Next Article in Journal
Improving Mobility: A Case Report on the Rehabilitation of a Gait Anomaly in an Asian Elephant at a Thai Elephant Conservation Center
Previous Article in Journal
Characterization of microRNA and Metabolite Profiles of Seminal Extracellular Vesicles in Boars
Previous Article in Special Issue
The Pathological and Histopathological Findings in Cats with Clinically Recognised Hypertrophic Cardiomyopathy Are Related to the Severity of Clinical Signs and Disease Duration
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Animals
Volume 15
Issue 11
10.3390/ani15111630
animals-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

Evolving FATE: A New Lens on the Pathogenesis and Management of Feline Cardiogenic Arterial Thromboembolism

by
Natasha S. Yeh
1,
Meg Shaverdian
2 and
Ronald H. L. Li
3,*
1
Terry Veterinary Medical Center, College of Veterinary Medicine, North Carolina State University, Raleigh, NC 27606, USA
2
Department of Surgical and Radiological Sciences, School of Veterinary Medicine, University of California, Davis, CA 95616, USA
3
Department of Clinical Sciences, College of Veterinary Medicine, North Carolina State University, Raleigh, NC 27606, USA
*
Author to whom correspondence should be addressed.
Animals 2025, 15(11), 1630; https://doi.org/10.3390/ani15111630
Submission received: 6 April 2025 / Revised: 23 May 2025 / Accepted: 29 May 2025 / Published: 1 June 2025
(This article belongs to the Special Issue Canine and Feline Cardiomyopathies—Current and Future Strategies for Diagnosis and Treatment)
Browse Figures
Versions Notes

Simple Summary

Feline arterial thromboembolism (FATE) is a severe and often fatal complication of feline cardiomyopathy, associated with a poor prognosis. Despite its clinical significance, the underlying pathophysiology remains incompletely understood. Current management strategies primarily focus on secondary prevention after a thromboembolic event, with limited emphasis on mitigating risk before onset. This review highlights emerging areas of research, including the roles of immunothrombosis, platelet heterogeneity, genetic testing, and precision medicine. Advancements in these fields may support the development of improved diagnostics and targeted therapies, ultimately enhancing outcomes for affected feline patients.

Abstract

Feline cardiogenic arterial thromboembolism (FATE) remains one of the most devastating complications of feline cardiomyopathies, with high mortality and recurrence rates. Despite its clinical importance, significant knowledge gaps persist in our understanding of FATE’s pathogenesis and optimal management strategies. Our review aims to address these gaps by providing a comprehensive overview of the current understanding of FATE, including disease mechanisms, risk factors, emerging diagnostics, and preventative strategies. Importantly, we identify key areas such as immunothrombosis, procoagulant platelets, platelet heterogeneity, and altered fibrinolysis where future research may yield novel biomarkers and therapeutic targets to improve outcomes in affected feline patients.

1. Introduction

Feline cardiogenic arterial thromboembolism (FATE) is a devastating complication in cats with cardiomyopathies. FATE occurs when an intracardiac thrombus develops, dislodges into the systemic circulation, and embolizes to distal arteries, where partial or complete obstruction of blood flow in the systemic vasculature impedes blood flow, creating blood turbulence and thrombus growth. This leads to tissue ischemia, pain, tissue necrosis, hypoperfusion, ischemic-reperfusion injury, and systemic inflammation (Figure 1) [1]. The mortality rate reported is as high as 54%, with nearly one-third of cats euthanized shortly after diagnosis, and about 50% of cats died within 48 h of initial hospitalization. Long-term prognosis in cats that survived beyond hospital discharge is variable, with a recurrence of FATE ranging from 16.7% to 75% [2,3,4,5,6]. However, this is greatly influenced by the antithrombotic strategy for a FATE event. Other factors that contribute to poor outcomes include concurrent congestive heart failure (CHF), atrial fibrillation, and sudden death [1,3,5,7,8,9]. Due to the poor prognosis of FATE, primary prevention in high-risk patients is crucial to reducing the risk of intracardiac thrombosis and subsequent thromboembolic events. However, effective prevention depends on the timely recognition of risk factors; yet veterinarians currently have limited tools to reliably identify predisposed cats. Current diagnostic measures rely solely on echocardiographic assessments; however, this is complicated by the fact that most at-risk cats are clinically asymptomatic and lack auscultatory abnormalities that would typically indicate the need for echocardiographic evaluation. In addition, current evidence in antithrombotic strategies heavily emphasizes secondary prevention following an initial FATE event, while largely neglecting primary prevention [1,3,6]. Moreover, existing diagnostic and therapeutic approaches do not consider the contribution of the immune system in driving immunothrombosis and systemic hypercoagulability. This review aims to provide a brief overview of the current understanding and knowledge gaps in FATE pathophysiology, risk assessment, and antithrombotic strategies. Additionally, we will propose and highlight some future research directions to bridge these gaps, ultimately advancing knowledge and improving outcomes for cats with FATE.

2. A Review of FATE Pathophysiology: Current Evidence and Knowledge Gap

Hemostatic balance is maintained by several regulatory mechanisms. In healthy animals, anticoagulant factors are slightly favored to maintain blood as a fluid state [10]. However, upon vascular injuries, primary and secondary hemostasis are activated to induce clot formation and wound healing [10]. While FATE pathophysiology is complex and not well understood, cardiomyopathies in cats can impact each of the three components of Virchow’s triad. Figure 2 summarizes the current understanding and knowledge gaps in the pathogenesis of FATE based on Virchow’s triad [1,8].

2.1. Platelet Activation

Systemic hypercoagulability as a leading cause of FATE has been explored. Platelets, the principal effector cells of primary hemostasis, are responsible for forming the initial platelet plug via the three-stage model of platelet activation, which involves adhesion, activation, and stabilization [9]. To date, a few ex vivo studies have documented increased platelet activation in cats with subclinical and clinical hypertrophic cardiomyopathy (HCM), which is the most prevalent form of cardiomyopathy, affecting up to 1 in 7 cats [11,12,13,14]. One study in a colony of Maine Coon cats with severe HCM, characterized by left atrial (LA) enlargement, left ventricular (LV) wall thickening and end-systolic cavity obliteration, found increased platelet activation, platelet-derived microparticles and platelet endothelial adhesion molecules compared to control cats [11]. Studies also documented platelet hyperresponsiveness to agonists in cats with HCM and transient myocardial thickening [12,13,14]. A study found a significant association between platelet priming and intracardiac thrombosis in cats with transient myocardial thickening due to wildfire-related injuries and smoke inhalation. Interestingly, despite LA enlargement, LA systolic function was increased in these cats, suggesting that underlying cardiomyopathies in cats are associated with increased platelet priming [14]. Platelet priming is a cellular response that leads to unrestrained and amplified platelet activation. However, the mechanisms underlying the observed platelet priming are not well understood.

2.2. Systemic Hypercoagulability

Secondary hemostasis further reinforces the initial platelet plug through the polymerization of fibrin, which is formed by a cascade of enzymatic reactions that convert prothrombin to thrombin. Systemic hypercoagulability, which is caused by an imbalance of excess thrombin generation or deficiencies in intrinsic anticoagulants, has been hypothesized to be the cause of FATE in cats with cardiomyopathies. There is, however, conflicting evidence that supports this hypothesis. One study, which assessed systemic coagulation by measuring thrombin antithrombin (TAT) complexes, antithrombin, factor VIII activity, and fibrinogen, found that a higher proportion of cats with clinical evidence of thrombosis (spontaneous echocardiographic contrast, FATE) had increased fibrinogen and TAT concentrations compared to healthy controls. However, their overall distributions were not significantly different [15]. Increased TAT complexes and decreased antithrombin concentration could indicate active thrombin generation and consumption of antithrombin [16]. In addition to plasma proteins, blood cells like platelets, erythrocytes, and leukocytes are integral to the activation of coagulation factors and fibrin, a process known as the cell-based model of coagulation [17]. Investigators have evaluated the cell-based model of coagulation using viscoelastic assays in whole blood with inconclusive results. One study, which utilized a novel point-of-care viscoelastic assay (VCM VET), found that cats with FATE were hypocoagulable as demonstrated by decreased alpha angle and maximum clot formation (MCF) when compared to healthy cats [18]. These observations were hypothesized to be secondary to consumptive thrombocytopenia, hyperlactatemia, or suboptimal blood collection. Another study that utilized the same assay in cats with FATE with and without congestive heart failure did not demonstrate any evidence of systemic hypercoagulability when compared to healthy cats [19]. However, these results should be interpreted with caution since neither study excluded cats with concurrent thrombocytopenia. Platelet count has been shown to be directly proportional to MCF on VCM VET despite clopidogrel treatments in cats [20]. Additionally, VCM has low sensitivity in detecting hypercoagulability in dogs with one study reporting a low positive predictive value for hypercoagulable sick dogs when compared to thromboelastography (TEG) [21,22]. VCM’s sensitivity and specificity in detecting feline hypercoagulability are currently unknown. While further research is needed to validate the use of viscoelastic testing in cats, the current evidence suggests that hypercoagulability alone is not the sole driving force of FATE pathogenesis.

2.3. Alterations in Fibrinolysis

Fibrinolysis is a highly regulated process aimed at re-establishing blood flow after clot formation via active thrombolysis. Cross-linked fibrin is cleaved by plasmin via formation of a tertiary complex consisting of tissue plasminogen activator or urokinase plasminogen activator, fibrin, and plasminogen [23]. A recent retrospective study by Busato et al. showed that the FATE prevalence is associated with the manifestations of CHF. Interestingly, cats with large volume pleural effusion were found to have a lower incidence of FATE (6.6%) compared to those with cardiogenic pulmonary edema (33%). The difference in FATE incidence is hypothesized to occur due to the intrinsic fibrinolytic properties in pleural effusion being resorbed into the systemic circulation, thus preventing thrombus formation [24]. Pulmonary edema might also be more proinflammatory than pleural effusion, leading to increased immunothrombosis, an intricate process that links systemic inflammation with coagulation.

2.4. Immunothrombosis

Activation of innate immunity and systemic inflammation may play a vital role in FATE pathogenesis [25,26]. As a vital component of the host defense mechanism, immunothrombosis occurs when infections or inflammation activate the immune and coagulation systems to facilitate microvascular thrombosis, preventing systemic dissemination of pathogens and promoting wound healing [27,28,29,30]. However, dysregulation of immunothrombosis has been demonstrated to cause systemic hypercoagulability and thromboembolic complications in humans and animal models [31,32]. A key component of immunothrombosis is the formation of neutrophil extracellular traps (NETs), which are decondensed extracellular chromatin decorated with antimicrobial proteins like neutrophil elastase, cathepsin G, and myeloperoxidase [33]. NET formation, also known as NETosis, plays an essential role in innate immunity by entrapping and killing microorganisms by subjecting them to high concentrations of antimicrobial proteins [25]. However, overzealous NETosis can lead to excessive clot formation, as NETs possess prothrombotic properties [34,35,36]. Circulating NETs in the form of cell-free DNA and citrullinated histones (citH) have been characterized in cats with FATE and HCM. Cell-free DNA (cfDNA) was observed to be higher in cats with FATE, but was not associated with any known risk factors of FATE [37]. Further characterization of cfDNA fragments revealed that prothrombotic cfDNA fragments that are greater than 300 base pairs were detected only in cats with HCM, with or without FATE [37]. The size profile of these cfDNA fragments indicated that an active process like NETosis, rather than a degradative process, was the primary cause for increased cfDNA levels [37]. Citrullinated histones, which are modified histones specific to NETs formation, were also significantly elevated in cats with HCM and FATE. Interestingly, the study showed that none of the clinically healthy cats had any detectable levels of citH. Additionally, it demonstrates that plasma citH is superior to cfDNA in correlating with known risk factors of thrombosis on echocardiogram [15,25]. In human and murine studies, histones are known to prime platelets to be hyper-responsive to physiologic agonists to augment adhesion, induce activation, and accelerate platelet-dependent thrombin generation via Toll-like receptors 2 and 4 [38,39]. Hence, histones may be a potential biomarker and therapeutic target for HCM cats and cats with FATE.

2.5. Blood Stasis

Alterations in hemodynamics within the heart occur in cats with HCM or other types of cardiomyopathies due to structural cardiac changes. In HCM, marked elevation in LV pressure caused by myocardial thickening and diastolic dysfunction leads to LA pressure overload, LA dilation, and, eventually, LA systolic dysfunction [40]. Decreased LA contractility causes blood flow stasis, facilitating blood cells, fibrinogen, and clotting factors to aggregate, forming intracardiac thrombus [40]. Spontaneous echocardiographic contrast (SEC), commonly referred to as “smoke” within the LA, is an ultrasonographic finding of increased echogenicity due to red blood cell aggregates formed at low blood flow velocity [40]. SEC and intracardiac thrombus within the LA appendage are high-risk factors for FATE development. Decreased LA blood flow, measured as left auricular flow velocity on an echocardiogram, is also an independent predictor of SEC and FATE [40].

