Recent Advances in Blood Cell-Inspired and Clot-Targeted Thrombolytic Therapies

. Myocardial infarction, stroke, and pulmonary embolism are all deadly conditions associated with excessive thrombus formation. Standard treatment for these conditions involves systemic delivery of thrombolytic agents to break up clots and restore blood fow; however, this treatment can impact the hemostatic balance in other parts of the vasculature, which can lead to excessive bleeding. To avoid this potential danger, targeted thrombolytic treatments that can successfully target thrombi and release an efective therapeutic load are necessary. Because activated platelets and fbrin make up a large proportion of clots, these two components provide ample opportunities for targeting. Tis review will highlight potential thrombus targeting mechanisms as well as recent advances in thrombolytic therapies which utilize blood cells and clotting proteins to efectively target and lyse clots.


Overview of Thrombotic Complications and Treatment Limitations
Excessive thrombus formation can lead to life-threatening conditions such as stroke, myocardial infarction, pulmonary embolism, or disseminated intravascular coagulation.Tese conditions can be treated surgically to break up thrombi and restore blood fow; however, less invasive methods are preferred to avoid surgical costs and complications such as infection or a reaction to anesthesia.Te most common noninvasive method is fbrinolytic or thrombolytic therapy which uses systemic delivery of fbrinolytic agents such as urokinase, tissue plasminogen activator (tPA), streptokinase, reteplase, and tenecteplase [1,2].Fibrinolytic agents activate plasminogen into plasmin which cleaves fbrin to break down clots.Te main complication of systemic delivery of thrombolytics is excessive bleeding which can result in hematomas at puncture sites, ecchymosis, hemoptysis, or intracranial bleeding [3].Te risk of a major bleeding event varies tremendously based on the fbrinolytic agent and the condition being treated.Daley et al. reviewed the bleeding rates when treating acute pulmonary embolisms with varying fbrinolytic agents in previous studies [4].Tey found that systemic treatment can result in bleeding risks in as many as 32.9% of patients.Of-target delivery of thrombolytics also limits the amount that reaches thrombi, thereby increasing the required drug dosage.Furthermore, uptake by the reticuloendothelial system is another large hurdle to drug delivery.Given these issues, nanoparticles that target thrombi and go unrecognized by the reticuloendothelial system are of great interest to treat thrombotic complications.Tis review highlights recent advancements in thrombolytic therapies that utilize, mimic, and target blood cells and clotting proteins.A summary of technologies is provided in Table 1.[35] Platelet-based and targeted c-Fe 2 O 3 and L-arginine magnetic nanoparticle-loaded platelets Natural thrombus targeting, magnetic feld Mouse focal cerebral ischemia model [41] tPA and melanin nanoparticle-loaded platelets Natural thrombus targeting Mouse/Rat cerebral thrombosis model and MCAO model [43] tPA-conjugated and PLGA-loaded platelets

Mechanisms and Cell Types Contributing to Thrombosis
Maintaining hemostatic balance between procoagulant and anticoagulant factors is imperative so that the body can respond efciently and efectively to injury.Under steady state conditions, blood fuidity is maintained by antithrombin, proteins C, S, and Z, and a tissue factor pathway inhibitor [5].After injury, the rate of activation of these proteins is decreased, downregulating their anticoagulant mechanisms.As a result, the conversion of prothrombin into thrombin is upregulated.Trombin converts fbrinogen into fbrin, creating a fbrin clot, which is then crosslinked by factor XIIIa. Te rate of activation of these proteases and complexes contributes to both thrombus formation and maintaining vessel integrity.However, if the rates of activation are not balanced, bleeding or thrombosis can occur.
Besides exposure of the vessel wall, thrombosis can be caused by a variety of factors such as blood pooling or atherosclerotic plaque rupture [6].Similarly, defciency of key antithrombotic proteins (antithrombin, protein C, and protein S) or increased levels of prothrombotic proteins (factors VII, XI, IX, VIII, or von Willebrand factor (vWF)) can also cause hypercoagulation [5].
