Abstract:S evere acute respiratory failure is the dominant cause of death in patients with coronavirus disease 2019 (CO-VID-19) (1). The pathophysiology and imaging features of severe COVID-19 pneumonia have been the focus of considerable interest from the outset of the pandemic. In early disease, widespread ground-glass opacification predominates at thoracic CT (2-6) and is supposedly associated with highly compliant lungs and disrupted vasoregulation (7). Vascular dysregulation is believed to be consequence of exagge… Show more
“…These abnormalities could represent unresolved/sequelae of the widespread microangiopathy described in the acute phase of the disease, characterized by occlusion of alveolar capillaries. During COVID-19 pneumonia, mottled defects were present in almost all patients scanned with DECT [ 17 , 18 ].…”
Section: Discussionmentioning
confidence: 99%
“…Their distribution was rated as unilateral/bilateral; central/peripheral. We also searched for the presence of vascular features described in the acute phase of COVID-19 pneumonia, i.e., the âvascular tree-in-budâ pattern and abnormally dilated peripheral vessels [17] . The presence, extent and severity of comorbid conditions that might interfere with CT lung perfusion analysis, i.e., emphysema and interstitial lung disease, was also recorded.…”
Section: Methodsmentioning
confidence: 99%
“…In comparison with autopsy findings in influenza-associated respiratory failure, alveolar capillary microthrombi were found to be 9 times more prevalent in patients with COVID-19 who also exhibited a 2.7 times higher amount of new vessel growth [13] . In-vivo insight into this distal pulmonary angiopathy was reported in patients with mild to severe COVID-19 pneumonia who underwent dual-energy CT angiography [15] , [16] , [17] , [18] , [19] , [20] . In the early clinical phase, increased lung perfusion matching with ground-glass opacities was reported.…”
Background
During COVID-19, the main manifestations of the disease are not only pneumonia but also coagulation disorders. The purpose of this study was to evaluate pulmonary vascular abnormalities 3 months after hospitalization for SARS-CoV-2 pneumonia in patients with persistent respiratory symptoms.
Methods
Among the 320 patients who participated in a systematic follow-up 3 months after hospitalization, 76 patients had residual symptoms justifying a specialized follow-up in the department of pulmonology. Among them, dual-energy CT angiography (DECTA) was obtained in 55 patients.
Findings
The 55 patients had partial (
n
=Â 40; 72.7%) or complete (
n
=Â 15; 27.3%) resolution of COVID-19 lung infiltration. DECTA was normal in 52 patients (52/55; 94.6%) and showed endoluminal filling defects in 3 patients (3/55; 5.4%) at the level of one (
n
=Â 1) and two (
n
=Â 1) segmental arteries of a single lobe and within central and peripheral arteries (
n
=Â 1). DECT lung perfusion was rated as non-interpretable (
n
=Â 2;3.6%), normal (
n
=Â 17; 30.9%) and abnormal (
n
=Â 36; 65.5%), the latter group comprising 32 patients with residual COVID-19 opacities (32/36; 89%) and 4 patients with normal lung parenchyma (4/36; 11%). Perfusion abnormalities consisted of (a) patchy defects (30/36; 83%), (b) PE-type defects (6/36; 16.6%) with (
n
=Â 1) or without proximal thrombosis (
n
=Â 5); and (c) focal areas of hypoperfusion (2/36; 5.5%). Increased perfusion was seen in 15 patients, always matching GGOs, bands and/or vascular tree-in- bud patterns.
Interpretation
DECT depicted proximal arterial thrombosis in 5.4% of patients and perfusion abnormalities suggestive of widespread microangiopathy in 65.5% of patients. Lung microcirculation was abnormal in 4 patients with normal lung parenchyma.
“…These abnormalities could represent unresolved/sequelae of the widespread microangiopathy described in the acute phase of the disease, characterized by occlusion of alveolar capillaries. During COVID-19 pneumonia, mottled defects were present in almost all patients scanned with DECT [ 17 , 18 ].…”
Section: Discussionmentioning
confidence: 99%
“…Their distribution was rated as unilateral/bilateral; central/peripheral. We also searched for the presence of vascular features described in the acute phase of COVID-19 pneumonia, i.e., the âvascular tree-in-budâ pattern and abnormally dilated peripheral vessels [17] . The presence, extent and severity of comorbid conditions that might interfere with CT lung perfusion analysis, i.e., emphysema and interstitial lung disease, was also recorded.…”
Section: Methodsmentioning
confidence: 99%
“…In comparison with autopsy findings in influenza-associated respiratory failure, alveolar capillary microthrombi were found to be 9 times more prevalent in patients with COVID-19 who also exhibited a 2.7 times higher amount of new vessel growth [13] . In-vivo insight into this distal pulmonary angiopathy was reported in patients with mild to severe COVID-19 pneumonia who underwent dual-energy CT angiography [15] , [16] , [17] , [18] , [19] , [20] . In the early clinical phase, increased lung perfusion matching with ground-glass opacities was reported.…”
Background
During COVID-19, the main manifestations of the disease are not only pneumonia but also coagulation disorders. The purpose of this study was to evaluate pulmonary vascular abnormalities 3 months after hospitalization for SARS-CoV-2 pneumonia in patients with persistent respiratory symptoms.
