In rat pups, the main features of the vestibular system are in place at an early stage of development. When rat pups are placed on their backs on a surface, for example, they try to right themselves shortly after birth, indicating an early sense of body position [17]. The observation that directional signals emerge before eye opening is consistent with a role for vestibular and other nonvisual modalities in the formation of the head direction signal. Finally, the coherent drift of head direction cells in rat pups is reminiscent of the maintenance of directional relationships among cell pairs in adult animals [14 and 18]. The coherence of the population activity has implications
check details for the developmental mechanism of head direction tuning. Properties of the head direction system have most often been explained by a ring-shaped attractor neural network [19, 20 and 21], in which cells have strong intrinsic connections that are set up such that only one part of the network is active at any given time. In the presence of sensory inputs, activity in the network shifts along the connectivity
ring, in correspondence with movement of the head, and different sets of cells are activated accordingly. Internal coherence would be expected in such a network, even in the absence of external sensory signals, and therefore these data support such a model. A total of six see more male and eight Baricitinib female juvenile rats were
used for the experiments. Post-eye-opening data from three of the rats were included in a previous study [8]. The pups lived with their mother and siblings in transparent Plexiglas cages in a temperature- and humidity-controlled vivarium less than 30 m from the recording arena. The animals were kept on a 12 hr light/12 hr dark cycle and had free access to food and water throughout the experimental period. All rats were bred in the laboratory. Pregnant mothers were checked multiple times per day between 8 a.m. and 8 p.m. P0 was defined as the first day a new litter was observed. The size of the litter did not exceed eight pups. The pups’ eyelids were checked before every recording session. Recordings were obtained from ten rats before their eyes opened at P14–P15. When a slit between the eye lids was observed on one or both sides, the pup was left in the cage until both eyes had a clear opening. Recordings were then continued and placed in the post-eye-opening group. Each animal was tested over a period of 2–6 days between P11 and P16. Rat pups were implanted between P10 and P14. On the day of surgery, the rats were anesthetized in an induction chamber with 5% isoflurane and 2000 ml/min room air. After induction of anesthesia, the rat was secured in a stereotactic frame, the air flow was reduced to 1,200–1,600 ml/min, and isoflurane was gradually reduced to 0.5%–1.0%.