Hostname: page-component-586b7cd67f-vdxz6 Total loading time: 0 Render date: 2024-11-24T08:12:26.723Z Has data issue: false hasContentIssue false

Renal, cardiac, neurological, cutaneous and coagulopathic long-term manifestations of COVID-19 after recovery; A review

Published online by Cambridge University Press:  21 September 2022

Reza Afrisham
Affiliation:
Department of Clinical Laboratory Sciences, School of Allied Medicine, Tehran University of Medical Sciences, Tehran, Iran
Yasaman Jadidi
Affiliation:
Department of Clinical Laboratory Sciences, School of Allied Medicine, Tehran University of Medical Sciences, Tehran, Iran
Maryam Davoudi
Affiliation:
Department of Clinical Laboratory Sciences, School of Allied Medicine, Tehran University of Medical Sciences, Tehran, Iran
Kiana Moayedi
Affiliation:
Department of Clinical Biochemistry, Faculty of Medicine, Tehran University of Medical Sciences, Tehran, Iran
Saina Karami
Affiliation:
Student research committee, Ahvaz Jundishapur University of Medical Sciences, Ahvaz, Iran Department of Parasitology, School of Medicine, Ahvaz Jundishapur University of Medical Sciences, Ahvaz, Iran
Sahar Sadegh-Nejadi
Affiliation:
Department of Clinical laboratory, Shariati Hospital, Tehran University of Medical Sciences, Tehran, Iran
Damoon Ashtary-Larky
Affiliation:
Nutrition and Metabolic Diseases Research Center, Ahvaz Jundishapur University of Medical Sciences, Ahvaz, Iran
ShadiSadat Seyyedebrahimi*
Affiliation:
Department of Clinical Biochemistry, Faculty of Medicine, Tehran University of Medical Sciences, Tehran, Iran
Shaban Alizadeh*
Affiliation:
Department of Hematology and Transfusion Medicine, School of Allied Medicine, Tehran University of Medical Sciences, Tehran, Iran
*
Authors for correspondence: Shaban Alizadeh, E-mail: [email protected]; ShadiSadat Seyyedebrahimi, E-mail: [email protected]
Authors for correspondence: Shaban Alizadeh, E-mail: [email protected]; ShadiSadat Seyyedebrahimi, E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) caused the novel global coronavirus disease 2019 (COVID-19) disease outbreak. Its pathogenesis is mostly located in the respiratory tract. However, other organs are also affected. Hence, realising how such a complex disturbance affects patients after recovery is crucial. Regarding the significance of control of COVID-19-related complications after recovery, the current study was designed to review the cellular and molecular mechanisms linking COVID-19 to significant long-term signs including renal and cardiac complications, cutaneous and neurological manifestations, as well as blood coagulation disorders. This virus can directly influence on the cells through Angiotensin converting enzyme 2 (ACE-2) to induce cytokine storm. Acute release of Interleukin-1 (IL1), IL6 and plasminogen activator inhibitor 1 (PAI-1) have been related to elevating risk of heart failure. Also, inflammatory cytokines like IL-8 and Tumour necrosis factor-α cause the secretion of von Willebrand factor (VWF) from human endothelial cells and then VWF binds to Neutrophil extracellular traps to induce thrombosis. On the other hand, the virus can damage the blood–brain barrier by increasing its permeability and subsequently enters into the central nervous system and the systemic circulation. Furthermore, SARS-induced ACE2-deficiency decreases [des-Arg9]-bradykinin (desArg9-BK) degradation in kidneys to induce inflammation, thrombotic problems, fibrosis and necrosis. Notably, the angiotensin II-angiotensin II type 1 receptor binding causes an increase in aldosterone and mineralocorticoid receptors on the surface of dendritic cells cells, leading to recalling macrophage and monocyte into inflammatory sites of skin. In conclusions, all the pathways play a key role in the pathogenesis of these disturbances. Nevertheless, more investigations are necessary to determine more pathogenetic mechanisms of the virus.

Type
Review
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press

Introduction

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) caused the novel global coronavirus disease 2019 (COVID-19) disease outbreak [Reference Mitsuyama1, Reference Mandal2]. This new virus is highly contagious as well as is a deadly virus [Reference Nami3]. As individuals with the virus are elevating worldwide, the complications and some disturbances caused by COVID-19 have widely increased [Reference van Vuren4]. Although, the most frequent signs of COVID-19 are respiratory symptoms [Reference Bodnar5], but, there are documents of COVID-19-correlated symptoms including blood coagulation disorders, renal and cardiac complications as well as cutaneous and neurological manifestations (Fig. 1) [Reference Nami3, Reference Mihalopoulos6Reference Lopez-Leon8]. As we know, Angiotensin converting enzyme 2 (ACE-2) is the receptor for coronaviruses [Reference Hoffmann9] and the spike (S) protein of virus attaches it on the cell surface of some organs (e.g. cardiovascular system, kidney, lung, gastrointestinal tract (GI), skin and brain). After cleavage by transmembrane serine protease 2 (TMPRSS2), the virus enters the cell [Reference Singh10].

Fig. 1. COVID-19 long-term symptoms. SAE, systemic arterial embolism; MI, myocardial infarction.

Upon viral entry, the innate immune system is recruited to fight the infection. Meanwhile, SARS-CoV-2 replicates in the pulmonary and endothelial cells of the pulmonary arteries and after destroying the cells, releases to the circulation. Macrophages and dendritic cells (DCs) endocytose the virus and present virus antigens to T helper type 1 (Th1). Further stimulation of Th1 gradually activates B cells to secrete neutralising antibodies and CD8 + T cells to destroy virus-infected cells. This stimulates the secretion of pro-inflammatory cytokines like Interlukine-6 (IL-6), IL-21, IL-18 and Tumour necrosis factor-α (TNF-α) and activates the nuclear factor kappa B (NF-κB) pathway, causing a systemic hyperinflammatory state that may involve other organs [Reference Ahmadian11, Reference Silva12]. Along with systemic hyperinflammatory, other cellular and molecular mechanisms may influence on vital organs. So, realising how such a complex disturbance affects patients after recovery is crucial. Regarding the significance of control of COVID-19-related complications after recovery, the current review was designed to study the cellular and molecular mechanisms linking COVID-19 to significant long-term signs including renal, cardiac, cutaneous and neurological complications, as well as blood coagulation disorders. To the best our knowledge, there are no comprehensive review to explore these events related to many long-term complications of COVID-19.

Renal manifestations

ACE2 plays a vital role in regulating the cardiovascular and renal systems via Renin-Angiotensin-Aldosterone System (RAAS). Renal juxtaglomerular cells begin to release renin in response to some conditions, including reduced renal perfusion, hypotension, ischaemia, sodium diuresis and sympathetic stimulation, which converts liver-derived angiotensinogen to angiotensin I (ANGI) [Reference Faour13]. Subsequently, ANGI is converted by ACE to ANGII, which in turn is further metabolised by ACE-2 into ANG I–7. Meanwhile, ANGI can also be metabolised by neutral endopeptidase to ANG 1–7. ANG1–7 and its receptor, i.e. Mas, acts as vasodilator, anti-inflammatory and anti-coagulant agents, whereas ANGII and its receptor, i.e. Angiotensin II type 1 receptor (AT1R), are vasoconstrictor, pro-inflammatory, pro-coagulant and fibrotic effectors [Reference de Carvalho, Sirois and Fernandes14]. Thus, in patients with cardiorenal diseases, ANGII can control fibrosis, hypertrophy and prooxidative hormone, which leads to an increase in salt and water retention [Reference Quadri15, Reference Culver, Li and Siragy16]. In kidneys, ACE2 is expressed on proximal tubule epithelial cells (PTECs), podocytes and endothelial cells [Reference Chen17]. Although the TMPRSS2 expression is low on PTECs, high levels of other proteases such as cathepsin and glutamyl aminotransferase, in these cells may help the virus entry [Reference Ahmadian11]. SARS-CoV-2 moves to the kidneys through the glomerular capillaries and arteries and then enters the glomerular epithelial cells to infect the podocytes. In this way, SARS-CoV-2 enters tubular fluid and reach PTECs [Reference Faour13, Reference Ye18]. The internalisation of ACE2 receptor induced by SARS-CoV-2 leads to ACE2 deficiency on cells, which shifts the ANG1–7-Mas pathways to angiotensin II-angiotensin II type 1 receptor (ANGII-AT1R) and induces a proinflammatory state [Reference Ahmadian11].

