The potential impact of nanomedicine on COVID-19-induced thrombosis – Nature.com

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Extensive reports of pulmonary embolisms, ischaemic stroke and myocardial infarctions caused by coronavirus disease 2019 (COVID-19), as well as a significantly increased long-term risk of cardiovascular diseases in COVID-19 survivors, have highlighted severe deficiencies in our understanding of thromboinflammation and the need for new therapeutic options. Due to the complexity of the immunothrombosis pathophysiology, the efficacy of treatment with conventional anti-thrombotic medication is questioned. Thrombolytics do appear efficacious, but are hindered by severe bleeding risks, limiting their use. Nanomedicine can have profound impact in this context, protecting delicate (bio)pharmaceuticals from degradation en route and enabling delivery in a targeted and on demand manner. We provide an overview of the most promising nanocarrier systems and design strategies that may be adapted to develop nanomedicine for COVID-19-induced thromboinflammation, including dual-therapeutic approaches with antiviral and immunosuppressants. Resultant targeted and side-effect-free treatment may aid greatly in the fight against the ongoing COVID-19 pandemic.
The coronavirus disease 2019 (COVID-19) pandemic continues to strain health-care systems globally, with 615.6 million cases and 6.5 million deaths reported worldwide as of September 2022¹. COVID-19 involves the (re)infection with severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), which can result in a variety of symptoms and complications. The impact of this pandemic is likely to be felt for the foreseeable future due to the emergence of new variants of concern such as Delta (B.1.617.2) and Omicron (B.1.1.529) and low vaccination rates in many countries. Particularly detrimental to the mortality associated with SARS-CoV-2 is its tendency to cause a hypercoagulable state, resulting in extensive reports of COVID-19-induced thrombosis², including incident rates as high as 49% in patients admitted to intensive care units³. Reports include arterial, venous and microvascular thrombosis, most commonly resulting in pulmonary embolism, stroke, deep vein thrombosis (DVT) and myocardial infarction, in order of frequency³. A high correlation between thrombotic markers and patient mortality has also been established, indicating that there is a need to improve current treatment approaches². Furthermore, a recent study indicated a substantial long-term risk for cardiovascular disease—including thromboembolisms—in patients with COVID-19, even if hospitalization did not occur⁴. Hence, COVID-19-related thrombosis is likely to remain a major challenge for some time to come.
Several aspects of COVID-19-induced thrombosis make it a unique challenge compared with conventional thrombosis. In non-COVID-19-related thrombosis, coagulation is commonly triggered by the exposure of blood to pro-thrombotic stimulants upon rupture of atherosclerotic plaques, resulting in atherothrombosis. These plaques are often a result of poor diet, lack of exercise and/or smoking⁵. In contrast, COVID-19-related thrombosis occurs relatively frequently in otherwise healthy individuals, suggesting other pathways of activation are to blame⁶. A common theory is that SARS-CoV-2 can infect vascular endothelial cells, causing damage to vascular walls and instigating a systemic immune response, resulting in immunothrombosis (Fig. 1)⁷. It should be noted that the pathophysiology in this schematic, particularly the immune response, is simplified, as several of the signaling pathways are poorly understood as of yet. Regardless, more in-depth accounts have been provided in recently published reviews^7,8.
Thrombosis appears to be a result of endothelial damage caused by SARS-CoV-2 infection stimulating an excessive immune response. It should be noted that the pathways involved are simplified, as they are highly complex and poorly understood as of yet. Following this immune response, formation of a thrombus is stimulated by upregulation of tissue factor (shown in yellow), and activation of platelets. It should be noted that several other coagulation markers are also involved, including von Willebrand factor, factor VIII and tumour necrosis factor-α. Finally, upregulation of plasminogen activator inhibitor-1 (PAI-1) also prevents breakdown of the clot by inhibiting the endogenous thrombolytic pathway. Figure created with BioRender.com.
The current consensus is that the immune response is enacted by three components, namely, systemic inflammation, activation of the complement system and formation of neutrophil extracellular traps (NETs), through a process known as NETosis. Inflammation and complement activation are known to contribute to conventional thrombosis, but the involvement of NETosis appears to be unique to the COVID-19 pathophysiology (Box 1). Together, these processes lead to upregulation of three components—activated platelets, tissue factor and thrombin—which are connected in a positive feedback loop and contribute to thrombogenesis^9,10. Thrombin facilitates cleavage of fibrinogen to form fibrin, which combined with activated platelets and red blood cells (RBCs) forms a thrombus. Hence, their upregulation explains the thrombogenicity of the immune response. Furthermore, breakdown of the blood clots (thrombolysis) is also hindered. Normally, clot degradation is facilitated by cleavage of fibrin to D-dimer by plasmin, as stimulated by tissue plasminogen activator (tPA). However, clinical studies of patients with COVID-19 indicate that thrombolysis is hindered by upregulation of plasminogen activator inhibitor-1, resulting in the thrombolytic system becoming overwhelmed¹¹.
Activation of neutrophils leads to formation of a NET, which involves lysis of the membrane and extracellular excretion of a DNA scaffold lined with antibacterial proteins. This process, known as NETosis, can trap and degrade a wide range of foreign bodies, thus proving vital in the body’s innate immune response¹⁰⁶. Unfortunately, excessive neutrophil activation and subsequent NETosis is frequently observed in patients with COVID-19, with detrimental consequences, including thrombogenesis¹⁰. This activation of neutrophils by SARS-CoV-2 infection occurs through a combination of direct and indirect pathways.
Direct activation involves infection of neutrophils themselves by SARS-CoV-2. Veras et al.¹⁰⁷ showed that this is commonly mediated by binding of the virus to ACE2 followed by internalization, and that inhibition of this pathway decreases NET production significantly. Following infection, pro-NETosis mediators are upregulated intracellularly, including ROS¹⁰⁸, and interleukin-8 via a self-reinforced production loop¹⁰⁹. Directly stimulated NETosis is viral-load dependent; hence, viable SARS-CoV-2, able to replicate intracellularly, causes increased NETosis when compared with an inactivated version of the virus^107,108.
Indirect activation, in contrast, is not strictly viral-load dependent, and may occur through any of three pathways. First, SARS-CoV-2 can activate platelets, which in turn trigger neutrophil activation, through a pathway that may even occur at low viral loads¹¹⁰. Second, infection of epithelial cells and macrophages stimulates production and excretion of proinflammatory mediators from said cells into the extracellular environment, resulting in activation of neutrophil¹¹¹. Finally, overexpression of various antibodies in response to SARS-CoV-2 infection may also stimulate NETosis. Critically, anti-NET antibodies become upregulated, which inhibit NET breakdown in severe COVID-19 cases¹¹².
Following NETosis, the NETs promote recruitment of all three components of the positive feedback loop illustrated in Fig. 1, thereby triggering thrombosis. Thrombin production is initiated by combination of the released DNA with serum factor XII¹¹³ while platelet activation is initiated by histones released as a by-product of the DNA excretion¹¹⁴. Neutrophils are also shown to upregulate tissue-factor expression as a response to complement activation induced by SARS-CoV-2, resulting in NETs with high levels of tissue factor¹⁰. Altogether, these three pro-thrombotic factors stimulate local formation of thrombi with a unique pathophysiology. Conventional pulmonary embolisms commonly result from dislodged thrombi originating from DVT traveling into the lung microvasculature¹¹⁵. In contrast, patients with COVID-19 primarily suffer from pulmonary embolisms with a complete absence of DVT¹¹⁶. This indicates in situ thrombogenesis, which can be explained by the localized formation and adherence of NETs to the site of lung infection. Notably, this altered source of thrombosis probably also affects the make-up of the thrombi. Conventional thrombi causing pulmonary embolisms stemming from DVT generally contain few platelets¹¹⁷. In contrast, the prominent role of platelets in COVID-19-induced thrombosis, and thrombocytopenia (low systemic platelet counts) observed in patients with COVID-19¹¹⁸, indicate that platelets are being incorporated into these thrombi. Hence, alternative treatment options may be applicable to treat this form of pulmonary embolism.
