Coronavirus disease-19 (COVID-19) is caused by the SARS-CoV2 virus and it is characterized by a heterogeneous and unpredictable course. In addition to asymptomatic forms, three stages of increasing severity have been identified in COVID-19.1 Most patients have the mildest form characterized by an acute infection, often olygosymptomatic or with flu-like symptoms.2 Around 15% of patients develop severe manifestations, including unilateral or bilateral pneumonia with progressive hypoxemia that cause acute respiratory distress syndrome (ARDS) requiring the use of mechanical ventilatory assistance. In the most serious form, there is a process of systemic hyperinflammation, with multi-organ involvement (cytokine storm), lymphopenia, and a strong elevation of acute phase reactants such as C-reactive protein, ferritin, D-dimers, cytokines, and chemokines with high risk of mortality.3 Data on histopathological samples on the various forms of COVID-19 that are based on autopsies of deceased patients are scarce. Microthrombi, diffuse alveolar damage, multiorgan thrombosis, hemophagocytosis, and immune cell depletion have been described in these autopsies.4

Overactivation of the innate immune system is very common in severe forms of COVID-19 and, surprisingly, lymphopenia is one of the usual findings in these patients, something that would be contradictory. This great activity of innate immunity triggers a state of hyperinflammation leading to a syndrome of massive cytokine release, characterized by ARDS, multiorgan dysfunctions and the presence of generalized microthrombi in capillaries and small vessels,5 a situation that resembles a thrombotic microangiopathy (TMA),6 a disseminated intravascular coagulation (DIC)7 or a catastrophic antiphospholipid syndrome (CAPS).8

When a virus infection occurs without prior contact with the immune system, a coordinated response of innate immunity and adaptive immunity is developed.

In the one hand, the innate immunity response has more rapid onset, it acts as the vanguard to initiate the control of the infection. It is carried out by the participation of a group of cells (neutrophils, monocytes and antigen presenting) and molecules effectors as the complement. These responses are characterized to be quick, stereotyped, and generally nonspecific. In the other hand, adaptive immunity is composed of cells and molecules that are specific antigens, and their effector capacity although it is more intense and prolonged than that of innate immunity requires a latency time. It can get started after recognition of the microorganism as foreign and the creation and subsequent elaboration of specific cells and molecules in sufficient quantity to carry out the control of the infection (primary response).9

In viral infections, as in other infections, the coordinated activity of innate and adaptive immunity is essential to generate an effective response.10 The mission of innate immunity is to try to resolve the infection quickly, and if not possible, contain it for as long as possible, necessary to develop an effective adaptive immunity response.

Although these responses in combination are effective in most infections, there are microorganisms that have the ability to escape the control of the immune system. These mechanisms include the incoordination of adaptive immunity generating insufficient and/or uncontrolled responses.11

Due to the ineffectiveness of the adaptive response, in a desperate attempt to control the infection, innate immunity contributes to the massive release of cytokines and the overactivation of local immune cells.12

SARS-CoV-2 infection produces a dysregulation with hyperactivation of adaptive immunity that leads to its exhaustion, which can be evidenced in total lymphocytopenia of both T and NK cells. This lymphopenia is directly proportional to the clinical severity.

After the control of adaptive immunity disappears, an overactivity of innate immunity occurs, leading to the massive release of cytokines of innate immunity (IL-1, IL-6, TNF-alpha), causing tissue damage and a hyperinflammatory state. This massive inflammatory response is not only ineffective but also leads to a situation of self-reactivity with the generation of a prothrombotic state. The sum of the damage generated by all these factors has fatal consequences at the systemic level.13–15

The baseline situation of the host before infection such as the elderly patients, presence of comorbidities, inherited situations of immunodeficiency, or drug treatments, add to the damage generated by the virus and the aberrant responses to infection. The combination of personal and infectious factors favor that the situation can become irreversible.16

Since the beginning of the pandemic, studies conducted in China described a large proportion of patients with elevated parameters associated with hypercoagulability, such as D-dimer, as well as a high incidence of thrombotic events in COVID-19 patients7,17,18 especially in those patients with more impaired lung function.19 Subsequently, reports emerged from research groups around the world that confirmed this higher incidence of thrombotic events, especially in patients at Intensive Care Units (ICU), where an incidence of 49% was described in patients with admissions greater than 2 weeks.18

Most of the thromboses (87%) were located in the lungs, this suggests a thrombosis secondary to local inflammation due to the virus.18 In many cases, these thrombotic events occurred even in patients receiving standard dose thromboprophylaxis. Laboratory tests revealed that patients with thrombotic events were those with elevated D-dimer, lactate dehydrogenase (LDH), fibrin and fibrinogen degeneration products, C-reactive protein, and moderate thrombocytopenia.20

However, many confounding factors coexist, for example the simple fact of admission to the ICU is a risk factor for thrombosis by itself.21 Furthermore, the presence of other known risk factors for thrombosis coincided in these patients: high age, smoking, and the presence of comorbidities such as high blood pressure, diabetes mellitus, and metabolic syndrome.22,23 Infection per se would be an additional coadjuvant factor for thrombosis, in addition, the conjunction of all these risk factors would lead to a highly prothrombotic situation.

