The respiratory center--the regulator of the respiratory system

The authors consider the respiratory centre to be the regulator of the respiratory system and to consist of 3 main functional blocks: chemoregulator, respiratory rhythm autogenerator and mechanoregulator, functions of which are provided by the neurons of medulla oblongata. The main aim of chemoregulator block is to maintain the level of ventilation volume speed, which is necessary to compensate the difference between the signals of setting and the firing from the chemoreceptors. The main aim of mechanoregulator block is to provide the functioning of the regulation loop of the respiratory muscles comparing the signals which come from the respiratory autogenerator, and the firing of the mechanoreceptors. The generator unit of the respiratory centre is a set of rhythm-forming associations, the system of 4 neurons (early and late inspiratory and expiratory) are typical among them. The neurons are connected by recurrent inhibitory bonds: the neuron of each rhythm-forming group, successively becoming excited, inhibits the two preceding neurons in the cycle; for all this the neuron of the successive group is released from inhibition and in such a way the rhythmogenesis occurs. The respiratory centre forms a common unit for chemo- and mechanoreceptor loops, through which the circuits of feedback for both loops are connected, providing the regulation of breathing.     

Spectral analysis of respiratory parameters in defensive respiratory reflexes

A detailed analysis of respiratory signals in normal breathing and defensive respiratory reflexes was performed to obtain maximum information that can be used for modelling of respiratory processes. Physiological interpretation of the problem is difficult and requires further measurements to achieve convincing conclusions. We suggest therefore that the search for appropriate methodological backgrounds should contribute to further clarification of the problems concerned with reciprocal linkage of the respiratory signals. Appropriate attention must be paid to investigations aimed at explaining the regulatory mechanisms of breathing.     

Selective infection of lower respiratory tract by respiratory viruses in children with recurrent respiratory tract infections.

Thirty preschool children presenting with recurrent respiratory infections and their unaffected siblings were observed prospectively for a year. The index children experienced more episodes of acute respiratory infection than their siblings. Respiratory viruses were the major cause of respiratory infections. The index children had lower respiratory tract disease, predominantly wheeze, during 34% of proved respiratory virus infections compared with 11% of such infections experienced by the control children (p less than 0.02). Atopic children had an increased tendency to wheeze that did not reach significance, but atopy was not associated with increased susceptibility to respiratory infections.     

Effect of different ways of respiratory support on the parameters of respiratory

We investigated the effect of three types of respiratory support on respiratory parameters in conscious healthy humans. For each type of respiratory support set specific changes in the pattern of volume and temporal parameters. One response to all types of respiratory support was hyperventilating, although varying degrees, and as a consequence, hypocapnia. These changes are not related to the metabolic needs and probably are the result of the interaction mechanisms of automatic and voluntary regulation of breathing movements.     

Active learning of respiratory physiology improves performance on respiratory physiology examinations

Active involvement in the learning process has been suggested to enhance creative thinking, judgement, interpretation, and problem-solving skills. Therefore, educators are encouraged to create an active-learning environment by incorporating active-learning strategies into the class. However, there is very little documentation of the effectiveness of active-learning strategies. Furthermore, faculty are often reluctant to incorporate new strategies without documentation of the effectiveness of these strategies. To address this concern, we compared the performance of two individual classes on an identical respiratory physiology examination. One class was taught respiratory physiology using active-learning strategies. The other class was taught respiratory physiology using the traditional lecture format. The results document that students who learned using active-learning strategies did significantly better (P < 0.05) on the respiratory physiology examination than students who learned by the traditional lecture format (61 +/- 2.2 vs. 86 +/- 1.0). Thus, by actively involving students in the learning process, academic performance is enhanced.     

The development of the respiratory chain of Saccharomyces carlsbergensis during respiratory adaptation

1. Subcellular fractionation of sphaeroplasts produced at different stages during the first 4h of respiratory adaptation of anaerobically grown glucose-de-repressed Saccharomyces carlsbergensis gave mitochondrial fractions that contained all the detectable c- and a-type cytochromes. 2. The rates of cytochrome formation were studied; individual cytochromes were produced at different rates so as to give respiratory chains having widely differing cytochrome ratios. A CO-reacting haemoprotein other than cytochrome a(3) also increased throughout 8h of respiratory adaptation. 3. Even after short periods of aeration, organisms contained mitochondria in which cytochrome-cytochrome interactions and the reaction of cytochrome a(3) with O(2) proceeded at rates almost as fast as in organelles from aerobically grown cells. 4. The technique of flow-flash photolysis enabled kinetic resolution of the reoxidation of cytochromes a(3) and a to be achieved and their individual contributions to extinction changes in the Soret region were assessed. The ratio cytochrome a(3)/cytochrome a increased over the early stages of adaptation.     

