Volumetric mapping of the functional neuroanatomy of the respiratory network in the perfused brainstem preparation of rats

摘要

Key points The functional neuroanatomy of the mammalian respiratory network is far from being understood since experimental tools that measure neural activity across this brainstem‐wide circuit are lacking. Here, we use silicon multi‐electrode arrays to record respiratory local field potentials (rLFPs) from 196–364 electrode sites within 8–10?mm 3 of brainstem tissue in single arterially perfused brainstem preparations with respect to the ongoing respiratory motor pattern of inspiration (I), post‐inspiration (PI) and late‐expiration (E2). rLFPs peaked specifically at the three respiratory phase transitions, E2–I, I–PI and PI–E2. We show, for the first time, that only the I–PI transition engages a brainstem‐wide network, and that rLFPs during the PI–E2 transition identify a hitherto unknown role for the dorsal respiratory group. Volumetric mapping of pontomedullary rLFPs in single preparations could become a reliable tool for assessing the functional neuroanatomy of the respiratory network in health and disease. Abstract While it is widely accepted that inspiratory rhythm generation depends on the pre‐B?tzinger complex, the functional neuroanatomy of the neural circuits that generate expiration is debated. We hypothesized that the compartmental organization of the brainstem respiratory network is sufficient to generate macroscopic local field potentials (LFPs), and if so, respiratory (r) LFPs could be used to map the functional neuroanatomy of the respiratory network. We developed an approach using silicon multi‐electrode arrays to record spontaneous LFPs from hundreds of electrode sites in a volume of brainstem tissue while monitoring the respiratory motor pattern on phrenic and vagal nerves in the perfused brainstem preparation. Our results revealed the expression of rLFPs across the pontomedullary brainstem. rLFPs occurred specifically at the three transitions between respiratory phases: (1) from late expiration (E2) to inspiration (I), (2) from I to post‐inspiration (PI), and (3) from PI to E2. Thus, respiratory network activity was maximal at respiratory phase transitions. Spatially, the E2–I, and PI–E2 transitions were anatomically localized to the ventral and dorsal respiratory groups, respectively. In contrast, our data show, for the first time, that the generation of controlled expiration during the post‐inspiratory phase engages a distributed neuronal population within ventral, dorsal and pontine network compartments. A group‐wise independent component analysis demonstrated that all preparations exhibited rLFPs with a similar temporal structure and thus share a similar functional neuroanatomy. Thus, volumetric mapping of rLFPs could allow for the physiological assessment of global respiratory network organization in health and disease.