2.6. Endothelial Injury

In healthy animals, the endothelium produces several anticoagulant molecules and vasodilatory agents to prevent excessive clot formation. These products include protein C receptors, a small proportion of protein C, thrombomodulin, prostaglandin, tissue factor pathway inhibitor, and heparan sulfate [17,41]. Once bound with thrombin, thrombomodulin (TM), an endothelial glycoprotein, exerts its anticoagulant effects by activating protein C to not only inhibit factors Va and VIIIa but also accelerate fibrinolysis. The TM-protein C system also possesses anti-inflammatory and cytoprotective properties [42]. Thrombomodulin has been demonstrated to be decreased in cats with overt HCM, indicating that endothelial dysfunction may play a role in hypercoagulability in cats with cardiomyopathies [43]. The endothelium also produces proteases, mainly tissue plasminogen activator, to induce fibrinolysis by converting plasminogen to plasmin [44]. Endothelial injuries in HCM caused by severe LA dilation and stretching of the myocardium may lead to exposure of subendothelial matrices and upregulation of procoagulant proteins. Upon endothelial injury or activation via thrombin, von Willebrand factor (vWF), a glycoprotein that resides within Weibel-Palade bodies, is secreted extracellularly. Following the cleavage of vWF by the enzyme ADAMTS13 to its less adhesive forms, vWF mediates platelet adhesion on the endothelium. In humans with HCM, vWF plasma concentrations are significantly increased secondary to microvascular dysfunction [45]. Increased circulating vWF, measured by immunodetection, has been shown to be associated in cats with acute FATE [46]. At the same time, vWF is shown to be upregulated in the endocardium of HCM-affected cats [47]. This evidence further supports the notion that cardiomyopathies can exacerbate endocardial and endothelial activation to facilitate thrombus formation.

3. Knowledge Gap and Future Research Directions in FATE Pathogenesis

3.1. Procoagulant Platelets

While increased platelet activation has been repeatedly shown to be associated with cats with cardiomyopathies, a lesser-known phenomenon is the effects of cardiomyopathies on different platelet phenotypes. In addition to the well-studied aggregatory platelets, procoagulant platelets are now a recognized sub-population of platelets, which exhibit distinct morphological and functional characteristics. Persistent exposure to potent agonists like collagen and thrombin causes platelets to lose their typical discoid shape and adopt balloon-shaped phenotypes with membrane blebbing. This transformation is accompanied by a sustained increase in intracellular calcium and the externalization of electronegative phospholipids like phosphatidylserine (PS), which enhances the assembly of coagulation factor complexes such as tenase and prothrombinase complexes to accelerate thrombin generation [48]. Through clot retraction, procoagulant platelets are translocated to the thrombus periphery, where increased fibrinogen binding further strengthens the thrombus structure [49]. While their role in hemostasis is crucial, an imbalance that favors their formation may lead to prothrombotic conditions such as ischemic stroke, coronary heart disease, deep vein thrombosis, and spontaneous intracranial hemorrhage in humans [50,51,52]. A recent study characterized the formation of procoagulant platelets in healthy cats using a set of platelet markers, including P-selectin, inner mitochondrial membrane potential (Δψm), and PS [53]. The results showed that, similar to human platelets, stimulation of feline platelets with thrombin and glycoprotein VI agonists induces similar phenotypes such as PS externalization, P-selectin expression, and a loss of Δψm. Future research should focus on the effects of cardiomyopathies on this dichotomy of platelet activation, since current antiplatelet strategies do not target the formation of procoagulant platelets.

3.2. Knowledge Gaps in Immunothrombosis

In addition to increased circulating citH and cfDNA in cats with HCM, arterial thrombi in cats are rich in citH, which suggests that NETs play an active role in the pathogenesis of FATE [54]. The underlying mechanisms of increased NETosis, however, are not well understood in cats with cardiomyopathies. One potential mechanism is that increased platelet activation may facilitate platelet-neutrophil interactions to promote NETs production. Activated platelets have been shown to stimulate neutrophils to produce NETs by directly or indirectly binding to neutrophils. Cellular mechanisms mediating this cell-to-cell crosstalk are species-dependent. For example, while the binding of platelet P-selectin to the neutrophil receptor, P-selectin glycoprotein ligand-1 (PSGL1), is crucial for NETosis in murine sepsis models, human neutrophils, on the other hand, require firm adhesion mediated via neutrophil integrins and platelet glycoprotein 1bα [55,56,57]. Increased circulating citH due to NETosis may further exacerbate platelet activation in cats with cardiomyopathies. Activated platelets also release a number of soluble mediators, creating an environment that favors the production of NETs by nearby neutrophils, creating a vicious cycle. Future research should focus on uncovering these underlying mechanisms as they are instrumental in the discovery of new therapeutic targets. Research is ongoing to explore and target the immunothrombotic interactions between neutrophils and platelets to reduce inflammation, NET production, and platelet priming.

3.3. Congestive Heart Failure and Fibrinolysis

Lastly, the effects of different manifestations of CHF on fibrinolysis require further investigation. Because cats at risk of FATE often have concurrent CHF, this has direct implications for optimizing the primary prevention of FATE. No studies have specifically investigated the fibrinolytic and coagulation profiles in cats with different CHF manifestations. One study described a trend of decreased plasminogen activity in cats with acquired heart disease, while others have found evidence of hypercoagulability, hyperfibrinogenemia, and increased blood viscosity in cats with HCM hypertrophic cardiomyopathy [15,58,59]. However, no studies, to date, have directly compared fibrinolysis in cats with CHF manifesting as large-volume pleural effusion or pulmonary edema. The biggest challenge of quantifying fibrinolysis is that the overall process is dependent on the quantity and quality of various fibrinolytic enzymes like tissue plasminogen activator and their inhibitors like plasminogen activator inhibitor-1 (PAI-1) and thrombin-activable fibrinolysis inhibitor (TAFI). Biomarkers of fibrinolysis, while clinically accessible, may be limited in their diagnostic ability in evaluating fibrinolysis. Fibrin degradation products, including D-dimer, a fragment of cross-linked fibrin, are associated with increased fibrinolysis due to recent or ongoing clot formation [60]. There is an association between plasma levels of D-dimers and FDPs for human patients with suspected thromboembolic disease [61]. A study concluded that elevated D-dimer concentrations were found in HCM cats with FATE, as well as cats with evidence of systolic anterior motion of the mitral valve [62]. D-dimer, however, has poor sensitivity and specificity in predicting thrombosis in cats with HCM. A study of asymptomatic HCM cats did not demonstrate any association between D-dimer levels and LA size when compared to healthy cats [8]. Another potential fibrinolysis biomarker is plasmin-alpha-2 antiplasmin complex (PAP). Alpha-2 antiplasmin inhibits plasmin by forming a covalent complex and is an indication of fibrinolysis activation. In humans, PAP is weakly associated with an increased risk of venous thromboembolism and ischemic stroke, and is increased in patients with acute myocardial infarction [63,64,65,66]. Its use has not been validated in cats.
Clot lysis assays have been used in human medicine as a standard method to evaluate overall fibrinolytic potential over time, but this has not been validated in cats. Assessment of fibrinolysis in whole blood using the viscoelastic assay, VCM VET, in cats with CHF has failed to demonstrate any differences in clot degradation between FATE cats with or without CHF. However, the addition of exogenous fibrinolysis activators, like tissue plasminogen activator, may increase the sensitivity of fibrinolysis potential, as it may test for the function of modulatory molecules such as PAI-1 and TAFI.

3.4. Blood Flow Stasis and Endothelial Injury

While it is universally accepted that SEC is associated with severe LA dysfunction, the blood elements causing the characteristic swirling pattern of blood flow on echocardiogram in cats are unclear. Previous in vitro studies in human whole blood have shown that blood echogenicity is largely dependent on the formation of erythrocyte-fibrinogen aggregates under low shear forces [67,68]. Although platelets are not echogenic in nature, platelet aggregates were found to be echogenic once they are activated. This was further confirmed by Zotz et al., who demonstrated that blood collected from the LA of human patients with SEC had significantly higher numbers of activated platelets, leukocytes, and platelet–monocyte aggregates [69]. Further studies in cats are needed to evaluate if platelets and leukocytes are involved in SEC formation.
Recall that vWFs are cleaved rapidly from their largest high-molecular-weight multimers to their less adhesive forms once they are released into the circulation. This proteolytic transformation of vWF is largely dependent on shear stress. For that reason, different cardiomyopathy phenotypes may influence the functional capacity of vWF in cats. In humans with the obstructive form of HCM, individuals with peak left ventricular outflow tract gradient of >30 mmHg are found to have functional impairment of vWF, characterized by decreased collagen-binding activity and lower levels of high molecular weight multimers [70]. These findings suggest that the thrombotic risk in cats with cardiomyopathies, especially HCM, may vary based on the degree of left ventricular outflow tract obstruction, and further studies are needed to better characterize the acquired changes in vWF structure and function. On the other hand, low shear stress in severely dilated LA with poor systolic function may increase the thrombogenic properties of vWF. In a study of human patients with atrial fibrillation, vWF quantity and function are directly proportional to LA function and are independent predictors of intracardiac thrombosis [71].

4. Current Risk Factors of FATE

Early identification of risk factors requires sensitive and specific diagnostic tests to identify risk factors associated with the development and progression of FATE. To date, the only reliable diagnostic test shown to predict SEC and FATE is echocardiography [8]. Table 1 summarizes the reported risk factors of FATE in cats.

4.1. Echocardiography

On echocardiogram, the presence of LA enlargement, commonly assessed by measuring the ratio of the diastolic LA diameter to aortic root diameter from a right-sided short axis view (LA:Ao, Figure 3C), is a significant risk factor for cardiac-related deaths such as CHF and FATE [40,72,73]. With proper training, skilled practitioners can acquire essential views, such as those shown in Figure 3, on point-of-care ultrasound to assess LV thickness and LA size in cats. A severely enlarged LA is an indication of concurrent or imminent congestive heart failure and often signals LA dysfunction. Systolic dysfunction of LA, evaluated by measuring the fractional shortening of LA or LA appendage flow velocities, increases the risk of blood flow stasis, causing SEC or intracardiac thrombosis (Figure 3D). LA appendage flow velocity <20 cm/s on echocardiography indicates severe LA systolic dysfunction and is an independent predictor of SEC formation and, possibly, FATE (Figure 3E,F) [40]. Previous thromboembolic events and reduced LA fractional shortening are also prognostic indicators for FATE and cardiac-related mortality [72,73].

4.2. Cardiac Biomarkers

Currently, there are no clinically available biomarkers that can accurately predict the onset of FATE. N-terminal prohormone of brain natriuretic peptide (NT-proBNP) is a cleaved by-product of B-type natriuretic peptide synthesized in the cardiac myocytes in response to stretch or stress. In an emergency setting, NT-proBNP is most useful when it is used in cats with respiratory distress to differentiate between cardiogenic and respiratory causes. If access to a cardiologist or point-of-care (POC) ultrasound is not possible, it is reasonable to measure serum or plasma NT-proBNP, especially in cats with radiographic evidence of cardiomegaly [74,75]. It is important to note that NT-proBNP is moderately accurate for detecting advanced stages of HCM but may be normal in cats with mild subclinical HCM [74]. Studies evaluating the use of POC NT-proBNP in apparently healthy cats showed that NT-proBNP testing is specific (96% to 100%) with an acceptable range of positive predictive values (78% to 100%) [76,77]. This means that a cat with a positive test likely has underlying heart disease and should be referred for echocardiography. The positive predictive value, which is an indication of true positives, would theoretically be higher in a population of cats greater than 7 years of age, given the higher prevalence of heart disease in geriatric cats. However, it is important to recognize that the cutoff of 200 pmol/L on POC NT-proBNP may result in false negatives, as cats with asymptomatic HCM can be found in the 100 to 200 pmol/L range [77].
Elevated cardiac troponin I (>0.06 ng/mL) showed high sensitivity and specificity for asymptomatic HCM cats compared to healthy cats [78,79]. However, comorbidities such as kidney disease, hyperthyroidism, and hypertension can cause elevated troponin I [78]. A study found that normal troponin I levels were detected in asymptomatic HCM cats without LA dilatation [79]. One study evaluating troponin I in feline HCM noted that two of the cats with thromboembolic disease had the highest elevations of the study population [80]. Other studies have shown a significant elevation in troponin I for cats with acute FATE compared to cats with mild to moderate HCM [75,78]. One cat within the study had a severely elevated troponin I six hours prior to the onset of FATE [75]. Thus, further studies are required to determine the predictive role of this biomarker. The authors recommend that cardiac biomarkers should be utilized in conjunction with other diagnostic tests. Research is ongoing to develop reliable diagnostic tests that may be readily available for veterinary practitioners to identify cats at risk of FATE.

