COVID-19-associated pulmonary embolism: Difference between revisions

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'''Editor-In-Chief:''' [[User:C Michael Gibson|C. Michael Gibson, M.S., M.D.]] [[Mailto:charlesmichaelgibson@gmail.com|[1]]]
'''Editor-In-Chief:''' [[User:C Michael Gibson|C. Michael Gibson, M.S., M.D.]] <nowiki>[[Mailto:charlesmichaelgibson@gmail.com|[1]]</nowiki>


==Overview==
==Overview==
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== Classification ==
== Classification ==
<br />
 
=== Acute Pulmonary Embolism ===
 
* Pathologically an embolus is said to be acute when it is situated centrally within in the vascular lumen, or in other case it causes the occlusion of vessel. It can cause immediate occurence of symptoms.
 
=== Chronic Pulmonary Embolism ===
 
* An embolus is said to be chronic , if it is eccentric and lies in lies with the vessel wall.
* It occouleds the lumen of vessel wall by more than 50 %.
* There is also evidence of recanalization within the thrombus.
* Chronic thromboembolism can cause pulmonary hypertension especially when there is >3 months of effective anticoagulation therapy and one of the following criteria.  a) Mean pulmonary arterial pressure greater than or equal to 25 mmHg  b) Pulmonary arterial wedge pressure less than or equal to 15 mmgHg  c) Abnormal lung V/Q scan or imaging findings suggestive of chronic pulmonary embolism on CTPA, CMR, CPA<br />
== Pathophysiology ==
== Pathophysiology ==
* As data on COVID-19 has been incomplete and evolving, the [[pathogenesis]] of pulmonary embolism has not yet been completely understood. Various contributors to the pathogenesis of pulmonary embolism in these patients are listed in the table below:
* As data on COVID-19 has been incomplete and evolving, the [[pathogenesis]] of pulmonary embolism has not yet been completely understood. Various contributors to the pathogenesis of pulmonary embolism in these patients are listed in the table below:
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!style="background: #4479BA; width: 200px;" | {{fontcolor|#FFF|Description of the underlying mechanism}}
!style="background: #4479BA; width: 200px;" | {{fontcolor|#FFF|Description of the underlying mechanism}}
|-
|-
|style="padding: 5px 5px; background: #DCDCDC; font-weight: bold" |[[Endothelial cells|Endothelial cells dysfunction]]<ref name="Teuwen Geldhof Pasut Carmeliet p.">{{cite journal | last=Teuwen | first=Laure-Anne | last2=Geldhof | first2=Vincent | last3=Pasut | first3=Alessandra | last4=Carmeliet | first4=Peter | title=COVID-19: the vasculature unleashed | journal=Nature Reviews Immunology | publisher=Springer Science and Business Media LLC | date=2020-05-21 | issn=1474-1733 | doi=10.1038/s41577-020-0343-0 | page=}}</ref>
|style="padding: 5px 5px; background: #DCDCDC; font-weight: bold" |[[Endothelial cells|Endothelial cells dysfunction]]
|
|
*It has been proposed that [[endothelial cells]] contribute towards the initiation and propagation of [[ARDS]] by changing the vascular barrier permeability, increasing the chance of procoagulative state that leads to endotheliitis and infiltration of inflammatory cells in the [[Pulmonary vasculature|pulmonary vasculature.]]
*It has been proposed that [[endothelial cells]] contribute towards the initiation and propagation of [[ARDS]] by changing the vascular barrier permeability, increasing the chance of procoagulative state that leads to endotheliitis and infiltration of inflammatory cells in the [[Pulmonary vasculature|pulmonary vasculature.]]
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|Most hospitalized critically ill immobile  [[COVID-19]] patients are prone to stasis of blood flow leading to another contributor towards the [[pathogenesis]] of [[pulmonary embolism]].
|Most hospitalized critically ill immobile  [[COVID-19]] patients are prone to stasis of blood flow leading to another contributor towards the [[pathogenesis]] of [[pulmonary embolism]].
|-
|-
|style="padding: 5px 5px; background: #DCDCDC; font-weight: bold" |[[Hypercoagulable state]]<ref name="Panigada Bottino Tagliabue Grasselli p.">{{cite journal | last=Panigada | first=Mauro | last2=Bottino | first2=Nicola | last3=Tagliabue | first3=Paola | last4=Grasselli | first4=Giacomo | last5=Novembrino | first5=Cristina | last6=Chantarangkul | first6=Veena | last7=Pesenti | first7=Antonio | last8=Peyvandi | first8=Fora | last9=Tripodi | first9=Armando | title=Hypercoagulability of COVID‐19 patients in Intensive Care Unit. A Report of Thromboelastography Findings and other Parameters of Hemostasis | journal=Journal of Thrombosis and Haemostasis | publisher=Wiley | date=2020-04-17 | issn=1538-7933 | doi=10.1111/jth.14850 | page=}}</ref>