Current clinical treatment of COVID-19-induced thrombosis relies primarily on low-molecular-weight heparin (LMWH) as an anticoagulant¹². LMWH inhibits thrombin activation and subsequent fibrin production, as well as reducing inflammation. Unfortunately, clinical results do not show a consistent benefit, with thrombotic events still occurring despite anticoagulant treatment^13,14. Furthermore, anticoagulants are inefficient at removing pre-existing blood clots. Therefore, alternative treatment options need to be considered to achieve recanalization of (partially) occluded vessels. This process must be fast to limit tissue damage, which occurs rapidly upon occlusion of a blood vessel¹⁵. Surgical interventions such as percutaneous transluminal coronary angioplasty or mechanical thrombectomy may be sufficiently rapid, but remain highly invasive and are limited by the location of the thrombus¹⁶. In particular, thrombi causing pulmonary embolisms, as frequently observed in patients with COVID-19, are complex to reach and are thus rarely removed in such manner. Therefore, calls have been made for administration of thrombolytics as clot-busting therapeutics to treat COVID-19 symptoms¹⁷.
Thrombolytics, such as tPA or urokinase, stimulate plasmin and subsequently the cleavage of fibrin, resulting in degradation of the thrombus. Hence, several thrombolytics (streptokinase, urokinase and alteplase) have been approved for the treatment of pulmonary embolism¹⁸, with the latter also being approved for the treatment of acute ischaemic stroke¹⁹. Clinical reports indicate that administration of thrombolytics is also effective in the context of patients with COVID-19, as they may assist the overwhelmed thrombolytic system^20,21,22. Unfortunately, thrombolytic treatment has limitations, such as the premature degradation of the thrombolytic enzymes by systemic proteolytic enzymes. Most damaging, however, is their substantial haemorrhagic risk²³. To monitor for such disastrous bleeding effects, administration occurs only in hospitals, prolonging the time to treatment and increasing treatment costs. Therefore, there is a critical need to improve the delivery of thrombolytics and reduce their side effects, potentially enabling on-the-spot treatment of patients with COVID-19 experiencing acute thrombotic events.
Nanotechnology has been vital in the ongoing fight against SARS-CoV-2 owing to the successful development and approval of two lipid nanoparticle-based messenger RNA vaccines²⁴. Furthermore, nanomedicine is also a promising strategy towards improving thrombolytic treatment via the delivery of thrombolytics with nanoparticles. Although such an approach is yet to be developed and tested for COVID-19-induced thrombosis due to the novelty of the disease, it has gathered widespread preclinical attention for the treatment of conventional atherothrombosis. Here, incorporation of the thrombolytic agent into nanoparticles enhances the effective dosage by increasing the circulation time and providing protection against premature degradation by systemic enzymes²⁵. Thus, overall dosage may be reduced, mitigating the haemorrhagic risk. In addition, nanoparticles function as a scaffold to introduce further functionality, such as active targeting and responsive drug release without compromising loading capacity, further improving efficacy and reducing side effects^26,27. Preclinical studies in rodents and some large animals such as canines have shown promising results; however, transition to clinical trials has been hampered by safety concerns and poor scalability, which is partially due to complex design. Therefore, this Review aims to highlight design approaches within this field with high translatability, and which may be adapted to the treatment of COVID-19-induced thrombosis.
Thus far, a wide range of nanoparticle systems has been developed for the treatment of acute thrombosis, which can largely be divided into liposomal, polymeric, inorganic and cell-derived nanoparticles (Fig. 2). Of these, liposomes and polymeric nanoparticles have seen the most use. Liposomes have gained widespread interest throughout many disease areas, due to their commercial success, ease of production and ability to incorporate a wide range of therapeutics^28,29. Polymeric nanoparticles, which have also seen commercial success in the form of poly(lactic-co-glycolic acid) (PLGA) nanoparticles, display similar relative ease of production, while providing greater control over drug release than liposomes³⁰, which are prone to leakage and non-specific release due to degradation²⁸. Such solid-core polymeric nanoparticles are limited to surface loading, which reduces their loading capacity and exposes the thrombolytic payload to enzymatic degradation. Hence, polymersomes are of interest, although these vesicle structures provide limited benefits over liposomes yet show increased complexity of production³¹. Inorganic nanoparticles have also become popular, mainly due to their inherent multifunctionality, which enables production of highly sophisticated nanocarriers without increasing the synthesis complexity. Such functionality includes hyperthermia induced by near-infrared radiation³² or magnetic stimulation^33,34, and even accumulation at the site of thrombosis via magnetic guidance³³. Mesoporous inorganic nanomaterials are of particular interest due to their increased drug-loading capacity compared with their solid counterparts. Unfortunately, many inorganic materials require complex surface modification to mitigate toxicity of the raw material, which may still pose a safety risk upon clearance and degradation in the body³⁵.
Strategies with high relevance to the treatment of COVID-19-induced thrombosis are shown. a, A comparison of the nanoparticle types, with benefits and limitations provided as a consideration for the design of clinically relevant thrombolytic nanomedicine. Thrombolytics are depicted as red ovals to indicate the relevant loading approaches. As depicted, the cell-derived vesicles contain endogenous surface receptors and ligands naturally present after production. b–d, Targeted delivery (b) and responsive delivery (c) may also be utilized to further improve efficacy and specificity of thrombolytic therapy for COVID-19-induced thrombosis, which degrades blood clots through stimulation of the thrombolytic pathway (d). Figure created with BioRender.com.
In contrast, cell-derived nanoparticles have gained considerable interest due to their high biocompatibility. This approach is particularly interesting for the treatment of acute thrombosis, as vesicles derived from RBCs or platelets can be used to generate nanoparticles displaying endogenous thrombus-binding proteins, enabling a natural affinity for blood clots^27,36. Such an approach also drastically improves the pharmacokinetics associated with nanoparticle systems. Compared with non-cloaked nanoparticles, RBC-derived and platelet-membrane-derived nanoparticles showed 3 and 1.5 times longer circulation times, respectively, which may be highly beneficial to extend the thrombolytic effect³⁶. Chen et al.³⁶ indicated this may be due to reduced elimination of these membrane-derived vesicles through the reticuloendothelial system, as macrophage uptake was decreased by 69.0% (RBC cloaked) and 70.2% (platelet cloaked). Unfortunately, the production of such endogenously derived vesicles at large scale is still challenging, limiting their translational potential³⁷.
As an alternative to mimicking the membrane physiology of endogenous cells, Colasuonno et al.²⁵ aimed to instead mimic their physical structure by utilizing more scalable polymeric nanoparticles. Specifically, RBCs were mimicked, as these cells have a long circulation time and can pass through even the smallest capillaries despite their large size due to their soft, discoidal shape. Thus, the authors produced soft, discoidal tPA-conjugated polymeric nanostructures²⁵. These nanostructures showed superior thrombolytic efficacy in vivo over spherical nanoparticles, reducing more blood clots and to a greater extent. This was conceivably due to improved adhesion to the blood clots combined with longer circulation times²⁵. Liver and kidney accumulation of the discoidal nanoconstructs was comparatively lower, indicating elimination via the reticuloendothelial system is affected by the shape of the nanoparticles²⁵. Due to these promising results, together with its scalability, this approach may have high translational potential, although its efficacy in COVID-19 models remains to be tested.
Finally, a vital consideration in the design of nanomedicine for COVID-19-induced thrombosis is their ability to stimulate NETosis. Several papers have reported nanoparticle-induced NETosis, which may aggravate the thrombogenic nature of the SARS-CoV-2 infection. Thus far, nanoparticle-induced NETosis has been reported for nanoparticles based on silver³⁸, gold^39,40, iron oxide^41,42, manganese oxide⁴¹, graphene oxide⁴³, cationic lipids⁴⁴, polystyrene⁴⁵ and nanodiamonds⁴⁵, although further research may reveal other materials exhibiting similar behaviour. There is as-of-yet contention over whether this is caused by the nanoparticles themselves or their dissolution products⁴⁶. Several studies have reported that smaller nanoparticles (<100 nm) are more prone to inducing NETosis than larger nanoparticles, supposedly due to their increased surface-area-to-volume ratio^39,45. Hence, NETosis may be mitigated by increasing the particle size. Surface functionalization with biocompatible layers of human serum albumin or dextran has also been shown to reduce the NET-generating properties of iron oxide nanoparticles⁴², providing another strategy for minimizing NETosis. Interestingly, several papers have indicated that the addition of polyethylene glycol—which is normally seen as highly biocompatible—does not reduce NETosis⁴⁰, and may even aggravate it⁴¹. Due to these variabilities, it is suggested that nanomedicines designed to treat COVID-19-induced thrombosis are optimized and tested pre-clinically for their ability to generate NETosis, to avoid potential pro-thrombotic effects.