5. Knowledge Gaps and Future Directions in Identifying Risk Factors

5.1. Platelet Heterogeneity as a Risk Factor of FATE

Circulating platelets in cats are highly variable in size, and increased mean platelet volume (MPV) in cats with FATE may indicate platelet activation due to micro-aggregation or underlying inflammation [81]. In people with heart diseases, elevated MPV is associated with increased hospitalization. However, its use in risk stratification in cats with cardiomyopathy requires further investigation. In recent years, researchers have increasingly recognized the importance of platelet heterogeneity, which explains why platelets behave and function differently between individuals. Assessing the proteome and RNA expression in platelets from cats with cardiomyopathies would be an important first step in characterizing platelet heterogeneity and its association with FATE. Lastly, the diagnostic significance of procoagulant platelets as biomarkers to predict thrombotic events in cardiomyopathic cats should be evaluated.

5.2. Hematological Variables as Risk Factors of FATE

Neutrophil-to-lymphocyte ratio (NLR) is an indicator of acute inflammatory stress response and an imbalance between innate and adaptive immunity during systemic diseases. Normal NLR ranges from 1 to 2, and an elevated NLR (>2) is associated with neoplasia and inflammatory disorders in cats [82,83,84]. Increased NLR has been shown to be a negative prognostic indicator in cats with HCM [82]. According to one retrospective observational study, increased NLR >4.46 was associated with reduced median survival time and cardiac-related deaths in cats with ACVIM Stages B and C cardiomyopathies, including those with intracardiac thrombus and spontaneous echo contrast [82]. Further research is needed to confirm whether serial assessment of NLR or NLR trends could be a more robust biomarker for assessing thrombotic risk in cardiomyopathic cats.

5.3. NETs as Biomarkers of FATE

Increased circulating NETs in the form of cell-free DNA and citH have been documented in cats with HCM. Of the two biomarkers, citH is significantly correlated with echocardiographic risk factors, including LA enlargement and left auricular flow velocity, suggesting its potential as a diagnostic marker for predicting FATE. Due to the cumbersome nature of electrophoresis and Western blot analysis, future research should be directed towards developing a feline-specific point-of-care assay that is highly sensitive and specific in measuring plasma citH. In addition, a longitudinal study that evaluates plasma citH over time in cats with subclinical HCM would provide additional diagnostic information on the pathophysiologic significance of immunothrombosis [25,54].

5.4. Other Biomarkers of FATE

MicroRNAs are non-coding RNAs that either silence or degrade messenger RNA sequences to regulate gene expression. Cats with HCM were previously found to have distinct microRNA expression profiles for LV and LA when compared to healthy cats without HCM [85]. In humans, circulating microRNA profiles have been evaluated in individuals using an unbiased array approach to distinguish not only those with clinical HCM, but also subclinical HCM from healthy controls [86]. These findings highlight the potential of utilizing circulating microRNAs for identifying cats with subclinical HCM, allowing for early thromboprophylaxis to prevent FATE.

6. Current Recommendations of Primary and Secondary FATE Prevention

Current guidelines recommend that all cats in Stage B2, C, and D cardiomyopathies should be treated with clopidogrel as primary thromboprophylaxis [87]. This recommendation is largely based on the aforementioned ex vivo studies as well as 2 prospective clinical trials. The FATCAT study showed that cats that were randomized to receive clopidogrel after an initial FATE event had a longer median time to FATE recurrence and a longer median survival time compared to those randomized to aspirin treatment [6]. There is currently not enough evidence to recommend the sole use of direct oral factor Xa inhibitors like rivaroxaban or apixaban, or anticoagulants like unfractionated heparin therapy and lower molecular weight heparin [87]. The SUPERCAT study, which compared clopidogrel to once-daily rivaroxaban treatment in cats that survived their first event of FATE, demonstrated no difference in ATE recurrence between the two groups [88]. However, this study was likely underpowered, and its results may have been biased by the greater progression of cardiomyopathy in cats within the rivaroxaban group compared to the clopidogrel group. In another ex vivo study, healthy cats treated with rivaroxaban alone had evidence of platelet priming compared to those treated with clopidogrel alone or dual agent therapy with clopidogrel and rivaroxaban [89]. The underlying mechanisms behind these findings remain unclear, necessitating further studies to determine whether anti-platelet therapy may have a cardioprotective effect. Additionally, it is important to note that the current evidence may not directly apply to the primary prevention of FATE, as major clinical trials have only included cats that survived an initial episode of FATE, which may have introduced selection bias and overstate the survival benefit of antithrombotics.
Dual agent therapy (DAT) aims to simultaneously target the interactions between primary and secondary hemostasis to further dampen platelet activation and thrombin propagation. A retrospective study observing the use of clopidogrel and the activated factor X (FXa) inhibitor, rivaroxaban, found favorable outcomes in clinical cats receiving DAT with 0% incidence of FATE in high-risk cats and a recurrence rate of 16.7% [5]. Another retrospective study that evaluated the use of continuous infusion of enoxaparin intravenously with clopidogrel in 36 FATE cases showed that enoxaparin administration was safe, but the in-hospital mortality rate remains high at 48%, which is similar to findings from other studies. [90]. An ex vivo study in a colony of healthy cats found that DAT with rivaroxaban and clopidogrel not only decreased circulating activated platelets but had synergistic inhibitory effects on thrombin-mediated platelet activation and platelet-dependent thrombin generation compared to rivaroxaban or clopidogrel alone. Further clinical trials are needed to evaluate the benefit of DAT in reducing the incidence of FATE in cats with clinical HCM.

7. Knowledge Gap and Future Directions in Optimizing Prevention Strategies

7.1. Genetic Testing

Clopidogrel is an antiplatelet drug that irreversibly inhibits the ADP receptor, P2Y12, after it is metabolized to its active metabolite by the liver [91]. The pharmacodynamic response to clopidogrel in cats is highly variable, with reduced efficacy reported in up to 30% of cats [12,45]. This, otherwise known as “clopidogrel resistance”, is caused by a single-nucleotide polymorphism within the ADP receptor gene, P2RY1, which encodes the ADP receptor, P2Y1 [92]. The P2RY1:A236G variant was found to be associated with a significant reduction of platelet inhibition by clopidogrel in HCM cats [92]. The exact mechanism of this altered pharmacogenomic response is unknown, since the clopidogrel active metabolite inhibits the other ADP receptor, P2Y12, and not P2Y1. Peptide modeling suggests that variants in P2RY1 may cause either upregulation or gain-of-function of the P2Y1 receptor. Clopidogrel may, therefore, not be the optimal antithrombotic therapy in cats with the heterozygous or homozygous variant. Given the high prevalence of clopidogrel resistance (homozygous 16.3%, heterozygous 51%), precision medicine utilizing molecular testing for this mutation may be a sensible approach to evaluate clopidogrel response and optimize thromboprophylaxis in cats with HCM [92]. Historically, the limited availability of genetic testing has been a barrier to optimizing antiplatelet therapy through a precision medicine approach. However, with the recent availability of feline-specific P2RY1 testing and increasing access to commercial whole-genome sequencing, clinicians in general practice now have tools to individualize antithrombotic therapy. This also underscores the importance of future clinical trials evaluating the clinical outcomes in cats with P2RY1-guided antithrombotic therapy in at-risk cats.
Further research in determining the microRNA profiles of cats with HCM may aid in distinguishing cats with subclinical disease and identifying those at increased risk for developing FATE [93]. How to effectively apply microRNA profiling in clinical practice remains unclear.

7.2. Platelet Function Testing in Clinical Practice

Light transmission aggregometry is the gold standard of monitoring antiplatelet therapy, but is poorly standardized among laboratories. Because it requires operators to generate platelet-rich plasma, in vitro activation during the centrifugation process can severely impact the utility of the assay in a clinical setting. In addition, the diagnosis of clopidogrel resistance requires aggregation measurements before and after treatments, making it impractical to utilize in practice. A more user-friendly and automated version of platelet aggregometry utilizing whole blood samples has successfully been validated in cats to evaluate clopidogrel response, but its availability is restricted to research or referral institutions [92,94]. The Platelet Function Analyzer (PFA-100 or 200) measures the duration required for the formation of the platelet plug within the aperture under high shear rates. Despite its ease of use, flow obstruction caused by in vitro platelet activation and aggregation may present a problem for assessing platelet function in cats [95,96]. PFA, therefore, may be a suitable test in assessing the antiplatelet effects of clopidogrel, although its diagnostic ability in identifying cats with clopidogrel resistance requires further evaluation [95,97]. Another POC assay called Plateletworks is an accessible test as it measures platelet aggregation by comparing platelet counts in EDTA-anticoagulated blood and specialized blood tubes containing agonists like ADP or collagen. Blood tubes containing platelet agonists induce platelet activation and aggregation, which then lowers the platelet count. The main advantage of this assay is that no specialized equipment is needed. Aggregation is mathematically derived by comparing platelet counts in blood tubes with or without platelet agonists using an automated analyzer. While the assay shows some promise in assessing antiplatelet effects of clopidogrel, it may not be sensitive enough to detect the drug effect of aspirin [98,99].

7.3. Monitoring of Anticoagulants

Current guidelines do not have specific recommendations on the routine monitoring of anticoagulants like low molecular weight heparins (LMWH) or direct oral FXa inhibitors. The gold standard assay for assessing the efficacy of LMWH and direct oral anticoagulants is measuring anti-factor Xa activity (aXa). In humans, the recommended therapeutic target of LMWH is 0.5 to 1 IU/mL [100]. However, the optimal ranges of aXa that would offer the best protection have yet to be established in cats. Compared to humans and dogs, cats have more rapid elimination of LMWH, while rivaroxaban has more predictable pharmacodynamic effects and a longer median half-life of about 8 h [101,102]. In one ex vivo study in cats, rivaroxaban achieved the recommended human target range for thromboprophylaxis, and the duration of protective aXa was dose-dependent [101]. Based on this data, it is difficult to justify routine testing of aXa activity to evaluate the anticoagulant effects of rivaroxaban in cats. Because the elimination of rivaroxaban is largely dependent on renal function and, to some degree, hepatic function, human beings with hepatic or kidney diseases receiving rivaroxaban are at a higher risk of developing hemorrhagic complications. For that reason, aXa testing is reserved for those with decreased renal function. Consequently, assessing rivaroxaban-mediated aXa in cats with kidney disease or those who develop SEC or intracardiac thrombosis during treatment is a sensible approach to guide dose adjustments. Future research should explore aXa-guided dose adjustments of direct oral anticoagulants to prevent FATE and its recurrence.

7.4. Viscoelastic Testing to Monitor Antithrombotic Therapies

Point-of-care viscoelastic testing provides a real-time quantitative and qualitative assessment of global coagulation, including primary and secondary hemostasis, contribution of blood cells to clot formation, and fibrinolysis [103]. Several analyzers are currently available to veterinary practitioners, including TEG, viscoelastic monitor (VCM-VET), and rotational thromboelastometry (ROTEM). Viscoelastic testing may be a valuable tool in guiding antithrombotic treatments in cats with FATE, but many questions remain due to the high interassay and interindividual variabilities and the lack of consensus on how to define hypercoagulability on viscoelastic testing assays in HCM-affected cats. Due to the lack of standardized reference intervals and considerable intraassay variability, further research to utilize viscoelastic testing for serial monitoring or assessing therapeutic response may be more beneficial than as a standalone diagnostic tool. One study evaluated TEG and VCM-VET for monitoring clopidogrel treatment in healthy cats. Using light transmission aggregometry as a gold standard, investigators found that cats that were resistant to clopidogrel had decreased R time on TEG, which suggest that R time may be used as a diagnostic tool to assess clopidogrel response [20]. Because viscoelastic tests assess both clot formation and breakdown, treatment decisions, whether anticoagulant or antiplatelet therapy, can be based on the baseline values that indicate a hypercoagulable state. For example, hyperreactive platelets are associated with increased maximum amplitude on TEG in a human study [104]. Since there is an identified association between platelets and intracardiac thrombosis in cats, elevated MA in FATE cats could encourage research in the safety and efficacy of alternative antiplatelet drugs in veterinary patients, beyond clopidogrel and aspirin. Recent studies have evaluated the utilization of VCM-VET in cats with HCM and FATE, given that it only requires a small volume of blood, and no specialized equipment or reagents are needed. A study evaluated viscoelastic testing to assess platelet function monitoring for healthy cats receiving clopidogrel and demonstrated hypercoagulable variables such as shortened K time and increased alpha angle on TEG and increased maximum clot formation (MCF) on VCM-VET [20]. Table 2 summarizes the utility of each viscoelastic test. More studies are required to identify the associations between viscoelastic parameters and clinical thrombotic risk in cats.