Furthermore, ACE2 regulates the Kallikrein Kinin System. In this regards, after producing kinin from bradykininogens, this metabolite acts on both B1 and B2 receptors to induce inflammation and increase vascular permeability [Reference de Carvalho, Sirois and Fernandes14, Reference Marceau19, Reference Donoghue20]. The most important agonist of B1 receptor is a bradykinin metabolite, i.e., [des-Arg9]-bradykinin (desArg9-BK), which is cleaved by ACE2. As regards SARS-induced ACE2-deficiency, it should said that not only it increases ANGII, but also decreases desArg9-BK degradation [Reference de Carvalho, Sirois and Fernandes14]. Also, Kallikrein can trigger the coagulation imbalance through activating factor 12 and plasmin. The mentioned renal changes can exacerbate systemic inflammation, thrombotic problems, fibrosis and necrosis mediated by COVID-19 in kidneys, resulting in renal damages [Reference de Carvalho, Sirois and Fernandes14].

The severity of these injuries varies from proteinuria to acute kidney injury (AKI) in ~5–70% patients [Reference Ahmadian11, Reference de Carvalho, Sirois and Fernandes14, Reference Vahdat21]. However, a recent meta-analysis on 18 043 patients showed that 32.6% of patients admitted to the intensive care unit (ICU) suffered from AKI [Reference Passoni22]. the incidence of AKI has been higher in non-survivors, ranging from 25–50% [Reference Chen23, Reference Zhou24]. Based on a systematic study on 193 patients with COVID-19, the corresponding figures for proteinuria, haematuria, urea nitrogen levels and creatinine levels were 44–65%, 27–44%, 14% and 10–14% [Reference Vahdat21]. Theoretically, Transient Receptor Potential Canonical Channel 6, as an ion channel in podocytes, can directly be activated by ANGII, which leads to proteinuria [Reference Faour13, Reference Hoffmann25]. The most common COVID-19-related renal complications are including acute tubular injury, collapsing glomerulopathy, thrombotic microangiopathy, complement activation and IL-6-induced renal vascular permeability [Reference Faour13, Reference Chen17]. Therefore, the kidney injury leads to: (i) hypoxia-induced acute tubular necrosis with high level of creatinine, (ii) collapsing focal segmental glomerulosclerosis together with haematuria, which are common in patients with APOL1 alleles, (iii) direct viral tropism of renal tissue with high levels of micro- or macro-albuminuria and (iv) hemodynamic changes mediated by endothelitis along with electrolyte imbalance [Reference Liakopoulos26]. Furthermore, the infiltration of some immune cells like lymphocytes into the renal interstitium can cause cells to release more pro-inflammatory cytokines and lymphocyte-derived toxic particles (e.g. perforin), causing more kidney injuries [Reference Faour13]. It is worth noting that rhabdomyolysis and acute cardiorenal syndrome are also associated with kidney failure [Reference Liakopoulos26]. In addition, some drug-induced nephrotoxicity may also occur in COVID-19 cases; for example, remdesivir can be nephrotoxic through damaging the mitochondria in the epithelial cells of the renal tubules [Reference Legrand27]. According to a systematic review, renovascular complications can be seen in COVID-19 cases with/without a pre-existing renal disorder. Hence, all COVID-19 patients should to be checked for their renal functions [Reference Kaur28].

Overall, although COVID-19-related renal histopathological changes involve both parenchyma and the interstitium of kidney, glomerular injuries are milder than interstitial ones [Reference Diao29, Reference Ferlicot30]. These changes have already been described in a study by Faour et al. [Reference Faour13]. However, some questions still remain in this area that need further study.

Cardiac manifestations

It has been shown that about 7.3% of COVID-19 patients suffer from heart pulsation as a primary sign [Reference Welsh31]. The most prevalent COVID-19-related cardiovascular manifestations have been cardiac injury and myocardial injury, with 35.29% and 29.41% of cases respectively [Reference Pratistha32]. COVID-19-induced hypoxia and myocardial damage can create cardiac electrical dysregulation and arrhythmias, which is common in 30%–50% of ICU cases [Reference Pranata, Huang and Raharjo33]. Moreover, about 20%–30% of hospitalised cases have had an increase in troponin I (cTnI) levels which is related to myocardial involvement [Reference Welsh31, Reference Mitrani, Dabas and Goldberger34]. In cardiac tissues, ACE-2 is highly expressed in venous and arterial smooth muscle cells (SMC), endothelial cells and cardiac fibroblasts [Reference Khan35, Reference Guo36]. It has been reported that COVID-19 can directly affect cardiomyocytes through their ACE-2 to induce inflammatory responses and cytokine storm, as aforementioned [Reference Khan35].

It has been offered that there is a connection between acute myocardial damages caused by COVID-19 infection and ACE-2. In fact, by shifting RAAS toward ANGII/AT1R, the level of inflammatory cytokines such as IL4, IL10 and IL6 are increased, which in turn activates T-cells in peripheral blood of COVID-19 patients. The overactivation of T cells leads to a rise in Th17 and cytotoxic CD8 T-cells [Reference Xu37]. In other words, when ANGII binds to AT1 receptor, atherosclerosis, hypertrophy, fibrosis, proliferation and vasoconstriction are increased, while, natriuresis and diuresis are decreased [Reference Tajbakhsh38]. On the contrary, if ANGII binds directly to AT2 receptor or converts to ANGIII and then binds to AT2 receptor or converts to ANG (1–7) and then adjoins to ANG (1–7) receptor (MasR), atherosclerosis, hypertrophy, fibrosis, proliferation and vasoconstriction are diminished and natriuresis and diuresis are elevated [Reference Tajbakhsh38].

The myocardial damage may occur during COVID-19-associated ‘cytokine storm’ that is followed by a Th1/Th2 imbalance and can exacerbate respiratory distress syndrome, hypoxaemia, shock and/or hypotension. Moreover, in COVID-19 patients, some factors including GCSF, IL10, IL7, IL2, IP10, MCPI, MIP1A and TNFα are elevated in inflammatory response [Reference Zheng39Reference Wong42]. It has been indicated that acute release of IL1, IL6 and plasminogen activator inhibitor 1 (PAI-1) were related to elevating risk of heart failure [Reference Wang43]. The cytokines caused the release of reactive oxygen species, superoxide anion and endogenous nitric oxide so that all of them could injure myocardial cells [Reference Sattar44]. C-reactive protein (CRP) is an important marker in systemic inflammatory and several infections. CRP helps in stimulation of atherosclerosis and instability of atherosclerotic plaque [Reference Wang43]. In addition, a high prevalence of COVID-19-mediated inflammatory stress can also cause arrhythmias through inducing electrolyte and hemodynamic disorder [Reference Khan35, Reference Bhatla45, Reference Kochi46]. In COVID-19 patients, strong interferon-mediated responses can contribute to myocardial dysfunction, especially in protective adaptive immunity by interferons [Reference Babapoor-Farrokhran47]. It has also been recommended that severe COVID-19 patients with higher N-terminal pro-brain natriuretic peptide (NT-proBNP) levels were older patients who had high levels of markers of systemic inflammatory. NT-proBNP levels presented as an independent risk factor of in-hospital survival rate in severe COVID-19 patients. So that, COVID-19 patients with higher NT-proBNP (above 88.64 pg/ml) levels had a lower survival rate [Reference Gao48].

Transforming growth factor-β1 (TGF-β1) acts as important mediator in the process of tissue fibrosis and leads to scarring by activating its downstream small mother against decapentaplegic (Smad) pathway [Reference Hu49]. In this direction, SARS-CoV-2 activates TGF-β signalling by the smad pathway to stimulating lung fibrosis. In addition, smad pathway activated by COVID-19 is a prevalent pathway of interstitial fibrosis development in the myocardium [Reference Babapoor-Farrokhran47]. In fact, TGF-β signalling in COVID-19 process is activated by both the non-canonical and the canonical signalling pathways [Reference Carlson50]. A papain-like protein as well as a nucleocapsid protein along with smad3 activate the canonical and the non-canonical pathways, so, TGF-β is upregulated [Reference Carlson50].