|style="padding: 5px 5px; background: #DCDCDC; font-weight: bold" |[[Hypercoagulable state]]
|
|
Various clinical studies have reported different [[prothrombotic factors]] in patients who are critically ill and are hospitalized due to [[COVID-19|COVID-19.]] These studies report various key lab factors that play an important role in the pathogenesis of pulmonary embolism.
Various clinical studies have reported different [[prothrombotic factors]] in patients who are critically ill and are hospitalized due to [[COVID-19|COVID-19.]] These studies report various key lab factors that play an important role in the pathogenesis of pulmonary embolism.
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*[[Pulmonary embolism]] can present with no symptoms to [[shock]] and even [[Sudden cardiac death|sudden cardiac arrest]].
*[[Pulmonary embolism]] can present with no symptoms to [[shock]] and even [[Sudden cardiac death|sudden cardiac arrest]].
* The most common symptoms that were observed in Prospective Investigation of Pulmonary Embolism Diagnosis II (PIOPED II) trial include:<ref name="Stein Beemath Matta Weg 2007 pp. 871–879">{{cite journal | last=Stein | first=Paul D. | last2=Beemath | first2=Afzal | last3=Matta | first3=Fadi | last4=Weg | first4=John G. | last5=Yusen | first5=Roger D. | last6=Hales | first6=Charles A. | last7=Hull | first7=Russell D. | last8=Leeper | first8=Kenneth V. | last9=Sostman | first9=H. Dirk | last10=Tapson | first10=Victor F. | last11=Buckley | first11=John D. | last12=Gottschalk | first12=Alexander | last13=Goodman | first13=Lawrence R. | last14=Wakefied | first14=Thomas W. | last15=Woodard | first15=Pamela K. | title=Clinical Characteristics of Patients with Acute Pulmonary Embolism: Data from PIOPED II | journal=The American Journal of Medicine | publisher=Elsevier BV | volume=120 | issue=10 | year=2007 | issn=0002-9343 | doi=10.1016/j.amjmed.2007.03.024 | pages=871–879}}</ref>
* The most common symptoms that were observed in Prospective Investigation of Pulmonary Embolism Diagnosis II (PIOPED II) trial include:  
**[[Dyspnea]] that is sudden in onset at rest or exertion (73%)
**[[Dyspnea]] that is sudden in onset at rest or exertion (73%)
**[[Pleuritic pain]] (44%)
**[[Pleuritic pain]] (44%)
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=====Laboratory findings=====
=====Laboratory findings=====
Lab findings of different case studies of patients having pulmonary embolism due to COVID-19 are given as <ref name="Bikdeli Madhavan Jimenez Chuich 2020 pp. 2950–29732">{{cite journal | last=Bikdeli | first=Behnood | last2=Madhavan | first2=Mahesh V. | last3=Jimenez | first3=David | last4=Chuich | first4=Taylor | last5=Dreyfus | first5=Isaac | last6=Driggin | first6=Elissa | last7=Nigoghossian | first7=Caroline Der | last8=Ageno | first8=Walter | last9=Madjid | first9=Mohammad | last10=Guo | first10=Yutao | last11=Tang | first11=Liang V. | last12=Hu | first12=Yu | last13=Giri | first13=Jay | last14=Cushman | first14=Mary | last15=Quéré | first15=Isabelle | last16=Dimakakos | first16=Evangelos P. | last17=Gibson | first17=C. Michael | last18=Lippi | first18=Giuseppe | last19=Favaloro | first19=Emmanuel J. | last20=Fareed | first20=Jawed | last21=Caprini | first21=Joseph A. | last22=Tafur | first22=Alfonso J. | last23=Burton | first23=John R. | last24=Francese | first24=Dominic P. | last25=Wang | first25=Elizabeth Y. | last26=Falanga | first26=Anna | last27=McLintock | first27=Claire | last28=Hunt | first28=Beverley J. | last29=Spyropoulos | first29=Alex C. | last30=Barnes | first30=Geoffrey D. | last31=Eikelboom | first31=John W. | last32=Weinberg | first32=Ido | last33=Schulman | first33=Sam | last34=Carrier | first34=Marc | last35=Piazza | first35=Gregory | last36=Beckman | first36=Joshua A. | last37=Steg | first37=P. Gabriel | last38=Stone | first38=Gregg W. | last39=Rosenkranz | first39=Stephan | last40=Goldhaber | first40=Samuel Z. | last41=Parikh | first41=Sahil A. | last42=Monreal | first42=Manuel | last43=Krumholz | first43=Harlan M. | last44=Konstantinides | first44=Stavros V. | last45=Weitz | first45=Jeffrey I. | last46=Lip | first46=Gregory Y.H. | title=COVID-19 and Thrombotic or Thromboembolic Disease: Implications for Prevention, Antithrombotic Therapy, and Follow-Up | journal=Journal of the American College of Cardiology | publisher=Elsevier BV | volume=75 | issue=23 | year=2020 | issn=0735-1097 | doi=10.1016/j.jacc.2020.04.031 | pages=2950–2973}}</ref>
Lab findings of different case studies of patients having pulmonary embolism due to COVID-19 are given as  