Along with coagulation proteins, platelets and other cell types contribute to clot formation and thrombus stability properties.Platelets are anucleated cells with a 2-3 μm diameter, ∼10-day half-life, and a relative abundance of ∼150,000-400,000/μl of blood [7][8][9].Platelets play a large role in primary hemostasis; once bound to vWF, exposed collagen, or soluble platelet agonists, platelets change shape, accumulate and aggregate at injury sites, and interact with fbrin(ogen) to form a plug to cease blood fow from a damaged vessel [10][11][12][13].Since platelets comprise a large portion of thrombi, they are excellent targets for thrombolytic therapies.One possible platelet target is Pselectin (13,000/platelet).Tis glycoprotein exists in α-granules until platelet activation, where it is translocated to the membrane.Glycoprotein (GP) Ib-IX-V complex (50,000/platelet) is another potential target as it is the second most common receptor on platelets; however, the most abundant and most commonly targeted is α IIb β 3 , also called the GPIIb-IIIa complex [8,[13][14][15].Tese receptors are located on platelet membranes (80,000-100,000/platelet) and intracellularly within granules (20,000-40,000/platelet).Once platelets become activated by initial agonist binding, these receptors undergo conformational changes to display a high afnity binding site for fbrinogen.Additionally, intracellular receptors translocate to the plasma membrane, and there is evidence suggesting that they are already complexed with fbrinogen to enhance fbrin clot formation [16].Given the abundance of these receptors on activated platelets, targeting them could be the key to efcient and precise thrombolytic delivery.Common thrombi-specifc receptors and platelet-and fbrin-based targeting agents for thrombolytic therapies are illustrated in Figure 1.
While red blood cells (RBCs) are not necessarily major contributors to thrombus formation; some studies indicate that elevated RBC levels could lead to serious thrombotic conditions such as cardiovascular disease or venous thromboembolism [17][18][19].A recent review summarizes evidence supporting RBCs' infuence on both hemostasis and thrombosis [20].Some proposed mechanisms of how RBCs encourage thrombosis include contributing to platelet margination toward the vessel wall, therefore increasing deposition of platelets on thrombi [21][22][23].Also, when RBCs are present in clots, they reduce the degree of clot contraction, which is an imperative step to promote blood fow past large thrombi [24,25].Despite these thrombotic associations, RBCs also provide advantageous characteristics Journal of Tissue Engineering and Regenerative Medicine to aid in therapeutic delivery to thrombus sites.Tese anuclear cells are biocompatible, deformable, and abundant, having a concentration of ∼ 4.2 − 6.1 × 10 9 /mL of blood.RBCs have a large surface area of ∼140 um 2 [18,26] and a long natural half-life of ∼70-120 days [27][28][29].While RBCs do not have direct thrombus targeting abilities intrinsically, they can be engineered with motifs or nanoparticles to create a camoufaged and targeted therapeutic vehicle.
White blood cells (WBCs) play an important role in the immune system and thrombosis [30].In an inactivated state, leukocytes release anticoagulant factors such as endothelial protein C receptors (EPCR) and tissue factor (TF) pathway inhibitors.Once activated during infammation, they release procoagulant factors including TF and matrix metalloproteinases [31,32].However, activated leukocytes have also been shown to release microparticles which contain both procoagulant TFs and anticoagulant factors such as EPCR [33].Additionally, leukocytes form complexes with activated platelets via P-selectin, contributing further to aggregation [34].Given that activated WBCs promote thrombosis in multiple ways, few researchers have used WBCs to treat thrombotic conditions.However, Burnouf et al. created a proof-of-concept for macrophage-loaded thrombolytic therapy by loading macrophages with polypyrrole-polyethylenimine nanocomplexes which target thrombi and lyse clots via near infrared (NIR) irradiation [35].Tey saw successful clot ablation of NIR treatments combined with test nanoformulations in a rat femoral vascular thrombosis model; however, they did not test the full macrophage-based nanoformulation in vivo.Another group combined neutrophils with urease catalysis micromotors to create a targeted treatment that can overcome blood fow resistance [36].Te micromotors produce ammonia and carbon dioxide to propel urokinase-silver nanoparticle-loaded neutrophils.Once at the thrombus site, the neutrophil will expel the internal cell contents to form neutrophil extracellular traps.Tese altered neutrophils were tested in vivo in carotid thrombosis and lower extremity arterial thrombosis mouse models.Tey demonstrated excellent thrombus targeting times (<30 minutes) and rapid thrombolysis in both models.Tese two studies are pioneering examples of how WBCs can be used to treat thrombotic complications.

