Tracheobronchitis is commonly observed at autopsy in COVID-19 patients [1, 2], likely in line with a local high expression of angiotensin-converting enzyme 2 receptors (ACE2) [3].

A case report suggested that tracheobronchitis could be detected in the COVID patients through a tracheobronchial uptake of radioactive particles inhaled for lung scintigraphy [4]. These particles tend to deposit and create “hot spots” in the central airways when airway resistance is increased, especially during bronchitis and chronic pulmonary obstructive disease (COPD) [5, 6].

The present study aimed to analyze the rates and associated factors of such signs of tracheobronchitis in the COVID patients referred to ventilation/perfusion lung scintigraphy with shortness of breath, suspected of pulmonary embolism, with comparison to a non-COVID population.

Materials and methods

We report a series of 10 consecutive patients with COVID-19, experiencing shortness of breath and referred to lung scintigraphy for suspected pulmonary embolism during the period of the COVID-19 outbreak (March 25 to May 15, 2020). One patient has been the subject of a previous case report [4]. The diagnosis of COVID-19 was ascertained by positive reverse transcriptase-polymerase chain reaction tests in 7 patients, and by serologic tests in 3 (Lateral Flow Immunoassay, BioSynex®, Illkirch-Graffenstaden, France).

A non-COVID group was constituted of 90 consecutive patients referred to lung scintigraphy on the same CZT camera for a suspected pulmonary embolism, but when viral circulation had become very low (from June 1st to September 1st, 2020). None had any clinical suspicion of COVID-19.

Lung imaging was acquired on a CZT-SPECT/CT system (Veriton®, Spectrum Dynamics Medical), starting with CT image acquisition.

Ventilation images were recorded over a 10-min period, after inhalation of 99mTc-labeled Technegas® during two to three consecutive deep inspirations [6], and perfusion scans were acquired over a 3-min period after injection of approximately 730 MBq of 99mTc-labeled albumin macroaggregates [6]. SPECT images were reconstructed with an OSEM iterative method adapted to the collimator system and displayed through 2.46-mm3 cubic voxels.

The total procedure time was 30 min overall when including the time required for patient handling and disinfection of the camera and materials.

Quantitative data were represented as mean ± SD and compared with ANOVA tests. Qualitative data were expressed as percentages and compared with Fisher exact tests.

Results

The mean age of the COVID patients was 67 ± 16 years, and all but 2 had oxygen supply (Table 1). None had any evident sign of pulmonary embolism on scintigraphy, but a tracheal and/or bronchial uptake was observed on the ventilation scans from 5 patients (Fig. 1, left panel), with uptake being unusually extended on both trachea and bronchi in 3 (numbers 1 to 3).

Table 1 Main characteristics of COVID patients
Fig. 1
figure 1

Illustrative baseline SPECT/CT slices, displayed on a coronal plane passing through the trachea and proximal bronchi, in patients with (left panel) or without (right panel) significant tracheal and/or bronchial Technegas® uptake. The uptake is particularly intense, diffuse, and unusual in patient numbers 1 to 3, presumably corresponding to a severe tracheobronchitis. Age, gender, and delay from symptom onset are given in the initial columns. Lung CT images are displayed with a gray scale, whereas perfusion and ventilation images are displayed separately with gray scales and additionally, through a fusion of ventilation images (gray scale) with perfusion images (color scale)

CT was considered subnormal in one of these 3 presumed tracheobronchitis cases (number 1), and the other 2 only exhibited very limited ground-glass opacities (numbers 2 and 3). In contrast, all other COVID patients had more extensive CT abnormalities extending to both lungs (Fig. 1).

There was no difference between the 3 COVID patients with, and those without, presumed tracheobronchitis regarding age (59 ± 9 years vs. 71 ± 18 years), the delay from symptom onset (16 ± 12 days vs. 19 ± 14 days), male gender (67% vs. 71%), active smoking (33% vs. 43%), or history of COPD (33% vs. 14%). It is of note, however, that RT-PCR was negative for 2 among these 3 COVID patients (67%), whereas for only one among the 7 other patients (14%).

The rate of Technegas® uptake involving both trachea and bronchi was only 3.3% in the non-COVID group (3/90) and, thus, much lower than in the COVID group (30%, P = 0.019) (Table 2).

Table 2 Comparisons of clinical and imaging characteristics between the COVID and non-COVID groups

Besides, in the 3 COVID patients with presumed tracheobronchitis, the tracheal uptake had limited upper extension on the larynx and pharynx (Fig. 2). In contrast, such upper extension was documented in all cases of tracheal uptake in the non-COVID group. This suggests a different mechanism of inadequate Technegas® inhalation for these latter.