In general, nanoparticles are cleared by the liver and spleen and accumulation at the site of thrombosis is limited, reducing their efficacy and specificity. Micrometre-sized particles may be used instead, as these particles can accumulate in the microvasculature of the lungs, treating localized thrombosis and thromboinflammation. However, caution must be exercised as microparticles >10 μm are able to occlude lung capillaries⁴⁷. Localized accumulation of nanoparticles may be achieved through decoration of the particles with ligands with affinity for components of the thrombi, which has widely been investigated for treatment of conventional atherothrombosis (Table 1). As these components also play a central role in COVID-19-induced thrombosis, decoration of nanoparticles with such ligands may be highly beneficial. It should be noted that the functional optimization of active targeting is complex; for example, a study showed that only 3.5% of proteins conjugated to a particle had an appropriate orientation for receptor recognition⁴⁸, and that the ligand surface density can affect targeting too⁴⁹. Furthermore, the addition of targeting ligands adds complexity; hence, scalability must be considered to ensure high translational potential.
To avoid this added complexity, therapeutics with inherently high affinity for thrombi may be utilized. For instance, the previously discussed discoidal polymeric nanostructures include tPA conjugated to the surface, where tPA’s notable affinity for fibrin and multivalent adhesive interactions have been suggested to contribute to an improved thrombolytic efficacy²⁵. Alternatively, LMWH, which has seen widespread clinical use in the treatment of COVID-19-induced thrombosis, selectively targets P-selectin on activated platelets, and provides effective targeting when applied to nanomedicine⁵⁰. Fucoidan, a complex polysaccharide derived from algae with anticoagulant properties, displays two orders of magnitude higher affinity for the same target (dissociation constant K_d = 1.2 × 10^–9 M)⁵¹. This, in combination with its Food and Drug Administration (FDA) approval, sparked the use of fucoidan in several thrombus-targeted nanoparticle systems, including poly(isobutylcyanoacrylate) nanoparticles⁵², manganese oxide⁵³ and mesoporous silica-coated gold nanorods⁵⁴.
Small peptides to target fibrin or activated platelets have been utilized by several groups, due to their ease of scalability and low immunogenicity⁵⁵. However, the greatest targeting efficiency was observed when a synergistic approach combining multiple ligands was applied. For example, decorating liposomes with both platelet- and fibrin-binding peptides enhanced their thrombus-anchorage efficacy compared with using only one of them⁵⁶. Interestingly, at high (beyond 5 mol%) total ligand density, the clot-anchorage capability decreased, indicating ligand conjugation must be optimized to ensure high targeting affinity⁵⁷. Combining a fibrin-binding peptide with an activatable cell-penetrating peptide also improved targeting efficacy and especially promoted penetration into the thrombus⁵⁸. Unfortunately, peptides often have poor proteolytic stability and have in general a lower affinity compared with, for instance, antibodies.
Due to the favourable high affinity of antibodies, several groups have explored the use of antibodies, seeing preclinical success also in large animal models. In a canine model, conjugation of an anti-fibrin monoclonal antibody (K_d = 1.0 × 10^–9 M) to a perfluorocarbon nanoparticle resulted in increased accumulation at the thrombus⁵⁹. In addition, a single-chain antibody was developed for activated αIIb/β3 using phage display⁶⁰ and poly(2-oxazoline)-based polymer capsules modified with this antibody were found to specifically target activated platelets⁶¹. Again, optimization of the conjugation of the ligands onto the nanoparticles is essential, including consideration of (1) the conjugation site of the linker to preserve affinity and warrant correct orientation, and (2) the density of the antibody on the nanoparticle surface⁶². Although production of antibodies is dearer than small peptides, scalability is not an issue, as evident from their considerable therapeutic market share⁶³.
As previously mentioned, the use of endogenously derived membranes in nanoparticles affords the benefit of inherent targeting capabilities, while also providing extended pharmacokinetic profiles. To this end, platelet and RBC membranes are both of interest; hence, their targeting capabilities were compared in two separate studies^27,36. Interestingly, Xu et al.²⁷ found that platelet membranes provided superior thrombus targeting, whereas Chen et al.³⁶ indicated that RBC membranes had higher affinity. This discrepancy can be attributed to the activation status of the platelet membranes, which varied between the studies, their affinity following activated platelets > RBC > inactivated platelets. As 81% of platelet membrane proteins are preserved in the coating, one might expect use of such activated platelet membranes may worsen thrombosis due to the activation of thrombogenesis²⁷. However, despite the presence of adhesion-associated proteins αIIb/β3, CD62p and P-selectin, no effect on aggregation of other platelets was observed²⁷. Nonetheless, it is critical to consider the source of platelet membrane to prevent potential (allogeneic) immune response. Finally, the therapeutic agent must also be considered. For instance, the Gong group utilized RBC-coated nanoparticles, as the incorporated drug (tirofiban) is an antagonist of the platelet αIIb/β3 receptor and could potentially compromise the targeting capability of an activated platelet membrane⁶⁴.
The vital role of neutrophils in the COVID-19 thrombotic pathophysiology makes this is another target of high interest. A neutrophil-targeting approach is particularly interesting for early treatment, as the thrombus does not need to be formed yet for this targeting to be effective. For instance, Cruz et al.⁶⁵ recently developed a short peptide sequence (CGEAIPMSIPPEVK) with affinity for neutrophil elastase, which is only expressed by activated neutrophils. Decoration of liposomes with said ligand enabled specific targeting of activated neutrophils, and subsequently promoted accumulation at the site of thrombosis. A dual targeting strategy also including a platelet-targeting peptide (DAEWVDVS) enabled binding to activated platelet–neutrophil complexes in a DVT mouse model⁶⁵. These complexes are highly prevalent following SARS-CoV-2 infection; therefore, this targeting approach may also enable efficient therapy for COVID-19-induced thrombosis.
Targeted therapy of thrombosis may also be achieved through development of responsive nanocarriers, which selectively release thrombolytics on demand. A wide range of stimuli have been studied for this purpose thus far, although not all approaches appear to be applicable to COVID-19-induced thrombosis. For instance, nanomedicines responsive to external stimuli such as magnetic fields and ultrasound rely on input from a trained professional. This complicates treatment; hence, the development of drug delivery systems with responsiveness to internal stimuli appears more conducive to the required rapid treatment of COVID-19-induced thrombosis. In addition, despite the success of shear- and pH-responsive nanomedicine in acute ischaemic stroke models^66,67, such approaches should also be disregarded due to the absence of these stimuli in pulmonary embolisms, which is the most common thrombotic complication in patients with COVID-19 at 87% (ref. ³). Various other approaches do appear to be highly relevant to COVID-19-induced thrombosis, and are therefore outlined below.
Enzyme-induced drug release is a widely used paradigm as it is highly selective and efficient⁶⁸. Examples of enzymes that are upregulated in COVID-19-induced thrombosis that may be exploited for this purpose include secreted phospholipase-A₂ (sPLA₂)⁶⁹ and thrombin⁹. sPLA₂ is produced by activated platelets and inflammatory cells⁷⁰, and can cleave the SN-2 ester bonds in glycerophospholipids. Hence, Pawlowski et al.⁵⁷ developed streptokinase-loaded liposomes, which exhibited disruption of the liposomal bilayer upon sPLA₂-induced cleavage, followed by burst release of the thrombolytic agent. This nanoparticle system enabled thrombolysis with an efficacy comparable to free streptokinase in a carotid arterial thrombosis mouse model, while negating the bleeding complications of the free drug. Furthermore, this simple nanocarrier system holds considerable clinical potential, due to the scalability and previous regulatory approval of liposomes. However, as liposomes tend to suffer from non-specific leakage of the payload, release of the thrombolytic was observed even in the absence of sPLA₂ (ref. ⁵⁷). In addition, sPLA₂ is involved not only in stimulation of thrombogenesis by COVID-19 but also in other aspects of COVID-19 pathophysiology⁶⁹. Hence, further in vivo studies in COVID-19 animal models are required to determine whether such an approach results in drug release specific to the site of thrombosis, or whether systemic release and subsequent bleeding might be observed.