Platelet-Derived, Inspired, and Targeted Thrombolytic Therapies
Platelets play an imperative role in hemostasis and thrombosis, and while platelets are primarily thought of as contributing to thrombotic outcomes, researchers have found ways to incorporate platelets into thrombolytic therapies to treat stroke, reperfusion injuries, pulmonary embolism, and other thrombotic conditions.Besides thrombus targeting, most of these complex therapeutics use the platelet membrane as a "cloak" to aid in immune system evasion through CD47 expression.Additionally, CD55 and CD59 expression prevent complement activation [37].Terefore, platelet-cloaks extend circulation time and halflife of the therapeutic in addition to limiting of-target efects which can be very costly when delivering anticoagulant, antiplatelet, or fbrinolytic agents [38].Te main two phases to create cell-membrane camoufaged nanoparticles are (1) platelet membrane isolation and (2) therapeutic loading [39,40].For membrane isolation, platelets are carefully lysed via freeze-thaw cycles [41][42][43] and centrifuged to separate membranes from internal cell contents.Biological or chemical cargo is then loaded through sonication, electroporation, or extrusion [40] (Figure 2).Researchers must determine which method is most appropriate for their specifc therapeutic and application.Recently, there have been exciting complex cargo designs that go beyond simple drug delivery and expand the potential impact of plateletderived therapeutics.Li et al. designed a nanocarrier that utilized both the natural targeting ability of platelets and a magnetic feld to localize particles to stroke lesions [41].Teir nanocarriers, platelet membrane envelopes loaded with c-Fe 2 O 3 and L-arginine magnetic nanoparticles (PAMNs), use a magnetic feld to target thrombus sites.
Tere, L-arginine stimulates nitric oxide (NO) release from endothelial cells, inducing vasodilation and helping restore blood fow to the tissue.In a mouse model of ischemia, PAMNs successfully localized to stroke lesions, released NO, and aided in blood vessel expansion, therefore reducing platelet aggregation and restoring blood fow to the local tissue.Yu et al. also developed a therapeutic that utilizes an external stimulus, but for the purpose of thrombolysis as opposed to targeting [43].Tey loaded platelet membranes Platelets can be loaded with thrombolytics through sonication, electroporation, or extrusion.Sonication uses ultrasonic waves to fuse cargo and membranes together [44], while electroporation exposes membranes to electrical waves, creating pores through which cargo can enter [45].Extrusion requires both cargo and membranes to be run through a porous membrane, where mechanical pressure forces them to interact [46].
with tPA to promote fbrin lysis and melanin nanoparticles to scavenge free radicals.Te particles assisted with both thrombolysis and neuroprotection from reperfusion injury.Teir proposed mechanism utilized platelets' natural targeting ability to reach thrombus sites where NIR irradiation would be administered.Te irradiation photoconverts melanin, causing platelet membrane rupture to release tPA and stimulate fbrinolysis.Meanwhile, melanin nanoparticles would cross the blood brain barrier, scavenge free radicals, and suppress infammation to reduce the risk of ischemia-reperfusion injury (Figure 3).In a rodent cerebral thrombosis model, groups that received therapeutic-loaded platelets showed a signifcant decrease in the infarct size, lower reactive oxygen species presence, and greater blood stream recovery.Trough the examples mentioned, there are obvious benefts for using platelet-derived therapeutics such as improved thrombus targeting abilities, immune evasion, and elongated half-lives [38].
