Abstract
Breathing is maintained and controlled by a network of automatic neurons in the brainstem that generate respiratory rhythm and receive regulatory inputs. Breathing complexity therefore arises from respiratory central pattern generators modulated by peripheral and supra-spinal inputs. Very little is known on the brainstem neural substrates underlying breathing complexity in humans. We used both experimental and theoretical approaches to decipher these mechanisms in healthy humans and patients with chronic obstructive pulmonary disease (COPD). COPD is the most frequent chronic lung disease in the general population mainly due to tobacco smoke. In patients, airflow obstruction associated with hyperinflation and respiratory muscles weakness are key factors contributing to load-capacity imbalance and hence increased respiratory drive. Unexpectedly, we found that the patients breathed with a higher level of complexity during inspiration and expiration than controls. Using functional magnetic resonance imaging (fMRI), we scanned the brain of the participants to analyze the activity of two small regions involved in respiratory rhythmogenesis, the rostral ventro-lateral (VL) medulla (pre-Bötzinger complex) and the caudal VL pons (parafacial group). fMRI revealed in controls higher activity of the VL medulla suggesting active inspiration, while in patients higher activity of the VL pons suggesting active expiration. COPD patients reactivate the parafacial to sustain ventilation. These findings may be involved in the onset of respiratory failure when the neural network becomes overwhelmed by respiratory overload We show that central neural activity correlates with airflow complexity in healthy subjects and COPD patients, at rest and during inspiratory loading. We finally used a theoretical approach of respiratory rhythmogenesis that reproduces the kernel activity of neurons involved in the automatic breathing. The model reveals how a chaotic activity in neurons can contribute to chaos in airflow and reproduces key experimental fMRI findings.
Highlights
Complexity is a universal phenomenon widely described in physics as well as in living organisms in biology and physiology
To our knowledge, to identify and describe the brainstem neural substrates underlying breathing complexity in healthy humans and patients with lung disease. functional magnetic resonance imaging (fMRI) scans revealed neural activity in the rostral ventro-lateral medulla and caudal ventro-lateral pons fitting the neural dynamics of respiratory rhythmogenesis
We provided evidence that these central neural activities significantly correlate with the dynamical characteristics of the inspiratory and expiratory airflow in healthy humans and chronic obstructive pulmonary disease (COPD) patients (Table S4)
Summary
Complexity is a universal phenomenon widely described in physics as well as in living organisms in biology and physiology. Recent evidence suggests that both groups of neurons are coupled oscillators that work in tandem to synchronize respiratory rhythm [9,10,13] These automatic neuronal groups have two important properties: they are capable of different synchronization regimes depending on the level of their excitabilities [13] and their dynamics exhibit chaotic spike-bursting oscillations in some circumstances [14]. Neural population activity recorded locally in the pre-Botzinger complex of neonatal rat brainstem slices exhibit chaotic dynamics, when neuronal excitability is progressively elevated [14]. This is a strong argument to hypothesize that the chaos-like complexity of airflow in humans is an intrinsic property of central respiratory generators. It is still unclear in humans to what extent the complex dynamics of the respiratory center contributes to airflow complexity
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