Thrombin, in contrast, is highly specific to acute thrombosis; thus, off-target drug release from thrombin-sensitive nanoparticles may be less likely. Thrombin stimulates cleavage of fibrinogen to fibrin; hence, thrombin sensitivity can be introduced through incorporation of peptides mimicking its binding site on fibrinogen. Gallwitz et al.⁷¹ performed an in-depth study to identify the preferred sequences, with LTPRGWRL showing the highest cleavage efficiency. Thus, several nanoparticle systems have used this or similar peptides to deliver thrombolytics in response to the presence of thrombin. For instance, Xu et al.²⁶ conjugated recombinant tissue plasminogen activator (rtPA) to the surface of their platelet membrane nanovesicles through a thrombin-cleavable peptide. Beside the highly specific responsive release observed, this cleavage also revealed a cell-penetrating peptide motif, increasing penetration into the thrombus²⁶. Unfortunately, surface loading as applied here probably has limited loading capacity and introduces susceptibility to premature degradation by systemic enzymes. Hence, a core-loaded system, such as proposed by Zhang et al.⁵³, may be more promising. Here, urokinase was loaded into the pores of mesoporous manganese dioxide (MnO₂), and conjugation of fucoidan through a thrombin-cleavable peptide to the surface prevented release while simultaneously providing targeting. This system displayed impressive in vivo thrombolytic capabilities and exhibited a low haemorrhagic risk⁵³.
Interestingly, the MnO₂ particles also acted as hydrogen peroxide (H₂O₂) scavengers, which may be highly beneficial in the treatment of COVID-19-induced thrombosis. An increase in reactive oxygen species (ROS), such as H₂O₂, is a chemical biomarker of thrombosis, as ROS promote platelet activation and inflammation⁷². Upregulated ROS levels were also reported in patients with COVID-19, contributing to many aspects of the pathophysiology. Therefore treatment with antioxidants has been identified as a promising approach against COVID-19 symptoms⁷³. The ability of the MnO₂ nanoparticles to reduce H₂O₂ levels by up to two-thirds compared with a control in vitro may therefore be of great benefit⁵³. Alternatively, Mei et al.⁷⁴ developed tPA-loaded polymeric nanoparticles, which contained 4-amino-2,2,6,6-tetramethylpiperidine-1-oxyl (4-amino-TEMPO) as H₂O₂ scavengers. This enabled a reduction of ROS levels in rat brains after ischaemic stroke to a level comparable to healthy brains. The protective effect of this was profound, as seen by a haemorrhagic propensity indistinguishable from the saline control⁷⁴. Although the ischaemic stroke model used here may not accurately mimic COVID-19-induced thrombosis, these results and the reported impact of ROS in COVID-19 pathophysiology warrant further testing of such systems in COVID-19 models. Thus, a system that delivers thrombolytic agents as well as provides ROS scavenging may enable treatment of COVID-19-induced thrombosis while simultaneously relieving COVID-19-related oxidative stress.
An alternative or complementary approach to the use of thrombolytics for the treatment of COVID-19-induced thrombosis may be the administration of therapeutics that suppress infection or the subsequent immune response. This has been an approach of great interest in the general treatment of COVID-19, with various clinical trials underway. This includes the immunosuppressants tocilizumab⁷⁵, a complement activation inhibitor, and recombinant human deoxyribonuclease (rhDNase)⁷⁶, a NETosis inhibitor, which have reached Phase III and Phase II, respectively. Antiviral agents have seen even greater success, with molnupiravir and paxlovid receiving regulatory approval^77,78. Several virucidal, virus-trapping and immunosuppressant nanomedicines have been developed and tested for treatment against COVID-19 (Fig. 3). The effect of these nanomedicines in reducing infection and the linked immune response may also translate into a lower thrombosis risk by limiting the underlying stimulatory pathways.
a, Virucidal nanoparticles associate with the virus through interaction of the positive nanoparticle surface (red) with the negatively charged virus particles, following by stimulation of lysis of the virus envelope. b, Virus-trapping nanoparticles competitively bind to SARS-CoV-2 via the ACE2 receptors (blue) present on their surface, preventing infection of endothelial cells. c, Immune-suppressing nanoparticles are surface-loaded with rhDNase (yellow), which breaks down the DNA strands (purple strands) to mitigate excessive NETosis. Thus, through all three approaches, the excessive immune response to SARS-CoV-2 infection may be limited, potentially aiding in preventing COVID-19-induced thrombosis. Figure created with BioRender.com.
Virucidal nanoparticles have seen much interest to prevent infection and replication of the virus in the body⁷⁹. Besides loading antiviral therapeutics into nanoparticles, the use of nanomaterials with inherent virucidal properties is an interesting approach. To this end, nanoparticles based on silver^80,81, polylysine⁸² and glycyrrhizic acid⁸³ have been investigated. These nanoparticles may bind to SARS-CoV-2, disrupting its integrity and subsequently preventing infection of endothelial cells and replication (Fig. 3a). In vivo testing of their efficacy has thus far been limited to the glycyrrhizic acid nanoparticles, which decreased infection and improved survival in a SARS-CoV-2 mouse model⁸³. Interestingly, both silver and polylysine nanoparticles showed a positive correlation between their antiviral activity and their surface charge^80,82. This was rationalized by an improved interaction with the viral particles, which display a negative charge at physiological pH. Furthermore, silver nanoparticles displayed size-dependent virucidal properties with 10 nm nanoparticles exhibiting optimal SARS-CoV-2 inhibition, whereas 100 nm nanoparticles were entirely ineffective^80,81. Once optimized, all nanoparticles displayed exceptional capacities to suppress viral replication, making the use of these nanomaterials a promising approach for the prevention of COVID-19-induced thrombosis. However, despite promising biocompatibility when in their nanoparticulate form, the cytotoxicity related to silver and glycyrrhizic acid, and potential stimulation of NETosis may complicate their use^81,83.
Alternatively, several groups have utilized angiotensin-converting enzyme-2 (ACE2)-expressing membranes to produce nanoconstructs that competitively bind and trap SARS-CoV-2, lightening the viral load (Fig. 3b)^84,85,86,87. ACE2 plays a critical role in SARS-CoV-2 binding and infection, and is highly expressed in kidney cells (HEK293), macrophages (THP-1) and lung spheroid cells (LSCs). Hence membranes derived from these cells provide excellent inherent targeting, binding and trapping of SARS-CoV-2^84,85,86,87. Li et al.⁸⁷ showed that LSCs express higher levels of ACE2 than HEK293 cells, resulting in improved SARS-CoV-2 neutralization by LSC-derived nanoparticles, thus making this approach preferable. However, use of macrophage-derived vesicles may be the most appropriate, as Tan et al.⁸⁴ showed that said nanoparticles not only reduced the viral load but also prevented NETosis by inhibiting proinflammatory factors. As upon infection the immune system’s overactivation contributes heavily to the severity of COVID-19 symptoms, such an approach may be highly beneficial in the prevention of COVID-19-induced thrombosis⁸⁸. Furthermore, nanostructures formed from these endogenously derived membranes display high biocompatibility, and can be core-loaded with a therapeutic⁸⁴. Complex large-scale production of cell-derived nanoparticles does still constitute a substantial hurdle to their translational potential. However, it is expected that this obstacle may be overcome in the future as more efficient methods are established.
Also of consideration is the route of administration of these antiviral nanoparticles, with inhalable formulations gathering notable interest for the treatment of COVID-19 due to the localized delivery directly to the primary site of infection⁸⁹. In contrast, intravenous injection, as is often used to administer nanomedicine, results in systemic delivery and often undesirable accumulation in the liver. Hence, Li et al.⁸⁷ designed their LSC-derived nanovesicles to be nebulized and inhaled. Viral clearance was subsequently improved substantially in mice infected with SARS-CoV-2 mimicking viruses. Accumulation in the lungs could be observed even after 72 hours, indicating localized delivery and prolonged protection⁸⁷. This is consistent with in-human studies of inhaled nanoparticles, which have indicated that accumulation of nanoparticles in the lungs is followed by translocation to the bloodstream via passive diffusion for an extended period of time⁹⁰. In contrast, the intravenously administered HEK293- and THP-1-derived nanoparticles appeared to be entirely localized to the liver after only 24 hours^84,86. Further studies should be performed to ensure adequate elimination and biocompatibility. Regardless, inhalable antiviral nanomedicine appears to be a promising approach towards the localized treatment of COVID-19.