While the use of platelet-derived therapies clearly has promise for treating thrombotic complications, there are some major hurdles that need to be overcome regarding large-scale production of platelet-derived therapies [47].Currently, there are no established protocols to scale up production of these products.In addition, these strategies all require the use of natural platelets, which relies on donor availability.Tere is a current blood shortage that will limit platelets available for production.Finally, the use of real platelets limits the product's shelf life.Given these challenges, research focused on large-scale production of platelet-derived therapeutics should be a priority.Some researchers, including our own group, are avoiding these hurdles by opting to mimic platelets instead [48,49].Our lab's approach to creating synthetic platelets employs a micron-sized hydrogel, or microgel, coupled to a fbrin-binding motif [50].Te microgel is ultra-low crosslinked (ULC) poly (N-isopropylacrylamide) copolymerized with acrylic acid (AAc).Similar to native platelets, these particles are ∼1 μm in diameter in solution, and their high deformability allows them to mimic activated platelet morphology [51].Our synthetic platelets, termed plateletlike-particles (PLPs), are created by conjugating ULC microgels to fbrin-specifc motifs; we have explored several diferent fbrin-binding elements including nanobodies, fulllength antibodies, and peptides.Te fbrin-binding ability allows PLP to bind to fbrin at injury sites.We have shown in rodent trauma models that following intravenous injection, PLPs target wound sites and interface with nascent fbrin fbers to augment clotting and decrease bleeding in vivo [50,52].We have also demonstrated that PLPs mimic platelet-mediated clot retraction, a function which stabilizes clots and promotes long term healing responses.Tis behavior is due to a Brownian Wrench type mechanism which arises from the combination of fbrin binding with the highly deformable microgel.In addition to their usefulness in treating bleeding after trauma, PLPs have also shown utility in treating chronic wounds [51], mitigating neuroinfammation after traumatic brain injury [53], and fghting infection when loaded with gold and silver nanoparticles [54,55].Te ability to target sites of fbrin also provides the ability to target existing thrombi to deliver fbrinolytic drugs.Our group has explored this approach and found that more highly crosslinked nanogels are more ideal for drug delivery.Tese fbrin-targeted nanogels are described in more detail in the fbrin-targeting section below.
Other researchers have also mimicked platelets for hemostatic applications and targeted delivery of fbrinolytics.Pawlowski et al. took inspiration from a previously developed platelet-derived microparticle nicknamed "platelet dust" [48].Platelet dust was more formally called plateletderived microparticles (PMPs) and was found to play important roles in cellular signaling, coagulation, and homeostasis [56,57].Pawlowski et al. created PMP-inspired nanovesicles (PMINs) that utilize a liposomal platform that targets activated platelets through GPIIb/IIIa and P-selectinspecifc RGD and EWVDV peptides.Once the PMINs accumulate at thrombi, leukocyte-driven enzymatic degradation causes a breach in the liposomal membrane, thereby releasing thrombolytic cargo streptokinase (Figure 4).In a carotid artery thrombosis mouse model, PMINs efectively targeted thrombi and delayed vessel occlusion while not impacting quiescent platelets and systemic hemostatic capabilities.Given these promising results, this platelet-mimetic platform could be used to deliver antiplatelet, anticoagulant, and fbrinolytic agents to treat a variety of thrombotic conditions.

Red Blood Cell-Derived and Inspired Thrombolytic Therapies
Given RBCs' abundance, larger size, and lengthened life span, RBCs provide another ingenious platform to camoufage and improve the delivery of thrombolytic therapies.Like platelets, RBC membranes are used as a cloak for camoufage.For this purpose, RBCs must frst be lysed and 6 Journal of Tissue Engineering and Regenerative Medicine separated from internal contents.One popular method of RBC lysis is hypotonic hemolysis [58][59][60] which involves exposing RBCs to a hypotonic bufer where they begin to swell until rupture/lysis, followed by centrifugation to separate internal contents and membranes.Drugs or nanoparticles can then be encapsulated by or conjugated onto those RBC membranes.Guido et al. summarize various techniques for encapsulation and conjugation of drugs into/ onto RBCs [27].For encapsulation, there are three main methods: exposure to the hypotonic environment, exposure to the hyperosmotic environment, and electroporation (Figure 5).All methods involve temporarily opening pores to difuse drugs into the RBCs.Extrusion has also been used for the fusion process due to the larger size and complexity of the cargo [59,60].