Viscoplasticity of respiratory tissues

Low-frequency mechanical behavior of various respiratory tissues shows certain similarities. In this study we test the hypothesis that rate-independent plastic processes along with rate-dependent viscoelastic processes are responsible. We considered oscillatory responses of several respiratory tissues measured over prescribed ranges of frequency (up to 6 Hz) and amplitude of forcing. These included the excised cat lung, the human chest wall in vivo, and two components of the chest wall: the excised dog rib cage and the excised rabbit abdominal viscera; some data were previously reported and some are new. We analyzed these data using the viscoplastic model of Hildebrandt (J. Appl. Physiol. 28: 365-372, 1970). It consists of three compartments: a plastoelastic compartment mechanically in parallel with a viscoelastic compartment, both in series with a lumped inertia. We fitted oscillatory data of the above respiratory tissues to the model by a least-squares technique. The fit was qualitatively consistent with the observations and exhibited moderately good to very good quantitative correspondence. As an independent verification of this approach, we obtained the stress relaxation after a step-volume change. Based on the oscillatory response of cat lungs, the calculated stress relaxation function was found to be generally consistent with corresponding observations. This study indicates that both plasticity and viscoelasticity appear to be important determinants of mechanical behavior of respiratory tissues at low frequencies and that inertial effects are negligible.     

Immunoprophylaxis of respiratory infections

Anti-infective antibody-based immunotherapy has gained renewed interest since the crisis of antibiotic resistance and because there is no therapy against various viral infections. The immunoprophylaxis of respiratory infections aims to utilize the ability of local antibodies to neutralize inhaled micro-organisms and their cytopathic products. Immunoglobulins for intravenous use (i.v.i.g.) have a wide spectrum of specificities. Hyperimmune i.v.i.g. containing high titers of specific antibodies have demonstrated efficacy in clinical trials, notably against the respiratory syncytial virus. Monoclonal antibodies have the advantage to be homogenous and specific for one selected epitope and several studies have demonstrated their efficacy to neutralize several infectious agents. Moreover, antibodies can be administered topically and are effective at lower doses than those needed for systemic administration. The mechanism of action could be the agglutination of bacteria or viruses at the epithelial surfaces of the respiratory tract inhibiting the early steps of the infectious process. Thanks to new technologies of humanized monoclonal antibodies, immunotherapy offers real promising perspectives for prophylactic and therapeutic therapies against a variety of current or emerging infectious diseases.     

Mechanoreceptor system of the respiratory center and its contribution to respiratory control

The mechanoreceptor system of the respiratory center (RC) includes airway mechanoreceptors together with their conducting pathways and bulbar neuronal structures conveying impulses from mechanoreceptors to the RCV.A. A. Bogomolets Institute of Physiology, Ukrainian Academy of Sciences, Kiev. Translated from Neirofiziologiya, Vol. 24, No. 4, pp. 351–368, May–June, 1992.     

Effect of withdrawal of respiratory CO2 oscillations on respiratory control at rest

We examined the effect of sudden withdrawal of respiratory oscillations of arterial PCO2 (CO2 oscillations) at resting metabolic rate on the control of respiration in 11 anesthetized paralyzed vagotomized dogs in normoxic normocapnia. A double-lumen endotracheal tube was inserted so that the left and right lungs were ventilated independently. By alternately ventilating each lung, we could completely abolish CO2 oscillations without affecting the mean blood gas levels (withdrawal of CO2 oscillations). The CO2 oscillation was calculated from arterial pH oscillation measured by a rapidly responding intra-arterial pH electrode. Respiratory center output was monitored by use of a moving time average of the phrenic neurogram. A 3-min period of withdrawal of CO2 oscillations was bracketed by two control periods (simultaneous ventilation of lungs for 3 min) to avoid the confounding effect of the baseline drift in the respiratory center output. The amplitude of the CO2 oscillations in the control was 2.33 +/- 0.89 (SD) Torr. When the difference in the mean level of arterial PCO2 between the control and withdrawal of CO2 oscillations was minimized (-0.09 +/- 0.54 Torr; P greater than 0.25), we found negligible change in the minute phrenic activity during withdrawal of CO2 oscillations (-0.02 +/- 6.11% of the control, P greater than 0.98, n = 49; 99% confidence interval -2.36 to 2.32%). Thus we conclude that the maintenance of normal respiration at rest is not critically dependent on a phasic afferent input to the respiratory center arising from respiratory CO2 oscillations.     

呼吸道病毒和呼吸道、肠道菌群的相互作用

随着新技术的应用,人们对人体不同部位的微生态系统有了进一步的认识,其中的微生物部分不仅指细菌还包括病毒。病毒的存在可以影响呼吸道和肠道菌群变化,同样呼吸道和肠道菌群状态也影响着病毒对人体的入侵程度。本研究就呼吸道和肠道菌群与呼吸道病毒相互作用关系的研究进展作一综述。