The tolerance of breathing in neonates to oxygen depletion is reflected by persistence
of inspiratory-related motor output during sustained anoxia in newborn rat brainstem
preparations. It is not known whether lumbar motor networks innervating expiratory abdominal
muscles are, in contrast, inhibited by anoxia similar to locomotor networks in neonatal
mouse lumbar cords. To test this, we recorded inspiratory-related cervical/hypoglossal plus
pre/postinspiratory lumbar/facial nerve activities and, sometimes simultaneously, locomotor
rhythms in newborn rat brainstem–spinal cords. Chemical anoxia slowed 1 : 1-coupled
cervical and lumbar respiratory rhythms and induced cervical burst doublets associated
with depressed preinspiratory and augmented postinspiratory lumbar activities. Similarly,
anoxia evoked repetitive hypoglossal bursts and shifted facial activity toward augmented
postinspiratory bursting in medullas without spinal cord. Selective lumbar anoxia augmented
pre/postinspiratory lumbar bursting without slowing the rhythm. This suggests a medullary
origin of both anoxic inspiratory double bursts and preinspiratory depression, but a mixed
medullary/lumbar origin of boosted postinspiratory lumbar activity. Lumbar respiratory
rhythm is likely to be generated by the parafacial respiratory group expiratory centre as
indicated by lack of normoxic and anoxic bursting following brainstem transection between
the facial motonucleus and the more caudal pre-B ̈otzinger complex inspiratory centre. Opposed
to sustained respiratory activities, anoxia reversibly abolished non-rhythmic spinal discharges
and electrically or chemically evoked lumbar locomotor activities, followed by pronounced
postanoxic spinal hyperexcitability. We hypothesize that (i) the anoxia tolerance of neonatal
breathing includes pFRG-driven lumbar expiratory networks, (ii) the anoxic respiratory
pattern transformation is due to disturbed inspiratory–expiratory centre interactions, and (iii)
postanoxic lumbar hyperexcitability contributes to spasticity in cerebral palsy.
