A model of the central and reflex inhibition of inspiration in the cat

An attempt is made to summarize the results obtained in previous work from this and other laboratories on the steady state and transient relationships between the mechanical and neural events in breathing and their precise timing in the breathing cycle at different blood chemical demands for ventilation and at different body temperatures, and to fit these results into a functional and realistic model of the bulbo-pontine inspiratory off-switch mechanisms. The experimentally based requirements for the model are briefly described and listed. After a presentation of the model in qualitative terms its functional properties are considered quantitatively and compared with the performance of the real, biological system. This has been achieved by assuming some simple mathematical approximations for the activities of the introduced physiological parameters and their chemical “drive” dependence. The gaps in our present knowledge are pointed out and some key experiments suggested. The proposed model is consistent with the main conclusions reached in previous work from this laboratory that there are three neural submechanisms which are mainly responsible for the effects of increased CO2 on ventilation: 1) a rise in the inspiratory off-switch threshold, 2) an increased rate of rise of the centrally generated inspiratory activity that projects to the off-switch mechanism (and to the spinal respiratory motoneurons), and 3) the vagal volume feed-back. Of these 1) and 2) are mainly responsible for the increase in tidal volume, whereas the vagal volume feed-back is mainly responsible for the increase in respiratory rate. The comparison between the model behaviour and experimental data suggest that the slight CO2 sensitivity of the pulmonary stretch receptors recently reported on, has to be taken into account. The model studies have suggested the increase in respiratory rate with increased temperature may be due either to an increased rate of rise of inspiratory activity or to a decreased off-switch threshold, or both in combination. The mechanism controlling the expiratory durations are briefly discussed.

[1]  M. Younes,et al.  Control of tidal volume and respiratory frequency in anesthetized cats. , 1973, Journal of applied physiology.

[2]  M. Jukes,et al.  Effects of various respiratory stimuli on the depth and frequency of breathing in man. , 1966, Respiration physiology.

[3]  H T Milhorn,et al.  Transient ventilatory response to hypoxia with and without controlled alveolar PCO2. , 1973, Journal of applied physiology.

[4]  R. Wyman,et al.  The spinal connections of the inspiratory neurones of the ventrolateral nucleus of the cat's tractus solitarius. , 1973, Brain research.

[5]  Lawrence A Leiter,et al.  Effect of body temperature on respiratory frequency in anesthetized cats. , 1973, Journal of applied physiology.

[6]  M. Mustafa,et al.  The effect of CO 2 upon discharge from slowly adapting stretch receptors in the lungs of rabbits. , 1972, Respiration physiology.

[7]  J. Widdicombe,et al.  Effects of hypoxia, hypercapnia and changes in body temperature on the pattern of breathing in cats. , 1974, Respiration physiology.

[8]  F. J. Clark,et al.  On the regulation of depth and rate of breathing , 1972, The Journal of physiology.

[9]  C. Euler,et al.  Control mechanisms determining rate and depth of respiratory movements , 1970 .

[10]  C. Knox,et al.  Characteristics of inflation and deflation reflexes during expiration of the cat. , 1973, Journal of neurophysiology.

[11]  M. I. Cohen Switching of the respiratory phases and evoked phrenic responses produced by rostral pontine electrical stimulation , 1971, The Journal of physiology.

[12]  Schoener Ep,et al.  Effect of hyperthermia and Pa CO2 on the slowly adapting pulmonary stretch receptor. , 1972 .

[13]  C. von Euler,et al.  Transient and steady state effects of CO-2 on mechanisms determining rate and depth of breathing. , 1974, Acta physiologica Scandinavica.

[14]  C. von Euler,et al.  Steady state effects of CO-2 and temperature on the relationship between lung volume and inspiratory duration (Hering-Breuer threshold curve). , 1974, Acta physiologica Scandinavica.

[15]  R. Wyman,et al.  Respiratory neurones of the ventrolateral nucleus of the solitary tract of cat: vagal input, spinal connections and morphological identification. , 1973, Brain research.

[16]  A. J. Berger,et al.  Respiratory recovery from CO 2 breathing in intact and chemodenervated awake dogs. , 1973, Journal of applied physiology.