Pathophysiology of pulmonary function anomalies in COVID-19 survivors

Altered T_LCO or D_LCO in COVID-19 survivors

The lung transfer (or diffusing) capacity for carbon monoxide (T_LCO or D_LCO; T_LCO being more commonly used in Europe whereas D_LCO is more commonly used in North America) reflects the capacity of carbon monoxide transfer from the environment to the pulmonary capillary blood and represents the most clinically practical standard methodology to assess gas exchange in the lung. In this article we will use the term T_LCO. K_CO, the transfer or diffusion coefficient, is the rate constant for carbon monoxide uptake from alveolar gas and is impacted mostly by the thickness and area of the alveolar capillary membrane, the volume of blood circulating in pulmonary capillaries coupling ventilated alveoli and the concentration and properties of haemoglobin in the alveolar capillaries blood (figure 2). K_CO and V_A are the two main factors that determine T_LCO (figure 2). From a mathematical standpoint, K_CO can be calculated as T_LCO/V_A under BTPS conditions (Body Temperature, ambient Pressure, Saturated with water vapour). It should be noted that K_CO is not a simple ratio, as the relationship between lung volume and carbon monoxide uptake is certainly less than 1:1 [16]. The use of K_CO has recently been recommended instead of T_LCO/V_A, as T_LCO/V_A may be interpreted that T_LCO can be normalised for V_A [17].

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Figure 2

Factors contributing to lung transfer (or diffusing) capacity for carbon monoxide ( T_LCO or D_LCO). See the text for more details and explanations.

Factors contributing to altered T_LCO or D_LCO in COVID-19 survivors

A low T_LCO is not exclusively determined by reduced V_A [18]; residual interstitial anomalies [19–21] and pulmonary vascular anomalies (i.e. abnormal capillary–alveolar units) [22] may play a fundamental role and this could also be the case in COVID-19 survivors (figure 3). This holds true as the interpretation of low T_LCO must consider the complex relationship between V_A, T_LCO and K_CO, and may inopportunely exclude the presence of abnormal gas exchange in the lung (figure 3). To prove this point, we can use data from “severe pneumonia” COVID-19 related patients discussed in this review article to model according to Hughes and Pride [16] what T_LCO and K_CO responses would be expected if V_A was diminished as a consequence of either suboptimal alveolar expansion or due to loss of alveolar units while having a normal expansion in communicating alveoli. We would then observe two trajectories:

• 1) in the first the decline in T_LCO would be largely greater than expected if a decrease in V_A was the unique anomaly, regardless of the mechanism behind the diminished V_A; and

• 2) the second one is that a decrease in V_A due to either of the abovementioned mechanisms would be associated with an augmentation in K_CO, which would be contrary to the diminished K_CO observed in many of the discharged patients with severe COVID-19; therefore, the decrease in K_CO may suggest that loss of alveolar units is not sufficient to determine the observed alteration in T_LCO.

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Figure 3

Algorithm allowing physiologists and clinicians to unravel mechanisms of a decreased T_LCO (or D_LCO). If T_LCO (or D_LCO) is reduced, the next step is to check whether the V_A is preserved or reduced. If  V_A is diminished, the next step is to check whether the V_A/TLC ratio is low (<80%) due to ventilation maldistribution secondary to an obstructive ventilatory defect or is preserved (≥80%) due to restrictive ventilatory defect, associated or not with impaired pulmonary gas exchange. If  V_A is preserved, please follow the arrows in the algorithm to get some explanations and to see whether the K_CO is reduced and if there are pulmonary gas exchange anomalies associated with this. “Coronavirus diseases” appears in red, as potential mechanisms explaining the T_LCO (or D_LCO) anomalies observed in coronavirus diseases such as COVID-19 (caused by SARS-CoV-2), severe acute respiratory syndrome (SARS; caused by SARS-CoV-1) and Middle East respiratory syndrome (MERS; caused by MERS-CoV) are yet not fully understood. See the text for more details and explanations. IPF: idiopathic pulmonary fibrosis; ILD: interstitial lung disease.

Altered T_LCO or D_LCO in COVID-19 survivors: a dangerous interplay between V_A and K_CO