8. Novel Antithrombotic Therapies

8.1. Rapamycin

Rapamycin, or sirolimus, is an inhibitor of the mammalian/mechanistic target of rapamycin (mTOR) pathway, which plays an important role in cell growth, metabolism, and immune responses. Rapamycin has gained significant interest for its therapeutic potential in cardiovascular diseases due to its ability to modulate key cellular processes such as inflammation and proliferation [105]. Delayed-release rapamycin, which was recently approved by the U.S Food and Drug Administration for use in cats with HCM, has cardioprotective effects by either halting or reversing concentric hypertrophy of the myocardium [106]. A multi-omic study also revealed that cats treated with rapamycin had a downregulation of proteins associated with complement activation, humoral immunity, and inflammatory response, indicating a potential modulating effect on inflammation and immunothrombosis [107]. An in vitro study in human platelets demonstrated that rapamycin reduces procoagulant platelet formation by protecting mitochondrial membrane potential (ΔΨm) and limiting phosphatidylserine (PS) externalization to prevent excessive thrombin generation via an mTORC1-independent mechanism [108]. However, the effects of rapamycin on other platelet functions remain poorly understood, with most studies limited to in vitro models, which yield conflicting results. In an in vitro study, rapamycin increases platelet aggregation and secretion in response to ADP and thrombin, while another study showed modulation in collagen response by reducing platelet aggregation and spreading [109,110]. In cats, a recent ex vivo study revealed that low-dose rapamycin administered orally every 7 days for 4 weeks significantly diminished the procoagulant potential of platelets by preventing the loss of ΔΨm. Additionally, rapamycin also modulated ADP-induced platelet activation [111]. While rapamycin holds promise for managing various cardiovascular conditions, further research is necessary to fully understand its long-term safety and potential to be used synergistically with existing therapies.

8.2. Non-Anticoagulated Heparins

The anticoagulant activity of UFH can be considered an undesirable effect, especially in cats with unknown coagulation status. While the use of unfractionated heparins (UFH) as an anticoagulant in cats with FATE is not novel, there is a knowledge gap concerning the use of UFH as an anti-inflammatory and anti-immunothrombotic agent to be utilized as a primary prevention therapy. Heparin’s anti-inflammatory properties stem from its ability to interact with proteins such as complements and histones, which are responsible for mediating systemic inflammatory response [112]. Taking that into consideration, there is ongoing research investigating new heparin derivatives, known as non-anticoagulated heparins (NAH), with preserved anti-inflammatory properties and reduced or obliterated anticoagulant activities. Currently, there are multiple formulations of NAH, with most being desulfated heparin since the sulfated nature of heparin confers a negative charge, allowing it to interact with multiple proteins, such as antithrombin (9). The downside of desulfated heparin is the variable effects it has on histone inhibition; however, other studies indicated that selectively desulfated heparin retains a high degree of histone scavenging capability. Considering that elevated histones in cats with HCM may play a role in CATE pathogenesis, more research is needed to evaluate the efficacy and safety of NAH in cats as a primary and secondary thromboprophylaxis.

8.3. Thrombolytic Therapy

Tissue plasminogen activator (tPA) is a thrombolytic agent that works by converting plasminogen to plasmin, which specifically degrades cross-linked fibrin in blood clots. It is considered the standard of care for treating acute ischemic stroke and myocardial infarction in humans since tPA targets thrombus more selectively than streptokinase [113,114]. The lack of high-quality evidence in veterinary studies limits the widespread use of thrombolytics and, therefore, should be used with caution in cats with FATE. Given that intracranial hemorrhage has been reported in approximately 2% of human patients treated with reteplase and alteplase, yet no hemorrhagic events were observed in cats enrolled in the BLASTT study, it is plausible that species-specific differences exist [115,116]. These findings highlight the need for further investigation into feline-specific dosing regimens to optimize the risk-benefit profile of thrombolytic therapy in this population. While the CURATIVE guidelines suggest that thrombolysis may be considered in cats with acute FATE, the ACVIM consensus statement advises against thrombolysis treatment for FATE [91,117]. To date, the best evidence for thrombolytic therapy comes from the BLASTT (Bilateral Lysis of Aortic Saddle Thrombus with Early Tissue Plasminogen Activator) study, a randomized, prospective clinical trial that compared alteplase (a second-generation tPA) to placebo. Similar to human recommendations, enrollment of cats was restricted to those that received tPA or placebo within 6 h of a FATE event. The study found that cats that survived to 48 h of hospitalization had improved limb functions compared to the placebo group, but there were no statistical differences in survival to discharge or adverse events such as acute kidney injury and reperfusion injury [116]. The study, however, was underpowered to evaluate survival and secondary outcomes. Another thrombolytic agent, streptokinase, which non-specifically activates plasminogen to induce a systemic fibrinolytic state, was evaluated in a retrospective study of 46 cats. The study found that 24% of cats experienced clinical bleeding and prolonged coagulation times [118]. Furthermore, a prospective study of eight cats treated with streptokinase showed that none of the cats survived to hospital discharge [119]. The International Study of Infarct Survival-3 found no difference in mortality between streptokinase and tPA in human patients with an acute onset of myocardial infarction [120]. However, the tPA group had significantly more strokes suspected to be secondary to cerebral hemorrhage [120]. Another human study compared varying regimens of tPA and streptokinase with subcutaneous and intravenous heparin and concluded that accelerated tPA with intravenous heparin was superior and had a significant reduction in mortality [121]. Accelerated tPA was administered as a bolus of 0.75 mg/kg over 30 min and then 0.5 mg/kg over 60 min [121]. Urokinase, which is a direct plasminogen activator that acts systemically, was evaluated in a retrospective study involving 12 cats. The study found that 5 of the 12 cats (42%) survived to discharge while hyperkalemia developed in 25% of cases [122].
Additionally, reteplase, a third-generation tissue plasminogen activator (tPA) approved for human acute myocardial infarction, was administered to twelve cats with bilateral arterial thromboembolism, resulting in a high 75% survival rate [123]. In human medicine, the RAISE trial, which compared reteplase to alteplase in patients with acute ischemic stroke, found that while reteplase was associated with better functional outcomes, it also had a higher incidence of intracranial hemorrhage [124]. Mortality rates between the two groups did not differ significantly. These findings suggest that reteplase may offer a promising option for FATE treatment, but further research is needed to assess its safety and efficacy in veterinary patients.

8.4. Interventional and Surgical Thrombectomy

Due to the high mortality and poor prognosis associated with FATE, novel therapies are being explored to improve patient outcomes. One case report highlighted the success of surgical embolectomy, where a cat exhibited no clinical signs 18 months after the procedure [125]. Because FATE commonly presents with concurrent congestive heart failure and severe cardiomyopathies, medical management of FATE remains the mainstay of therapy, given the high risk of anesthesia-related complications. In addition to patient stability, additional perioperative factors such as thrombus accessibility, vessel diameter, limb viability, and time to intervention may determine the feasibility of interventions and the type of interventions [126]. To date, only case reports and case series have described the efficacy of surgical thrombectomy and rheolytic thrombectomy for the treatment of FATE [125,127]. Rheolytic thrombectomy, a procedure utilizing pressurized saline jets to lyse the thrombus in combination with vacuum-assisted aspiration of clot fragments, was performed in six cats with bilateral FATE [127]. Although successful clot dissolution was achieved in five of the six cases, only three cats (50%) survived to hospital discharge, which is similar to the 48 h survival rate in recent studies consisting of only medical management. Recurrence rate among survivors was reported to be high, with one cat with documented recurrence of FATE, while the third cat survived for two years post-intervention before succumbing to congestive heart failure and chronic renal disease.

8.5. Histone Deacetylase Inhibitors and Scavenging

Given the prothrombotic and proinflammatory properties of histones, future preventive strategies targeting immunothrombosis should focus on inhibiting histone modification, scavenging free circulating histones, and attenuating NETosis. While currently approved by the FDA for treating neoplastic diseases, HDAC inhibitors are also being explored for their potential therapeutic benefits in human cardiac conditions [128,129]. Overexpression of certain histone deacetylases (HDACs), which are enzymes that remove acetyl groups from histone proteins, has been linked to cardiac hypertrophy in humans [129]. Increased histone deacetylation by HDAC can augment inflammation by influencing gene expression. In mouse models, HDAC inhibitors have demonstrated cardioprotective effects. HDAC inhibitors may also decrease NET formation and subsequent release of histones, since histone acetylation can increase NET formation. Although HDAC inhibitors have been studied in canine cancer cell lines, additional research is needed to evaluate their potential benefits in FATE-affected cats [130,131]. Targeting NET formation by inhibiting histone citrullination or interfering with platelet–neutrophil interactions may help to alleviate systemic hypercoagulability. Monoclonal antibodies can be a viable therapy to target adhesion molecules that mediate the interactions between platelets and neutrophils. Lastly, besides NAH, other proteins such as Clusterin have shown promise as a histone scavenging molecule to reduce immunothrombosis in mouse models [132].

9. Conclusions

Research is ongoing to optimize FATE recognition and identify risk factors for FATE so that proper treatments can be administered. Currently, identification of FATE risk factors relies on echocardiographic findings, but research is underway for other biomarkers and assays to predict FATE. Antiplatelet drugs remain the cornerstone of FATE prevention and treatment. Platelet function monitoring, genetic testing, and possibly viscoelastic testing in the future can be used to assess clopidogrel resistance in cats that are on antiplatelet drugs and to aid in more directed and targeted therapies.

Author Contributions

Conceptualization, N.S.Y. and R.H.L.L.; writing—original draft, N.S.Y., M.S. and R.H.L.L.; writing—review and editing, N.S.Y., M.S. and R.H.L.L. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

This work did not involve the use of animals and, therefore, ethical approval was not specifically required for publication.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declared no potential conflicts of interest with respect to the research, authorship, and publication of this article.