Overall, various cellular and molecular mechanisms such as recognition of ACE-2 and receptor infection, cytokine storm and induction in several inflammatory responses are contributed in cardiac dysfunction, which can increase pulmonary vascular resistance, as well as result in pulmonary heart disease and hypertension.

Neurological complications

Besides the acute clinical manifestation of respiratory virus, understanding the neurological complications following COVID-19 illness will be crucial [Reference Peterson, Sarangi and Bangash51]. A tremendous number of clinical studies have reported that many of COVID-19 patients had at least one neurological manifestation [Reference To7]. In a 2022 meta-analysis, 2791 out of 18 258 COVID-19 patients had neurological symptoms with the mortality rate of 29.1% [Reference Mahdizade Ari52]. A scoping review on neurological manifestations in COVID-19 patients has revealed that the spectrum of these symptoms ranged from mild to severe [Reference Chen53]. The mild manifestations included olfactory and gustatory disorders, dizziness, headache, vomiting, malaise, fatigue and anorexia. Whereas, ischaemic stroke, impaired consciousness, encephalopathy, cognition and memory impairments, meningitis, diplopia and ophthalmoplegia are regarded as severe symptoms [Reference Chen23, Reference Wenting54, Reference Lechien55].

Neurologic complications can also be divided into central nervous system (CNS) and peripheral nervous system (PNS) involvements. The CNS involvement comprises headache and dizziness, impaired consciousness, acute cerebrovascular disease, corticospinal tract signs, ataxia and seizure, meningitis, encephalitis and stroke. While, the PNS involvement includes hyposmia and dysgeusia, vision impairment, nerve pain and Guillian-Barre syndrome [Reference Baig56, Reference Tandon57].

Interestingly, sex and age differences have been reported to affect the severity of neurological manifestations. Differences in humoral and innate immune responses to viral infections between men and women as well as age-related expression of ACE2 are supposed to be involved [Reference Liguori58, Reference Sullivan and Fischer59]. In addition, Heart disorders, diabetes and dyslipidemia have increased the risk of developing neurological complications in COVID-19 by 2-fold in a meta-analysis on 4401 patients [Reference Radwan60]. [Reference Sullivan and Fischer59] Moreover, some neurological symptoms like Parkinsonism can be developed in cases who recovered from COVID-19 as shown on a clinical study. Thus, Parkinsonism is a post-COVID neurological symptom [Reference Ali61].

However, the aetiology for COVID-19 neurological consequences is not completely understood. Post- COVID 19 neurological disorders are shown in Figure 2. From the existent studies on the neuropathogenicity of COVID-19, two possible underlying mechanisms have been proposed: (1) Direct mechanisms and (2) Indirect mechanisms [Reference To7, Reference Chen53]. In direct invasion, SARS-CoV-2 could affect the nervous system mainly through the neuronal pathways and to a lesser extent through the blood circulation pathways or lymphatic system [Reference Chen23, Reference Wenting54]. In terms of neuronal pathway, the virus mainly spreads via the transcribial route from the olfactory epithelium along with the olfactory nerve to the olfactory bulb in the nasal cavity and forebrain [Reference Reza-Zaldívar62]. This latter route effectively makes it a channel among the nasal epithelium, the entire brain and cerebrospinal fluid and subsequently causes inflammation and demyelinating reactions [Reference Liguori58, Reference Sullivan and Fischer59, Reference Reza-Zaldívar62, Reference Desforges63]. Another potential mechanism is the neuronal retrograde or anterograde transmission. In this route, the viruses invade the sensory or motor nerve endings and migrate by the motor proteins including dynein and kinesins [Reference Guillaud64]. These mentioned pathways can lead to dysfunction of the respiratory and/or gastrointestinal centres [Reference Whittaker, Anson and Harky65].

Fig. 2. Post-COVID 19 neurological disorders. (1) viral entrance through ACE2 receptor; (2) inflammatory cytokines increase due to activated microglia; (3) SARS-Cov 2 leads to inflammated mitral cells; (4) virus migration through motor proteins such as dynein and kinesin; (5) virus BBB infiltration; (6) virus may cause coagulation; (7) BBB break-down serve as a gate for virus penetration into the brain; (8) virus activates microglial cells; (9) rise in inflammatory cytokines; (10) neuronal death occurrence. TMPRSS2, Transmembrane protease, serine 2; ACE2, Angiotensin-converting enzyme 2; NRP1, neuropilin-1; CD147, cluster of differentiation 147; BBB, blood–brain barrier; WBC, White blood cells; RBC, Red blood cells.

Accumulating evidence suggests that SARS-CoV-2 gains entry to the CNS through the ACE2 and TMPRSS2 receptors on sustentacular cells in the human olfactory neuroepithelium and several brain structures as well as via CD147 and Neuropilin-1 (NRP1) receptors in sensory neuron [Reference To7, Reference Chen23, Reference Peterson, Sarangi and Bangash51, Reference Chen53Reference Sullivan and Fischer59, Reference Reza-Zaldívar62Reference Fodoulian66]. Based on studies, both ACE2 and NRP1 are highly expressed in the brain. Although ACE2 is mostly expressed in circumventricular organs and endothelial vasculature, NRP1 is generally expressed in the hippocampus, endothelial cells, mural cells, perivascular macrophages and microglia [Reference Hernández67, Reference Davies68]. Following the dissemination of the coronaviruses in the nervous system, it can damage the blood–brain barrier by increasing its permeability and subsequently enter into the CNS and the systemic circulation [Reference Baig56, Reference Tandon57].

In addition to direct infection injury, the nervous system may be affected indirectly due to a severe systemic reaction in response to a viral infection outside the nervous system. In this regard, neuro-inflammation, hypoxia, coagulation disorders, dysregulated blood pressure (due to binding to ACE2 receptors) as well as altered glucose and lipid metabolism are considered as indirect possible mechanisms in neurological consequences of COVID-19 [Reference Chen23, Reference Chen53Reference Sullivan and Fischer59, Reference Reza-Zaldívar62Reference Whittaker, Anson and Harky65].

It has been supposed that the neurotropic potential of the COVID-19 is closely related to the development of a systemic inflammatory response syndrome (SIRS) [Reference Liguori58]. SIRS mediates the release of inflammatory cytokines (cytokine storm) and free radicals, which affect the central and peripheral nervous system. As a consequence of a cytokine storm [cytokines (e.g., IL-6, IL-1TNF-α, IL-1β, IFN-γ, IL-4, IL-10)], glial cells will be activated [Reference Chen53, Reference Wenting54]. This activation can induce a pro-inflammatory state which is positively correlated with the severity of neurological symptoms [Reference Almutairi69]. Encephalitis and encephalopathy have been related to a rise in the levels of proinflammatory cytokines and antioxidants based on two clinical studies [Reference Studart-Neto70, Reference Iltaf71]. On the other hand, headache has less been associated with mortality since patients with headaches have experienced less cellular effectors related to cytokine storm, including D-dimer and ferritin [Reference Trigo72].

Another detrimental effect of coronaviruses is hypoxia injury that caused by lung tissue lesions. This, in turn, leads to subsequent nervous system damage such as interstitial oedema and encephalopathy. Moreover, headache due to ischaemia, congestion and even coma can be observed [Reference To7]. Interestingly, hypoxia has been implicated in the tau hyperphosphorylation in Alzheimer's. Furthermore, increased ACE expression in brain of Alzheimer's patients suggests that COVID-19 may contribute the incidence of this neurodegenerative disease as well [Reference Ding73, Reference Quincozes-Santos74].

