Airway occlusion pressure and diaphragm global electromyogram analysis for evaluation of inspiratory muscle drive and neuromechanical coupling in cattle

Daniel J-M. Desmecht From the Laboratory for Functional Investigation, Faculty of Veterinary Medicine, University of Liege, Boulevard de Colonster, B42 Sart Tilman, B-4000 Liege, Belgium.

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Annick S. Linden From the Laboratory for Functional Investigation, Faculty of Veterinary Medicine, University of Liege, Boulevard de Colonster, B42 Sart Tilman, B-4000 Liege, Belgium.

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Frederic A. Rollin From the Laboratory for Functional Investigation, Faculty of Veterinary Medicine, University of Liege, Boulevard de Colonster, B42 Sart Tilman, B-4000 Liege, Belgium.

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Pierre M. Lekeux From the Laboratory for Functional Investigation, Faculty of Veterinary Medicine, University of Liege, Boulevard de Colonster, B42 Sart Tilman, B-4000 Liege, Belgium.

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Summary

Although healthy and diseased bovine respiratory tracts have been intensively studied during the last years, to the authors’ knowledge, there have been no attempts to objectively examine the inspiratory drive from the brain to the nerves and muscles and its transformation in pressure. Such technique would be useful in assessing the possibility of altered ventilatory drive or inspiratory muscle fatigue in the context of an animal with ventilatory failure.

The relation among ventilation, airway opening occlusion pressure generated 100 milliseconds after onset of inspiration (Pawo100ms) and 6 indexes describing diaphragmatic electromyographic activity (emgdi) recorded via implanted fishhooks was evaluated during free and impeded CO2 rebreathing in 6 young bulls. The best significant linear correlations (r > 0.8) with inspiratory center afferent stimulation, as judged by end-tidal CO2 concentration in expired air, were found for Pawo100ms, peak moving time average or variance emgdi, and mean integrated emgdi, whatever had been the respiratory impedance. However, with an inspiratory load, Pawo100ms responses systematically had greater increase for a given change in the driving emgdi, implying dependence of the former not only on neural input, but also on configurational factors that determine inspiratory muscle excitation-pressure generation couplings. The reproducibility of emgdi absolute values and changes was satisfactory up to 10 hours, but could not be repeated from one day to the other.

It was concluded that, provided the constancy of the electrical coupling of the recording system to the tissue being studied is ensured, specific emgdi and Pawo100ms values correlate reliably with amount of CO2 during free and loaded breathing. Simultaneous collection of both values during experimentally induced pulmonary disease in calves could, therefore, produce information to help answer questions about the role of cns and inspiratory muscle dysfunction in case of ventilatory failure. Careful interpretation, however, requires additional measurements, such as end-expiratory lung volume, and some familiarity with the underlying physiologic processes that link phrenic nerve discharge to generation of negative pressure at the airway opening.

Summary

Although healthy and diseased bovine respiratory tracts have been intensively studied during the last years, to the authors’ knowledge, there have been no attempts to objectively examine the inspiratory drive from the brain to the nerves and muscles and its transformation in pressure. Such technique would be useful in assessing the possibility of altered ventilatory drive or inspiratory muscle fatigue in the context of an animal with ventilatory failure.

The relation among ventilation, airway opening occlusion pressure generated 100 milliseconds after onset of inspiration (Pawo100ms) and 6 indexes describing diaphragmatic electromyographic activity (emgdi) recorded via implanted fishhooks was evaluated during free and impeded CO2 rebreathing in 6 young bulls. The best significant linear correlations (r > 0.8) with inspiratory center afferent stimulation, as judged by end-tidal CO2 concentration in expired air, were found for Pawo100ms, peak moving time average or variance emgdi, and mean integrated emgdi, whatever had been the respiratory impedance. However, with an inspiratory load, Pawo100ms responses systematically had greater increase for a given change in the driving emgdi, implying dependence of the former not only on neural input, but also on configurational factors that determine inspiratory muscle excitation-pressure generation couplings. The reproducibility of emgdi absolute values and changes was satisfactory up to 10 hours, but could not be repeated from one day to the other.

It was concluded that, provided the constancy of the electrical coupling of the recording system to the tissue being studied is ensured, specific emgdi and Pawo100ms values correlate reliably with amount of CO2 during free and loaded breathing. Simultaneous collection of both values during experimentally induced pulmonary disease in calves could, therefore, produce information to help answer questions about the role of cns and inspiratory muscle dysfunction in case of ventilatory failure. Careful interpretation, however, requires additional measurements, such as end-expiratory lung volume, and some familiarity with the underlying physiologic processes that link phrenic nerve discharge to generation of negative pressure at the airway opening.

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