Studies based on autopsies of deceased patients from COVID-19 are the best way to discern whether multiorgan involvement in patients with COVID-19 is secondary to the multiple comorbidities present or is caused by a primary thrombotic disorder.6

The available literature shows discrepancies, since some authors did not find microangiopathy features in the organs, which is why it is attributed to associated comorbidities.43,44 In another serie of autopsies, the presence of generalized fibrinous microthrombi located at the level of the lung, respecting other organs such as the kidney and the skin.45 However, the presence of SARS-CoV2 has been reported in podocytes and renal tubules in patients with death due to respiratory failure. In addition to this finding in renal histology, structural damage attributable to other comorbidities was found, with the presence of microthrombi. A higher incidence of hypoxia and multi-organ failure was also seen, this suggests a mixed etiology of these alterations.46

Complement deposition in the lung has been reported, that suggest a systemic activation of both the classical and the lectin-based complement pathways. These deposits have also been seen in the microvasculature of the skin, both in purpuric lesions and in healthy skin tissue. These findings are consistent with multiorgan vascular disease.47,48

Microthrombi in pulmonary circulation are a frequent finding in autopsies for COVID-19. This phenomenon has also been previously described in autopsies of patients who died from H1N1 virus infection. These findings suggest the presence of an immune-mediated systemic coagulopathy that could be classified as the TMA associated with severe viral infection.49 The spectrum of TMA includes several diseases such as DIC, CAPS, and hemolytic uremic syndrome (HUS). All of them have in common an overactivation of platelets and the coagulation cascade.6 This situation of excessive activation of platelets increases the risk of thrombosis and subsequent consumption that can cause bleeding. But this rarely occurs in COVID-19 coagulopathy and in other TMAs.50 However, as we have explained above, complement activation could be involved in COVID-19 coagulopathy, as occurs in TMA syndrome.

Multiorgan involvement with complement deposition may occur in the context of a typical infection in CAPS and HUS (Shiga toxin). A high prevalence of antiphospholipid antibodies has been described in patients with COVID-19 (see below). In the case of HUS, SARS-CoV-2 has been seen in specific regions with alterations suggestive of microangiopathy47,49 suggests that this virus could be a trigger for coagulopathy as in the case of Shiga toxin in HUS.51 Distinguishing the different TMA syndromes is often difficult because there is an overlap in clinical and pathophysiological features like complement activation. These coagulopathies should be considered a spectrum disorder rather than independent diseases.6 As in the rest of coagulopathies, there is no single cause responsible for coagulopathy caused by SARS-CoV2. The sum of the events caused by the infection itself, the alterations in the complement cascade and coagulation, as well as the coexistence of other comorbidities favor a prothrombotic state.

Antiphospholipid syndrome (APS) is a systemic autoimmune disease characterized by the appearance of thrombosis or gestational morbidity (clinical criteria) in a patient with persistently high levels of antiphospholipid antibodies (aPL).52 The aPLs recognized in the classification criteria are lupus anticoagulant, anticardiolipin and anti-beta2-glycoprotein I antibodies of IgG and IgM isotypes. Presence of double or triple aPL positivity has been associated to higher risk of thrombosis.53 The aPL levels rise nonspecifically during acute infections.54 Therefore, to avoid false positives, the classification criteria indicated that to classify a patient with a thrombotic event as APS, there must be positivity of aPL in 2 determinations separated 12 weeks.55

There are three forms of APS: (1) APS associated with the presence of another autoimmune disease such as systemic lupus erythematosus, (2) an isolated APS form without other autoimmunity (primary APS), and (3) CAPS, the most severe form with multiorgan involvement, and evidence histopathology of multiple vascular occlusions. It associates poor response to anticoagulant treatment and a high risk of mortality.56

There are signs and symptoms not included in the classification criteria despite being very frequent, as livedo reticularis or thrombocytopenia. There are also extra-criteria aPL that have been associated with APS clinical events but are not included in the classification criteria. Among them the aB2GPI of IgA isotype, the anti-phosphatidylserine prothrombin (aPS/PT).57 A high prevalence of aB2GPI IgA antibodies has been seen in patients with kidney and heart failure on the transplant waiting list, and their presence has been associated with an increased risk of thrombosis and early graft loss due to thrombosis after transplantation.58,59 The origin of aPL is not yet well understood. From the first description of APS, it was observed the influence of microbial and viral agents influencing the production of aPL and an infectious etiology for this syndrome was postulated.60,61 It has been suggested that the mechanism of molecular mimicry between the β2GPI molecule and some molecular structures of various microorganisms may be present in the pathogenesis of APS.62

The mechanism by which aPL induces thrombosis is also not well understood. It is not well known. Meroni described the theory of the 2 hits, stating that the mere presence of aPL (first hit) is not enough to generate a thrombotic event. A trigger (second hit) is required to produce endothelial activation, such as complement activation, infection or surgery.63

The suspicion that there could be a relationship between APS and the prothrombotic situation of COVID-19 patients began with the observation of 3 patients with thrombotic events during admission, in which positivity was mainly observed for aPL of the IgA isotype (aCL and aB2GP1).64 Numerous reports of association of the presence of aPL with thrombosis in COVID appeared, such as cerebral infarcts in patients without a previous history of APS, many of them with double aPL positivity.65,66

After beginning to perform systematic aPL screening in COVID-19 patients, numerous studies emerged on the incidence of aPL in COVID-19 patients. The results surprised the scientific community, after showing high rates of presence of positive LA with a prevalence between 50 and 90% of COVID-19 patients67,68 especially among those with elevated aPTT, showing up to 91% positivity for LAC.69

Given the high prevalence of aPL in COVID patients and its lack of association with the characteristic events of APS, it has been suggested that these aPL are actually false positives.

The hypercoagulability associated with COVID-19 appears to be directly related to the severity of the disease and to a worse prognosis for patients. Therefore, therapeutic decisions often include the use of therapeutic anticoagulation in high-risk individuals.92

Current data recommend the use of prophylactic anticoagulation with low molecular weight heparin in hospitalized patients with COVID-19. It should be taken into account that regardless of the thrombotic association of aPL, antithrombotic prophylaxis should be done due to the high thrombotic risk as a consequence of multiple factors of hyperinflammation, platelet activation, and endothelial dysfunction. So its positivity should not change this practice.93

Current data suggest that anticoagulant treatment improves the results. However, despite anticoagulation, more thrombotic complications were significantly observed compared to non-COVID-19 ARDS patients (11.7% vs. 2.1%, p<0.008).67 This situation has a certain parallelism with the CAPS.94 In COVID-19, possibly higher anticoagulant doses should be administered and associated with other adjuvant treatments, making an analogy with the therapeutic approach of CAPS, whose treatment is based on the combination of heparin, corticosteroids and plasmapheresis.95 In this way, anticoagulation and corticosteroids have shown good results in these patients, although there are very few data on plasmapheresis. Perhaps it could bring benefits in the subgroup of patients with COVID-19 with high titers of aPL.74

The data provided by the literature show that there is a coagulopathy associated with COVID-19 that encompasses a spectrum of alterations that suggest an immune-mediated mechanism reminiscent of APS, and its most severe form, CAPS.

In this way, the early introduction of anticoagulant treatment led to an improvement in the prognosis of these patients. In addition to APS, many similarities have also been found with other subtypes of TMA. A high prevalence of aPL has been reported in COVID-19 patients, especially in older patients with a worse clinical course, although these alterations can act as confounding factors. For this reason, there is great controversy about the clinical association of these antibodies with thrombotic events. The current results do not allow a statistical relationship to be established.

It is important to take into account that most of the studies show important methodological shortcomings that make difficult to establish correct interpretation of the aPL. Especially the absence of control populations or, in the cases in which they are included, these controls are not comparable because they tend to be much younger than the patients studied. It is known that infections cause temporary elevation of aPL, therefore, the classification criteria require repeating a second determination at 12 weeks, which is not performed in almost all studies. Another no less important deficiency is the heterogeneity of the methods for determining aPL, with large discrepancies in prevalence depending on the different diagnostic systems used. Sufficiently contrasted solid phase tests should be used to minimize this problem.

The evidence of the results suggests the determination of the most important extra-criteria aPL (IgA isotype of anti B2GPI and aPS/PT), since they are the most prevalent aPL, and should be incorporated into aPL studies to assess COVID-19 coagulopathy.

Despite the controversy that exists in the clinical association of aPL, the analysis of the results suggests that in most patients, aPL would not be the direct cause of the procoagulant situation in COVID-19 coagulopathy. This is because it is possibly a multifactorial coagulopathy, in which various mechanisms participate including aPL, in an additive way. It is necessary to evaluate whether in the context of the infection there are alterations in the levels of the molecules related to the coagulation processes, such as elevations of procoagulant molecules (such as proteases) or deficiencies of anticoagulant molecules (such as serine proteases, protein C, etc.) or phospholipid-binding proteins. These alterations could be further favoring the generation of a prothrombotic state in these patients. Despite the existence of similarities with various microangiopathies, we are probably facing a new coagulopathy secondary to SARS-CoV2 infection. New studies are needed to better explain this new immune-mediated phenomenon.

It is mandatory to carry out systematic studies on the presence of aPL in large groups of COVID-19 patients, assessing both the initial prevalence and the temporal evolution to confirm which ones remain positive and the possible relationship of the presence of aPL with the appearance of complications in the patients not only in convalescence but also in the medium and long term.

The authors declare they have nothing to disclose regarding conflict of interest with respect to this manuscript.