Methods
Among the 320 patients who participated in a systematic follow-up 3 months after hospitalization, 76 patients had residual symptoms justifying a specialized follow-up in the department of pulmonology. Among them, dual-energy CT angiography (DECTA) was obtained in 55 patients.
Findings
The 55 patients had partial (
n
=Â 40; 72.7%) or complete (
n
=Â 15; 27.3%) resolution of COVID-19 lung infiltration. DECTA was normal in 52 patients (52/55; 94.6%) and showed endoluminal filling defects in 3 patients (3/55; 5.4%) at the level of one (
n
=Â 1) and two (
n
=Â 1) segmental arteries of a single lobe and within central and peripheral arteries (
n
=Â 1). DECT lung perfusion was rated as non-interpretable (
n
=Â 2;3.6%), normal (
n
=Â 17; 30.9%) and abnormal (
n
=Â 36; 65.5%), the latter group comprising 32 patients with residual COVID-19 opacities (32/36; 89%) and 4 patients with normal lung parenchyma (4/36; 11%). Perfusion abnormalities consisted of (a) patchy defects (30/36; 83%), (b) PE-type defects (6/36; 16.6%) with (
n
=Â 1) or without proximal thrombosis (
n
=Â 5); and (c) focal areas of hypoperfusion (2/36; 5.5%). Increased perfusion was seen in 15 patients, always matching GGOs, bands and/or vascular tree-in- bud patterns.
Interpretation
DECT depicted proximal arterial thrombosis in 5.4% of patients and perfusion abnormalities suggestive of widespread microangiopathy in 65.5% of patients. Lung microcirculation was abnormal in 4 patients with normal lung parenchyma.
Acute respiratory distress syndrome (ARDS) in patients with Coronavirus disease 19 (COVID-19) is associated with an unusually high incidence of pulmonary embolism (PE) and microthrombotic disease, with evidence for reduced fibrinolysis. We describe seven patients requiring invasive ventilation for COVID-19 ARDS with pulmonary thromboembolic disease, pulmonary hypertension ñ severe right ventricular (RV) dysfunction on echocardiography, who were treated with alteplase as fibrinolytic therapy. All patients were non-smokers, 6 (86%) were male and median age was 56.7 (50-64) years. They had failed approaches including therapeutic anticoagulation, prone ventilation (n=4), inhaled nitric oxide (n=5) and nebulised epoprostenol (n=2). The median duration of mechanical ventilation prior to thrombolysis was 7 (5-11) days. Systemic alteplase was administered to 6 patients (50mg or 90mg bolus over 120 minutes) at 16 (10-22) days after symptom onset. All received therapeutic heparin pre- and post-thrombolysis, without intracranial haemorrhage or other major bleeding. Alteplase improved PaO2/FiO2 (PF) ratio (from 97.0 (86.3-118.6) to 135.6 (100.7-171.4), p=0.03) and ventilatory ratio (from 2.76 (2.09 -3.49) to 2.36 (1.82 ù 3.05), p=0.011) at twenty-four hours. Echocardiographic parameters at 2 (1-3) days (n=6) showed RVSP was 63 (50.3-75) then 57 (49-66) mmHg post-thrombolysis (p=0.26), TAPSE was unchanged (from 18.3 (11.9-24.5) to 20.5 (15.4-24.2) mm, p=0.56) and RV fractional area change (from 15.4 (11.1-35.6) to 31.2 (16.4-33.1) %, p=0.09). At 7 (1-13) days after thrombolysis, using DECT imaging (n=3), average relative peripheral lung enhancement increased from 12.6 to 21.6% (p=0.06). Conclusion: Thrombolysis improved PF ratio and ventilatory ratio at 24h as rescue therapy in patients with RV dysfunction due to COVID-19 ARDS despite maximum therapy, as part of a multimodal approach, and requires further study.
“…4 ) ( Vieillard-Baron et al, 2013 ; Boissier et al, 2013 ; Chiumello and Pesenti, 2013 ). This coupling between the pulmonary vasculature and the right ventricle was particularly important in ARDS induced by more vascular inflammation as experienced globally during the coronavirus pandemic ( Patel et al, 2020 ; Ridge et al, 2020 ; Tavazzi et al, 2019 ; Bleakley et al, 2020 ). Fig.…”
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