*Elevated [[D-dimer|d-dimers]]
*Elevated [[D-dimer|d-dimers]]
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===== CTPA & Ventilation Perfusion Scan =====
===== CTPA & Ventilation Perfusion Scan =====


*Prompt diagnosis of PE in COVID-19 patient is difficult in this regard that various symptoms of [[COVID-19]] overlap with that of [[pulmonary embolism]]. American Society of Hematology provides the following guidelines regarding the diagnosis of pulmonary embolism:<ref name="Hematology.org 2020">{{cite web | title=COVID-19 and Pulmonary Embolism | website=Hematology.org | date=2020-05-18 | url=https://www.hematology.org:443/covid-19/covid-19-and-pulmonary-embolism | access-date=2020-06-23}}</ref>
*Prompt diagnosis of PE in COVID-19 patient is difficult in this regard that various symptoms of [[COVID-19]] overlap with that of [[pulmonary embolism]]. American Society of Hematology provides the following guidelines regarding the diagnosis of pulmonary embolism:
** Normal [[d-dimers]] level in a patient with low to moderate [[Pretest probability of DVT|pretest probability]] is sufficient to rule out the diagnosis of PE. [[D-dimers|D-dimers level]] is usually elevated in COVID-19 patients. This is not applicable to a patient with a high pretest probability.
** Normal [[d-dimers]] level in a patient with low to moderate [[Pretest probability of DVT|pretest probability]] is sufficient to rule out the diagnosis of PE. [[D-dimers|D-dimers level]] is usually elevated in COVID-19 patients. This is not applicable to a patient with a high pretest probability.
** Inpatient with suspected PE with symptoms like [[hypotension]], [[tachycardia]], and sudden drop in [[oxygen saturation]] with a high pretest probability of PE, computed [[tomography]] with [[pulmonary angiography]] is used for the diagnosis. Contraindication to the use of [[CT pulmonary angiogram|CTPA]] warrants investigation with [[Ventilation/perfusion scan|ventilation/perfusion scan.]]
** Inpatient with suspected PE with symptoms like [[hypotension]], [[tachycardia]], and sudden drop in [[oxygen saturation]] with a high pretest probability of PE, computed [[tomography]] with [[pulmonary angiography]] is used for the diagnosis. Contraindication to the use of [[CT pulmonary angiogram|CTPA]] warrants investigation with [[Ventilation/perfusion scan|ventilation/perfusion scan.]]

