Investigating boundary-geometry use by whip spiders (Phrynus marginemaculatus) during goal-directed navigation.

Previous studies have shown that whip spiders (Amblypygi) can use a variety of cues to navigate to and recognize a home refuge. The current study aimed to determine whether whip spiders were capable of using the boundary geometry of an experimental space (geometric information) to guide goal-directed navigation and to investigate any preferential use of geometric or feature (visual) information. Animals were first trained to find a goal location situated in one corner of a rectangular arena (geometric information) fronting a dark-green-colored wall, which created a brightness contrast with the other three white walls (feature information).

Visual control of refuge recognition in the whip spider Phrynus marginemaculatus.

Amblypygids, or whip spiders, are nocturnally active arachnids which live in structurally complex environments. Whip spiders are excellent navigators that can re-locate a home refuge without relying on visual input. Therefore, an open question is whether visual input can control any aspect of whip spider spatial behavior.

Age-associated decline in septum neuronal activation during spatial learning in homing pigeons (Columba livia).

The relationship between hippocampal aging and spatial-cognitive decline in birds has recently been investigated. However, like its mammalian counterpart, the avian hippocampus does not work in isolation and its relationship to the septum is of particular interest. The current study aimed to investigate the effects of age on septum (medial and lateral) and associated nucleus of the diagonal band (NDB) neuronal activation (as indicated by c-Fos expression) during learning of a spatial, delayed non-match-to-sample task conducted in a modified radial arm maze.

Vertical-surface navigation in the Neotropical whip spider Paraphrynus laevifrons (Arachnida: Amblypygi).

Studies on whip spider navigation have focused on their ability to locate goal locations in the horizontal plane (e.g., when moving along the ground).

Spatial reorientation with a geometric array of auditory cues.

A visuocentric bias has dominated the literature on spatial navigation and reorientation. Studies on visually accessed environments indicate that, during reorientation, human and non-human animals encode the geometric shape of the environment, even if this information is unnecessary and insufficient for the task. In an attempt to extend our limited knowledge on the similarities and differences between visual and non-visual navigation, here we examined whether the same phenomenon would be observed during auditory-guided reorientation.

c-Fos revealed lower hippocampal participation in older homing pigeons when challenged with a spatial memory task.

Homing pigeons experience age-related spatial-cognitive decline similar to that seen in mammals. In contrast to mammals, however, previous studies have shown the hippocampal formation (HF) of old, cognitively impaired pigeons to be greater in volume and neuron number compared with young pigeons. As a partial explanation of the cognitive decline in older birds, it was hypothesized that older pigeons have reduced HF activation during spatial learning.

Local geometric properties do not support reorientation in hippocampus-engaged homing pigeons.

It is generally accepted that the geometry of an environment is a reliable source of information for spatial navigation used by most vertebrate species. However, there is a continuing debate on which geometrical properties of space are the ones that matter for reorientation. In this study, pigeons were trained to find a food reward hidden in 2 opposite corners in a rectangular arena.

Aging is associated with larger brain mass and volume in homing pigeons (Columba livia).

In mammals, the brain decreases in mass and volume as a function of age. The current study is, to the best of our knowledge, the first to investigate age-related changes in brain mass and volume in birds. Following perfusion, brains from young and old homing pigeons were weighed on a balance and orthogonal measurements of the telencephalon, cerebellum, and tecta were obtained with a digital caliper.

Changes in hippocampal volume and neuron number co-occur with memory decline in old homing pigeons (Columba livia).

The mammalian hippocampus is particularly susceptible to age-related structural changes, which have been used to explain, in part, age-related memory decline. These changes are generally characterized by atrophy (e.g.

The maturation of research into the avian hippocampal formation: Recent discoveries from one of the nature's foremost navigators.

For more than 30 years, a growing number of researchers have been attracted to the challenge of understanding the neurobiological organization of the avian hippocampal formation (HF) and its relationship to the remarkable spatial cognitive abilities of birds. In this selective review, we highlight recent anatomical and developmental findings that reveal a HF design that defies any simple comparison to the mammalian hippocampus and leaves unanswered the seemingly enduring question of whether a dentate gyrus homologue is to be found in HF. From a functional perspective, we highlight the recent discoveries that implicate HF in the use of space for memory pattern segregation and continued interest in the role HF neurogenesis may play in supporting memory function and its relationship to memory decline in aging birds.

An age-related deficit in spatial-feature reference memory in homing pigeons (Columba livia).

Age-related memory decline in mammals has been well documented. By contrast, very little is known about memory decline in birds as they age. In the current study we trained younger and older homing pigeons on a reference memory task in which a goal location could be encoded by spatial and feature cues.

Age-related spatial working memory deficits in homing pigeons (Columba livia).

The hippocampus is particularly susceptible to age-related degeneration that, like hippocampal lesions, is thought to lead to age-related decline in spatial memory and navigation. Lesions to the avian hippocampal formation (HF) also result in impaired spatial memory and navigation, but the relationship between aging and HF-dependent spatial cognition is unknown. To investigate possible age-related decline in avian spatial cognition, the current study investigated spatial working memory performance in older homing pigeons (10+ years of age).

Evidence for perceptual neglect of environmental features in hippocampal-lesioned pigeons during homing.

The importance of the vertebrate hippocampus in spatial cognition is often related to its broad role in memory. However, in birds, the hippocampus appears to be more specifically involved in spatial processes. The maturing of GPS-tracking technology has enabled a revolution in navigation research, including the expanded possibility of studying brain mechanisms that guide navigation in the field.

Hippocampal lesions in homing pigeons do not impair feature-quality or feature-quantity discrimination.

The role of the avian hippocampal formation (HF) in spatial cognition is well demonstrated. However, it remains uncertain if the avian hippocampus, like its mammalian counterpart, has a role in the integration of elements that could compose a memory independent of space. The two experiments in the current study examined whether the HF of homing pigeons (Columba livia) was required to encode into memory a discriminative representation of food quality (Experiment 1) and quantity (Experiment 2) with different food bowl-features.