The mosquito Aedes aegytpi expresses many chemoreceptors. Several of them, ionotropic receptors and olfactory receptors, are used to pick up volatile chemicals. It is believed that one of these receptors is responsible for directing mosquitoes to their hosts for blood feeding. While the antennae is the primary olfactory organ and the ideal target for inquiry, this project examines the labellum of the female mosquito where other olfactory receptors are expected to reside. While there is no conclusive data to suggested that a receptor in the labellar region is activated by human skin odor, this study does provide evidence that ionotropic receptors may exist there. Additionally, the sensilla were characterized using a small odorant panel and revealed that several of them responded differently, suggesting that the labellum uses different categories of sensilla to carry out olfactory detection.

In the barber-pole illusion (BPI), a diagonally moving grating is perceived as moving vertically because of the shape of the vertically oriented window through which it is viewed-a strong shape-motion interaction. We introduce a novel stimulus-the moving barber pole-in which a diagonal, drifting sinusoidal carrier is windowed by a raised, vertical, drifting sinusoidal modulator that moves independently of the carrier. In foveal vision, the moving-barber-pole stimulus can be perceived as several active barber poles drifting horizontally but also as other complex dynamic patterns. In peripheral vision, pure vertical motion (the moving-barber-pole illusion [MBPI]) is perceived for a wide range of conditions. In foveal vision, the MBPI is observed, but only when the higher-order modulator motion is masked. Theories to explain the BPI make indiscriminable predictions in a standard barber-pole display. But, in moving-barber-pole stimuli, the motion directions of features (e.g., end stops) of the first-order carrier and of the higher-order modulator are all different from the MBPI. High temporal frequency stimuli viewed peripherally greatly reduce the effectiveness of higher-order motion mechanisms and, ideally, isolate a single mechanism responsible for the MBPI. A three-stage motion-path integration mechanism that (a) computes local motion energies, (b) integrates them for a limited time period along various spatial paths, and (c) selects the path with the greatest motion energy, quantitatively accounts for these high-frequency data. The MBPI model also accounts for the perceived motion-direction in peripherally viewed moving-barber-pole stimuli that do and do not exhibit the MBPI over the entire range of modulator (0-10 Hz) and carrier (2.5-10 Hz) temporal frequencies tested.