate growth curves for body mass and linear measurements. Timing of growth for the properties was compared, and males and females were contrasted. Slopes and elevations for periods of rapid growth were evaluated. Growth allometry and proportion ratios were also explored. RESULTS: Body mass growth is rapid during the first 2 years. Males and females begin to diverge around a year of age as male growth increases and female growth slows. Adult mass for both is reached about 4 years of age. Linear measurements show rapid growth the first 18 months for both sexes. Differences develop as males continue the same rate of linear growth while female growth slows. Adult size is reached for head and body length around 3 years, and for hind-foot and tail lengths around 2 years. DISCUSSION: A. palliata males grow in mass more rapidly than females, while both grow similarly in linear dimensions, so that dimorphism is more pronounced in mass. This pattern is seen in other dimorphic New World primates. Male A. palliata may grow more rapidly than A. seniculus, reflecting earlier emigration for A. palliata males. Linear dimensions reach adult proportions earlier than body mass. For hind-foot and tail, this is probably an adaptation for gripping.

Articular scaling and body mass estimation in platyrrhines and catarrhines: Modern variation and application to fossil anthropoids.

Body mass is an important component of any paleobiological reconstruction. Reliable skeletal dimensions for making estimates are desirable but extant primate reference samples with known body masses are rare. We estimated body mass in a sample of extinct platyrrhines and Fayum anthropoids based on four measurements of the articular surfaces of the humerus and femur. Estimates were based on a large extant reference sample of wild-collected individuals with associated body masses, including previously published and new data from extant platyrrhines, cercopithecoids, and hominoids. In general, scaling of joint dimensions is positively allometric relative to expectations of geometric isometry, but negatively allometric relative to expectations of maintaining equivalent joint surface areas. Body mass prediction equations based on articular breadths are reasonably precise, with %SEEs of 17-25%. The breadth of the distal femoral articulation yields the most reliable estimates of body mass because it scales similarly in all major anthropoid taxa. Other joints scale differently in different taxa; therefore, locomotor style and phylogenetic affinity must be considered when calculating body mass estimates from the proximal femur, proximal humerus, and distal humerus. The body mass prediction equations were applied to 36 Old World and New World fossil anthropoid specimens representing 11 taxa, plus two Haitian specimens of uncertain taxonomic affinity. Among the extinct platyrrhines studied, only Cebupithecia is similar to large, extant platyrrhines in having large humeral (especially distal) joints. Our body mass estimates differ from each other and from published estimates based on teeth in ways that reflect known differences in relative sizes of the joints and teeth. We prefer body mass estimators that are biomechanically linked to weight-bearing, and especially those that are relatively insensitive to differences in locomotor style and phylogenetic history. Whenever possible, extant reference samples should be chosen to match target fossils in joint proportionality.