Mechanisms of gas transfer impairment utilizing nitric oxide following severe COVID-19 pneumonitis.

Reduced carbon monoxide diffusing capacity (DLCO ) is common after recovery from severe COVID-19 pneumonitis. The extent to which this relates to alveolar membrane dysfunction as opposed to vascular injury is uncertain. Simultaneous measurement of nitric oxide diffusing capacity (DLNO ) and DLCO can partition gas diffusion into its two components: alveolar-capillary membrane conductance (DmCO ) and capillary blood volume (VC ). We sought to evaluate DmCO and VC in the early and later recovery periods after severe COVID-19. Patients attended for post-COVID-19 clinical review and lung function testing including DLNO /DLCO . Repeat testing occurred when indicated and comparisons made using t-tests. Forty-nine (eight female) subjects (mean ± SD age: 58 ± 13, BMI: 34 ± 8) who had severe COVID-19 pneumonitis, WHO severity classification of 6 ± 1, and prolonged (21 ± 22 days) hospital stay, were assessed 2 months (61 ± 35 days) post discharge. DLCO adj (z-score -1.70 ± 1.49, 25/49 < lower limit of normal [LLN]) and total lung capacity (z-score -1.71 ± 1.30) were both reduced. DmCO and VC and were reduced to a similar extent (z-score -1.19 ± 1.05 and -1.41 ± 1.20, p = 0.4). Seventeen (one female) patients returned for repeat testing 4 months (122 ± 61 days) post discharge. In this subgroup with more impaired lung function, DLCO adj improved but remained below LLN (z-score -3.15 ± 0.83 vs. -2.39 ± 0.86, p = 0.01), 5/17 improved to >LNN. DmCO improved (z-score -2.05 ± 0.89 vs. -1.41 ± 0.78, p = 0.01) but VC was unchanged (z-score -2.51 ± 0.55 vs. -2.29 ± 0.59, p = 0.16). Alveolar membrane conductance is abnormal in the earlier recovery phase following severe COVID-19 but significantly improves. In contrast, reduced VC persists. These data raise the possibility that persisting effects of acute vascular injury may contribute to gas diffusion impairment long after severe COVID-19 pneumonitis.

Right heart function during simulated altitude in patients with pulmonary arterial hypertension.

OBJECTIVE: Patients with pulmonary arterial hypertension (PAH) are often recommended supplemental oxygen for altitude travel due to the possible deleterious effects of hypoxia on pulmonary haemodynamics and right heart function. This includes commercial aircraft travel; however, the direct effects and potential risks are unknown. METHODS: Doppler echocardiography and gas exchange measures were investigated in group 1 patients with PAH and healthy patients at rest breathing room air and while breathing 15.1% oxygen, at rest for 20 min and during mild exertion. RESULTS: The 14 patients with PAH studied were clinically stable on PAH-specific therapy, with functional class II (n=11) and III (n=3) symptoms when tested. Measures of right ventricular size and function were significantly different in the PAH group at baseline as compared to 7 healthy patients (p<0.04). There was no evidence of progressive right ventricular deterioration during hypoxia at rest or under exertion. Pulmonary arterial systolic pressure (PASP) increased in both groups during hypoxia (p<0.01). PASP in hypoxia correlated strongly with baseline PASP (p<0.01). Pressure of arterial oxygen correlated with PASP in hypoxia (p<0.03) but not at baseline, with three patients with PAH experiencing significant desaturation. The duration and extent of hypoxia in this study was tolerated well despite a mild increase in symptoms of breathlessness (p<0.01). CONCLUSIONS: Non-invasive measures of right heart function in group 1 patients with PAH on vasodilator treatment demonstrated a predictable rise in PASP during short-term simulated hypoxia that was not associated with a deterioration in right heart function.

The impact of severe lung disease on evidential breath analysis collection.

BACKGROUND: It is a legal requirement to supply a breath analysis sample when requested by Police at roadside checkpoints. The current device requires a 1L sample at 8L·min(-1). Court disputes commonly attribute respiratory disease for failure to produce a sample. OBJECTIVE: To determine whether respiratory disease aetiology and/or severity precludes an adequate breath sample using a modern evidential breath analyser. METHODS: Subjects performed breath analysis following standard Police procedure. Three efforts within 15min were allowed and any reasons for failure recorded. RESULTS: 24 subjects with interstitial lung disease (ILD) and 26 subjects with chronic obstructive pulmonary disease (COPD) were studied and met minimum respiratory function criteria as per device specifications. 18 ILD subjects (75%) and 24 COPD subjects (92%) were able to provide a sample. All subjects with a vital capacity below 1.5L were unable to provide a sample. DISCUSSION: In the balance of probabilities most patients with lung disease are able to supply an evidential breath sample. The exception is a very severe disease, particularly in volume limited patients.

Abnormal ventilatory control in Parkinson's disease--further evidence for non-motor dysfunction.

There has been increasing recognition of pre-motor manifestations of Parkinson's disease (PD) resulting from early brainstem involvement. We sought to determine whether ventilatory control is abnormal. Patients with PD without respiratory disease were recruited. Spirometry, lung volumes, diffusing capacity and respiratory muscle strength were assessed. Occlusion pressure and ventilation were measured with increasing CO(2). Arterial blood gases were taken at rest and following 20 min exposure to 15% O(2). A linear correlation assessed associations between respiratory function and indices of PD severity. 19 subjects (17 males) with mild-moderate PD were studied (mean (SD) age 66 (8) years). Respiratory flows and volumes were normal in 16/19. Maximum inspiratory and expiratory pressures were below LLN in 13/19 and 15/19 respectively. 7/15 had a reduced ventilatory response to hypercapnia and 11/15 had an abnormal occlusion pressure. There was no correlation between impairment of ventilatory response and reduction in respiratory muscle strength. Response to mild hypoxia was normal and there were no associations between disease severity and respiratory function. Our findings suggest that patients with mild-moderate PD have abnormal ventilatory control despite normal lung volumes and flows.