A review of current published literatures has indicated that coagulation dysfunction was another indirect mechanism in case of neuroinvasive potential of SARS-CoV2. Coagulopathy, including elevated D-dimer levels, prolonged prothrombin time, decreased platelet counts, elevated PAI-1 and Von Willebrand factor (VWF) have been highlighted in severe cases [Reference Chen23, Reference Chen53Reference Sullivan and Fischer59, Reference Reza-Zaldívar62Reference Whittaker, Anson and Harky65]. It may render these patients prone to ischaemic strokes and other cerebrovascular events [Reference Wenting54].

To put these findings together, understanding the neurotropic characteristics of SARS-CoV-2 is substantial to individualise and prioritise the treatment protocols in the context of patients with COVID-19. However, more studies are needed to clarify the underlying mechanism of neuropathogenicity of the new coming virus.

Cutaneous manifestations

Cutaneous manifestations of COVID-19 are heterogeneous and occur in 1–20% of cases. Many studies classify them into five general categories, which are summarised in Table 1 [Reference Novak75, Reference Farinazzo76]. Overall, the spike protein of SARS-CoV-2 enters the skin through ACE2 receptors on the surface of epithelial cells, keratinocytes, endothelial vessels and eccrine glands that can directly damage them [Reference Colmenero77]. Upon virus entry, innate immunity is activated to prevent viral replication and plasmacytoid dendritic cells (pDCs) establish synapse with infected cells and upregulate toll-like receptor 7 (TLR7) and release the type-I interferons (IFNI) [Reference Cappel, Cappel and Wetter78, Reference Assil79]. Indeed, TLRs sense pathogen-associated molecular patterns (PAMPs) such as single-stranded RNA, unmethylated double-stranded DNA (CpG), lipoproteins, flagellin and lipopolysaccharide that induce the secretion of inflammatory cytokines [Reference Lim and Staudt80]. In chronic infections and autoimmune diseases, pDCs are constantly activated and participate in the pathogenesis through IFNI overactivity [Reference Barrat and Su81]. Thus, the most skin lesions, including erythematous/vesicular /urticarial rashes, are those that are also common in other viral infections (e.g. Herpesviridae). Additionally, some legions may either be exacerbated by co-infection/reactivation of SARS-CoV-2 with other viruses or by a drug-induced reaction; however, a combination of the two is also possible [Reference Novak75, Reference Farinazzo76, Reference Maldonado, Romero-Aibar and Pérez-San-Gregorio82].

Table 1. The classification of common skin lesions based on their target groups, frequency, COVID-19 severity, timing and mechanisms

DHR, drug hypersensitivity reaction; IgE, immunoglobulin E.

The other two types of eruptions are of vascular origin: (1) chilblain- or pernio-like and (2) ischaemic types such as livedoid racemosa, retiform purpura and acral ischaemia. A histopathological study shows the perivascular and perieccrine infiltration of T lymphocytes and pDCs in these legions [Reference Cappel, Cappel and Wetter78]. Chilblain-like is a late-onset eruption, thus PCR may be negative, that may exhibit in young people with mild and asymptomatic COVID-19 through IFNI responses and an endothelial dysfunction. Since youngers have stronger innate immune systems; they can inhibit the virus without activating acquired immunity, resulting in negative antibody tests [Reference Gallman and Fassett83]. Nevertheless, the ischaemic legions are related to hypercoagulability and complement deposition in elderly with severe COVID-19. In critical COVID-19, the impairment of IFNI responses downregulates ACE2, shifting the RAAS toward ANGII. ANGII in turn stimulates T cells to increase the expression of AT1R [Reference Cappel, Cappel and Wetter78, Reference Herrada84]. The ANGII-AT1R binding causes an increase in aldosterone and mineralocorticoid receptors on the surface of DC cells, leading to the production of pro-inflammatory cytokines (such as IL-6) and further recalling macrophage and monocyte into the inflammatory sites of skin [Reference Cappel, Cappel and Wetter78]. Furthermore, in ischaemic lesions of patients with pulmonary thromboembolism, complement induces thrombotic microvascular injury through mannan binding lectin (MBL) pathways [Reference Magro85, Reference Eriksson86]. In other words, the viral spike glycoproteins enter directly into ACE2-containing cells and through their glycan moiety interact with MBL, activating it to increase IL6, followed by platelet aggregation and complement deposition [Reference Magro85]. In Chilblain, however, an increase in IFN1 upregulates ACE2 and its vasoprotective mechanism via shifting the RAAS toward ANG1–7, resulting in only an impermanent acral vasospasm [Reference Cappel, Cappel and Wetter78, Reference Gallman and Fassett83]. Both vasospasm and thrombotic states can also mediate a local hypoxia in the cutaneous vasculature, which inhibit the regulatory T cells and their anti-inflammatory checkpoints by stimulating Hypoxia-inducible factor 1-alpha and induce a cutaneous endothelial dysfunction [Reference Dang87, Reference Jahani, Dokaneheifard and Mansouri88]. Ethnic, age, gender, hormonal and genetic factors can also affect the skin pathogenesis of COVID-19 by interfering with any of these pathways [Reference Cappel, Cappel and Wetter78, Reference Gallman and Fassett83].

Moreover, the humoral immunity dysregulation induced by COVID-19 can produce autoantibodies (including antiphospholipid antibodies), which may cause skin lesions through inducing an autoimmune reaction mediated by molecular mimicry, immune complex-trigged inflammation and prothrombotic state [Reference Gallman and Fassett83]. In one study, the injection of purified IgG from COVID-19 cases into thrombotic mice could accelerate thrombus formation [Reference Zuo89]. This is probably the mechanism by which multisystem inflammatory syndrome develops cutaneous and organ damages in children after 4–6 weeks of COVID-19. More importantly, the activation of antibody-secreting cells needs several weeks, thus autoantibody-mediated lesions usually are a late-onset outcome [Reference Consiglio90].

Overall, the reviewed studies show that there is a link between skin manifestations and COVID-19, but whether SARS-CoV-2 is the cause of other underlying conditions is still unclear and needs further investigation.

Coagulopathic disorders

COVID-19 patients are also at emerging risk of thrombosis disorder. Two meta-analysis studies showed that the rates of the deep vein thrombosis, pulmonary embolism and arterial thrombus were 19.8%, 18.9% and 3.7%, respectively [Reference Di Minno91, Reference Klok92]. Moreover, thrombogenesis was highly associated with the mortality so that 50% of nonsurvivors have shown a procoagulant state, while only 7% of survivors have presented this symptom [Reference Levi93]. Strikingly, thrombosis is a part of the innate immune reaction to pathogens that is called immunothrombosis [Reference Shaw94, Reference Engelmann and Massberg95]. Neutrophil activation with neutrophil extracellular traps (NETOSIS), endothelial cell lesion and activation, as well as platelet activation and aggregation, altogether with coagulation protease activation, take a part in the process of immunothrombosis, particularly in lung [Reference Shaw94, Reference Frantzeskaki, Armaganidis and Orfanos96]. In addition, PAMPs, damage-associated molecular patterns (DAMPs), along with extracellular histones and DNA, have recently been considered in immunothrombosis. PAMPs and DAMPs raise TF explanation on monocytes and stimulate the process of Neutrophil extracellular traps (NETs) so that, immunothrombosis is induced [Reference Shaw94, Reference Ito97, Reference Gould, Lysov and Liaw98]. Cell-free DNA and extracellular histones are the important parts of NETs which are secreted from dead cells, and they increase the inflammation and induce the thrombosis via damaging fibrinolysis, raising thrombin production and stimulating platelet activation [Reference Shaw94, Reference Gould, Lysov and Liaw98, Reference Alhamdi and Toh99]. Based on clinical studies, the severity of COVID-19 is a key factor to increase the level of NETs in blood, tracheal aspirates and different organs of patients [Reference Veras100Reference Schurink102].

