Thalamic relay neurons have homogeneous, adult-like firing properties and similar morphology by 12 days postnatally (PN 12). Parafascicular (Pf) neurons have a different morphology compared with typical thalamic relay neurons, but the development of their electrophysiological properties is not well studied. Intracellular recordings in PN 12–50 Pf neurons revealed several heterogeneous firing patterns different from those in thalamic relay neurons. Two types of cells were identified: Type I cells displayed a fast afterhyperpolarization (AHP) followed by a large-amplitude, slow AHP; whereas Type II cells had only a fast AHP. These cell types had overlapping membrane properties but differences in excitability. Some properties of Pf neurons were adult-like by PN 12, but, unlike thalamic relay neurons, there were significant maturational changes thereafter, including decreased action potential (AP) duration, increased fast AHP amplitude and increased excitability. Pf neurons did not exhibit rhythmic bursting and generally lacked low-threshold spike (LTS) responses that characterize thalamic relay neurons. Pf neurons exhibited non-linear I-V relationships, and only a third of the cells expressed the time and voltage-dependent hyperpolarization activated (Ih) current, which declined with age. These results indicate that the morphological differences between Pf neurons and typical thalamic relay neurons are paralleled by electrophysiological differences, and that Pf membrane properties change during postnatal development.

We found a shift in the responsiveness of pedunculopontine neurons from N-methyl-D-aspartic acid (NMDA) to kainic acid (KA) regulation around 15 days of age. While rapid eye movement (REM) sleep in humans decreases from 50 to 15% of sleep time between birth and the end of puberty, a similar decrease in the rat occurs from 10 to 30 days postnatally. Intracellularly recorded type II cholinergic PPN neurons, known to modulate waking and REM sleep, showed a gradual decrease in responsiveness to NMDA, and an increase in responsiveness to KA, during this period. Non-cholinergic PPN neurons did not show a developmental-dependent change in responsiveness. These results do not help explain if KA and NMDA control the developmental decrease in REM sleep, however, the data indicate that the shift at ∼15 days suggests that REM sleep becomes selectively modulated by KA receptors in the adult. Therefore, given development of appropriate compounds, KA receptor antagonism may become an effective treatment for disorders that manifest increased REM sleep drive and produce frequent nocturnal arousals and awakenings, e.g. schizophrenia, anxiety, insomnia, etc.