For conjugation, therapeutic molecules can be attached to RBC membranes through external linkers such as streptavidin [61,62] or RBC-specifc antibodies [63].Since both encapsulation and conjugation require RBC manipulation, hemolysis, loss of glycocalyx or protection of surface conjugated ligands, and change in osmotic pressure can occur [27].It has also been shown that conjugation with rigid nanoparticles (polystyrene), as opposed to soft nanogels (lysozyme-dextran), induces RBC agglutination and increases RBC stifness which can impact its ability to maneuver microvasculature and penetrate clots [64].Careful consideration must be made when deciding how to incorporate thrombolytic elements into RBC membranes.Historically, RBC membranes started of as camoufage for basic anticoagulants or fbrinolytics such as heparin [65] and tPA [61,66].More advanced examples have recently been described.For example, Shao et al. created an erythrocyte membrane-cloaked Janus polymeric motor (JPM) nanoparticle (EM-JPM) composed of heparin and chitosan multilayers that were partially gold coated [58].EM-JPMs combine mechanical force, heat, and anticoagulant abilities to break up thrombi.Tey showed promising targeted and fbrinolytic abilities in an in vitro fbrin clot model under both static and fow conditions; however, animal studies are necessary for further validation.To address multiple issues associated with thrombotic disorders, Zhao et al. designed a fbrin-targeted RBC membrane-cloaked dextran-tirofban conjugate (T-RBC-DTC) nanoparticle that has enhanced targeting ability, stimulus-controlled drug delivery, long circulation time, and ROS scavenging capabilities [60].T-RBC-DTC nanoparticles are cloaked in an RBC membrane and conjugated to the fbrin-targeting peptide, Cys-Arg-Glu-Lys-Ala (CREKA).Te antithrombotic cargo, dextrantirofban conjugate nanoparticles, utilizes dextran as an H 2 O 2 responsive linker that can be oxidized by ROS.Tis responsive linker both scavenges ROS and releases tirofban, an antithrombotic agent.In a carotid thrombosis mouse model, they saw sufcient accumulation at thrombus sites and enhanced antithrombotic activity compared to free tirofban which can be seen in Figure 6.Te researchers noted when designing this therapeutic that they chose an RBC coating over a platelet coating because the antiplatelet agent, tirofban, could compromise the targeting ability of the platelets.Interestingly, another researcher was also considering both platelet and RBC coatings and decided to put the two cells up against each other [67].Teir results indicated that while both RBC (RFNP) and platelet (PFNP) membrane-coated fullerenol-loaded MSNs enhanced circulation times, reduced macrophage phagocytosis, showed excellent blood compatibility, biosafety, and reduced bleeding times; only RFNPs signifcantly enhanced thrombolysis in vivo when compared to the free drug.Chen et al. predicted that when the platelets were collected, they were inactivated by reagents such as ethylenediaminetetraacetic acid which most likely reduced their fbrin-binding afnity.Overall, benefts of using RBCs over platelets are their abundance, larger size, and ability to be loaded with antiplatelet agents without compromising membrane receptors.
While RBC-derived nanoparticles have shown great promise for delivery of antithrombotic therapies, they also share similar limitations with platelets including issues related to scaling up and blood product shortages.One major limitation that is unique to RBCs is blood incompatibility which can cause serious issues such as hemolysis and agglutination [27].Using RBCs that share the same blood type as the patient is ideal; however, that is not always possible.To avoid all issues associated with using real RBCs, some researchers have found ways to mimic RBCs.Colasuonno et al. designed a porous hydrogel-based particle that mimics the discoidal shape of RBCs [68].Tey directly conjugated tPA to PLGA and polyethylene glycol (PEG) matrices via activated carboxylic groups (tPA-DPNs) and used silica molds to achieve a discoidal shape.Refer to Figure 7 for a schematic Journal of Tissue Engineering and Regenerative Medicine and characterization.In a thrombosis mouse model, tPA-DPNs dissolved almost 90% of blood clots, while free tPA only dissolved 40%, verifying the importance of targeted delivery.