It has been offered that high fibrin degradation product levels (called D-dimer), long prothrombin time (PT), activated partial thromboplastin times, reduction in platelet counts, raised levels of fibrinogen, are commonly occurred in COVID-19 patients during thrombosis [Reference Shaw94]. A considerable elevation of factors v, viii; and VWF has also been indicated in intense COVID-19 patients. Furthermore, high plasma levels of VWF antigen and pro-peptide are revealed in severe COVID-19 which they are indicative of endothelial stimulation as well as injury by secretion of VWF from Weibel-Plade bodies [Reference Shaw94, Reference Goshua103]. In a study in 2020, Goshua et al. evaluated COVID-19 associated coagulopathy. They indicated that P_selectin and VWF antigen (markers of endothelial cell and platelet activation), as well as soluble thrombomodulin (a marker of endothelial cell activation) were significantly increased in ICU patients in comparison with non-ICU patients. In addition, they reported mortality to be significantly related to soluble thrombomodulin and VWF antigen among all patients [Reference Goshua103].

Platelets release VWF cumulative in α-granules just till activation. ADAMTS-13 (a disintegrin and metalloproteinase with a thrombospondin type 1 motif, member 13) is expressed by hepatic stellate and endothelial cells [Reference Bryckaert104, Reference Zheng105]. ADAMTS-13 controls the activation of VWF via excision of ultra-large VWF multimers (> 10 000 KDa) which are released from endothelial cells into active high molecular weight multimers (< 10 000 KDa) under stress states [Reference Stockschlaeder, Schneppenheim and Budde106]. Intense deficiency of ADAMTS-13 results in accumulation of ultra-large VWF multimers and causes microvascular thrombosis, thrombocytopenia and thrombotic thrombocytopenic purpura (TTP) [Reference Katneni107]. A mechanism that notably contributes in ADAMTS-13 deficiency is linked to the antiphospholipid antibody production within SARS-CoV-2 infection [Reference Helms108Reference Bowles111]. Antiphospholipid antibodies have been incompatibility announced in all patients of COVID-19 [Reference Helms108, Reference Galeano-Valle110, Reference Bowles111]. Despite, the prolongation of aPTT [Reference Bowles111], the patients with antiphospholipid syndrome have unusual ADAMTS-13 plasmatic activity, so that, an increased risk of thrombosis is seen [Reference Austin112]. Antiphospholipid antibodies during active SARS-CoV-2 infection maybe attach the spacer domain of ADAMTS-13 which can intervene in the identification and proteolysis of VWF [Reference Katneni113]. In this regard, studies reported that COVID-19 nonsurvivors have shown higher VWF and lower ADAMTS13 compared with survivors [Reference Bazzan114, Reference Marco and Marco115].

Overall it can be seen that TLRs-3 and −7 are activated by the viral RNA to induce the NF-κB Pathway and the interferon regulatory factors, that they raise the production and release of pro-inflammatory cytokines [Reference Shaw94]. This pro-inflammatory condition has been seen in several viral diseases such as influenza and SARS-CoV-2 [Reference Katneni113]. The elevation of these pro-inflammatory cytokines such as IL-1, IL-6 and TNFα can promote thrombosis [Reference Goshua103]. So that, inflammatory cytokines (IL-8 and TNF- α) cause the secretion of VWF from human endothelial cells and then VWF binds to NETs to induce thrombosis [Reference Katneni113]. Moreover, proinflammatory situation is influential on haemostasis by blocking of fibrinolysis [Reference Katneni113]. Also increased levels of myeloperoxidase as a NET-linked marker have been demonstrated in COVID-19 patients [Reference Shaw94]. More importantly, the interaction among complement activation, inflammation and the coagulation cascade is seen to be crucial to understanding the COVID-19 pathophysiology and is involved to triggering disseminated intravascular coagulation [Reference Dolhnikoff116]. Membrane attack complex (C5b-9) and C3a are both responsible for platelet activation. Moreover, C5a increases cellular and plasma TF expression [Reference Fletcher-Sandersjöö and Bellander117]. Moreover, it has been established that considerable hypoxaemia in COVID-19 patients is caused in prothrombotic conditions through stimulation of endothelial synthesis of procoagulants, upregulation of plasminogen activator inhibitor and releasing tissue factor and VWF as well [Reference Katneni113].

On the other hand, a large number of patients with non-valvular atrial fibrillation who use direct oral anticoagulants (DOACs) (to prevent systemic embolism and stroke) may be treated with antiviral drugs (lupinavid/rynovid, varonavid), cloquine or hydroxychloroquine, antibiotics and tocilizumab for the treatment of severe respiratory syndrome caused by COVID-19 [Reference Testa118]. Since both DOACs and antiviral drugs are substrates of cytochrome P450-based metabolic pathways; the simultaneous use of these two drugs can greatly elevate the plasma level of DOACs and lead to an increased risk of uncontrolled bleeding and thrombotic complications [Reference Testa118, Reference Schutgens119].

In conclusion, hypercoagulability, as a noticeable feature of COVID-19, can cause thrombotic vascular events. Several mechanisms may be involved in the occurrence of the thrombosis, such as inflammatory storm, renin angiotensin system dysregulation and uncontrolled inflammation-mediated endothelial injury. However, to get a better understanding of COVID-19, more studies are needed.

Conclusions

Regarding the significance of control of COVID-19-related complications after recovery, the current study has summarised to review the cellular and molecular mechanisms linking COVID-19 to some long-term symptoms including renal, cardiac, cutaneous, neurological and coagulopathic complications. As mentioned earlier, this virus can directly influence on the cells through ACE-2 to induce cytokine storm to increase the risk of heart failure and thrombosis. On the other hand, the virus can damage the blood–brain barrier by increasing its permeability and subsequently enters into the CNS and the systemic circulation. Furthermore, SARS-induced ACE2-deficiency decreases desArg9-BK degradation in kidneys to induce inflammation, thrombotic problems, fibrosis and necrosis. Notably, the ANGII-AT1R binding causes an increase in aldosterone and mineralocorticoid receptors on the surface of DC cells, leading to recalling macrophage and monocyte into inflammatory sites of skin. All the pathways play a key role in the pathogenesis of these disturbances and physicians should be aware in their attention to all these complications and take precision steps for control, screening and even cure. Nevertheless, more investigations are necessary to determine more pathogenetic mechanisms of the virus.

Acknowledgements

Not applicable.

Author's contributions

RA and SHA were the leader in the current study and revised the manuscript. YJ, MD and SS contributed to the conception and drafting of the manuscript, DAL, SS contributed to the conception and writing of the manuscript. KM designed figures and contributed to writing the manuscript. All authors have read and approved the final manuscript.

Financial support

Not applicable.

Conflict of interest

The authors declare that they have no competing interests.

Ethical standard

Not applicable.

Consent for publication

Not applicable.

Data availability statements

Not applicable.