Revision as of 10:12, 27 June 2020

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [[Mailto:charlesmichaelgibson@gmail.com|[1]]

Overview

  • In May 2020, various autopsies studies revealed pulmonary embolism to be the common cause of death in COVID-19 infected patients.
  • These patients in their mid-70s had preexisting medical conditions such as cardiac diseases, hypertension, diabetes, and obesity.
  • These studies highlight the role of hypercoagulability as the main contributor to the fatality in these patients.
  • Various studies have described Virchow's triad to be the main component of the hypercoagulable state in these patients.

Historical Perspective

  • In late 2019, a novel coronavirus had been identified in Wuhan ,China which has now reached a pandemic state across whole world.
  • Various case reports and case series have suggested hypercoagulability to be one of the cause of death in COVID-19 patients.
  • Proposed mechanism of multiple organ dysfunction that occurs in COVID-19 patients are multifactorial but they include a hypercoagulable state with micro and macro-circulatory thrombosis.
  • Based on these case reports and case series, various guidelines have been proposed now to initiate anticoagulants in critically ill patients and those who are admitted to the hospital.

Classification

Acute Pulmonary Embolism

  • Pathologically an embolus is said to be acute when it is situated centrally within in the vascular lumen, or in other case it causes the occlusion of vessel. It can cause immediate occurence of symptoms.

Chronic Pulmonary Embolism

  • An embolus is said to be chronic , if it is eccentric and lies in lies with the vessel wall.
  • It occouleds the lumen of vessel wall by more than 50 %.
  • There is also evidence of recanalization within the thrombus.
  • Chronic thromboembolism can cause pulmonary hypertension especially when there is >3 months of effective anticoagulation therapy and one of the following criteria. a) Mean pulmonary arterial pressure greater than or equal to 25 mmHg b) Pulmonary arterial wedge pressure less than or equal to 15 mmgHg c) Abnormal lung V/Q scan or imaging findings suggestive of chronic pulmonary embolism on CTPA, CMR, CPA

Pathophysiology

  • As data on COVID-19 has been incomplete and evolving, the pathogenesis of pulmonary embolism has not yet been completely understood. Various contributors to the pathogenesis of pulmonary embolism in these patients are listed in the table below:
Pathology Description of the underlying mechanism
Endothelial cells dysfunction
  • It has been proposed that endothelial cells contribute towards the initiation and propagation of ARDS by changing the vascular barrier permeability, increasing the chance of procoagulative state that leads to endotheliitis and infiltration of inflammatory cells in the pulmonary vasculature.
  • It has been proposed that COVID-19 can directly affect endothelial cells leading to widespread endotheliitis. SARS-CoV-2 also binds to the ACE2 receptors which alter the activity of ACE2.
  • Reduced ACE2 activity leads to activation of the kallikrein-bradykinin pathway, which increases vascular permeability.
  • The activated neutrophils migrate towards the pulmonary endothelial cells and produce cytotoxic mediators including reactive oxygen species.
Stasis Most hospitalized critically ill immobile COVID-19 patients are prone to stasis of blood flow leading to another contributor towards the pathogenesis of pulmonary embolism.
Hypercoagulable state

Various clinical studies have reported different prothrombotic factors in patients who are critically ill and are hospitalized due to COVID-19. These studies report various key lab factors that play an important role in the pathogenesis of pulmonary embolism.


Causes

Differentiating Pulmonary Embolism from other Diseases

Epidemiology and demographics

  • Various case reports and case series report relatively high incidence of pulmonary embolism in ICU patients.
  • The incidence of thrombotic complications is reported to be 31 % in one study. In this study pulmonary embolism was the most common thrombotic complication.
  • Another study reported an overall 24% cumulative incidence of pulmonary embolism in patients with COVID-19 pneumonia, 50% (30–70%) in ICU and 18% (12–27%) in other patients.
  • In Non-ICU settings (In-patient), pulmonary embolism is reported to occur in 3% percent of patients in one study.

Risk Factors

Multivariate analysis showed following risk factors that predispose a patient of COVID-19 to pulmonary embolism

Natural History,Complications and Prognosis

Overview

Pulmonary embolism in critically ill patients of COVID-19 is a frequent finding. It can lead to the development of cardiogenic shock, sudden cardiac arrest and pulmonary hypertension if developed chronically. There has been various investigational and treatment approach to treat the hypercoagulability leading to these complications in COVID-19 patients. Patients that are at risk of pulmonary embolism such as those with deep venous thrombosis are advised to take oral anticoagulants. Studies show that there is high cumulative incidence of PE in COVID-19 patients which suggests more frequent use of contrast medium on CT for the evaluation of COVID-19 patients.