While the anomalies in T_LCO observed in patients affected by “severe pneumonia” COVID-19 may be partially explained by diminished V_A, the decrease in K_CO measured together with the diminished V_A also implies that abnormal gas exchange in the lung occurs (figure 3). Now, the question arises as whether this is due to anomaly of the alveolar–capillary barrier or to abnormal pulmonary blood volume. Unfortunately, this cannot be easily determined based on data presented in the studies discussed in this review article. Lung fibrosis associated with acute respiratory distress syndrome (ARDS) in COVID-19 patients would likely alter alveolar-capillary units, giving rise to loss of alveolar units and altered gas exchange in the lung. The consequence would be a decrease in both V_A and K_CO (for that diminished V_A). There is mounting evidence for impaired pulmonary haemodynamics in COVID-19 patients [10], including vascular pruning, decreased pulmonary blood volume and abnormal pulmonary blood volume distribution as measured via high-resolution CT [23]. Figure 3 shows that a decrease in K_CO may develop in the context of alveolar-capillary damage, microvascular pathology, or anaemia. Factors responsible for a reduced V_A are numerous and may include decreased alveolar expansion, alveolar damage or loss, or inspired gas maldistribution in the context of an obstructive ventilatory defect. Therefore, when K_CO turns normal, in the presence of a low T_LCO, it is associated with reduced V_A, thus indicating a restrictive ventilatory defect (see below and figure 3). This is because only the functional alveolar units have been sampled thereby providing an erroneous picture toward more preserved areas of the lungs (figure 3). It should be noted that if V_A is preserved, there is no restrictive ventilatory defect because V_A is always a fraction of TLC, i.e. if V_A is preserved so is TLC (figure 3). To conclude and for the sake of clarity: the same T_LCO may occur with various combinations of V_A and K_CO, each suggesting different abnormal respiratory conditions. It is difficult to interpret which one plays the predominant role because both diminished V_A and K_CO concur to the pathogenesis of altered lung diffusion capacity. T_LCO gives a global evaluation of gas exchange in the lung, while the alveolar-capillary membrane diffusing capacity only depends on molecular diffusion of the membranes. We would thus need more refined techniques capable of measuring more specifically the alveolar-capillary membrane. These could include measurement of T_LCO with inhaled gas mixtures containing two or three different oxygen fractions, or combined T_LCO and transfer (or diffusing) capacity measurements of the lung for nitric oxide (T_LNO or D_LNO). Such sophisticated analysis could shed light on the precise mechanisms of reduced T_LCO in COVID-19 survivors and may allow distinguishing between interstitial and pulmonary capillary anomalies. On this topic, an Italian study by Barisione and Brusasco [24] in 94 patients recovering from mild-to-severe COVID-19 found a greater alteration of T_LNO than T_LCO, suggesting loss of alveolar units with alveolar membrane damage rather than loss of lung capillary bed (see “Future directions, perspectives and conclusions” section).

Restrictive ventilatory defect in COVID-19 survivors

The second most common abnormality in COVID-19 survivors is a restrictive ventilatory defect. A restrictive ventilatory defect is defined by a pathologically decreased TLC. If caused by parenchymal lung disease, restrictive ventilatory defect is accompanied by reduced gas transfer, which may be marked clinically by desaturation during exercise or even at rest (see the above paragraph).

Factors contributing to restrictive ventilatory defect in COVID-19 survivors

TLC is the greatest volume of gas in the lungs achieved after maximal voluntary inspiration. It depends on the static balance between the outward forces generated by inspiratory muscles during a maximal inspiratory effort and the inward elastic forces of the chest wall and lung. It is the lung that normally contributes the most to the elastic recoil forces of the respiratory system at TLC. At TLC, these two sets of forces are equal and opposite in sign. The decrease in TLC usually reflects the reduced lung volumes either because of an alteration in lung parenchyma or because of a disease of the pleura, chest wall, or neuromuscular apparatus that may respectively affect the compliance of the lung or the compliance of the chest wall or the pressure-generating capacity of the inspiratory muscles. Interstitial lung anomalies, such as those observed in some forms of COVID-19 [25], may result in a restrictive ventilatory defect (figures 1 and 3).

At the time of hospital discharge

In the study by Fumagalli et al. [26], 13 patients with COVID-19 pneumonia were enrolled and the authors found that at the time of clinical recovery, 10 out of 13 patients presented with a restrictive pattern measured by spirometry: forced expiratory volume in the first second (FEV₁) and forced vital capacity (FVC) were lower than lower limit of normality values, while FEV₁/FVC was higher compared with the upper limit of normality values. These results obtained in a very small sample size should be taken with caution as measurement of TLC, preferably with plethysmography, was not included and the diagnosis of restrictive pattern was made exclusively on the reduced FVC, which is questionable and not acceptable [27]. In addition, T_LCO measurement was not employed; this would have permitted a better understanding of the origin and the quality of pulmonary gas exchange damage.