References

Mitsuyama, K et al. (2020) Clinical features and pathogenic mechanisms of gastrointestinal injury in COVID-19. Journal of Clinical Medicine 9, 3630.CrossRefGoogle ScholarPubMed
Mandal, A et al. (2020) Gastrointestinal manifestations in COVID-19 infection and its practical applications. Cureus 12, 8750.Google ScholarPubMed
Nami, M et al. (2020) The interrelation of neurological and psychological symptoms of COVID-19: risks and remedies. Journal of Clinical Medicine 9, 2624.CrossRefGoogle ScholarPubMed
van Vuren, EJ et al. (2021) The neuropsychiatric manifestations of COVID-19: interactions with psychiatric illness and pharmacological treatment. Biomedicine & Pharmacotherapy 135, 111200.CrossRefGoogle Scholar
Bodnar, B et al. (2021) Cellular mechanisms underlying neurological/neuropsychiatric manifestations of COVID-19. Journal of Medical Virology 93, 19831998.CrossRefGoogle ScholarPubMed
Mihalopoulos, M et al. (2020) COVID-19 and kidney disease: molecular determinants and clinical implications in renal cancer. European Urology Focus 6, 10861096.CrossRefGoogle ScholarPubMed
To, KK-W et al. (2020) Consistent detection of 2019 novel coronavirus in saliva. Clinical Infectious Diseases 71, 841843.CrossRefGoogle ScholarPubMed
Lopez-Leon, S et al. (2021) More than 50 long-term effects of COVID-19: a systematic review and meta-analysis. Scientific reports 11, 112.CrossRefGoogle ScholarPubMed
Hoffmann, M et al. (2020) SARS-CoV-2 cell entry depends on ACE2 and TMPRSS2 and is blocked by a clinically proven protease inhibitor. Cell 181, 271280.CrossRefGoogle ScholarPubMed
Singh, H et al. (2021) ACE2 and TMPRSS2 polymorphisms in various diseases with special reference to its impact on COVID-19 disease. Microbial Pathogenesis 150, 104621.CrossRefGoogle ScholarPubMed
Ahmadian, E et al. (2021) COVID-19 and kidney injury: pathophysiology and molecular mechanisms. Reviews in Medical Virology 31, 2176.CrossRefGoogle ScholarPubMed
Silva, MJA et al. (2022) Innate immunity to SARS-CoV-2 infection: a review. Epidemiology & Infection 150, 149.CrossRefGoogle ScholarPubMed
Faour, WH et al. (2021) Mechanisms of COVID-19-induced kidney injury and current pharmacotherapies. Inflammation Research 71, 118.Google ScholarPubMed
de Carvalho, PR, Sirois, P and Fernandes, PD (2021) The role of kallikrein-kinin and renin-angiotensin systems in COVID-19 infection. Peptides 135, 170428.CrossRefGoogle Scholar
Quadri, SS et al. (2016) Interaction of the renin angiotensin and Cox systems in the kidney. Frontiers in Bioscience (Scholar Edition) 8, 215.Google ScholarPubMed
Culver, S, Li, C and Siragy, HM (2017) Intrarenal angiotensin-converting enzyme: the old and the new. Current Hypertension Reports 19, 17.CrossRefGoogle ScholarPubMed
Chen, A et al. (2021) Similarities and differences between COVID-19-associated nephropathy and HIV-associated nephropathy. Kidney Diseases 8, 112.CrossRefGoogle ScholarPubMed
Ye, M et al. (2006) Glomerular localization and expression of angiotensin-converting enzyme 2 and angiotensin-converting enzyme: implications for albuminuria in diabetes. Journal of the American Society of Nephrology 17, 30673075.CrossRefGoogle ScholarPubMed
Marceau, F (1995) Kinin B1 receptors: a review. Immunopharmacology 30, 126.CrossRefGoogle ScholarPubMed
Donoghue, M et al. (2000) A novel angiotensin-converting enzyme–related carboxypeptidase (ACE2) converts angiotensin I to angiotensin 1–9. Circulation Research 87, e1e9.CrossRefGoogle ScholarPubMed
Vahdat, S (2022) Clinical profile, outcome and management of kidney disease in COVID-19 patients–a narrative review. European Review for Medical and Pharmacological Sciences 26, 21882195.Google ScholarPubMed
Passoni, R et al. (2021) Occurrence of acute kidney injury in adult patients hospitalized with COVID-19: a systematic review and meta-analysis. Nefrología 42, 404414.CrossRefGoogle ScholarPubMed
Chen, T et al. (2020) Clinical characteristics of 113 deceased patients with coronavirus disease 2019: retrospective study. Bmj 368, 1091.CrossRefGoogle ScholarPubMed
Zhou, F et al. (2020) Clinical course and risk factors for mortality of adult inpatients with COVID-19 in Wuhan, China: a retrospective cohort study. The Lancet 395, 10541062.CrossRefGoogle ScholarPubMed
Hoffmann, S et al. (2004) Angiotensin II type 1 receptor overexpression in podocytes induces glomerulosclerosis in transgenic rats. Journal of the American Society of Nephrology 15, 14751487.CrossRefGoogle ScholarPubMed
Liakopoulos, V et al. (2021) COVID-19 and the kidney: time to take a closer look. International Urology and Nephrology 54, 15.Google Scholar
Legrand, M et al. (2021) Pathophysiology of COVID-19-associated acute kidney injury. Nature Reviews Nephrology 17, 751764.CrossRefGoogle ScholarPubMed
Kaur, A et al. (2022) Renovascular complications in Covid19: a systematic review. International Journal of Early Childhood 14, 2022.Google Scholar
Diao, B et al. (2021) Human kidney is a target for novel severe acute respiratory syndrome coronavirus 2 infection. Nature Communications 12, 19.CrossRefGoogle ScholarPubMed
Ferlicot, S et al. (2021) The spectrum of kidney biopsies in hospitalized patients with COVID-19, acute kidney injury and/or proteinuria. Nephrology Dialysis Transplantation 36, 12531262.CrossRefGoogle Scholar
Welsh, P et al. (2019) Cardiac troponin T and troponin I in the general population: comparing and contrasting their genetic determinants and associations with outcomes. Circulation 139, 27542764.CrossRefGoogle Scholar
Pratistha, FSM et al. (2022) Systematic review of cardiovascular manifestations in COVID-19 and management consideration. Open Access Macedonian Journal of Medical Sciences 10, 332339.CrossRefGoogle Scholar
Pranata, R, Huang, I and Raharjo, SB (2020) Incidence and impact of cardiac arrhythmias in coronavirus disease 2019 (COVID-19): a systematic review and meta-analysis. Indian Pacing and Electrophysiology Journal 20, 193198.CrossRefGoogle ScholarPubMed
Mitrani, RD, Dabas, N and Goldberger, JJ (2020) COVID-19 cardiac injury: implications for long-term surveillance and outcomes in survivors. Heart Rhythm 17, 19841990.CrossRefGoogle ScholarPubMed
Khan, I et al. (2020) At the heart of COVID-19 [published online ahead of print May 5, 2020]. Journal of Cardiac Surgery 72, 799–404.Google Scholar
Guo, J et al. (2020) Coronavirus disease 2019 (COVID-19) and cardiovascular disease: a viewpoint on the potential influence of angiotensin-converting enzyme inhibitors/angiotensin receptor blockers on onset and severity of severe acute respiratory syndrome coronavirus 2 infection. Journal of the American Heart Association 9, e016219.CrossRefGoogle ScholarPubMed
Xu, Z et al. (2020) Pathological findings of COVID-19 associated with acute respiratory distress syndrome. The Lancet Respiratory Medicine 8, 420422.CrossRefGoogle ScholarPubMed
Tajbakhsh, A et al. (2021) COVID-19 and cardiac injury: clinical manifestations, biomarkers, mechanisms, diagnosis, treatment, and follow up. Expert Review of Anti-infective Therapy 19, 345357.CrossRefGoogle ScholarPubMed
Zheng, Y-Y et al. (2020) COVID-19 and the cardiovascular system. Nature Reviews Cardiology 17, 259260.CrossRefGoogle ScholarPubMed
Huang, C et al. (2020) Clinical features of patients infected with 2019 novel coronavirus in Wuhan, China. The Lancet 395, 497506.CrossRefGoogle ScholarPubMed
Wei, Z and Qian, H (2020) Myocardial injury in patients with COVID-19 pneumonia. Zhonghua xin xue guan bing za zhi 48, E006.Google ScholarPubMed
Wong, C et al. (2004) Plasma inflammatory cytokines and chemokines in severe acute respiratory syndrome. Clinical & Experimental Immunology 136, 95103.CrossRefGoogle ScholarPubMed
