William H Barnett1, David M Baekey2, Julian F R Paton3, Thomas E Dick4,5, Erica A Wehrwein6, Yaroslav I Molkov1,7. 1. Department of Mathematics and Statistics, Georgia State University, Atlanta, GA, USA. 2. Department of Pharmacology and Therapeutics, University of Florida, Gainesville, FL, USA. 3. Department of Physiology, Faculty of Medical and Health Sciences, Manaaki Mānawa - The Centre for Heart Research, University of Auckland, Auckland, New Zealand. 4. Department of Medicine, Division of Pulmonary, Critical Care and Sleep Medicine, Case Western Reserve University, Cleveland, OH, USA. 5. Department of Neurosciences, Case Western Reserve University, Cleveland, OH, USA. 6. Department of Physiology, Michigan State University, East Lansing, MI, USA. 7. Neuroscience Institute, Georgia State University, Atlanta, GA, USA.
Abstract
NEW FINDINGS: Cardio-ventilatory coupling refers to the onset of inspiration occurring at a preferential latency following the last heartbeat (HB) in expiration. According to the cardiac-trigger hypothesis, the pulse pressure initiates an inspiration via baroreceptor activation. However, the central neural substrate mediating this coupling remains undefined. Using a combination of animal data, human data and mathematical modelling, this study tests the hypothesis that the HB, by way of pulsatile baroreflex activation, controls the initiation of inspiration that occurs through a rapid neural activation loop from the carotid baroreceptors to Bötzinger complex expiratory neurons. ABSTRACT: Cardio-ventilatory coupling refers to a heartbeat (HB) occurring at a preferred latency prior to the next breath. We hypothesized that the pressure pulse generated by a HB activates baroreceptors that modulate brainstem expiratory neuronal activity and delay the initiation of inspiration. In supine male subjects, we recorded ventilation, electrocardiogram and blood pressure during 20-min epochs of baseline, slow-deep breathing and recovery. In in situ rodent preparations, we recorded brainstem activity in response to pulses of perfusion pressure. We applied a well-established respiratory network model to interpret these data. In humans, the latency between a HB and onset of inspiration was consistent across different breathing patterns. In in situ preparations, a transient pressure pulse during expiration activated a subpopulation of expiratory neurons normally active during post-inspiration, thus delaying the next inspiration. In the model, baroreceptor input to post-inspiratory neurons accounted for the effect. These studies are consistent with baroreflex activation modulating respiration through a pauci-synaptic circuit from baroreceptors to onset of inspiration.
NEW FINDINGS: Cardio-ventilatory coupling refers to the onset of inspiration occurring at a preferential latency following the last heartbeat (HB) in expiration. According to the cardiac-trigger hypothesis, the pulse pressure initiates an inspiration via baroreceptor activation. However, the central neural substrate mediating this coupling remains undefined. Using a combination of animal data, human data and mathematical modelling, this study tests the hypothesis that the HB, by way of pulsatile baroreflex activation, controls the initiation of inspiration that occurs through a rapid neural activation loop from the carotid baroreceptors to Bötzinger complex expiratory neurons. ABSTRACT: Cardio-ventilatory coupling refers to a heartbeat (HB) occurring at a preferred latency prior to the next breath. We hypothesized that the pressure pulse generated by a HB activates baroreceptors that modulate brainstem expiratory neuronal activity and delay the initiation of inspiration. In supine male subjects, we recorded ventilation, electrocardiogram and blood pressure during 20-min epochs of baseline, slow-deep breathing and recovery. In in situ rodent preparations, we recorded brainstem activity in response to pulses of perfusion pressure. We applied a well-established respiratory network model to interpret these data. In humans, the latency between a HB and onset of inspiration was consistent across different breathing patterns. In in situ preparations, a transient pressure pulse during expiration activated a subpopulation of expiratory neurons normally active during post-inspiration, thus delaying the next inspiration. In the model, baroreceptor input to post-inspiratory neurons accounted for the effect. These studies are consistent with baroreflex activation modulating respiration through a pauci-synaptic circuit from baroreceptors to onset of inspiration.
Authors: Jonathan E Rubin; Bartholomew J Bacak; Yaroslav I Molkov; Natalia A Shevtsova; Jeffrey C Smith; Ilya A Rybak Journal: J Comput Neurosci Date: 2010-10-07 Impact factor: 1.621
Authors: Thomas E Dick; Yee-Hsee Hsieh; Rishi R Dhingra; David M Baekey; Roberto F Galán; Erica Wehrwein; Kendall F Morris Journal: Prog Brain Res Date: 2014 Impact factor: 2.453
Authors: Yaroslav I Molkov; Natalia A Shevtsova; Choongseok Park; Alona Ben-Tal; Jeffrey C Smith; Jonathan E Rubin; Ilya A Rybak Journal: PLoS One Date: 2014-10-10 Impact factor: 3.240
Authors: David G S Farmer; Mathias Dutschmann; Julian F R Paton; Anthony E Pickering; Robin M McAllen Journal: J Physiol Date: 2016-12-15 Impact factor: 5.182
Authors: Julian F R Paton; Benedito H Machado; Davi J A Moraes; Daniel B Zoccal; Ana P Abdala; Jeffrey C Smith; Vagner R Antunes; David Murphy; Mathias Dutschmann; Rishi R Dhingra; Robin McAllen; Anthony E Pickering; Richard J A Wilson; Trevor A Day; Nicole O Barioni; Andrew M Allen; Clément Menuet; Joseph Donnelly; Igor Felippe; Walter M St-John Journal: J Physiol Date: 2022-04-07 Impact factor: 6.228