In the study by Mo et al. [20], 110 patients with COVID-19 infection were enrolled, which included 24 cases of mild illness, 67 cases of pneumonia and 19 cases of severe pneumonia. Spirometry, plethysmography and T_LCO tests were performed on the day of or 1 day before hospital discharge. The authors found that 47% of their patients had anomalies in T_LCO, 25% in TLC, 14% in FEV₁, 9% in FVC, 4.5% in the FEV₁/FVC ratio and 7% in small airway function. The most interesting observation was the significant difference in impaired T_LCO among the different groups of severity, which accounted for 30% in mild illness, 42% in pneumonia and 84% in severe pneumonia, respectively (p<0.05). This trend of the gradual decrease in level of T_LCO among patients was identical with the varying degree of severity. Of note, in 50% of the T_LCO-impaired patients, K_CO was still within the normal range, which might indicate that the T_LCO decrease was more than the K_CO in recovered subjects. In addition, the value of TLC as % of predicted in severe pneumonia cases was much less than that of pneumonia or mild illness, suggesting higher impairment of lung volume in severe cases. No significant difference among the discharged survivors with different severity with regards to other ventilatory defects (e.g. reduced FEV₁/FVC) was observed.

These two studies, strongly suggest that respiratory function needs to be carefully investigated in COVID-19 patients, as was already done for other atypical pneumonias such as severe influenza A (H1N1) pneumonia [28]. This is because the lung is the most affected organ in COVID-19 and previous other atypical pneumonias, with anomalies that include diffuse alveolar epithelium destruction, capillary damage/bleeding, hyaline membrane formation, alveolar septal fibrous proliferation, and pulmonary consolidation.

In discharged patients

In the same study by Fumagalli et al. [26], FVC was still lower than the lower limit of normality after 6 weeks from hospital discharge. Again, these results obtained in a very small sample size should be taken with caution as measurement of TLC was not included and the diagnosis of restrictive pattern was made exclusively on the reduced FVC, which is questionable and not acceptable [27]. Another study by Huang et al. [29] performed respiratory function testing in 57 COVID-19 patients after 30 days following hospital discharge and found anomalies in 75% of them; 10%, 9%, 44%, 12% and 53% of enrolled patients had FVC, FEV₁, FEV₁/FVC ratio, TLC, and T_LCO values <80% of predicted values, respectively, whereas 49% and 23% of patients presented with maximum static inspiratory and expiratory pressure (P_Imax and P_Emax, respectively) values <80% of the corresponding predicted values. Compared with non-severe cases (n=40), severe patients (n=17) showed higher incidence of T_LCO impairment (76% versus 43%, p=0.019), and significantly lower percentage of predicted TLC. Of note, only 11% of patients showed obstructive and 12% restrictive ventilatory defects [29]. What is also striking, yet surprising, is that a small percentage of patients with no residual imaging abnormalities presented with a slight decrease in T_LCO. Similar to this study, Frija-Masson et al. [30] observed abnormal lung function in more than 50% of COVID-19 patients after 30 days from hospital discharge. One third of the abovementioned patients had decreased T_LCO values indicating that these patients have lung vascular damage, which coincides with the data from Huang et al. [29].

By constrast, Rogliani et al. [31] have recently pointed out that hospitalised patients with mild-to-moderate forms of COVID-19 are not at risk of developing pulmonary fibrosis. In their study, patients were enrolled within 2 months from hospital discharge and the authors found that FEV₁ and FVC, both expressed as % predicted, were in the normal range. Again, these results should be taken with caution as neither measurement of TLC nor of T_LCO was included in the study.

Several studies have explored pulmonary function in COVID-19 survivors at 3 months [21, 32–35] and 4 months [36–38] after hospital discharge. Most of these studies showed alteration in T_LCO (in more than 50% of patients), in TLC (in more than 10% of patients), and in pressure-generating capacity of respiratory muscles (in less than 40–50% of patients), but to a much lesser extent alterations in the airway functions (in less than 10% of patients). However, the proportion of altered lung function may be lower in studies that included patients with less severe initial disease [39, 40]. Taken together, these studies strongly converged to the conclusion that the worse the lung involvement during SARS-CoV-2 infection (in those patients who developed ARDS or those who required invasive mechanical ventilation) the worse the impairment in pulmonary function after 3–6 months, especially in terms of T_LCO, and the lower the likelihood to normalise pulmonary function over time. Accordingly, respiratory rehabilitation and gradual physical activity immediately after hospital discharge should be encouraged as it can minimise impairment or improve respiratory function such as TLC and T_LCO, quality of life and anxiety in these fragile patients [41].

In conclusion, several mechanisms, sequential or not, may occur and explain the damages induced by SARS-CoV-2 infections of the lungs. They include the microvascular damage with interstitial thickening with clear lungs on radiology examinations along with a severe hypoxaemia [42, 43], the development of alveolar injury inducing a gradual loss of the alveolar spaces [43], and last but not least the diminished V_A that may be explained by changes in mechanical properties of the lungs and the chest wall and by dysfunction of the respiratory muscles after critical illness. These anomalies can be temporary or responsible for a potential long-lasting pulmonary parenchymal dysfunction post-COVID-19 [44].