As an alternative approach to limiting the immunothrombotic response to SARS-CoV-2 infection, the effect of NETosis may also be mitigated by degrading the extracellular trap components. This area of research has thus far been led by the Park group, who utilized PLGA–dopamine⁹¹ and melanin-like nanoparticles⁹² to deliver rhDNase. rhDNase breaks down the DNA fibres present in NETs, hence reducing the thrombogenicity related to NETosis (Fig. 3c). Park et al. were able to deliver said therapeutic with a higher stability compared with free rhDNase; thus, this approach enabled significantly improved reductions in NETosis levels in blood samples of patients with COVID-19 and a sepsis mouse model^91,92. A previous study showed that reducing NETosis in an identical sepsis model reduced thrombosis⁹³; hence, it is expected that these particles may exhibit a similar effect.
Despite these promising results, such antiviral or immunosuppressant approaches are limited to the prevention of thrombogenesis similar to LMWH, and can therefore not effectively remove pre-existing thrombi. Hence, the development of dual-therapeutic nanomedicine based on these antiviral or immunosuppressant nanoparticles co-loaded with a thrombolytic is suggested as a promising approach towards the holistic treatment of COVID-19-induced thrombosis. It should be noted that such dual-therapeutic strategies do introduce additional challenges. The loading of therapeutics must be well optimized, to ensure both therapeutic effects are achieved at adequate efficacy while avoiding toxicity. This increased complexity may only be acceptable if the scalability of synthesis is ensured, which is an obstacle many nanomaterials are currently limited by. Regardless, this appears to be an avenue of research with the potential to greatly improve the treatment of COVID-19-induced thrombosis if further investigated.
The development of nanomedicine to treat COVID-19-induced thrombosis may have a great impact on improving patient outcomes worldwide. Current challenges to reaching clinical uptake lie primarily in the novelty of the virus, a lack of testing in COVID-19-specific animal models, as well as the translatability of current nanomedicines. Our understanding of the immunothrombotic pathophysiology stimulated by SARS-CoV-2 infection is still limited, but it appears to vary drastically from conventional thrombosis. This probably means that conventional thrombosis animal models are non-representative; hence, COVID-19 models or models of immunothrombosis, such as sepsis models, should be utilized instead. Although sepsis models are relatively easy to establish and operate, their relevance to COVID-19-induced pathophysiology of immunothrombosis remains to be confirmed⁹⁴. COVID-19 models introduce higher complexity, as conventionally utilized animals such as mice and canines show innate insusceptibility to SARS-CoV-2 infection and can therefore not be used^95,96. However, highly representative immunothrombosis in response to SARS-CoV-2 has been observed in minks, Roborovski dwarf hamsters and rhesus macaques⁹⁵. Despite the added complexity, these models ensure higher accuracy in determining the clinical potential of nanomedicine for the treatment of COVID-19-induced thrombosis and should therefore be explored.
In general, clinical adoption of nanomedicine for cardiovascular diseases has remained lower than other disease areas, such as cancer, due to a higher translational hurdle. In particular, concerns regarding safety and cost have limited clinical trials of nanomedicine⁹⁷. Nanomedicine for COVID-19-induced thrombosis will probably face the same hurdles; thus, advances in this field should be informed by translatable design to minimize these challenges going forward. Primarily, this includes the choice of nanomaterial utilized. Regulatory-approved nanomaterials utilized in other areas, such as liposomes, PLGA nanoparticles and iron oxide nanoparticles, may at this time produce faster translatable systems. However, these systems can suffer drawbacks regarding payload loading and leakage; hence, focusing on improving scalability and assessing the safety of alternative nanomaterials, which negate these issues, may be more beneficial in the long term. Sophisticated approaches such as post-modifications introducing targeting of thrombi have delivered promising preclinical results. However, the balance between sophistication and ease of synthesis of such design approaches must be considered to ensure both safety and scalability. This includes both the choice of targeting ligand (Table 1) and the design of stimuli-responsive systems, which—despite the encouraging results—require further research to optimize current approaches or investigate alternative opportunities as to afford clinically relevant targeted nanomaterials.
Besides the challenges involved in the design of nanomedicine for COVID-19-induced thrombosis, this area also provides exciting opportunities for the development of highly powerful, yet translatable nanomedicines. Here, the application of multifunctional nanomaterials appears particularly promising. For instance, H₂O₂-scavenging nanoparticles were earmarked as these enable simultaneous anti-inflammatory effects while delivering thrombolytic therapeutics, which is particularly relevant in the treatment of COVID-19. Virucidal or virus-trapping nanoparticles are also of interest, due to their proven efficacy against SARS-CoV-2 infection. Finally, the use of immunosuppressants to reduce NETosis has been highlighted as a promising strategy to prevent thrombogenesis. In particular, co-delivery of thrombolytics in antiviral or immunosuppressant nanoparticles may be promising to remove existing blood clots as well as prevent further COVID-19-induced thrombogenesis. Formulation of inhalable nanomedicine may also ensure localized delivery directly to the site of infection. Despite the added challenges related to such a strategy, it is expected that such nanomedicines may aid greatly in treating the unique pathophysiology of COVID-19-induced thrombosis, justifying further research in this exciting field to fill critical gaps.
Dong, E., Du, H. & Gardner, L. An interactive web-based dashboard to track COVID-19 in real time. Lancet Infect. Dis. 20, 533–534 (2020).
Article  CAS  Google Scholar 
Wichmann, D. et al. Autopsy findings and venous thromboembolism in patients with COVID-19: a prospective cohort study. Ann. Intern. Med. 173, 268–277 (2020).
Article  Google Scholar 
Klok, F. A. et al. Confirmation of the high cumulative incidence of thrombotic complications in critically ill ICU patients with COVID-19: An updated analysis. Thromb. Res. 191, 148–150 (2020).
Article  CAS  Google Scholar 
Xie, Y., Xu, E., Bowe, B. & Al-Aly, Z. Long-term cardiovascular outcomes of COVID-19. Nat. Med. 28, 583–590 (2022).
Article  CAS  Google Scholar 
Virani, S. S. et al. Heart disease and stroke statistics—2021 update. Circulation 143, e254–e743 (2021).
Article  Google Scholar 
Wilcox, T., Smilowitz, N. & Berger, J. Age and sex differences in incident thrombosis in patients hospitalized with COVID-19. J. Am. Coll. Cardiol. 77, 1826 (2021).
Article  CAS  Google Scholar 
Chen, A.-T., Wang, C.-Y., Zhu, W.-L. & Chen, W. Coagulation disorders and thrombosis in COVID-19 patients and a possible mechanism involving endothelial cells: a review. Aging Dis. 13, 144–156 (2022).
Article  Google Scholar 
Behzadifard, M. & Soleimani, M. NETosis and SARS-COV-2 infection related thrombosis: a narrative review. Thromb. J. 20, 13 (2022).
Article  CAS  Google Scholar 
Campello, E. et al. Thrombin generation in patients with COVID-19 with and without thromboprophylaxis. Clin. Chem. Lab. Med. 59, 1323–1330 (2021).
Article  CAS  Google Scholar 
Skendros, P. et al. Complement and tissue factor–enriched neutrophil extracellular traps are key drivers in COVID-19 immunothrombosis. J. Clin. Investig. 130, 6151–6157 (2020).
Article  CAS  Google Scholar 
Goshua, G. et al. Endotheliopathy in COVID-19-associated coagulopathy: evidence from a single-centre, cross-sectional study. Lancet Haematol. 7, e575–e582 (2020).
Article  Google Scholar 
Thachil, J. et al. ISTH interim guidance on recognition and management of coagulopathy in COVID-19. J. Thromb. Haemost. 18, 1023–1026 (2020).
Article  CAS  Google Scholar 
Sholzberg, M. et al. Effectiveness of therapeutic heparin versus prophylactic heparin on death, mechanical ventilation, or intensive care unit admission in moderately ill patients with COVID-19 admitted to hospital: RAPID randomised clinical trial. Brit. Med. J. 375, n2400 (2021).
Article  Google Scholar 
The REMAP-CAP, ACTIV-4a & ATTACC Investigators Therapeutic anticoagulation with heparin in critically ill patients with COVID-19. N. Engl. J. Med. 385, 777–789 (2021)..
Kalogeris, T., Baines, C. P., Krenz, M. & Korthuis, R. J. Cell biology of ischemia/reperfusion injury. Int. Rev. Cell Mol. Biol. 298, 229–317 (2012).
