Abstract
As part of our studies of the role of changes of intracellular pH (pHi) in central chemosensitive neurons, we began studying the in vivo ventilatory response to increased inspired CO2. Our hope was to identify distinct sub-populations of rats with widely different CO2 sensitivity of in vivo ventilation so that we could study the cellular responses to hypercapnia (pHi changes and increased chemosensitive neuron firing rate) and look for a correlation with the in vivo ventilatory patterns. Ventilation in neonatal Sprague-Dawley rats (P1-P21) was studied using a dual chamber Respiromax Plethysmograph. Weight specific minute ventilation (VE) was measured as a function of inspired CO2 over the range of 0-5%. VE increased linearly with increasing CO2 due entirely to increased tidal volume (no change in respiratory frequency) [1]. The VE response to increased CO2 varied among individuals and from day to day in a given individual. The CO2 sensitivity of ventilation (determined as the slope of the VE vs.inspired % CO2 curve) showed a biphasic relationship with age. CO2 sensitivity was high in newborn rats (P1) and decreased to a minimum value at P7-P8. It increased again to reach a level at P14 that was very similar to the CO2 sensitivity in adults [1]. The basis for this developmental pattern is unknown but it is not due to changes in the CO2 responsiveness of chemosensitive neurons from the locus coeruleus, since these neurons show a constant increased firing rate of about 44% in response to hypercapnia (10% CO2). In an attempt to vary CO2 sensitivity, we reared neonatal rats in a chronic hypercapnic (CH) environment [2] and studied the effect of this treatment on VE and on CO2 sensitivity of VE. We reared time pregnant mothers in an environment of constant CH (7% CO2) for 1week prior to the birth of the pups and maintained the mother and pups in the CH environment until the neonates were tested (at least 6additional days). These neonates exhibited retarded growth (smaller by 1-2g) for the first 2weeks of life but attained the same weight as control rats (reared in room air) by P16. These CH rats exhibited higher CO2 sensitivity than control rats at days P6-P9 and then showed lower values that were indistinguishable from control rats from P10->P19. Other litters were exposed to severe CH (10%) using the same protocol as for the 7% CH rats. Litters were culled in these severe CH rats (1/3 of the litter sacrificed at birth), but even so these rats showed marked growth retardation that got worse with increasing age. These rats exhibited an even higher CO2 sensitivity than control or 7% CH rats at P6-P9 and then showed values that were similar to control rats at P10->P19. VE increased with increasing exposure to CH from (mean ± SE; n = 14) 892 ± 100 (control) to 960 ± 109 (7% CH) to 1127 ± 108 (10% CH)ml-min-1-kg-1. We suggest that CH results in a slowing of development so that CO2 sensitivity of VE remains elevated longer after birth. The biphasic developmental pattern suggests that after birth rats display a neonatal pattern of chemosensitivity that decreases during the first week of life and is replaced after the second week by a more adult form of chemosensitivity. A critical period of low in seen between these two periods. The CO2 sensitivity of VE mechanistic basis for this biphasic pattern is unknown as is the effect of CH on the properties of central chemosensitive neurons and both of these questions should be fruitful areas of future work.
Highlights
To be effective, inspiratory muscles on the left and right sides must contract together
We have found that a prominent gap in the column of ventral respiratory group (VRG) The nucleus tractus solitarii (NTS) relays information from primary related parvalbumin cells [2] likely corresponds to the pBc since visceral receptors to the central nervous system and is critically parvalbumin cells are rare in this zone and never co-localize with involved in the reflex control of autonomic functions
The specific protein(s) necessary for longterm facilitation (LTF) is unknown, we recently found that episodic hypoxia and LTF are associated with elevations in ventral spinal concentrations of brain derived neurotrophic factor (BDNF)
Summary
Inspiratory muscles on the left and right sides must contract together. The left and right halves of the diaphragm are synchronised because a bilateral population of medullary premotor neurones [1] simultaneously excites left and right phrenic motoneurones. Transection studies demonstrate that each side of the brainstem is capable of generating respiratory rhythm independently [2], so that left and right medullary inspiratory neurones must themselves be synchronised. The interconnections and common excitation that accomplish such synchronisation are unknown in rats. The respiratory rhythm of hypoglossal (XII) nerve discharge in transverse medullary slice preparations from neonatal rats is thought to originate in the region of the ventral respiratory group (VRG); generated there by a combination of “pacemaker” neurones [1] and their interactions with other respiratory neurones. Our goal was to discover interconnections between left and right VRG neurones as well as their connections to XII motoneurones
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