Wang, J et al. (2020) Dysfunctional coagulation in COVID-19: from cell to bedside. Advances in Therapy 37, 30333039.CrossRefGoogle Scholar
Sattar, Y et al. (2020) COVID-19 cardiovascular epidemiology, cellular pathogenesis, clinical manifestations and management. IJC Heart & Vasculature 29, 100589.CrossRefGoogle ScholarPubMed
Bhatla, A et al. (2020) COVID-19 and cardiac arrhythmias. Heart Rhythm 17, 14391444.CrossRefGoogle ScholarPubMed
Kochi, AN et al. (2020) Cardiac and arrhythmic complications in patients with COVID-19. Journal of Cardiovascular Electrophysiology 31, 10031008.CrossRefGoogle ScholarPubMed
Babapoor-Farrokhran, S et al. (2020) Myocardial injury and COVID-19: possible mechanisms. Life Sciences 253, 117723.CrossRefGoogle ScholarPubMed
Gao, L et al. (2020) Prognostic value of NT-proBNP in patients with severe COVID-19. Respiratory Research 21, 17.CrossRefGoogle ScholarPubMed
Hu, H-H et al. (2018) New insights into TGF-β/Smad signaling in tissue fibrosis. Chemico-Biological interactions 292, 7683.CrossRefGoogle ScholarPubMed
Carlson, FR Jr et al. (2020) Multiorgan damage in patients with COVID-19: is the TGF-β/BMP pathway the missing link? Basic to Translational Science 5, 11451148.CrossRefGoogle ScholarPubMed
Peterson, CJ, Sarangi, A and Bangash, F (2021) Neurological sequelae of COVID-19: a review. The Egyptian Journal of Neurology. Psychiatry and Neurosurgery 57, 18.Google Scholar
Mahdizade Ari, M et al. (2022) Neurological manifestations in patients with COVID-19: a systematic review and meta-analysis. Journal of Clinical Laboratory Analysis 36, e24403.CrossRefGoogle ScholarPubMed
Chen, X et al. (2021) A systematic review of neurological symptoms and complications of COVID-19. Journal of Neurology 268, 392402.CrossRefGoogle ScholarPubMed
Wenting, A et al. (2020) COVID-19 neurological manifestations and underlying mechanisms: a scoping review. Frontiers in Psychiatry 11, 860.CrossRefGoogle ScholarPubMed
Lechien, JR et al. (2020) Olfactory and gustatory dysfunctions as a clinical presentation of mild-to-moderate forms of the coronavirus disease (COVID-19): a multicenter European study. European Archives of Oto-Rhino-Laryngology 277, 22512261.CrossRefGoogle ScholarPubMed
Baig, AM et al. (2020) Evidence of the COVID-19 virus targeting the CNS: tissue distribution, host–virus interaction, and proposed neurotropic mechanisms. ACS Chemical Neuroscience 11, 995998.CrossRefGoogle ScholarPubMed
Tandon, M et al. (2021) A comprehensive systematic review of CSF analysis that defines neurological manifestations of COVID-19. International Journal of Infectious Diseases 104, 390397.CrossRefGoogle ScholarPubMed
Liguori, C et al. (2020) Subjective neurological symptoms frequently occur in patients with SARS-CoV2 infection. Brain, Behavior, and Immunity 88, 1116.CrossRefGoogle ScholarPubMed
Sullivan, BN and Fischer, T (2021) Age-associated neurological complications of COVID-19: a systematic review and meta-analysis. Frontiers in Aging Neuroscience 13, 374.CrossRefGoogle ScholarPubMed
Radwan, N et al. (2022) Neurological associations Among COVID-19 patients: a systematic review and meta-analysis. Dr Sulaiman Al Habib Medical Journal 4, 111.CrossRefGoogle Scholar
Ali, SS et al. (2022) New-onset Parkinsonism as a COVID-19 infection sequela: a systematic review and meta-analysis. Annals of Medicine and Surgery 80, 104281.CrossRefGoogle ScholarPubMed
Reza-Zaldívar, EE et al. (2021) Infection mechanism of SARS-COV-2 and its implication on the nervous system. Frontiers in Immunology 11, 3738.CrossRefGoogle ScholarPubMed
Desforges, M et al. (2020) Human coronaviruses and other respiratory viruses: underestimated opportunistic pathogens of the central nervous system? Viruses 12, 14.CrossRefGoogle Scholar
Guillaud, L et al. (2020) Anterograde axonal transport in neuronal homeostasis and disease. Frontiers in Molecular Neuroscience 13, 179.CrossRefGoogle ScholarPubMed
Whittaker, A, Anson, M and Harky, A (2020) Neurological manifestations of COVID-19: a systematic review and current update. Acta Neurologica Scandinavica 142, 1422.CrossRefGoogle ScholarPubMed
Fodoulian, L et al. (2020) SARS-CoV-2 receptors and entry genes are expressed in the human olfactory neuroepithelium and brain. IScience 23, 101839.CrossRefGoogle ScholarPubMed
Hernández, VS et al. (2021) ACE2 Expression in rat brain: implications for COVID-19 associated neurological manifestations. Experimental Neurology 345, 113837.CrossRefGoogle ScholarPubMed
Davies, J et al. (2020) Neuropilin-1 as a new potential SARS-CoV-2 infection mediator implicated in the neurologic features and central nervous system involvement of COVID-19. Molecular Medicine Reports 22, 42214226.Google ScholarPubMed
Almutairi, MM et al. (2021) Neuroinflammation and its impact on the pathogenesis of COVID-19. Frontiers in Medicine 8, 745789.CrossRefGoogle ScholarPubMed
Studart-Neto, A et al. (2020) Neurological consultations and diagnoses in a large, dedicated COVID-19 university hospital. Arquivos de Neuro-Psiquiatria 78, 494500.CrossRefGoogle Scholar
Iltaf, S Sr et al. (2020) Frequency of neurological presentations of coronavirus disease in patients presenting to a tertiary care hospital during the 2019 coronavirus disease pandemic. Cureus 12, 17.Google ScholarPubMed
Trigo, J et al. (2020) Factors associated with the presence of headache in hospitalized COVID-19 patients and impact on prognosis: a retrospective cohort study. The Journal of Headache and Pain 21, 110.CrossRefGoogle ScholarPubMed
Ding, Q et al. (2021) Protein expression of angiotensin-converting enzyme 2 (ACE2) is upregulated in brains with Alzheimer's disease. International Journal of Molecular Sciences 22, 1687.CrossRefGoogle ScholarPubMed
Quincozes-Santos, A et al. (2021) Association between molecular markers of COVID-19 and Alzheimer's disease. Journal of Medical Virology 94, 833835.CrossRefGoogle ScholarPubMed
Novak, N et al. (2021) SARS-CoV-2, COVID-19, skin and immunology–what do we know so far? Allergy 76, 698713.CrossRefGoogle ScholarPubMed
Farinazzo, E et al. (2021) Synthesis of the data on COVID-19 skin manifestations: underlying mechanisms and potential outcomes. Clinical, Cosmetic and Investigational Dermatology 14, 991.CrossRefGoogle ScholarPubMed
Colmenero, I et al. (2020) SARS-CoV-2 endothelial infection causes COVID-19 chilblains: histopathological, immunohistochemical and ultrastructural study of seven paediatric cases. British Journal of Dermatology 183, 729737.CrossRefGoogle ScholarPubMed
Cappel, MA, Cappel, JA and Wetter, DA (2021) Pernio (chilblains), SARS-CoV-2, and COVID toes unified through cutaneous and systemic mechanisms. in mayo clinic proceedings. Elsevier 96, 9891005.Google Scholar
Assil, S et al. (2019) Plasmacytoid dendritic cells and infected cells form an interferogenic synapse required for antiviral responses. Cell Host & Microbe 25, 730745, e6.CrossRefGoogle ScholarPubMed
Lim, K-H and Staudt, LM (2013) Toll-like receptor signaling. Cold Spring Harbor Perspectives in Biology 5, a011247.CrossRefGoogle ScholarPubMed
Barrat, FJ and Su, L (2019) A pathogenic role of plasmacytoid dendritic cells in autoimmunity and chronic viral infection. Journal of Experimental Medicine 216, 19741985.CrossRefGoogle ScholarPubMed
Maldonado, MD, Romero-Aibar, J and Pérez-San-Gregorio, M (2021) COVID-19 pandemic as a risk factor for the reactivation of herpes viruses. Epidemiology & Infection 149, e145.CrossRefGoogle ScholarPubMed
Gallman, AE and Fassett, MS (2021) Cutaneous pathology of COVID-19 as a window into immunologic mechanisms of disease. Dermatologic Clinics 39, 533543.CrossRefGoogle ScholarPubMed