Article  CAS  Google Scholar 
Blanc, R. et al. Recent advances in devices for mechanical thrombectomy. Expert Rev. Med. Devices 17, 697–706 (2020).
Article  CAS  Google Scholar 
Whyte, C. S., Morrow, G. B., Mitchell, J. L., Chowdary, P. & Mutch, N. J. Fibrinolytic abnormalities in acute respiratory distress syndrome (ARDS) and versatility of thrombolytic drugs to treat COVID-19. J. Thromb. Haemost. 18, 1548–1555 (2020).
Article  CAS  Google Scholar 
Ucar, E. Y. Update on thrombolytic therapy in acute pulmonary thromboembolism. Eurasian J. Med. 51, 186–190 (2019).
CAS  Google Scholar 
Warach, S. J., Dula, A. N. & Milling, T. J. Tenecteplase thrombolysis for acute ischemic stroke. Stroke 51, 3440–3451 (2020).
Article  Google Scholar 
Wang, J. et al. Tissue plasminogen activator (tPA) treatment for COVID-19 associated acute respiratory distress syndrome (ARDS): a case series. J. Thromb. Haemost. 18, 1752–1755 (2020).
Article  CAS  Google Scholar 
Kosanovic, D. et al. Recombinant tissue plasminogen activator treatment for COVID-19 associated ARDS and acute cor pulmonale. Int. J. Infect. Dis. 104, 108–110 (2021).
Article  CAS  Google Scholar 
Barrett, C. D. et al. Study of alteplase for respiratory failure in SARS-CoV-2 COVID-19: a vanguard multicenter, rapidly adaptive, pragmatic, randomized controlled trial. Chest 161, 710–727 (2022).
Article  CAS  Google Scholar 
Rothschild, D. P., Goldstein, J. A. & Bowers, T. R. Low-dose systemic thrombolytic therapy for treatment of submassive pulmonary embolism: clinical efficacy but attendant hemorrhagic risks. Catheter. Cardiovasc. Interv. 93, 506–510 (2019).
Google Scholar 
Huang, X. et al. Nanotechnology-based strategies against SARS-CoV-2 variants. Nat. Nanotechnol. 17, 1027–1037 (2022).
Article  CAS  Google Scholar 
Colasuonno, M. et al. Erythrocyte-inspired discoidal polymeric nanoconstructs carrying tissue plasminogen activator for the enhanced lysis of blood clots. ACS Nano 12, 12224–12237 (2018).
Article  CAS  Google Scholar 
Xu, J. et al. Sequentially site-specific delivery of thrombolytics and neuroprotectant for enhanced treatment of ischemic stroke. ACS Nano 13, 8577–8588 (2019).
Article  CAS  Google Scholar 
Xu, J. et al. Engineered nanoplatelets for targeted delivery of plasminogen activators to reverse thrombus in multiple mouse thrombosis models. Adv. Mater. 32, 1905145 (2020).
Article  CAS  Google Scholar 
Russell, L. M., Hultz, M. & Searson, P. C. Leakage kinetics of the liposomal chemotherapeutic agent doxil: the role of dissolution, protonation, and passive transport, and implications for mechanism of action. J. Control. Release 269, 171–176 (2018).
Article  CAS  Google Scholar 
Kim, J.-Y., Kim, J.-K., Park, J.-S., Byun, Y. & Kim, C.-K. The use of PEGylated liposomes to prolong circulation lifetimes of tissue plasminogen activator. Biomaterials 30, 5751–5756 (2009).
Article  CAS  Google Scholar 
Zhang, W., Mehta, A., Tong, Z., Esser, L. & Voelcker, N. H. Development of polymeric nanoparticles for blood–brain barrier transfer—strategies and challenges. Adv. Sci. 8, 2003937 (2021).
Article  CAS  Google Scholar 
Matoori, S. & Leroux, J.-C. Twenty-five years of polymersomes: lost in translation? Mater. Horiz. 7, 1297–1309 (2020).
Article  CAS  Google Scholar 
Wang, X. et al. Near-infrared triggered release of uPA from nanospheres for localized hyperthermia-enhanced thrombolysis. Adv. Funct. Mater. 27, 1701824 (2017).
Article  Google Scholar 
Wang, S. et al. Accelerating thrombolysis using a precision and clot-penetrating drug delivery strategy by nanoparticle-shelled microbubbles. Sci. Adv. 6, eaaz8204 (2020).
Article  CAS  Google Scholar 
Voros, E. et al. TPA immobilization on iron oxide nanocubes and localized magnetic hyperthermia accelerate blood clot lysis. Adv. Funct. Mater. 25, 1709–1718 (2015).
Article  CAS  Google Scholar 
Yang, G., Phua, S. Z. F., Bindra, A. K. & Zhao, Y. Degradability and clearance of inorganic nanoparticles for biomedical applications. Adv. Mater. 31, 1805730 (2019).
Article  Google Scholar 
Chen, K. et al. Intrinsic biotaxi solution based on blood cell membrane cloaking enables fullerenol thrombolysis in vivo. ACS Appl. Mater. Interfaces 12, 14958–14970 (2020).
Article  CAS  Google Scholar 
Wang, J., Chen, D. & Ho, E. A. Challenges in the development and establishment of exosome-based drug delivery systems. J. Control. Release 329, 894–906 (2021).
Article  CAS  Google Scholar 
Kang, H., Seo, J., Yang, E.-J. & Choi, I.-H. Silver nanoparticles induce neutrophil extracellular traps via activation of PAD and neutrophil elastase. Biomolecules 11, 317 (2021).
Article  CAS  Google Scholar 
Yang, Y. et al. Gold nanoparticles synergize with bacterial lipopolysaccharide to enhance class A scavenger receptor dependent particle uptake in neutrophils and augment neutrophil extracellular traps formation. Ecotoxicol. Environ. Saf. 211, 111900 (2021).
Article  CAS  Google Scholar 
Bartneck, M., Keul, H. A., Zwadlo-Klarwasser, G. & Groll, J. Phagocytosis independent extracellular nanoparticle clearance by human immune cells. Nano Lett. 10, 59–63 (2010).
Article  CAS  Google Scholar 
Snoderly, H. T. et al. PEGylation of metal oxide nanoparticles modulates neutrophil extracellular trap formation. Biosensors 12, 123 (2022).
Article  CAS  Google Scholar 
Bilyy, R. et al. Inert coats of magnetic nanoparticles prevent formation of occlusive intravascular co-aggregates with neutrophil extracellular traps. Front. Immunol. 9, 2266 (2018).
Article  Google Scholar 
Mukherjee, S. P. et al. Graphene oxide is degraded by neutrophils and the degradation products are non-genotoxic. Nanoscale 10, 1180–1188 (2018).
Article  CAS  Google Scholar 
Hwang, T.-L., Aljuffali, I. A., Hung, C.-F., Chen, C.-H. & Fang, J.-Y. The impact of cationic solid lipid nanoparticles on human neutrophil activation and formation of neutrophil extracellular traps (NETs). Chem. Biol. Interact. 235, 106–114 (2015).
Article  CAS  Google Scholar 
Muñoz, L. E. et al. Nanoparticles size-dependently initiate self-limiting NETosis-driven inflammation. Proc. Natl Acad. Sci. USA 113, E5856–E5865 (2016).
Article  Google Scholar 
Yang, H. et al. Nanomaterial exposure induced neutrophil extracellular traps: a new target in inflammation and innate immunity. J. Immunol. Res. 2019, 3560180 (2019).
Article  Google Scholar 
Kutscher, H. L. et al. Threshold size for optimal passive pulmonary targeting and retention of rigid microparticles in rats. J. Control. Release 143, 31–37 (2010).
Article  CAS  Google Scholar 
Herda, L. M., Hristov, D. R., Lo Giudice, M. C., Polo, E. & Dawson, K. A. Mapping of molecular structure of the nanoscale surface in bionanoparticles. J. Am. Chem. Soc. 139, 111–114 (2017).
Article  CAS  Google Scholar 
Faria, M. et al. Minimum information reporting in bio-nano experimental literature. Nat. Nanotechnol. 13, 777–785 (2018).
Article  CAS  Google Scholar 
Lu, T.-Y. et al. Dual-targeting glycol chitosan/heparin-decorated polypyrrole nanoparticle for augmented photothermal thrombolytic therapy. ACS Appl. Mater. Interfaces 13, 10287–10300 (2021).