Fig. 2
figure 2

Anterior maximum intensity projection (MIP) images obtained from the ventilation scans of the 3 COVID patients with uptake on both trachea and bronchi (numbers 1, 2, and 3), of the 3 non-COVID patients with uptake on both trachea and bronchi (numbers 11, 12, and 13), and of representative examples of non-COVID patients with uptake on trachea (numbers 21, 22, and 23) or bronchi (numbers 31, 32, and 33). A schematic representation of the corresponding uptake areas is additionally displayed in the right column. Note the tracheobronchial uptake of the COVID patients has the particularity of being restricted to proximal bronchi and trachea, without significant extension to the larynx or distal bronchi, thus corresponding to areas with high ACE2 expression [3] and to a presumed tracheobronchitis

COVID patient number 1, who had a presumed tracheobronchitis but subnormal CT, had a second SPECT/CT 1 month later, owing to dyspnea’s recurrence 1 week after discontinuation of anticoagulant treatment (Fig. 3). The latter images demonstrated decreased signs of tracheobronchitis (red arrows), with the advent of pulmonary emboli over the right inferior lobe—i.e., with perfusion defects exceeding ventilation defects and with CT signs of pulmonary infarction and atelectasis (blue arrows). A small mismatch area could be detected at the same site on a reanalysis of the baseline SPECT images from this patient (blue arrow).

Fig. 3
figure 3

SPECT/CT images of patient number 1 recorded at baseline (left panel) and 1 month later (right panel), with the representation of different orientations of lung CT slices, as well as the corresponding perfusion and ventilation slices displayed separately with gray scales and additionally, through a fusion of ventilation images (gray scale) with perfusion images (color scale). See text for additional information. Areas of presumed tracheobronchitis are indicated with red arrows and areas of pulmonary embolism with blue arrows

A withdrawal of signs of tracheobronchitis or pulmonary embolism was documented on additional follow-up scintigraphies from COVID patient numbers 1 and 2. Finally, at the 3–4 months follow-up stage, the 3 COVID patients with presumed tracheobronchitis were no longer, or were only poorly, symptomatic.

Discussion

The signs evocative of a COVID-related tracheobronchitis, presented herein and specifically involving areas with high ACE2 expression [3], are very different from bronchial foci commonly observed in COPD patients [5, 6], as well as in our non-COVID population (Fig. 2). The extension of our presumed cases of tracheobronchitis was remarkable here, tending to explain shortness of breath and the need for oxygen supply and contrasting with limited parenchymal lung abnormalities.

These observations compare well with recent results from an international autopsy series of COVID-19 patients [2]. As many as 76% of these patients had a diffuse tracheobronchitis, and 35% had both an acute and diffuse form, a proportion that is close to the 30% observed herein [2]. In addition, tracheobronchitis was commonly associated with signs of a local viral persistence [2].

Such severe and extended forms of tracheobronchitis have already been documented in patients dying from an influenza A/H1N1 viral infection [7] and also in patients with rheumatoid arthritis and ulcerative colitis, where it was found reversible under corticosteroids [8, 9].

The reason why COVID-19 predominates on the upper instead of the lower respiratory tract of some of our patients is presently unknown, but this predominance does not imply a low severity, as evidenced by the case with subsequent pulmonary embolism.

COVID-19-related pulmonary emboli are known to predominate on small pulmonary arteries [2]. This is likely why they exhibited a particular evolution on our scintigraphies, with a limited sub-segmental onset and a subsequent extension (Fig. 3).

A limitation is that no direct confirmation of tracheobronchitis was obtained on bronchoscopy, due to the known risk of acute exacerbation of the respiratory condition in patients with severe tracheobronchitis [9]. However, a causal link between the tracheobronchial uptake of Technegas® and diseases of the upper respiratory tract has been extensively established [5, 6].

It must also be noted that a few non-COVID patients exhibited a Technegas® uptake involving both trachea and bronchi (3%), and this was likely explained by a different mechanism of inadequate inhalation of Technegas® (i.e., with the tracheal uptake being extended to the larynx (Fig. 2)).

The incidence of such presumed severe tracheobronchitis was 30% herein, but the corresponding 95% confidence interval is very large given the limited sample size, ranging from 11 to 60%. Furthermore, this incidence was observed here in a particular COVID population, mostly including patients with significant symptom aggravation. Thereby, this incidence is presumably different and much lower in more general COVID-19 populations.

Therefore, this observational study suggests that in COVID-19 patients with shortness of breath, a scintigraphy pattern of a presumed tracheobronchitis may constitute the main if not the only sign of respiratory involvement, further identifying a new potential therapeutic target which may require specific treatments.