Fibrin-Derived, Inspired, and Targeted Thrombolytic Therapies
Fibrin and its precursor, fbrinogen, are common components in thrombolytic therapy mechanisms due to fbrin's abundance in clots and fbrinogen's binding motifs.Fibrinogen contains RGD peptides which target and bind to activated platelets via integrin α IIb β 3 [69].Normally, this leads to further platelet accumulation; however, researchers have utilized this fbrinogen-derived targeting motif to break up clots instead of enhancing them.Chung et al. used a fbrinogen-derived RGD peptide (Gly-Arg-Gly-Asp) to hone their tPA-loaded PLGA nanoparticles to thrombus sites in a clot-occluded tube model [70].While their tPA-loaded PLGA nanoparticles did not have the shortest clot lysis time when compared to their nontargeted nanoparticles, they did have the highest percentage of digested clots.Similarly, Absar et al. also used a fbrinogen-derived c-chain Cterminal peptide (CQQHHLGGAKQAGDV) to target their albumin-camoufaged tPA-loaded nanoparticles to thrombi [71].Teir results were also not ideal because nanoparticle thrombolytic activity was similar to free tPA.To improve upon these therapies, Ye et al. incorporated entire fbrinogen molecules onto the dopamine core of their nattokinase-loaded microcapsules [49].Tese microcapsules   showed excellent antithrombotic performance in vitro through sharp dissolution of fbrin clots and a high blood clotting index.While fbrinogen and fbrinogen-derived RGD binding motifs are still commonly used in targeted thrombolytic therapies, cyclic RGD (cRGD) peptides have also grown in popularity.cRGD peptides mimic fbrinogenderived peptides but have a diferent conformation that gives them an advantage over linear RGD peptides in regards to specifcity and afnity [72].Huang et al. tested cRGDconjugated liposomes and linear RGD-conjugated liposomes in a rat carotid injury model and found that cRGDbound liposomes were signifcantly better at binding activated platelets [69].Following this fnding, Zhang et al. loaded cRGD-bound liposomes with urokinase and tested them in a mouse mesenteric thrombosis model where they found that liposomal carriers reduced the dosage of urokinase necessary to achieve sufcient thrombolysis by 75% [73].Similarly, Huang et al. conjugated cRGD to a tPAloaded lipid nanoparticle, creating a multiarmed nanovesicle which was tested under both static and fow conditions in vitro where the nanoparticles showed efcient tPA release at thrombus sites and clot lysis times similar to free tPA [74].
Further in vivo research will need to be conducted to expand the impact of both fbrinogen-derived and fbrinogenmimicked thrombolytic therapies.Comparatively, fbrintargeted thrombolytic therapies have been extensively researched, and more recent advances will be highlighted here.Adzerikho et al. set out to create a thrombolytic nanovesicle that could accomplish both rapid and prolonged fbrinolytic efects [75].Teir liposomal platform incorporated both bound and free streptokinase and was conjugated to FnI-3C, a fbrin-specifc antibody.Tey found that a 40 : 60 ratio of bound to free streptokinase resulted in the largest thrombolytic efect which was 13 times greater than the free drug in a rat thrombosis model.Utilizing a diferent platform and a fbrin-specifc antibody, our lab has developed a fbrin-specifc nanogel (FSN) that can be loaded with fbrinolytic agents to treat multiple thrombotic complications such as myocardial infarction (MI) or disseminated intravascular coagulation (DIC) [76][77][78].FSNs have a core-shell conformation and are synthesized through polymerization reactions between poly (N-isopropylacrylamide) (pNIPAM) and N,N′-Methylenebis (acrylamide) (BIS), conjugated to an antifbrin fragment E antibody, and loaded with the appropriate agent.FSN synthesis can be seen in Figure 8.To treat thrombotic complications, FSNs were loaded with tPA.It was hypothesized that FSNs could prevent premature release of tPA and directly deliver tPA to microthrombi and break them up.In the context of treating thrombotic occlusion associated with MI, tPA-FSNs dual loaded with a small molecule Rho-kinase inhibitor, Y-27632, were found to localize to injured heart tissue and signifcantly improve left ventricular ejection fraction 2 and 4 weeks post-MI [76].Tese studies also showed a signifcant decrease in the infarct size and signs of fbrosis 4 weeks post-MI.Our group has also used tPA-FSNs to treat the complex thrombotic disorder, DIC.DIC results are due to excessive thrombin generation secondary to many conditions including sepsis, trauma, and pregnancy.Trombi form throughout the microvasculature and can lead to clotting factor consumption, hemorrhage, multi-organ failure, and, in up to 70% of cases, death.In a rat model of LPS-induced DIC, we found that tPA-FSNs decreased the amount of visible multiorgan microthrombi and increased platelet and D-dimer concentration, both signs of thrombus ablation [77].Additionally, tPA-FSNs were well tolerated in vivo even up to 20 times the optimized therapeutic dose.In vivo studies also showed tPA-FSNs were cleared within 24 hours [78].