References

  1. Smith, S.A.; Tobias, A.H. Feline arterial thromboembolism: An update. Vet. Clin. Small Anim. Pract. 2004, 34, 1245–1271. [Google Scholar] [CrossRef]
  2. Rush, J.E.; Freeman, L.M.; Fenollosa, N.K.; Brown, D.J. Population and survival characteristics of cats with hypertrophic cardiomyopathy: 260 cases (1990–1999). J. Am. Vet. Med. Assoc. 2002, 220, 202–207. [Google Scholar] [CrossRef]
  3. Schoeman, J.P. Feline Distal Aortic Thromboembolism: A Review of 44 Cases (1990–1998). J. Feline Med. Surg. 1999, 1, 221–231. [Google Scholar] [CrossRef] [PubMed]
  4. Smith, S.A.; Tobias, A.H.; Jacob, K.A.; Fine, D.M.; Grumbles, P.L. Arterial Thromboembolism in Cats: Acute Crisis in 127 Cases (1992–2001) and Long-Term Management with Low-Dose Aspirin in 24 Cases. J. Vet. Intern. Med. 2003, 17, 73–83. [Google Scholar] [CrossRef] [PubMed]
  5. Lo, S.T.; Walker, A.L.; Georges, C.J.; Li, R.H.; Stern, J.A. Dual therapy with clopidogrel and rivaroxaban in cats with thromboembolic disease. J. Feline Med. Surg. 2022, 24, 277–283. [Google Scholar] [CrossRef] [PubMed]
  6. Hogan, D.F.; Fox, P.R.; Jacob, K.; Keene, B.; Laste, N.J.; Rosenthal, S.; Sederquist, K.; Weng, H.-Y. Secondary prevention of cardiogenic arterial thromboembolism in the cat: The double-blind, randomized, positive-controlled feline arterial thromboembolism; clopidogrel vs. aspirin trial (FAT CAT). J. Vet. Cardiol. 2015, 17, S306–S317. [Google Scholar] [CrossRef] [PubMed]
  7. Fox, P.R.; Keene, B.W.; Lamb, K.; Schober, K.A.; Chetboul, V.; Luis Fuentes, V.; Wess, G.; Payne, J.R.; Hogan, D.F.; Motsinger-Reif, A.; et al. International collaborative study to assess cardiovascular risk and evaluate long-term health in cats with preclinical hypertrophic cardiomyopathy and apparently healthy cats: The REVEAL Study. J. Vet. Intern. Med. 2018, 32, 930–943. [Google Scholar] [CrossRef]
  8. Shaverdian, M.; Li, R.H.L. Preventing Cardiogenic Thromboembolism in Cats: Literature Gaps, Rational Recommendations, and Future Therapies. Vet. Clin. N. Am. Small Anim. Pract. 2023, 53, 1309–1323. [Google Scholar] [CrossRef]
  9. Scharf, R.E. Platelet Signaling in Primary Haemostasis and Arterial Thrombus Formation: Part 1. Hämostaseologie 2018, 38, 203–210. [Google Scholar] [CrossRef]
  10. Gale, A.J. Continuing Education Course #2: Current Understanding of Hemostasis. Toxicol. Pathol. 2011, 39, 273–280. [Google Scholar] [CrossRef]
  11. Tablin, F.; Schumacher, T.; Pombo, M.; Marion, C.T.; Huang, K.; Norris, J.W.; Jandrey, K.E.; Kittleson, M.D. Platelet Activation in Cats with Hypertrophic Cardiomyopathy. J. Vet. Intern. Med. 2014, 28, 411–418. [Google Scholar] [CrossRef] [PubMed]
  12. Li, R.H.L.; Stern, J.A.; Ho, V.; Tablin, F.; Harris, S.P. Platelet Activation and Clopidogrel Effects on ADP-Induced Platelet Activation in Cats with or without the A31P Mutation in MYBPC3. J. Vet. Intern. Med. 2016, 30, 1619–1629. [Google Scholar] [CrossRef] [PubMed]
  13. Helenski, C.A.; Ross, J.N. Platelet Aggregation in Feline Cardiomyopathy. J. Vet. Intern. Med. 1987, 1, 24–28. [Google Scholar] [CrossRef]
  14. Tan, A.W.K.; Li, R.H.L.; Ueda, Y.; Stern, J.A.; Hussain, M.; Haginoya, S.; Sharpe, A.N.; Gunther-Harrington, C.T.; Epstein, S.E.; Nguyen, N. Platelet Priming and Activation in Naturally Occurring Thermal Burn Injuries and Wildfire Smoke Exposure Is Associated With Intracardiac Thrombosis and Spontaneous Echocardiographic Contrast in Feline Survivors. Front. Vet. Sci. 2022, 9, 892377. [Google Scholar] [CrossRef]
  15. Bédard, C.; Lanevschi-Pietersma, A.; Dunn, M. Evaluation of coagulation markers in the plasma of healthy cats and cats with asymptomatic hypertrophic cardiomyopathy. Vet. Clin. Pathol. 2007, 36, 167–172. [Google Scholar] [CrossRef]
  16. Wells, M.; Sheffield, W.; Blajchman, M. The Clearance of Thrombin-antithrombin and Related Serpin-enzyme Complexes from the Circulation: Role of Various Hepatocyte Receptors. Thromb. Haemost. 1999, 81, 325–337. [Google Scholar] [CrossRef]
  17. Smith, S.A. The cell-based model of coagulation. J. Vet. Emerg. Crit. Care 2009, 19, 3–10. [Google Scholar] [CrossRef] [PubMed]
  18. Johnson, A.J.; Rozanski, E.A.; De Laforcade, A.M.; Davila, C.; Rush, J.E.; Guillaumin, J. Viscoelastic coagulation monitoring parameters in cats with acute arterial thromboembolism. J. Vet. Intern. Med. 2024, 38, 2045–2051. [Google Scholar] [CrossRef]
  19. Moses, I.A.; Hallowell, T.C.; Johnson, J.A. Feline aortic thromboembolism with and without congestive heart failure did not exhibit hypercoagulability using a novel viscoelastic coagulation monitor. Am. J. Veter Res. 2024, 85, ajvr.24.03.0065. [Google Scholar] [CrossRef]
  20. Rosati, T.; Jandrey, K.E.; Stern, J.A.; Nguyen, N.; Li, R.H.L. Evaluation of clopidogrel response in healthy cats using a novel viscoelastic test and thromboelastography. Front. Vet. Sci. 2024, 11, 1371781. [Google Scholar] [CrossRef]
  21. Hennink, I.; Peters, L.; van Geest, G.; Adamik, K.-N. Evaluation of a Viscoelastic Coagulation Monitoring System (VCM Vet®) and Its Correlation with Thromboelastometry (ROTEM®) in Diseased and Healthy Dogs. Animals 2023, 13, 405. [Google Scholar] [CrossRef]
  22. Buriko, Y.; Chalifoux, N.V.; Clarkin-Breslin, R.; Silverstein, D.C. Comparison of a viscoelastic point-of-care coagulation monitor with thromboelastography in sick dogs with hemostatic abnormalities. Vet. Clin. Pathol. 2023, 52, 217–227. [Google Scholar] [CrossRef] [PubMed]
  23. Kane, K.K. Fibrinolysis—A review. Ann. Clin. Lab. Sci. 1984, 14, 443–449. [Google Scholar] [PubMed]
  24. Busato, F.; Drigo, M.; Zoia, A. Reduced risk of arterial thromboembolism in cats with pleural effusion due to congestive heart failure. J. Feline Med. Surg. 2022, 24, e142–e152. [Google Scholar] [CrossRef] [PubMed]
  25. Li, R.H.L.; Tablin, F. A Comparative Review of Neutrophil Extracellular Traps in Sepsis. Front. Vet. Sci. 2018, 5, 291. [Google Scholar] [CrossRef]
  26. Ryan, T.A.J.; O’Neill, L.A.J. Innate immune signaling and immunothrombosis: New insights and therapeutic opportunities. Eur. J. Immunol. 2022, 52, 1024–1034. [Google Scholar] [CrossRef]
  27. Clark, S.R.; Ma, A.C.; Tavener, S.A.; McDonald, B.; Goodarzi, Z.; Kelly, M.M.; Patel, K.D.; Chakrabarti, S.; McAvoy, E.; Sinclair, G.D.; et al. Platelet TLR4 activates neutrophil extracellular traps to ensnare bacteria in septic blood. Nat. Med. 2007, 13, 463–469. [Google Scholar] [CrossRef]
  28. Li, P.; Li, M.; Lindberg, M.R.; Kennett, M.J.; Xiong, N.; Wang, Y. PAD4 is essential for antibacterial innate immunity mediated by neutrophil extracellular traps. J. Exp. Med. 2010, 207, 1853–1862. [Google Scholar] [CrossRef]
  29. McDonald, B.; Davis, R.P.; Kim, S.-J.; Tse, M.; Esmon, C.T.; Kolaczkowska, E.; Jenne, C.N. Platelets and neutrophil extracellular traps collaborate to promote intravascular coagulation during sepsis in mice. Blood 2017, 129, 1357–1367. [Google Scholar] [CrossRef]
  30. Pilsczek, F.H.; Salina, D.; Poon, K.K.H.; Fahey, C.; Yipp, B.G.; Sibley, C.D.; Robbins, S.M.; Green, F.H.Y.; Surette, M.G.; Sugai, M.; et al. A Novel Mechanism of Rapid Nuclear Neutrophil Extracellular Trap Formation in Response to Staphylococcus aureus. J. Immunol. 2010, 185, 7413–7425. [Google Scholar] [CrossRef]
  31. Nicolai, L.; Leunig, A.; Brambs, S.; Kaiser, R.; Weinberger, T.; Weigand, M.; Muenchhoff, M.; Hellmuth, J.C.; Ledderose, S.; Schulz, H.; et al. Immunothrombotic Dysregulation in COVID-19 Pneumonia Is Associated with Respiratory Failure and Coagulopathy. Circulation 2020, 142, 1176–1189. [Google Scholar] [CrossRef] [PubMed]
  32. Stark, K.; Massberg, S. Interplay between inflammation and thrombosis in cardiovascular pathology. Nat. Rev. Cardiol. 2021, 18, 666–682. [Google Scholar] [CrossRef]
  33. Mesa, M.A.; Vasquez, G. NETosis. Autoimmune Dis. 2013, 2013, 1–7. [Google Scholar] [CrossRef] [PubMed]
  34. Schulz, C.; Massberg, S. Demystifying the prothrombotic role of NETs. Blood 2017, 129, 925–926. [Google Scholar] [CrossRef]
  35. Zhang, Y.; Wang, C.; Yu, M.; Zhao, X.; Du, J.; Li, Y.; Jing, H.; Dong, Z.; Kou, J.; Bi, Y.; et al. Neutrophil extracellular traps induced by activated platelets contribute to procoagulant activity in patients with colorectal cancer. Thromb. Res. 2019, 180, 87–97. [Google Scholar] [CrossRef]
  36. Zhou, P.; Li, T.; Jin, J.; Liu, Y.; Li, B.; Sun, Q.; Tian, J.; Zhao, H.; Liu, Z.; Ma, S.; et al. Interactions between neutrophil extracellular traps and activated platelets enhance procoagulant activity in acute stroke patients with ICA occlusion. EBiomedicine 2020, 53, 102671. [Google Scholar] [CrossRef]
  37. Li, R.H.L.; Fabella, A.; Nguyen, N.; Kaplan, J.L.; Ontiveros, E.; Stern, J.A. Circulating neutrophil extracellular traps in cats with hypertrophic cardiomyopathy and cardiogenic arterial thromboembolism. Vet. Intern. Med. 2023, 37, 490–502. [Google Scholar] [CrossRef] [PubMed]
  38. Fuchs, T.A.; Bhandari, A.A.; Wagner, D.D. Histones induce rapid and profound thrombocytopenia in mice. Blood 2011, 118, 3708–3714. [Google Scholar] [CrossRef]
  39. Semeraro, F.; Ammollo, C.T.; Morrissey, J.H.; Dale, G.L.; Friese, P.; Esmon, N.L.; Esmon, C.T. Extracellular histones promote thrombin generation through platelet-dependent mechanisms: Involvement of platelet TLR2 and TLR4. Blood 2011, 118, 1952–1961. [Google Scholar] [CrossRef]
  40. Schober, K.E.; Maerz, I. Assessment of Left Atrial Appendage Flow Velocity and its Relation to Spontaneous Echocardiographic Contrast in 89 Cats with Myocardial Disease. Vet. Intern. Med. 2006, 20, 120–130. [Google Scholar] [CrossRef]
  41. Neubauer, K.; Zieger, B. Endothelial cells and coagulation. Cell Tissue Res. 2022, 387, 391–398. [Google Scholar] [CrossRef] [PubMed]
  42. De Wouwer, M.V.; Collen, D.; Conway, E.M. Thrombomodulin-Protein C-EPCR System: Integrated to Regulate Coagulation and Inflammation. ATVB 2004, 24, 1374–1383. [Google Scholar] [CrossRef] [PubMed]
  43. Ciaramella, P.; Piantedosi, D.; Lindquist, E.; Loria, A.D.; Cortese, L.; Skeels, M.; Persechino, A. Plasma Thrombomodulin (TM) Concentration in Cats with Cardiomyopathies. Vet. Res. Commun. 2006, 30, 289–291. [Google Scholar] [CrossRef]
  44. Oliver, J.J.; Webb, D.J.; Newby, D.E. Stimulated Tissue Plasminogen Activator Release as a Marker of Endothelial Function in Humans. Arter. Thromb. Vasc. Biol. 2005, 25, 2470–2479. [Google Scholar] [CrossRef] [PubMed]
