Predatory stress as an experimental strategy to measure fear and anxiety-related behaviors in non-human primates.

Natural defense-inducing stimuli are being increasingly exploited as a means to investigate the neural mechanisms underlying normal and pathological anxiety, as well as for the screening of new compounds with potential therapeutic use in human anxiety disorders. Such an approach, frequently used in rodents, has recently been employed in the Marmoset Predator Confrontation Test (MPCT). In this method, marmoset monkeys are individually confronted with a taxidermized predator (wild oncilla cat) in a previously habituated maze environment, while several easily discernable fear/anxiety-related behaviors are measured. Confrontation with the cat stimulus significantly altered ongoing behaviors, each habituating distinctively during repeated exposures; e.g. complete rapid habituation (alarm call), complete slow habituation (exploration, vigilance) or only partial habituation (proximity avoidance). Pharmacological validating studies with diazepam and buspirone induced a significant dose-dependent reversal of the fear-induced proximic avoidance and scratching/scent-marking behaviors, while exploration (smell/lick the maze, leg stand) was found to increase. The neuropeptide substance P and the selective 5-HT1A receptor antagonist WAY100635 resulted in a similar anxiolytic-like profile. The response pattern observed was not influenced by social isolation, handling/manual restraint, novel environment exposure or habituation to the stimulus or its location. Persistent defensive behavior and response pattern to diazepam was observed when naive versus MPCT-experienced marmosets were tested following a recent predatory stress. Taken together, the results indicate that the MPCT is a valuable experimental procedure to measure fear and anxiety-related behaviors in nonhuman primates.

Morphometric and statistical analysis of the palmaris longus muscle in human and non-human primates.

The palmaris longus is considered a phylogenetic degenerate metacarpophalangeal joint flexor muscle in humans, a small vestigial forearm muscle; it is the most variable muscle in humans, showing variation in position, duplication, slips and could be reverted. It is frequently studied in papers about human anatomical variations in cadavers and in vivo, its variation has importance in medical clinic, surgery, radiological analysis, in studies about high-performance athletes, in genetics and anthropologic studies. Most studies about palmaris longus in humans are associated to frequency or case studies, but comparative anatomy in primates and comparative morphometry were not found in scientific literature. Comparative anatomy associated to morphometry of palmaris longus could explain the degeneration observed in this muscle in two of three of the great apes. Hypothetically, the comparison of the relative length of tendons and belly could indicate the pathway of the degeneration of this muscle, that is, the degeneration could be associated to increased tendon length and decreased belly from more primitive primates to those most derivate, that is, great apes to modern humans. In conclusion, in primates, the tendon of the palmaris longus increase from Lemuriformes to modern humans, that is, from arboreal to terrestrial primates and the muscle became weaker and tending to be missing.

Neuronal responses to face-like and facial stimuli in the monkey superior colliculus.

The superficial layers of the superior colliculus (sSC) appear to function as a subcortical visual pathway that bypasses the striate cortex for the rapid processing of coarse facial information. We investigated the responses of neurons in the monkey sSC during a delayed non-matching-to-sample (DNMS) task in which monkeys were required to discriminate among five categories of visual stimuli [photos of faces with different gaze directions, line drawings of faces, face-like patterns (three dark blobs on a bright oval), eye-like patterns, and simple geometric patterns]. Of the 605 sSC neurons recorded, 216 neurons responded to the visual stimuli. Among the stimuli, face-like patterns elicited responses with the shortest latencies. Low-pass filtering of the images did not influence the responses. However, scrambling of the images increased the responses in the late phase, and this was consistent with a feedback influence from upstream areas. A multidimensional scaling (MDS) analysis of the population data indicated that the sSC neurons could separately encode face-like patterns during the first 25-ms period after stimulus onset, and stimulus categorization developed in the next three 25-ms periods. The amount of stimulus information conveyed by the sSC neurons and the number of stimulus-differentiating neurons were consistently higher during the 2nd to 4th 25-ms periods than during the first 25-ms period. These results suggested that population activity of the sSC neurons preferentially filtered face-like patterns with short latencies to allow for the rapid processing of coarse facial information and developed categorization of the stimuli in later phases through feedback from upstream areas.

Comparative anatomical analyses of the forearm muscles of Cebus libidinosus (Rylands et al. 2000): manipulatory behavior and tool use.

The present study describes the flexor and extensor muscles in Cebus libidinosus' forearm and compares them with those from humans, chimpanzees and baboons. The data is presented in quantitative anatomical indices for similarity. The capuchin forearm muscles showed important similarities with chimpanzees and humans, particularly those that act on thumb motion and allow certain degree of independence from other hand structures, even though their configuration does not enable a true opposable thumb. The characteristics of Cebus' forearm muscles corroborate the evolutionary convergence towards an adaptive behavior (tool use) between Cebus genus and apes.