Complications

Various complications have been reported ranging from acute right heart failure and sudden cardiac arrest due to pulmonary embolism in COVID-19 patients. The following complications have been frequently reported in various case reports and case series.

Prognosis

COVID-19 patients presenting with pulmonary embolism have a poor prognosis. It has been reported that despite adequate anticoagulation being advised to patients in ICU, there is still relatively high incidence of PE in these patients. Few studies showed VTE to be the main cause of death in COVID-19 patients which suggests setting a lower threshold for diagnostic imaging for DVT or PE.

Diagnosis

History and Symptoms

  • COVID-19 patients are usually at high risk of hypercoagulability and as there is an increased incidence of pulmonary embolism in ICU patients, they mostly have overlapping symptoms with pneumonia, ARDS, and sometimes present only with fever progressing to pulmonary embolism and sudden cardiac arrest.
  • Pulmonary embolism can present with no symptoms to shock and even sudden cardiac arrest.
  • The most common symptoms that were observed in Prospective Investigation of Pulmonary Embolism Diagnosis II (PIOPED II) trial include:
    • Dyspnea that is sudden in onset at rest or exertion (73%)
    • Pleuritic pain (44%)
    • Calf or thigh pain (44%)
    • Calf or thigh swelling (41%)
    • Cough (34%)

Physical Examination

On physical examination following signs can be demonstrated in COVID-19 patients.[1]

General
Cardiac examination
Lung examination
DVT signs
  • Calf or thigh
  • Calf and thigh
Laboratory findings

Lab findings of different case studies of patients having pulmonary embolism due to COVID-19 are given as


Imaging studies

Chest-X ray

Chest radiography in not a primarily diagnostic test in pulmonary embolism patient. It is neither sensitive and nor specific. Chest-X ray is used to rule out other conditions that can mimic symptoms of pulmonary embolism such as bacterial pneumonia ,cardiogenic cause of dyspnea and pneumothorax.

CTPA & Ventilation Perfusion Scan
Right-sided segmental and subsegmental pulmonary arterial filling defects (yellow arrows) in keeping with acute distal pulmonary emboli. Source: Dr Gianluca Martinellihttps://radiopaedia.org/cases/76817

Treatment

  • Different treatment strategies for COVID-19 patients suffering from pulmonary embolism are given in the table below:
Different treatment options Details
Prophylaxis All hospitalized patients with COVID 19 should get proper venous thromboembolism prophylaxis in the absence of any contraindication of anticoagulation.
  • In ICU setting, empiric use of intermediate or therapeutic dose anticoagulation should be instituted.
  • In a non-ICU setting, all hospitalized patients should be treated with prophylactic low dose molecular weight heparin.
Acute Pulmonary embolism
Outpatient treatment[2]
  • Critically ill patients that have recovered from COVID-19 and had a documented VTE are usually given a minimum of 3 months of anticoagulation.
  • Patients not admitted to hospitals but at risk of VTE, such as prior VTE episode, recent surgery, prolonged immobilization are usually given a prophylactic dose of Rivaroxaban 10 mg daily for 31 days or 39 days.


References

  1. Stein, Paul D.; Beemath, Afzal; Matta, Fadi; Weg, John G.; Yusen, Roger D.; Hales, Charles A.; Hull, Russell D.; Leeper, Kenneth V.; Sostman, H. Dirk; Tapson, Victor F.; Buckley, John D.; Gottschalk, Alexander; Goodman, Lawrence R.; Wakefied, Thomas W.; Woodard, Pamela K. (2007). "Clinical Characteristics of Patients with Acute Pulmonary Embolism: Data from PIOPED II". The American Journal of Medicine. Elsevier BV. 120 (10): 871–879. doi:10.1016/j.amjmed.2007.03.024. ISSN 0002-9343.
  2. Invalid <ref> tag; no text was provided for refs named Hematology.org 2020
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