Respiratory physiology & neurobiology
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Respir Physiol Neurobiol · Mar 2003
Comparative StudyMechanical chest-wall vibration does not relieve air hunger.
Mechanical vibration of the chest wall can reduce dyspnea. It is unclear which sensations of respiratory discomfort are modulated by vibration (work/effort, air hunger, tightness). We performed two experiments to test whether vibration modifies air hunger: Experiment 1-eight adults performed six breath holds and rated their uncomfortable 'urge to breathe.' Vibration was applied separately at four chest-wall and two control sites, using two amplitudes. ⋯ Experiment 2-nine adults were mechanically ventilated (mean 8.73 L/min) at constant hypercapnia (mean 48 mmHg) to produce mild to moderate ratings of air hunger (mean 37% of scale) with minimal respiratory muscle work. Vibration at 2nd or 3rd intercostal spaces during either inspiration or expiration did not change air hunger compared to triceps vibration. These experiments demonstrated that vibration does not relieve air hunger; we postulate that the effect of vibration is specific to the form of dyspnea.
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Respir Physiol Neurobiol · Feb 2003
Modeling of the expiratory flow pattern of spontaneously breathing cats.
A mathematical model was developed describing the entire expiratory flow pattern during spontaneous, tidal breathing in the absence of expiratory muscle activity. It provides estimates for the time constants of the respiratory system (tau RS(model)) and of the decay of continuing inspiratory muscle activity in early expiration (tau mus(model)). ⋯ Fitted peak flow and time to peak tidal expiratory flow were not significantly different from those measured. In conclusion, for spontaneously breathing, anesthetized cats our model provides a close fit of the expiratory flow and parameter estimates were comparable with independently measured values.
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Respir Physiol Neurobiol · Aug 2002
Conventional mechanical ventilation of healthy lungs induced pro-inflammatory cytokine gene transcription.
We investigated the potential inflammatory reaction induced by mechanical ventilation (MV) using 10 ml/kg tidal volume and no positive end-expiratory pressure (PEEP) in control (C, n = 8), spontaneously breathing (SB, n = 12) and mechanically ventilated (MV, n = 12) rabbits with normal lungs. After 6 h (MV and SB groups) or immediately (C group), lungs were removed for measurement of wet-to-dry (W/D) weight ratio and for bronchoalveolar lavage (BAL). Pulmonary mechanics were also studied. ⋯ In MV group, BAL macrophage count was greater (P < 0.05) than in SB one. MV induced an upregulation of MCP-1, TNF-alpha, and IL-1beta gene transcription (mRNAs), without significant elevation of the corresponding protein cytokines in the BAL supernatant, except for MCP-1 (P < 0.05). These data suggest that MV, even using moderate tidal volume, elicits a pro-inflammatory stimulus to the lungs.
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Respir Physiol Neurobiol · Apr 2002
Comparative StudyThe length-force relationship of the human genioglossus in patients with obstructive sleep apnea.
During sleep, patients with obstructive sleep apnea (OSA) have repetitive episodes of upper airway collapse, which are terminated by increased activity of upper airway dilator muscles. The repetitive activation of the genioglossus (GG) may result in muscle remodeling. We hypothesized that OSA patients have an altered length-force relationship, increased force generation and/or decreased force maintenance as compared with control subjects. ⋯ Force maintenance was not significantly different between the two groups. We conclude that in OSA patients relative to normal controls, the length-force relationship of the GG is altered, specifically at longer muscle lengths. We speculate that the GG is remodeled in OSA patients and that this facilitates airway re-opening to terminate obstructive events.