  45. Cambronero, F.; Vilchez, J.A.; García-Honrubia, A.; Ruiz-Espejo, F.; Moreno, V.; Hernández-Romero, D.; Bonacasa, B.; González-Conejero, R.; De La Morena, G.; Martínez, P.; et al. Plasma levels of Von Willebrand factor are increased in patients with hypertrophic cardiomyopathy. Thromb. Res. 2010, 126, e46–e50. [Google Scholar] [CrossRef]
  46. Stokol, T.; Brooks, M.; Rush, J.E.; Rishniw, M.; Erb, H.; Rozanski, E.; Kraus, M.S.; Gelzer, A.L. Hypercoagulability in Cats with Cardiomyopathy. Vet. Intern. Med. 2008, 22, 546–552. [Google Scholar] [CrossRef]
  47. Cheng, W.-C.; Wilkie, L.; Kurosawa, T.A.; Dobromylskyj, M.; Priestnall, S.L.; Luis Fuentes, V.; Connolly, D.J. Immunohistological Evaluation of Von Willebrand Factor in the Left Atrial Endocardium and Atrial Thrombi from Cats with Cardiomyopathy. Animals 2021, 11, 1240. [Google Scholar] [CrossRef]
  48. Agbani, E.O.; Poole, A.W. Procoagulant platelets: Generation, function, and therapeutic targeting in thrombosis. Blood 2017, 130, 2171–2179. [Google Scholar] [CrossRef]
  49. Nechipurenko, D.Y.; Receveur, N.; Yakimenko, A.O.; Shepelyuk, T.O.; Yakusheva, A.A.; Kerimov, R.R.; Obydennyy, S.I.; Eckly, A.; Léon, C.; Gachet, C.; et al. Clot Contraction Drives the Translocation of Procoagulant Platelets to Thrombus Surface. Arterioscler. Thromb. Vasc. Biol. 2019, 39, 37–47. [Google Scholar] [CrossRef]
  50. Prodan, C.I.; Stoner, J.A.; Dale, G.L. Lower Coated-Platelet Levels Are Associated with Increased Mortality After Spontaneous Intracerebral Hemorrhage. Stroke 2015, 46, 1819–1825. [Google Scholar] [CrossRef]
  51. Prodan, C.I.; Vincent, A.S.; Dale, G.L. Coated-platelet levels are elevated in patients with transient ischemic attack. Transl. Res. 2011, 158, 71–75. [Google Scholar] [CrossRef] [PubMed]
  52. Pasalic, L.; Wing-Lun, E.; Lau, J.K.; Campbell, H.; Pennings, G.J.; Lau, E.; Connor, D.; Liang, H.P.; Muller, D.; Kritharides, L.; et al. Novel assay demonstrates that coronary artery disease patients have heightened procoagulant platelet response. J. Thromb. Haemost. 2018, 16, 1198–1210. [Google Scholar] [CrossRef]
  53. Shaverdian, M.; Nguyen, N.; Li, R.H.L. A novel technique to characterize procoagulant platelet formation and evaluate platelet procoagulant tendency in cats by flow cytometry. Front. Vet. Sci. 2024, 11, 1480756. [Google Scholar] [CrossRef] [PubMed]
  54. Li, R.H.; Nguyen, N.; Stern, J.A.; Duler, L.M. Neutrophil extracellular traps in feline cardiogenic arterial thrombi: A pilot study. J. Feline Med. Surg. 2022, 24, 580–586. [Google Scholar] [CrossRef] [PubMed]
  55. Sreeramkumar, V.; Adrover, J.M.; Ballesteros, I.; Cuartero, M.I.; Rossaint, J.; Bilbao, I.; Nácher, M.; Pitaval, C.; Radovanovic, I.; Fukui, Y.; et al. Neutrophils scan for activated platelets to initiate inflammation. Science 2014, 346, 1234–1238. [Google Scholar] [CrossRef]
  56. Etulain, J.; Martinod, K.; Wong, S.L.; Cifuni, S.M.; Schattner, M.; Wagner, D.D. P-selectin promotes neutrophil extracellular trap formation in mice. Blood 2015, 126, 242–246. [Google Scholar] [CrossRef]
  57. Carestia, A.; Kaufman, T.; Rivadeneyra, L.; Landoni, V.I.; Pozner, R.G.; Negrotto, S.; D’Atri, L.P.; Gómez, R.M.; Schattner, M. Mediators and molecular pathways involved in the regulation of neutrophil extracellular trap formation mediated by activated platelets. J. Leukoc. Biol. 2016, 99, 153–162. [Google Scholar] [CrossRef]
  58. Welles, E.G.; Boudreaux, M.K.; Crager, C.S.; Tyler, J.W. Platelet function and antithrombin, plasminogen, and fibrinolytic activities in cats with heart disease. Am. J. Vet. Res. 1994, 55, 619–627. [Google Scholar] [CrossRef]
  59. Siostrzonek, P.; Koppensteiner, R.; Gössinger, H.; Zangeneh, M.; Heinz, G.; Kreiner, G.; Stümpflen, A.; Buxbaum, P.; Ehringer, H.; Mösslacher, H. Hemodynamic and hemorheologic determinants of left atrial spontaneous echo contrast and thrombus formation in patients with idiopathic dilated cardiomyopathy. Am. Heart J. 1993, 125, 430–434. [Google Scholar] [CrossRef]
  60. Kirby, R.; Linklater, A. Monitoring and Intervention for the Critically Ill Small Animal: The Rule of 20; John Wiley & Sons: Hoboken, NJ, USA, 2016; ISBN 978-1-118-90083-3. [Google Scholar]
  61. Moresco, R.N.; Júnior, R.H.; Vargas, L.C.R.; Silla, L.M.D.R. Association between plasma levels of D-dimer and fibrinogen/fibrin degradation products (FDP) for exclusion of thromboembolic disorders. J. Thromb. Thrombolysis 2006, 21, 199–202. [Google Scholar] [CrossRef]
  62. Kim, T.-Y.; Han, S.-H.; Choi, R.; Hyun, C. Evaluation of Plasma D-dimer Concentration in Cats with Hypertrophic Cardiomyopathy. J. Vet. Clin. 2014, 31, 85–89. [Google Scholar] [CrossRef]
  63. Reed, G.; Houng, A.; Singh, S.; Wang, D. α2-Antiplasmin: New Insights and Opportunities for Ischemic Stroke. Semin. Thromb. Hemost. 2016, 43, 191–199. [Google Scholar] [CrossRef] [PubMed]
  64. Singh, S.; Saleem, S.; Reed, G.L. Alpha2-Antiplasmin: The Devil You Don’t Know in Cerebrovascular and Cardiovascular Disease. Front. Cardiovasc. Med. 2020, 7, 608899. [Google Scholar] [CrossRef] [PubMed]
  65. Singh, S.; Houng, A.K.; Reed, G.L. Venous stasis-induced fibrinolysis prevents thrombosis in mice: Role of α2-antiplasmin. Blood 2019, 134, 970–978. [Google Scholar] [CrossRef]
  66. Meltzer, M.E.; Doggen, C.J.M.; de Groot, P.G.; Rosendaal, F.R.; Lisman, T. Plasma levels of fibrinolytic proteins and the risk of myocardial infarction in men. Blood 2010, 116, 529–536. [Google Scholar] [CrossRef]
  67. Merino, A.; Hauptman, P.; Badimon, L.; Badimon, J.J.; Cohen, M.; Fuster, V.; Goldman, M. Echocardiographic “smoke” is produced by an interaction of erythrocytes and plasma proteins modulated by shear forces. J. Am. Coll. Cardiol. 1992, 20, 1661–1668. [Google Scholar] [CrossRef]
  68. Rastegar, R.; Harnick, D.J.; Weidemann, P.; Fuster, V.; Coller, B.; Badimon, J.J.; Chesebro, J.; Goldman, M.E. Spontaneous echo contrast videodensity isflow-related and is dependent on the relative concentrations of fibrinogen and red blood cells. J. Am. Coll. Cardiol. 2003, 41, 603–610. [Google Scholar] [CrossRef]
  69. Zotz, R.J.; Müller, M.; Genth-Zotz, S.; Darius, H. Spontaneous Echo Contrast Caused by Platelet and Leukocyte Aggregates? Stroke 2001, 32, 1127–1133. [Google Scholar] [CrossRef]
  70. Le Tourneau, T.; Susen, S.; Caron, C.; Millaire, A.; Maréchaux, S.; Polge, A.-S.; Vincentelli, A.; Mouquet, F.; Ennezat, P.-V.; Lamblin, N.; et al. Functional Impairment of Von Willebrand Factor in Hypertrophic Cardiomyopathy. Circulation 2008, 118, 1550–1557. [Google Scholar] [CrossRef]
  71. Ammash, N.; Konik, E.A.; McBane, R.D.; Chen, D.; Tange, J.I.; Grill, D.E.; Herges, R.M.; McLeod, T.G.; Friedman, P.A.; Wysokinski, W.E. Left Atrial Blood Stasis and Von Willebrand Factor–ADAMTS13 Homeostasis in Atrial Fibrillation. Arterioscler. Thromb. Vasc. Biol. 2011, 31, 2760–2766. [Google Scholar] [CrossRef]
  72. Payne, J.R.; Borgeat, K.; Connolly, D.J.; Boswood, A.; Dennis, S.; Wagner, T.; Menaut, P.; Maerz, I.; Evans, D.; Simons, V.E.; et al. Prognostic Indicators in Cats with Hypertrophic Cardiomyopathy. Vet. Intern. Med. 2013, 27, 1427–1436. [Google Scholar] [CrossRef]
  73. Payne, J.R.; Borgeat, K.; Brodbelt, D.C.; Connolly, D.J.; Luis Fuentes, V. Risk factors associated with sudden death vs. congestive heart failure or arterial thromboembolism in cats with hypertrophic cardiomyopathy. J. Vet. Cardiol. 2015, 17, S318–S328. [Google Scholar] [CrossRef]
  74. Hsu, A.; Kittleson, M.D.; Paling, A. Investigation into the use of plasma NT-proBNP concentration to screen for feline hypertrophic cardiomyopathy. J. Vet. Cardiol. 2009, 11, S63–S70. [Google Scholar] [CrossRef] [PubMed]
  75. Bakirel, U.; Ulgen Saka, S.; Yildiz, K. Feline Arteriyel Tromboembolizm Tanısı ve Prognozunda Kardiyak Biyobelirteçlerin Rolü ve Önemi. Kafkas Univ. Vet. Fak. Derg. 2021, 27, 409–415. [Google Scholar] [CrossRef]
  76. Harris, A.N.; Beatty, S.S.; Estrada, A.H.; Winter, B.; Bohannon, M.; Sosa, I.; Hanscom, J.; Mainville, C.A.; Gallagher, A.E. Investigation of an N-Terminal Prohormone of Brain Natriuretic Peptide Point-of-Care ELISA in Clinically Normal Cats and Cats with Cardiac Disease. Vet. Intern. Med. 2017, 31, 994–999. [Google Scholar] [CrossRef]
  77. Lu, T.; Côté, E.; Kuo, Y.; Wu, H.; Wang, W.; Hung, Y. Point-of-care N-terminal pro B-type natriuretic peptide assay to screen apparently healthy cats for cardiac disease in general practice. Vet. Intern. Med. 2021, 35, 1663–1672. [Google Scholar] [CrossRef] [PubMed]
  78. Hertzsch, S.; Roos, A.; Wess, G. Evaluation of a sensitive cardiac troponin I assay as a screening test for the diagnosis of hypertrophic cardiomyopathy in cats. Vet. Intern. Med. 2019, 33, 1242–1250. [Google Scholar] [CrossRef]
  79. Hori, Y.; Iguchi, M.; Heishima, Y.; Yamashita, Y.; Nakamura, K.; Hirakawa, A.; Kitade, A.; Ibaragi, T.; Katagi, M.; Sawada, T.; et al. Diagnostic utility of cardiac troponin I in cats with hypertrophic cardiomyopathy. J. Vet. Intern. Med. 2018, 32, 922–929. [Google Scholar] [CrossRef]
  80. Hemdon, W.E.; Kittleson, M.D.; Sanderson, K.; Drobatz, K.J.; Clifford, C.A.; Gelzer, A.; Summerfield, N.J.; Linde, A.; Sleeper, M.M. Cardiac Troponin I in Feline Hypertrophic Cardiomyopathy. J. Vet. Intern. Med. 2002, 16, 558–564. [Google Scholar] [CrossRef]
  81. Park, Y.; Schoene, N.; Harris, W. Mean platelet volume as an indicator of platelet activation: Methodological issues. Platelets 2002, 13, 301–306. [Google Scholar] [CrossRef]
  82. Fries, R.C.; Kadotani, S.; Stack, J.P.; Kruckman, L.; Wallace, G. Prognostic Value of Neutrophil-to-Lymphocyte Ratio in Cats with Hypertrophic Cardiomyopathy. Front. Vet. Sci. 2022, 9, 813524. [Google Scholar] [CrossRef] [PubMed]
  83. Naito, E.; Yuki, M.; Hirano, T.; Kainuma, D.; Aoyama, R. Prognostic utility of preoperative neutrophil–lymphocyte ratio in cats with malignant mammary tumors. Res. Vet. Sci. 2021, 135, 349–354. [Google Scholar] [CrossRef] [PubMed]
  84. Neumann, S. Neutrophil-to-lymphocyte and platelet-to-lymphocyte ratios in dogs and cats with acute pancreatitis. Vet. Clin. Pathol. 2021, 50, 45–51. [Google Scholar] [CrossRef]
  85. Joshua, J.; Caswell, J.L.; Monné Rodriguez, J.M.; Kipar, A.; O’Sullivan, M.L.; Wood, G.; Fonfara, S. MicroRNA profiling of the feline left heart identifies chamber-specific expression signatures in health and in advanced hypertrophic cardiomyopathy. J. Mol. Cell. Cardiol. Plus 2023, 4, 100037. [Google Scholar] [CrossRef]