Taking a less biomaterial-centered approach, Li. et al. created a fbrin-targeted treatment with CREKA-modifed microbubbles [79].Under physiologically relevant fow, the CREKA-modifed microbubbles bound frmly to thrombi.Zhao et al. also used CREKA as the targeting agent for their therapeutic, but their design used photothermal therapy in addition to thrombolytic therapy to create a nanoparticle that deeply penetrates thrombus sites and ablates them [80].Teir design is a coassembly of a photothermal probe, 1,1′dioctadecyl-3,3,3′,3′-tetramethylindotricarbocyanine iodide (DiR) and ticagrelor, an antiplatelet drug.Tis coassembly core is conjugated to CREKA via PEG.In vivo, these nanoparticles target and accumulate in fbrin-rich clots where they are exposed to irradiation.Photoconversion of DiR increases the local temperature which helps break up noncovalent interactions, allowing the ticagrelor to further penetrate clots.Tis photothermal-amplifed antithrombotic efect was tested in a rat carotid arterial thrombosis model.Te nanoparticles combined with photothermal therapy outperformed all single therapies and had a thrombolysis therapeutic rate greater than 75%.Fibrin-targeted and fbrinogen-derived therapies, whether alone or combined with other therapeutic methods, have shown great promise for safely delivering thrombolytics and efectively lysing clots.Figure 8: Fibrin-specifc nanogel synthesis schematic and characterization.Schematic of core-shell particle synthesis and FSN fabrication followed by subsequent tPA loading through a rehydration technique.Figure 8 is reproduced from Mihalko et al. [77], with permission from Elsevier.

Conclusions
For a thrombolytic therapy to be successful, three main things must occur: precise thrombus targeting, efcient load deposition, and efective clot lysis.Most thrombi are composed mainly of activated platelets and fbrin, making these the two main targets.Most of the technologies mentioned in this review target only one of those components; however, targeting both could be a potential avenue for thrombolytic therapies.In fact, this combined targeting technique has been shown to anchor clots more efciently with a lower ligand density than single-targeted nanoparticles [81].Another targeting aspect to consider is the use of external guidance.While thrombolytic therapies that utilize platelets and RBCs as camoufage do aid in targeting, only platelets have proven clot-targeting mechanisms.External guidance, such as magnets or NIR, is sometimes necessary to direct the therapeutics to clots.Similarly, most of the technologies mentioned in this review utilize difusion for drug release, but some also use NIR to release the thrombolytic cargo.Tese combined therapies may have enhanced clot targeting and clot ablating capabilities, but their translatability is hindered due to the sophisticated machinery necessary for the therapeutic to be efective.
While RBCs do not have an internal targeting mechanism, RBCs may be better at loading vesicles because they are not limited by the chemical nature of the cargo as opposed to platelets.Similarly, blood-cell mimics provide the same advantageous characteristics of blood-cell-derived drug delivery systems but have the additional beneft of not relying on donor availability or being concerned with dangerous consequences of blood incompatibility.Still, the immunogenicity of certain artifcial materials should be carefully reviewed.Multiple technologies discussed in this review used PEG as a linker or a nanoparticle component which could create challenges later when assessing immune responses in humans.Te physiomechanical properties of these therapeutics are also important to consider.Te particle size, shape, and stifness afect intravascular drug delivery systems [82].While most drug delivery systems are spherical due to energy minimization, anisotropic shapes have demonstrated better vessel wall margination and adhesion in a hemodynamic environment.Similarly, stif microsized nanoparticles marginate towards vessel walls more efectively, but soft and fexible nanosized particles navigate microvasculature more efciently.Te geometry and material properties of these drug delivery systems must be carefully tuned to promote thrombus targeting.
Te application of these therapeutics to both arterial and venous clots should also be examined.Most therapeutics were tested in arterial clots which are mainly composed of platelets and fbrin, while venous clots are composed mainly of RBCs and fbrin [83].For this reason, fbrin-targeted and derived thrombolytics may be preferred because they can target both arterial and venous clots.Overall, blood-cell inspired and clot-targeted therapies have the potential to make delivering thrombolytic agents safer and more efective to improve the outcomes of patients sufering from lifethreating thrombotic disorders.Additionally, clot-targeted fbrinolytic therapies could improve therapy for recalcitrant clots by enhancing the accumulation/concentration of fbrinolytics directly at the clot.

Figure 2 :
Figure 2: Platelet and thrombolytic therapeutic fusion techniques.Platelets can be loaded with thrombolytics through sonication, electroporation, or extrusion.Sonication uses ultrasonic waves to fuse cargo and membranes together[44], while electroporation exposes membranes to electrical waves, creating pores through which cargo can enter[45].Extrusion requires both cargo and membranes to be run through a porous membrane, where mechanical pressure forces them to interact[46].

Figure 3 :
Figure 3: Schematic illustration of the fabrication of tPA and melanin nanoparticle-loaded platelets and their application for cascaded thrombolysis and neuroprotection mechanisms in ischemic stroke.Figure 3 is reproduced from Yu et al. [43], with permission from Elsevier.

Figure 4 :
Figure 4: Schematic representation of platelet-derived microparticles (PMP) (a) showing characteristic surface entities, with (A) showing a representative red fuorescence image of PE-anti-CD62P stained active platelets (stained for P-selectin and shown with blue arrows) shedding PMPs (shown with yellow arrows), and (B) showing a representative high resolution SEM image of active platelet shedding microparticle, with PMPs (shown with yellow arrows) visible as submicron vesicular structures; (b) schematic representation of PMPinspired nanovesicle (PMIN), with (A) showing a representative cryo-TEM image of PMINs developed for the studies; (c) the envisioned mechanism of targeted thrombolytic action using PMINs, where (A) PMINs can actively anchor onto platelet-rich thrombi by virtue of heteromultivalent binding to integrin GPIIb-IIIa and P-selectin on active platelets, (B) clot-bound PMINs get acted upon by sPLA2 enzymes secreted from leukocytes and active platelets in the thrombus milieu, and (C) drug released from degraded PMINs renders site-specifc fbrinolysis.Figure 4 is reproduced from Pawlowski et al. [48], with permission from Elsevier.

Figure 5 :
Figure 5: RBC lysis and fusion methods.Schematic illustrating RBC lysis, centrifugation, and fusion for small and large molecules.

Figure 6 :
Figure 6: Terapeutic potential of the T-RBC-DTC NPs in the FeCl 3 -induced carotid artery thrombosis mouse model.(a) H & E staining of the carotid arteries from the mice subjected to various treatments.Scale bar: 200 μm.(b) Quantitative analysis of the thrombosis degree.Data are shown as mean ± SD (n � 5).(c) Te levels of TNF-α after various treatments as detected by ELISA.Data are shown as mean ± SD (n � 5).(d) Te levels of sCD40 L after various treatments.Data are shown as mean ± SD (n � 5).* p < 0.05, * * p < 0.01, * * * p < 0.001.Figure 6 is reproduced from Zhao et al. [60], with permission from Elsevier.

Figure 7 :
Figure 7: Physicochemical properties of discoidal polymeric nanoconstructs associated with tPA molecules (tPA-DPNs).(a) Schematic representation of tPA-DPNs, highlighting the porous structure of DPNs and their direct conjugation with tPA.(b) Multisizer analysis of DPNs (green) and tPA-DPNs (orange).(c) Te TEM image of DPNs demonstrating the circular shape with a base diameter of ∼1000 nm.Te upper-left inset shows a fuorescent microscopy image of a RhB-DPN superimposed on its TEM image.(d) Te SEM image of DPNs demonstrating the diameter of ∼1200 nm and the height of ∼347 nm.(e) Te AFM image of DPNs demonstrating the diameter of ∼1100 nm and the height of ∼300 nm.(f ) Size stability of tPA-DPNs in PBS at 37 °C via DLS analysis (n � 3).Figure 7 is reproduced from Colasuonno et al. [68].
Figure 7: Physicochemical properties of discoidal polymeric nanoconstructs associated with tPA molecules (tPA-DPNs).(a) Schematic representation of tPA-DPNs, highlighting the porous structure of DPNs and their direct conjugation with tPA.(b) Multisizer analysis of DPNs (green) and tPA-DPNs (orange).(c) Te TEM image of DPNs demonstrating the circular shape with a base diameter of ∼1000 nm.Te upper-left inset shows a fuorescent microscopy image of a RhB-DPN superimposed on its TEM image.(d) Te SEM image of DPNs demonstrating the diameter of ∼1200 nm and the height of ∼347 nm.(e) Te AFM image of DPNs demonstrating the diameter of ∼1100 nm and the height of ∼300 nm.(f ) Size stability of tPA-DPNs in PBS at 37 °C via DLS analysis (n � 3).Figure 7 is reproduced from Colasuonno et al. [68].

Table 1 :
Blood cell-inspired and clot-targeted thrombolytic therapy technologies, targeting agents, and animal models in which they were tested.