Article  CAS  Google Scholar 
Bachelet, L. et al. Affinity of low molecular weight fucoidan for P-selectin triggers its binding to activated human platelets. Biochim. Biophys. Acta 1790, 141–146 (2009).
Article  CAS  Google Scholar 
Juenet, M. et al. Thrombolytic therapy based on fucoidan-functionalized polymer nanoparticles targeting P-selectin. Biomaterials 156, 204–216 (2018).
Article  CAS  Google Scholar 
Zhang, H. et al. Thrombus-targeted nanoparticles for thrombin-triggered thrombolysis and local inflammatory microenvironment regulation. J. Control. Release 339, 195–207 (2021).
Article  CAS  Google Scholar 
Chang, L.-H. et al. Thrombus-specific theranostic nanocomposite for codelivery of thrombolytic drug, algae-derived anticoagulant and NIR fluorescent contrast agent. Acta Biomater. 134, 686–701 (2021).
Article  CAS  Google Scholar 
Apostolopoulos, V. et al. A global review on short peptides: frontiers and perspectives. Molecules 26, 430 (2021).
Article  CAS  Google Scholar 
Sun, M. et al. Combination targeting of ‘platelets + fibrin’ enhances clot anchorage efficiency of nanoparticles for vascular drug delivery. Nanoscale 12, 21255–21270 (2020).
Article  CAS  Google Scholar 
Pawlowski, C. L. et al. Platelet microparticle-inspired clot-responsive nanomedicine for targeted fibrinolysis. Biomaterials 128, 94–108 (2017).
Article  CAS  Google Scholar 
Yang, A. et al. Thrombin-responsive engineered nanoexcavator with full-thickness infiltration capability for pharmaceutical-free deep venous thrombosis theranostics. Biomater. Sci. 8, 4545–4558 (2020).
Article  CAS  Google Scholar 
Marsh, J. N. et al. A fibrin-specific thrombolytic nanomedicine approach to acute ischemic stroke. Nanomedicine 6, 605–615 (2011).
Article  CAS  Google Scholar 
Schwarz, M. et al. Conformation-specific blockade of the integrin GPIIb/IIIa. Circ. Res. 99, 25–33 (2006).
Article  CAS  Google Scholar 
Bates, A. & Power, C. A. David vs. Goliath: the structure, function, and clinical prospects of antibody fragments. Antibodies 8, 28 (2019).
Article  CAS  Google Scholar 
Yong, K. W., Yuen, D., Chen, M. Z. & Johnston, A. P. R. Engineering the orientation, density, and flexibility of single-domain antibodies on nanoparticles to improve cell targeting. ACS Appl. Mater. Interfaces 12, 5593–5600 (2020).
Article  CAS  Google Scholar 
Lu, R.-M. et al. Development of therapeutic antibodies for the treatment of diseases. J. Biomed. Sci. 27, 1 (2020).
Article  CAS  Google Scholar 
Zhao, Y. et al. Biomimetic fibrin-targeted and H₂O₂-responsive nanocarriers for thrombus therapy. Nano Today 35, 100986 (2020).
Article  CAS  Google Scholar 
Cruz, M. A. et al. Nanomedicine platform for targeting activated neutrophils and neutrophil–platelet complexes using an α1-antitrypsin-derived peptide motif. Nat. Nanotechnol. 17, 1004–1014 (2022).
Article  CAS  Google Scholar 
Korin, N. et al. Shear-activated nanotherapeutics for drug targeting to obstructed blood vessels. Science 337, 738–742 (2012).
Article  CAS  Google Scholar 
Marosfoi, M. G. et al. Shear-activated nanoparticle aggregates combined with temporary endovascular bypass to treat large vessel occlusion. Stroke 46, 3507–3513 (2015).
Article  CAS  Google Scholar 
Wang, Y., Shim, M. S., Levinson, N. S., Sung, H.-W. & Xia, Y. Stimuli-responsive materials for controlled release of theranostic agents. Adv. Funct. Mater. 24, 4206–4220 (2014).
Article  CAS  Google Scholar 
Snider, J. M. et al. Group IIA secreted phospholipase A2 is associated with the pathobiology leading to COVID-19 mortality. J. Clin. Invest. 131, e149236 (2021).
Article  CAS  Google Scholar 
Takahashi, S. et al. Phospholipase A2 expression in coronary thrombus is increased in patients with recurrent cardiac events after acute myocardial infarction. Int. J. Cardiol. 168, 4214–4221 (2013).
Article  Google Scholar 
Gallwitz, M., Enoksson, M., Thorpe, M. & Hellman, L. The extended cleavage specificity of human thrombin. PLoS ONE 7, e31756 (2012).
Article  CAS  Google Scholar 
Freedman, J. E. Oxidative stress and platelets. Arterioscler. Thromb. Vasc. Biol. 28, s11–s16 (2008).
Article  CAS  Google Scholar 
Laforge, M. et al. Tissue damage from neutrophil-induced oxidative stress in COVID-19. Nat. Rev. Immunol. 20, 515–516 (2020).
Article  CAS  Google Scholar 
Mei, T. et al. Encapsulation of tissue plasminogen activator in pH-sensitive self-assembled antioxidant nanoparticles for ischemic stroke treatment—synergistic effect of thrombolysis and antioxidant. Biomaterials 215, 119209 (2019).
Article  CAS  Google Scholar 
Genentech Inc. Efficacy of tocilizumab on patients with COVID-19. ClinicalTrials.gov. https://clinicaltrials.gov/ct2/show/study/NCT04356937 (2020).
Simmons, J. Phase 2 trial using rhDNase to reduce mortality in COVID-19 patients with respiratory failure (DAMPENCOVID). ClinicalTrials.gov. https://clinicaltrials.gov/ct2/show/NCT04445285 (2020).
Syed, Y. Y. Molnupiravir: first approval. Drugs 82, 455–460 (2022).
Article  CAS  Google Scholar 
Lamb, Y. N. Nirmatrelvir plus ritonavir: first approval. Drugs 82, 585–591 (2022).
Article  CAS  Google Scholar 
Peplow, M. Nanotechnology offers alternative ways to fight COVID-19 pandemic with antivirals. Nat. Biotechnol. 39, 1172–1174 (2021).
Article  CAS  Google Scholar 
He, Q. et al. Antiviral properties of silver nanoparticles against SARS-CoV-2: effects of surface coating and particle size. Nanomaterials 12, 990 (2022).
Article  CAS  Google Scholar 
Jeremiah, S. S., Miyakawa, K., Morita, T., Yamaoka, Y. & Ryo, A. Potent antiviral effect of silver nanoparticles on SARS-CoV-2. Biochem. Biophys. Res. Commun. 533, 195–200 (2020).
Article  CAS  Google Scholar 
Stagi, L. et al. Effective SARS-CoV-2 antiviral activity of hyperbranched polylysine nanopolymers. Nanoscale 13, 16465–16476 (2021).
Article  CAS  Google Scholar 
Zhao, Z. et al. Glycyrrhizic acid nanoparticles as antiviral and anti-inflammatory agents for COVID-19 treatment. ACS Appl. Mater. Interfaces 13, 20995–21006 (2021).
Article  CAS  Google Scholar 
Tan, Q. et al. Macrophage biomimetic nanocarriers for anti-inflammation and targeted antiviral treatment in COVID-19. J. Nanobiotechnol. 19, 173 (2021).
Article  CAS  Google Scholar 
Ma, X. et al. HACE2-exosome-based nano-bait for concurrent SARS-CoV-2 trapping and antioxidant therapy. ACS Appl. Mater. Interfaces 14, 4882–4891 (2022).
Article  CAS  Google Scholar 
Wang, C. et al. Membrane nanoparticles derived from ACE2-rich cells block SARS-CoV-2 infection. ACS Nano 15, 6340–6351 (2021).
Article  CAS  Google Scholar 
Li, Z. et al. Cell-mimicking nanodecoys neutralize SARS-CoV-2 and mitigate lung injury in a non-human primate model of COVID-19. Nat. Nanotechnol. 16, 942–951 (2021).
Article  CAS  Google Scholar 
Peddapalli, A. et al. Demystifying excess immune response in COVID-19 to reposition an orphan drug for down-regulation of NF-κB: a systematic review. Viruses 13, 378 (2021).
Article  CAS  Google Scholar 
Eedara, B. B. et al. Inhalation delivery for the treatment and prevention of COVID-19 infection. Pharmaceutics 13, 1077 (2021).