Herrada, AA et al. (2010) Aldosterone promotes autoimmune damage by enhancing Th17-mediated immunity. The Journal of Immunology 184, 191202.CrossRefGoogle ScholarPubMed
Magro, C et al. (2021) The skin as a critical window in unveiling the pathophysiologic principles of COVID-19. Clinics in Dermatology 39, 934965.CrossRefGoogle ScholarPubMed
Eriksson, O et al. (2020) Mannose-binding lectin is associated with thrombosis and coagulopathy in critically ill COVID-19 patients. Thrombosis and Haemostasis 120, 17201724.Google ScholarPubMed
Dang, EV et al. (2011) Control of TH17/Treg balance by hypoxia-inducible factor 1. Cell 146, 772784.CrossRefGoogle Scholar
Jahani, M, Dokaneheifard, S and Mansouri, K (2020) Hypoxia: a key feature of COVID-19 launching activation of HIF-1 and cytokine storm. Journal of Inflammation 17, 110.CrossRefGoogle ScholarPubMed
Zuo, Y et al. (2020) Prothrombotic autoantibodies in serum from patients hospitalized with COVID-19. Science Translational Medicine 12, eabd3876.CrossRefGoogle ScholarPubMed
Consiglio, CR et al. (2020) The immunology of multisystem inflammatory syndrome in children with COVID-19. Cell 183, 968981, e7.CrossRefGoogle ScholarPubMed
Di Minno, A et al. (2020) COVID-19 and venous thromboembolism: a meta-analysis of literature studies. in seminars in thrombosis and hemostasis. Thieme Medical Publishers 46, 763771.Google Scholar
Klok, F et al. (2020) Incidence of thrombotic complications in critically ill ICU patients with COVID-19. Thrombosis Research 191, 145147.CrossRefGoogle ScholarPubMed
Levi, M et al. (2020) Coagulation abnormalities and thrombosis in patients with COVID-19. The Lancet Haematology 7, e438e440.CrossRefGoogle ScholarPubMed
Shaw, RJ et al. (2021) COVID-19 and immunothrombosis: emerging understanding and clinical management. British Journal of Haematology 194, 518529.CrossRefGoogle ScholarPubMed
Engelmann, B and Massberg, S (2013) Thrombosis as an intravascular effector of innate immunity. Nature Reviews Immunology 13, 3445.CrossRefGoogle ScholarPubMed
Frantzeskaki, F, Armaganidis, A and Orfanos, SE (2017) Immunothrombosis in acute respiratory distress syndrome: cross talks between inflammation and coagulation. Respiration; International Review of Thoracic Diseases 93, 212225.CrossRefGoogle ScholarPubMed
Ito, T (2014) PAMPS and DAMPs as triggers for DIC. Journal of Intensive Care 2, 19.CrossRefGoogle ScholarPubMed
Gould, T, Lysov, Z and Liaw, P (2015) Extracellular DNA and histones: double-edged swords in immunothrombosis. Journal of Thrombosis and Haemostasis 13, S82S91.CrossRefGoogle ScholarPubMed
Alhamdi, Y and Toh, CH (2016) The role of extracellular histones in haematological disorders. British Journal of Haematology 173, 805811.CrossRefGoogle ScholarPubMed
Veras, FP et al. (2020) SARS-CoV-2–triggered neutrophil extracellular traps mediate COVID-19 pathology. Journal of Experimental Medicine 217, e20201129.CrossRefGoogle ScholarPubMed
Ng, H et al. (2021) Circulating markers of neutrophil extracellular traps are of prognostic value in patients with COVID-19. Arteriosclerosis, Thrombosis, and Vascular Biology 41, 988994.CrossRefGoogle ScholarPubMed
Schurink, B et al. (2020) Viral presence and immunopathology in patients with lethal COVID-19: a prospective autopsy cohort study. The Lancet Microbe 1, e290e299.CrossRefGoogle ScholarPubMed
Goshua, G et al. (2020) Endotheliopathy in COVID-19-associated coagulopathy: evidence from a single-centre, cross-sectional study. The Lancet Haematology 7, e575e582.CrossRefGoogle ScholarPubMed
Bryckaert, M et al. (2015) Of von Willebrand factor and platelets. Cellular and Molecular Life Sciences 72, 307326.CrossRefGoogle ScholarPubMed
Zheng, XL (2015) ADAMTS13 and von Willebrand factor in thrombotic thrombocytopenic purpura. Annual Review of Medicine 66, 211225.CrossRefGoogle ScholarPubMed
Stockschlaeder, M, Schneppenheim, R and Budde, U (2014) Update on von Willebrand factor multimers: focus on high-molecular-weight multimers and their role in hemostasis. Blood Coagulation & Fibrinolysis 25, 206.CrossRefGoogle ScholarPubMed
Katneni, UK et al. (2019) von Willebrand factor/ADAMTS-13 interactions at birth: implications for thrombosis in the neonatal period. Journal of Thrombosis and Haemostasis 17, 429440.CrossRefGoogle ScholarPubMed
Helms, J et al. (2020) High risk of thrombosis in patients with severe SARS-CoV-2 infection: a multicenter prospective cohort study. Intensive Care Medicine 46, 10891098.CrossRefGoogle ScholarPubMed
Lee, SJ et al. (2016) Thrombotic risk of reduced ADAMTS13 activity in patients with antiphospholipid antibodies. Blood Coagulation & Fibrinolysis 27, 907912.CrossRefGoogle ScholarPubMed
Galeano-Valle, F et al. (2020) Antiphospholipid antibodies are not elevated in patients with severe COVID-19 pneumonia and venous thromboembolism. Thrombosis Research 192, 113115.CrossRefGoogle Scholar
Bowles, L et al. (2020) Lupus anticoagulant and abnormal coagulation tests in patients with COVID-19. New England Journal of Medicine 383, 288290.CrossRefGoogle ScholarPubMed
Austin, S et al. (2008) The VWF/ADAMTS13 axis in the antiphospholipid syndrome: ADAMTS13 antibodies and ADAMTS13 dysfunction. British Journal of Haematology 141, 536544.CrossRefGoogle ScholarPubMed
Katneni, UK et al. (2020) Coagulopathy and thrombosis as a result of severe COVID-19 infection: a microvascular focus. Thrombosis and Haemostasis 120, 16681679.Google ScholarPubMed
Bazzan, M et al. (2020) Low ADAMTS 13 plasma levels are predictors of mortality in COVID-19 patients. Internal and Emergency Medicine 15, 861863.CrossRefGoogle ScholarPubMed
Marco, A and Marco, P (2021) Von Willebrand factor and ADAMTS13 activity as clinical severity markers in patients with COVID-19. Journal of Thrombosis and Thrombolysis 52, 497503.CrossRefGoogle ScholarPubMed
Dolhnikoff, M et al. (2020) Pathological evidence of pulmonary thrombotic phenomena in severe COVID-19. Journal of Thrombosis and Haemostasis: JTH 18, 15171519.CrossRefGoogle ScholarPubMed
Fletcher-Sandersjöö, A and Bellander, B-M (2020) Is COVID-19 associated thrombosis caused by overactivation of the complement cascade? A literature review. Thrombosis Research 194, 3641.CrossRefGoogle ScholarPubMed
Testa, S et al. (2020) Direct oral anticoagulant plasma levels’ striking increase in severe COVID-19 respiratory syndrome patients treated with antiviral agents: the Cremona experience. Journal of Thrombosis and Haemostasis 18, 13201323.CrossRefGoogle ScholarPubMed
Schutgens, RE (2021) DOAC in COVID-19: yes or no? HemaSphere 5, e526.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. COVID-19 long-term symptoms. SAE, systemic arterial embolism; MI, myocardial infarction.

Figure 1

Fig. 2. Post-COVID 19 neurological disorders. (1) viral entrance through ACE2 receptor; (2) inflammatory cytokines increase due to activated microglia; (3) SARS-Cov 2 leads to inflammated mitral cells; (4) virus migration through motor proteins such as dynein and kinesin; (5) virus BBB infiltration; (6) virus may cause coagulation; (7) BBB break-down serve as a gate for virus penetration into the brain; (8) virus activates microglial cells; (9) rise in inflammatory cytokines; (10) neuronal death occurrence. TMPRSS2, Transmembrane protease, serine 2; ACE2, Angiotensin-converting enzyme 2; NRP1, neuropilin-1; CD147, cluster of differentiation 147; BBB, blood–brain barrier; WBC, White blood cells; RBC, Red blood cells.

Figure 2

Table 1. The classification of common skin lesions based on their target groups, frequency, COVID-19 severity, timing and mechanisms