  86. Sucharov, C.C.; Neltner, B.; Pietra, A.E.; Karimpour-Fard, A. Circulating MicroRNAs Identify Early Phenotypic Changes in Sarcomeric Hypertrophic Cardiomyopathy. Circulation 2023, 16, e010291. [Google Scholar] [CrossRef]
  87. Goggs, R.; Bacek, L.; Bianco, D.; Koenigshof, A.; Li, R.H.L. Consensus on the Rational Use of Antithrombotics in Veterinary Critical Care (CURATIVE): Domain 2—Defining rational therapeutic usage. J. Vet. Emerg. Crit. Care 2019, 29, 49–59. [Google Scholar] [CrossRef]
  88. Brainard, B.M.; Coleman, A.E.; Kurosawa, A.; Rush, J.E.; Hogan, D.F.; Brooks, M.B.; Kraus, M.S. Therapy with clopidogrel or rivaroxaban has equivalent impacts on recurrence of thromboembolism and survival in cats following cardiogenic thromboembolism: The SUPERCAT study. J. Am. Vet. Med. Assoc. 2024, 263, 1–10. [Google Scholar] [CrossRef]
  89. Lo, S.T.; Li, R.H.L.; Georges, C.J.; Nguyen, N.; Chen, C.K.; Stuhlmann, C.; Oldach, M.S.; Rivas, V.N.; Fousse, S.; Harris, S.P.; et al. Synergistic inhibitory effects of clopidogrel and rivaroxaban on platelet function and platelet-dependent thrombin generation in cats. J. Vet. Intern. Med. 2023, 37, 1390–1400. [Google Scholar] [CrossRef] [PubMed]
  90. Mitropoulou, A.; Hassdenteufel, E.; Lin, J.; Bauer, N.; Wurtinger, G.; Vollmar, C.; Henrich, E.; Hildebrandt, N.; Schneider, M. Retrospective Evaluation of Intravenous Enoxaparin Administration in Feline Arterial Thromboembolism. Animals 2022, 12, 1977. [Google Scholar] [CrossRef]
  91. Luis Fuentes, V.; Abbott, J.; Chetboul, V.; Côté, E.; Fox, P.R.; Häggström, J.; Kittleson, M.D.; Schober, K.; Stern, J.A. ACVIM consensus statement guidelines for the classification, diagnosis, and management of cardiomyopathies in cats. Vet. Intern. Med. 2020, 34, 1062–1077. [Google Scholar] [CrossRef]
  92. Ueda, Y.; Li, R.H.L.; Nguyen, N.; Ontiveros, E.S.; Kovacs, S.L.; Oldach, M.S.; Vernau, K.M.; Court, M.H.; Stern, J.A. A genetic polymorphism in P2RY1 impacts response to clopidogrel in cats with hypertrophic cardiomyopathy. Sci. Rep. 2021, 11, 12522. [Google Scholar] [CrossRef]
  93. Weber, K.; Rostert, N.; Bauersachs, S.; Wess, G. Serum microRNA profiles in cats with hypertrophic cardiomyopathy. Mol. Cell Biochem. 2015, 402, 171–180. [Google Scholar] [CrossRef] [PubMed]
  94. Hyatt, C.E.; Brainard, B.M. Point of Care Assessment of Coagulation. Top. Companion Anim. Med. 2016, 31, 11–17. [Google Scholar] [CrossRef]
  95. Kornya, M.R.; Abrams-Ogg, A.C.G.; Blois, S.L.; Wood, R.D. Platelet function analyzer-200 closure curve analysis and assessment of flow-obstructed samples. Vet. Clin. Pathol. 2023, 52, 576–582. [Google Scholar] [CrossRef] [PubMed]
  96. Jandrey, K.E. Assessment of platelet function. J. Vet. Emerg. Crit. Care 2012, 22, 81–98. [Google Scholar] [CrossRef]
  97. Teuber, M.; Mischke, R. Influence of a low dosage of clopidogrel on platelet function in cats as measured by the platelet function analyser PFA-100 and the multiplate analyser. Res. Vet. Sci. 2016, 109, 149–156. [Google Scholar] [CrossRef]
  98. Den Toom, M.L.; Van Leeuwen, M.W.; Szatmári, V.; Teske, E. Effects of clopidogrel therapy on whole blood platelet aggregation, the Plateletworks® assay and coagulation parameters in cats with asymptomatic hypertrophic cardiomyopathy: A pilot study. Vet. Q. 2017, 37, 8–15. [Google Scholar] [CrossRef] [PubMed]
  99. Ho, K.K.; Abrams-Ogg, A.C.; Wood, R.D.; O’Sullivan, M.L.; Kirby, G.M.; Blois, S.L. Assessment of platelet function in healthy cats in response to commonly prescribed antiplatelet drugs using three point-of-care platelet function tests. J. Feline Med. Surg. 2017, 19, 638–647. [Google Scholar] [CrossRef]
  100. Gouin-Thibault, I.; Pautas, E.; Siguret, V. Safety Profile of Different Low-Molecular Weight Heparins Used at Therapeutic Dose. Drug-Saf. 2005, 28, 333–349. [Google Scholar] [CrossRef]
  101. Dixon-Jimenez, A.C.; Brainard, B.M.; Brooks, M.B.; Nie, B.; Arnold, R.D.; Loper, D.; Abrams, J.C.; Rapoport, G.S. Pharmacokinetic and pharmacodynamic evaluation of oral rivaroxaban in healthy adult cats. J. Vet. Emerg. Crit. Care 2016, 26, 619–629. [Google Scholar] [CrossRef]
  102. Alwood, A.J.; Downend, A.B.; Brooks, M.B.; Slensky, K.A.; Fox, J.A.; Simpson, S.A.; Waddell, L.S.; Baumgardner, J.E.; Otto, C.M. Anticoagulant Effects of Low-Molecular-Weight Heparins in Healthy Cats. J. Vet. Intern. Med. 2007, 21, 378–387. [Google Scholar] [CrossRef] [PubMed]
  103. McMichael, M.A.; Smith, S.A. Viscoelastic coagulation testing: Technology, applications, and limitations. Vet. Clin. Pathol. 2011, 40, 140–153. [Google Scholar] [CrossRef] [PubMed]
  104. Bowbrick, V.A.; Mikhailidis, D.P.; Stansby, G. Influence of platelet count and activity on thromboelastography parameters. Platelets 2003, 14, 219. [Google Scholar] [CrossRef]
  105. Saxton, R.A.; Sabatini, D.M. mTOR Signaling in Growth, Metabolism, and Disease. Cell 2017, 168, 960–976. [Google Scholar] [CrossRef]
  106. Kaplan, J.L.; Rivas, V.N.; Walker, A.L.; Grubb, L.; Farrell, A.; Fitzgerald, S.; Kennedy, S.; Jauregui, C.E.; Crofton, A.E.; McLaughlin, C.; et al. Delayed-release rapamycin halts progression of left ventricular hypertrophy in subclinical feline hypertrophic cardiomyopathy: Results of the RAPACAT trial. J. Am. Vet. Med. Assoc. 2023, 261, 1628–1637. [Google Scholar] [CrossRef]
  107. Rivas, V.N.; Kaplan, J.L.; Kennedy, S.A.; Fitzgerald, S.; Crofton, A.E.; Farrell, A.; Grubb, L.; Jauregui, C.E.; Grigorean, G.; Choi, E.; et al. Multi-Omic, Histopathologic, and Clinicopathologic Effects of Once-Weekly Oral Rapamycin in a Naturally Occurring Feline Model of Hypertrophic Cardiomyopathy: A Pilot Study. Animals 2023, 13, 3184. [Google Scholar] [CrossRef] [PubMed]
  108. Śledź, K.M.; Moore, S.F.; Durrant, T.N.; Blair, T.A.; Hunter, R.W.; Hers, I. Rapamycin restrains platelet procoagulant responses via FKBP-mediated protection of mitochondrial integrity. Biochem. Pharmacol. 2020, 177, 113975. [Google Scholar] [CrossRef]
  109. Aslan, J.E.; Tormoen, G.W.; Loren, C.P.; Pang, J.; McCarty, O.J.T. S6K1 and mTOR regulate Rac1-driven platelet activation and aggregation. Blood 2011, 118, 3129–3136. [Google Scholar] [CrossRef]
  110. Babinska, A.; Markell, M.S.; Salifu, M.O.; Akoad, M.; Ehrlich, Y.H.; Kornecki, E. Enhancement of human platelet aggregation and secretion induced by rapamycin. Nephrol. Dial. Transpl. 1998, 13, 3153–3159. [Google Scholar] [CrossRef]
  111. Li, R.H.L.; Shaverdian, M.S.; Nguyen, N.N.; Fitzgerald, S.F.; Rivas, V.R.; Stern, J.A. Ex vivo effects of rapamycin on platelet activation and procoagulant platelet phenotypes in cats. Abstracts from the International Veterinary Emergency and Critical Care Symposium and the European Veterinary Emergency and Critical Care Annual Congress 2024. J. Vet. Emerg. Crit. Care 2024, 34, S2–S47. [Google Scholar] [CrossRef]
  112. Huang, X.; Han, S.; Liu, X.; Wang, T.; Xu, H.; Xia, B.; Kong, G.; Li, J.; Zhu, W.; Hu, H.; et al. Both UFH and NAH alleviate shedding of endothelial glycocalyx and coagulopathy in LPS-induced sepsis. Exp. Ther. Med. 2020, 19, 913–922. [Google Scholar] [CrossRef] [PubMed]
  113. Alberts, M.J. tPA in acute ischemic stroke: United States experience and issues for the future. Neurology 1998, 51, S53–S55. [Google Scholar] [CrossRef] [PubMed]
  114. Dewar, B.; Shamy, M. tPA for Acute Ischemic Stroke and Its Controversies: A Review. Neurohospitalist 2020, 10, 5–10. [Google Scholar] [CrossRef]
  115. Li, S.; Gu, H.-Q.; Li, H.; Wang, X.; Jin, A.; Guo, S.; Lu, G.; Che, F.; Wang, W.; Wei, Y.; et al. Reteplase versus Alteplase for Acute Ischemic Stroke. N. Engl. J. Med. 2024, 390, 2264–2273. [Google Scholar] [CrossRef]
  116. Guillaumin, J.; DeFrancesco, T.C.; Scansen, B.A.; Quinn, R.; Whelan, M.; Hanel, R.; Goy-Thollot, I.; Bublot, I.; Robertson, J.B.; Bonagura, J.D. Bilateral lysis of aortic saddle thrombus with early tissue plasminogen activator (BLASTT): A prospective, randomized, placebo-controlled study in feline acute aortic thromboembolism. J. Feline Med. Surg. 2022, 24, e535–e545. [Google Scholar] [CrossRef]
  117. Sharp, C.R.; Blais, M.-C.; Boyd, C.J.; Brainard, B.M.; Chan, D.L.; de Laforcade, A.; Goggs, R.; Guillaumin, J.; Lynch, A.; Mays, E.; et al. 2022 Update of the Consensus on the Rational Use of Antithrombotics and Thrombolytics in Veterinary Critical Care (CURATIVE) Domain 6: Defining rational use of thrombolytics. J. Vet. Emerg. Crit. Care 2022, 32, 446–470. [Google Scholar] [CrossRef]
  118. Moore, K.E.; Morris, N.; Dhupa, N.; Murtaugh, R.J.; Rush, J.E. Retrospective Study of Streptokinase Administration in 46 Cats with Arterial Thromboembolism. J. Vet. Emerg. Crit. Care 2000, 10, 245–257. [Google Scholar] [CrossRef]
  119. Ramsey, C.C.; Riepe, R.D.; Macintire, D.K.; Burney, D.P. Streptokinase a practical clot buster. In Proceedings of the 5th International Veterinary Emergency and Critical Care Symposium, San Antonio, TX, USA, 15–18 September 1996; pp. 225–228. [Google Scholar]
  120. Hunt, D.; Varigos, J.; Dienstl, F.; Lechleitner, P.; Debacker, G.; Kornitzer, M.; Cairns, J.; Turpie, A.; Fritzhansen, P.; Skagen, K.; et al. ISIS-3: A randomised comparison of streptokinase vs tissue plasminogen activator vs anistreplase and of aspirin plus heparin vs aspirin alone among 41,299 cases of suspected acute myocardial infarction. Lancet 1992, 339, 753–770. [Google Scholar] [CrossRef]
  121. The GUSTO Investigators. An International Randomized Trial Comparing Four Thrombolytic Strategies for Acute Myocardial Infarction. N. Engl. J. Med. 1993, 329, 673–682. [Google Scholar] [CrossRef]
  122. Whelan, M.F.; O’Toole, T.E.; Chan, D.L.; Rush, J.E. Retrospective Evaluation of Urokinase Use in Cats with Arterial Thromboembolism; Abstract from the 11th IVECCS. J. Vet. Emerg. Crit. Care 2005, 15, S8. [Google Scholar]
  123. Hassdenteufel, E.; Mitropoulou, A.; Vollmar, C.; Henrich, E.; Neu, H.J.; Lehmann, H.; Wurtinger, G.; Hildebrandt, N.; Schneider, M. Thrombolytic therapy with Reteplase in Cats with Arterial Thromboembolism. Abstracts from the European Veterinary Emergency and Critical Care Annual Congress 2022. J. Vet. Emerg. Crit. Care 2022, 32, S2–S37. [Google Scholar] [CrossRef]