Article  CAS  Google Scholar 
Miller, M. R. et al. Inhaled nanoparticles accumulate at sites of vascular disease. ACS Nano 11, 4542–4552 (2017).
Article  CAS  Google Scholar 
Lee, Y. Y. et al. Long-acting nanoparticulate DNase-1 for effective suppression of SARS-CoV-2-mediated neutrophil activities and cytokine storm. Biomaterials 267, 120389 (2021).
Article  CAS  Google Scholar 
Park, H. H. et al. Bioinspired DNase-I-coated melanin-like nanospheres for modulation of infection-associated NETosis dysregulation. Adv. Sci. 7, 2001940 (2020).
Article  CAS  Google Scholar 
Alsabani, M. et al. Reduction of NETosis by targeting CXCR1/2 reduces thrombosis, lung injury, and mortality in experimental human and murine sepsis. Br. J. Anaesth. 128, 283–293 (2022).
Article  CAS  Google Scholar 
Beristain-Covarrubias, N. et al. Understanding infection-induced thrombosis: lessons learned from animal models. Front. Immunol. 10, 2569 (2019).
Article  CAS  Google Scholar 
Shou, S. et al. Animal models for COVID-19: hamsters, mouse, ferret, mink, tree shrew, and non-human primates. Front. Microbiol. 12, 626553 (2021).
Article  Google Scholar 
Shi, J. et al. Susceptibility of ferrets, cats, dogs, and other domesticated animals to SARS-coronavirus 2. Science 368, 1016–1020 (2020).
Article  CAS  Google Scholar 
Cicha, I. et al. From design to the clinic: practical guidelines for translating cardiovascular nanomedicine. Cardiovasc. Res. 114, 1714–1727 (2018).
Article  CAS  Google Scholar 
Bai, S. et al. Multimodal and multifunctional nanoparticles with platelet targeting ability and phase transition efficiency for the molecular imaging and thrombolysis of coronary microthrombi. Biomater. Sci. 8, 5047–5060 (2020).
Article  CAS  Google Scholar 
Huang, Y. et al. An activated-platelet-sensitive nanocarrier enables targeted delivery of tissue plasminogen activator for effective thrombolytic therapy. J. Control. Release 300, 1–12 (2019).
Article  CAS  Google Scholar 
Sánchez-Cortés, J. & Mrksich, M. The platelet integrin alphaIIbbeta3 binds to the RGD and AGD motifs in fibrinogen. Chem. Biol. 16, 990–1000 (2009).
Article  Google Scholar 
Absar, S., Nahar, K., Kwon, Y. M. & Ahsan, F. Thrombus-targeted nanocarrier attenuates bleeding complications associated with conventional thrombolytic therapy. Pharm. Res. 30, 1663–1676 (2013).
Article  CAS  Google Scholar 
Zhong, Y. et al. Low-intensity focused ultrasound-responsive phase-transitional nanoparticles for thrombolysis without vascular damage: a synergistic nonpharmaceutical strategy. ACS Nano 13, 3387–3403 (2019).
Article  CAS  Google Scholar 
Chen, H.-A., Ma, Y.-H., Hsu, T.-Y. & Chen, J.-P. Preparation of peptide and recombinant tissue plasminogen activator conjugated poly(lactic-co-glycolic acid) (PLGA) magnetic nanoparticles for dual targeted thrombolytic therapy. Int. J. Mol. Sci. 21, 2690 (2020).
Article  CAS  Google Scholar 
Singh, M. P. et al. Reprogramming the rapid clearance of thrombolytics by nanoparticle encapsulation and anchoring to circulating red blood cells. J. Control. Release 329, 148–161 (2021).
Article  CAS  Google Scholar 
Kawata, H. et al. A new drug delivery system for intravenous coronary thrombolysis with thrombus targeting and stealth activity recoverable by ultrasound. J. Am. Coll. Cardiol. 60, 2550–2557 (2012).
Article  CAS  Google Scholar 
Papayannopoulos, V. Neutrophil extracellular traps in immunity and disease. Nat. Rev. Immunol. 18, 134–147 (2018).
Article  CAS  Google Scholar 
Veras, F. P. et al. SARS-CoV-2–triggered neutrophil extracellular traps mediate COVID-19 pathology. J. Exp. Med. 217, e20201129 (2020).
Article  CAS  Google Scholar 
Arcanjo, A. et al. The emerging role of neutrophil extracellular traps in severe acute respiratory syndrome coronavirus 2 (COVID-19). Sci. Rep. 10, 19630 (2020).
Article  CAS  Google Scholar 
Kaiser, R. et al. Self-sustaining IL-8 loops drive a prothrombotic neutrophil phenotype in severe COVID-19. JCI Insight 6, e150862 (2021).
Article  Google Scholar 
Wu, M. et al. Transcriptional and proteomic insights into the host response in fatal COVID-19 cases. Proc. Natl Acad. Sci. USA 117, 28336–28343 (2020).
Article  CAS  Google Scholar 
Liao, M. et al. Single-cell landscape of bronchoalveolar immune cells in patients with COVID-19. Nat. Med. 26, 842–844 (2020).
Article  CAS  Google Scholar 
Zuo, Y. et al. Autoantibodies stabilize neutrophil extracellular traps in COVID-19. JCI Insight 6, e150111 (2021).
Google Scholar 
Englert, H. et al. Defective NET clearance contributes to sustained FXII activation in COVID-19-associated pulmonary thrombo-inflammation. eBioMedicine 67, 103382 (2021).
Article  CAS  Google Scholar 
Semeraro, F. et al. Extracellular histones promote thrombin generation through platelet-dependent mechanisms: involvement of platelet TLR2 and TLR4. Blood 118, 1952–1961 (2011).
Article  CAS  Google Scholar 
Girard, P. et al. Deep venous thrombosis in patients with acute pulmonary embolism: prevalence, risk factors, and clinical significance. Chest 128, 1593–1600 (2005).
Article  Google Scholar 
Helms, J. et al. High risk of thrombosis in patients with severe SARS-CoV-2 infection: a multicenter prospective cohort study. Intensive Care Med. 46, 1089–1098 (2020).
Article  CAS  Google Scholar 
Chernysh, I. N. et al. The distinctive structure and composition of arterial and venous thrombi and pulmonary emboli. Sci. Rep. 10, 5112 (2020).
Article  CAS  Google Scholar 
Guan, W.-j et al. Clinical characteristics of coronavirus disease 2019 in China. N. Engl. J. Med. 382, 1708–1720 (2020).
Article  CAS  Google Scholar 
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P.R. thanks the Australian Institute of Nuclear Science and Engineering (AINSE) for a postgraduate research award. L.E. thanks AINSE for an early-career research grant and the CASS Foundation for a science/medicine grant (10021). C.E.H. thanks the National Health and Medical Research Council (NHMRC) of Australia for a Senior Research Fellowship (award number GNT1154270).
Drug Delivery, Disposition and Dynamics, Monash Institute of Pharmaceutical Sciences, Monash University, Parkville, Victoria, Australia
Peije Russell, Lars Esser & Nicolas H. Voelcker
Commonwealth Scientific and Industrial Research Organisation (CSIRO), Manufacturing, Clayton, Victoria, Australia
Peije Russell & Lars Esser
Australian Centre for Blood Diseases, Central Clinical School, Monash University, Melbourne, Victoria, Australia
Peije Russell & Christoph E. Hagemeyer
Melbourne Centre for Nanofabrication, Victorian Node of Australian National Fabrication Facility, Clayton, Victoria, Australia
Nicolas H. Voelcker
Department of Materials Science and Engineering, Monash University, Clayton, Victoria, Australia
Nicolas H. Voelcker
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Correspondence to Christoph E. Hagemeyer or Nicolas H. Voelcker.
The authors declare no competing interests.
Nature Nanotechnology thanks Wei Tao and the other, anonymous, reviewer(s) for their contribution to the peer review of this work.
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Russell, P., Esser, L., Hagemeyer, C.E. et al. The potential impact of nanomedicine on COVID-19-induced thrombosis. Nat. Nanotechnol. (2022). https://doi.org/10.1038/s41565-022-01270-6
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Received: 04 April 2022
Accepted: 12 October 2022
Published: 19 December 2022
DOI: https://doi.org/10.1038/s41565-022-01270-6
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