  124. The RAISE Investigators. Reteplase versus Alteplase for Acute Ischemic Stroke. N. Engl. J. Med. 2024, 390, 2264–2273. [Google Scholar] [CrossRef] [PubMed]
  125. Vezzosi, T.; Buralli, C.; Briganti, A.; Vannozzi, I.; Giacomelli, E.; Talamanca, G.F.; Sansoni, A.; Domenech, O.; Tognetti, R. Surgical embolectomy in a cat with cardiogenic aortic thromboembolism. J. Vet. Cardiol. 2020, 28, 48–54. [Google Scholar] [CrossRef] [PubMed]
  126. Thrombectomy and Thrombolysis—the Interventional Radiology Approach—2011.pdf. Available online: https://drive.google.com/file/d/1-k5wf0vhwhDdlK7_SRvnVzobBeauov8G/view?usp=drive_open&usp=embed_facebook (accessed on 16 May 2025).
  127. Reimer, S.B.; Kittleson, M.D.; Kyles, A.E. Use of Rheolytic Thrombectomy in the Treatment of Feline Distal Aortic Thromboembolism. J. Vet. Intern. Med. 2006, 20, 290–296. [Google Scholar] [CrossRef]
  128. Lu, J.; Qian, S.; Sun, Z. Targeting histone deacetylase in cardiac diseases. Front. Physiol. 2024, 15, 1405569. [Google Scholar] [CrossRef]
  129. Kulthinee, S.; Yano, N.; Zhuang, S.; Wang, L.; Zhao, T.C. Critical Functions of Histone Deacetylases (HDACs) in Modulating Inflammation Associated with Cardiovascular Diseases. Pathophysiology 2022, 29, 471–485. [Google Scholar] [CrossRef]
  130. Kisseberth, W.C.; Murahari, S.; London, C.A.; Kulp, S.K.; Chen, C.-S. Evaluation of the effects of histone deacetylase inhibitors on cells from canine cancer cell lines. Am. J. Vet. Res. 2008, 69, 938–945. Available online: https://avmajournals.avma.org/view/journals/ajvr/69/7/ajvr.69.7.938.xml (accessed on 17 May 2025).
  131. Dias, J.N.R.; Aguiar, S.I.; Pereira, D.M.; André, A.S.; Gano, L.; Correia, J.D.G.; Carrapiço, B.; Rütgen, B.; Malhó, R.; Peleteiro, C.; et al. The histone deacetylase inhibitor panobinostat is a potent antitumor agent in canine diffuse large B-cell lymphoma. Oncotarget 2018, 9, 28586–28598. [Google Scholar] [CrossRef]
  132. Augusto, J.-F.; Beauvillain, C.; Poli, C.; Paolini, L.; Tournier, I.; Pignon, P.; Blanchard, S.; Preisser, L.; Soleti, R.; Delépine, C.; et al. Clusterin Neutralizes the Inflammatory and Cytotoxic Properties of Extracellular Histones in Sepsis. Am. J. Respir. Crit. Care Med. 2023, 208, 176–187. [Google Scholar] [CrossRef]
Animals 15 01630 g001
Figure 1. Diagram summarizing the sequence of events leading to cardiogenic arterial thromboembolism. Aggregates of blood cells and fibrin polymers settle to form an intracardiac thrombus inside a diseased and enlarged left atrium (LA). The thrombus then dislodges, travels through the left ventricle (LV) and aorta (Ao) to embolize to distal arteries. The thrombus embolizes most commonly to the aortic bifurcation, causing partial or complete obstruction. Stenosis of the vascular lumen creates blood flow turbulence, which facilitates further thrombus growth. Arterial thrombosis leads to impedance of blood flow, tissue ischemia, necrosis, ischemic reperfusion injuries, and multiple organ failure.
Figure 1. Diagram summarizing the sequence of events leading to cardiogenic arterial thromboembolism. Aggregates of blood cells and fibrin polymers settle to form an intracardiac thrombus inside a diseased and enlarged left atrium (LA). The thrombus then dislodges, travels through the left ventricle (LV) and aorta (Ao) to embolize to distal arteries. The thrombus embolizes most commonly to the aortic bifurcation, causing partial or complete obstruction. Stenosis of the vascular lumen creates blood flow turbulence, which facilitates further thrombus growth. Arterial thrombosis leads to impedance of blood flow, tissue ischemia, necrosis, ischemic reperfusion injuries, and multiple organ failure.
Animals 15 01630 g001
Animals 15 01630 g002
Figure 2. Summary of Virchow’s triad and known causes and knowledge gaps of derangements of each component, which includes systemic hypercoagulability, blood flow stasis, turbulence, and endothelial injury. NETs—neutrophil extracellular traps, vWF—von Willebrand factor.
Figure 2. Summary of Virchow’s triad and known causes and knowledge gaps of derangements of each component, which includes systemic hypercoagulability, blood flow stasis, turbulence, and endothelial injury. NETs—neutrophil extracellular traps, vWF—von Willebrand factor.
Animals 15 01630 g002
Animals 15 01630 g003
Figure 3. Representative images of echocardiograms in cats with hypertrophic cardiomyopathy. (A) Right parasternal short-axis view of the left ventricle (LV). Note the marked thickening of the LV free wall (* indicates the papillary muscle). (B) M-mode of the LV at the level of the papillary muscle in a normal cat and a cat with HCM. Note the significant reduction in LV diameter during diastole. (C) Right parasternal short-axis view at the level of the left atrium (LA) demonstrating marked LA enlargement (Ao = aorta). (D) An organized thrombus (arrow) is visible in the LA with marked chamber enlargement in an asymptomatic cat with HCM. (E) Pulsed Doppler tracing from a cat without heart disease. Normal left auricular flow velocities showing mean emptying flow velocity of 0.8 m/s (arrow). The filling flow velocity is shown as an arrowhead. (F) Recorded pulsed Doppler tracing from a cat with HCM and left atrial enlargement showing low mean flow velocity (arrow).
Figure 3. Representative images of echocardiograms in cats with hypertrophic cardiomyopathy. (A) Right parasternal short-axis view of the left ventricle (LV). Note the marked thickening of the LV free wall (* indicates the papillary muscle). (B) M-mode of the LV at the level of the papillary muscle in a normal cat and a cat with HCM. Note the significant reduction in LV diameter during diastole. (C) Right parasternal short-axis view at the level of the left atrium (LA) demonstrating marked LA enlargement (Ao = aorta). (D) An organized thrombus (arrow) is visible in the LA with marked chamber enlargement in an asymptomatic cat with HCM. (E) Pulsed Doppler tracing from a cat without heart disease. Normal left auricular flow velocities showing mean emptying flow velocity of 0.8 m/s (arrow). The filling flow velocity is shown as an arrowhead. (F) Recorded pulsed Doppler tracing from a cat with HCM and left atrial enlargement showing low mean flow velocity (arrow).
Animals 15 01630 g003
Table 1. Risk factors associated with cardiogenic arterial thromboembolism.
Table 1. Risk factors associated with cardiogenic arterial thromboembolism.
History/Clinical AssessmentMale
Breed disposition (Ragdolls, Maine Coon) with mutation of myosin binding protein C gene (MYBPC3)
Previous thrombotic event(s)
Heart murmur
Gallop rhythm
BiomarkersElevated troponin (>0.06 ng/mL) *
Elevated NT-proBNP (>99 pmol/L) or POC positive (>200 pmol/L) *
Thoracic Radiographs Cardiomegaly (VHS > 8)
LA enlargement
Echocardiogram LV systolic dysfunction (LV fractional shortening and emptying fraction)
LA systolic dysfunction (Low LAA velocity, Low LA fractional shortening)
Spontaneous echocardiographic contrast and/or intracardiac thrombus
LA enlargement (LA:Ao > 1.6)
ElectrocardiogramArrhythmias: atrial fibrillation, ventricular arrhythmias
* No direct association with thrombosis but likely indicates significant heart disease that warrants further investigations; LA—left atrial; LAA—left atrial appendage; LA:Ao—Left atrium to aortic root ratio; LV—left ventricular; VHS—vertebral heart score.
Table 2. Comparison of viscoelastic tests.
Table 2. Comparison of viscoelastic tests.
Viscoelastic TestResults InterpretationProsConsSample Required
TEG
  • Hypercoagulability may be diagnosed by 2 or more of the following:
    Decreased R-time
    Decreased K time
    Increased MA
    Increased alpha angle
    Increased G value
  • Hyperfibrinolysis
    Increased LY30 and LY60 (>15.2%)
  • Global assessment of coagulation, including fibrinolysis
  • Influenced by hematocrit and viscosity
  • No clinical studies evaluating the association with thrombotic risk
  • High intra-assay variability
  • Limited availability
Citrated or fresh whole blood
ROTEM
  • Hypercoagulability may be diagnosed by 2 or more of the following:
    Decreased CT
    Decreased CFT
    Increased alpha angle
    Increased MCF
  • Hyperfibrinolysis
    Lysis > 15% within 30–60 min
    ML > 15%
    Decreased LOT
  • Global assessment of coagulation, including fibrinolysis
  • Point of care
  • Separate assays to assess intrinsic, extrinsic, and fibrinogen activity
  • Influenced by hematocrit and viscosity
  • No clinical studies evaluating the association with thrombotic risk
  • High intra-assay variability
Citrated whole blood
VCMHypercoagulable
  • Decreased CT and CFT
  • Increased alpha angle and MCF
Hyperfibrinolysis
  • Increased Li30, Li45 (%)
  • Global assessment of coagulation, including fibrinolysis
  • Point of care
  • More accessible
  • minimal training required
  • Readings can be affected by vibrations and movement
  • No clinical association with thrombotic risk
Fresh whole blood
TEG—Thromboelastography; R-time—Reaction time; MA—Maximum Amplitude; LY30—Lysis at 30 minutes; LY60—Lysis at 60 minutes; ROTEM—Rotational Thromboelastometry; CT—Clotting time; CFT—Clot formation time; MCF—Maximum clot firmness; ML—Maximum lysis; LOT—Lysis onset time; VCM—Viscoelastic monitoring; Li30—Clot Lysis after 30 min; Li45—Clot Lysis after 45 min.
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Yeh, N.S.; Shaverdian, M.; Li, R.H.L. Evolving FATE: A New Lens on the Pathogenesis and Management of Feline Cardiogenic Arterial Thromboembolism. Animals 2025, 15, 1630. https://doi.org/10.3390/ani15111630

AMA Style

Yeh NS, Shaverdian M, Li RHL. Evolving FATE: A New Lens on the Pathogenesis and Management of Feline Cardiogenic Arterial Thromboembolism. Animals. 2025; 15(11):1630. https://doi.org/10.3390/ani15111630

Chicago/Turabian Style

Yeh, Natasha S., Meg Shaverdian, and Ronald H. L. Li. 2025. "Evolving FATE: A New Lens on the Pathogenesis and Management of Feline Cardiogenic Arterial Thromboembolism" Animals 15, no. 11: 1630. https://doi.org/10.3390/ani15111630

APA Style

Yeh, N. S., Shaverdian, M., & Li, R. H. L. (2025). Evolving FATE: A New Lens on the Pathogenesis and Management of Feline Cardiogenic Arterial Thromboembolism. Animals, 15(11), 1630. https://doi.org/10.3390/ani15111630

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop