The hypercoagulability state is a common condition in patients with cancer, contributing to tumor-related morbidity and mortality (1), or even revealing silent malignancies (2). A close association between cancer and thrombophilic states exists, both physio-pathologically and clinically (1,3–5). Indeed, it is known that an imbalance between coagulation and fibrinolytic system happens in malignancy, because the cancer cells are able to produce and release procoagulant factors, such as tissue factors, cancer procoagulants, fibrinolityc protein (urokinase and tissue plasminogen activator), citokines (including tumor necrosis factor-α and interleurk-1β) and antiangiogenetic molecules (1,3–5). Moreover, cancer cells interact with host vascular and blood cells, including endothelial cells, leukocytes and platelets, and these mechanisms lead to signalling cascades resulting in coagulation activation and thrombi formation (1).

Thromboembolic events can affect the venous or/and the arterious circulation (3). Venous thromboembolism is found in 10–20% of patients with cancer and the incidence is 4–7 times higher compared with patients without cancer. Deep-vein-thrombosis (DVT) is the most common manifestation (6). The incidence of arterial thromboembolism ranges from 1 to 4.7% and non-bacterial thrombotic endocarditis (NBTE) is a rare manifestation (7). The incidence of NBTE is unknown and often is a post-mortem finding, occurring in 1.6% in the adult autopsies (6). Several factors are associated with increased risk of arterial and venous thromboembolic events, including cancer-associated factors, patients-associated factors and treatment-associated factors (3,7). Among cancer-associated factors, lung, gastric and pancreatic cancer, especially in advanced stages, are associated with a higher risk of thromboembolic events (3,8–10). Patient-associated factors contributing to higher risk include older and female patients with low performance status and history of viral or bacterial infection, chronic kidney disease, pulmonary disease and obesity (3,7). Meanwhile, treatment factors associated with increased risk of thrombi formation include chemotherapy and antiangiogenetic drugs, hormonal therapy, prolonged hospitalization or central venous catheters (7).

The treatment depends on the severity of thrombotic event; a massive pulmonary embolism could be fatal and requires early hospitalization, whereas mild to moderate cases are treated with anticoagulant therapy, namely unfranctioned heparins (fondaparinux) or low molecular weight heparin (7). Recently, the Hokusai VTE Cancer Trial demonstrated that non-inferiority of Edoxaban, an oral factor Xa inhibitor, for at least 6 months and up to 12 months compared to subcutaneous deltaparin in cancer patients with recurrent venous thromboembolism (11). Thus, Edoxaban could be a valid alternative to unfranctioned heparins (fondaparinux) or low molecular weight heparin.

The present study reports a case of a patient presenting with a newly diagnosed locally advanced non-small cell lung cancer (NSCLC) who developed widespread thromboembolisms that prevented any chance of local or systemic therapy. An underlying NBTE, previously misdiagnosed as a patent foramen ovale (PFO), was deemed responsible for the systemic hypercoagulability state.

NBTE is a rare but serious manifestation of the hypercoagulability state in patients with cancer, observed in ~1.25% of autoptic cases compared with 0.2% of autopsies performed in patients without cancer (16). Adenocarcinoma histology is frequently involved in the occurrence of NBTE with pancreatic adenocarcinoma being the most common (6,19).

The pathogenesis of NBTE endocarditis is not completely understood. The local and systemic milieu of pro-thrombotic factors secreted by tumors, such as tumor necrosis factor, interleukin 1, tissue factor and cancer procoagulant, are likely to be involved in the development and maintenance of cardiac vegetations (1). Cardiac vegetations are composed of aseptic thrombi, lacking inflammatory reaction and growing on valvular surface. Aortic and mytralic valves are the most commonly implicated, while the valves of the right side of the heart are less frequently affected (20).

In patients with cancer, embolization occurs in around 50% of NBTE cases (21). Notably, NBTE leads to embolization events more frequently compared with bacterial forms, given their mild cellular composition and the weaker intercellular links (22). The spleen, kidneys, brain, mesenteric and coronary arterial circulation are the most commonly structures implicated in NBTE (21,23,24).

The peculiarity of the present case was the development of systemic embolisms in a short period of time, while undergoing LMWH for a misdiagnosed PFO. Asymptomatic kidney and splenic infarctions were the first to be detected concomitantly with DVT, PTE and cerebral dissemination. The venous and pulmonary circulation is less frequently involved in NBTE embolization but are the most common manifestations of the hypercoagulability state (6). Therefore, differential pathogenetic mechanisms of NBTE on the basis of DVT and PTE cannot exclude. After presenting with these thromboembolic manifestations, the patient then developed cardiac, mesenteric and lower limb ischemia. Notably, the last brain CT scan (Fig. 4) documented a variety of lesions compatible with strokes occurring at different time points, suggesting that there were continuous emboli shedding from the valvular vegetations.

TEE, the best diagnostic tool to identify bacterial or non-bacterial endocarditis, has higher sensitivity compared with TTE (25,26). In the present case, TTE did not show abnormalities. Otherwise, the TEE documented a different cardiac involvement in terms of a PFO as the origin of the embolic foci. Both TTE and TEE, performed 40 days later, demonstrated sub-centimetric vegetation on the mitral valve, which explained the development of the cardiogenic thromboembolic state. Considering this, the importance of performing TEE by experienced physicians to rule out the possibility of endocarditis should be reiterated, particular when accompanying symptoms, radiological features and medical history (for example history of malignancy, as in the present case, or recurrent thrombotic events) are suggestive of NBTE.

The treatment of NBTE relies on therapy targeting the underlying pathology, for example lung cancer in the present case, but inflammatory chronic diseases (including systemic lupus erythematosus or connective tissue disorders) can also be a cause (27). NBTE also relies on anticoagulant therapy (6). Surgical intervention is not recommended for NBTE in patients affected by advanced and non-curable cancer (28). Both unfractionated heparin and LMWH are potentially effective in decreasing the risk of embolization (6). On the other hand, vitamin K antagonists, such as warfarin, fail to prevent the systemic emboli in NBTE, potentially due to the not involvement of vitamin K-dependent factors (factors II, VII, IX and X and protein C and S), inducing the trombophilic state in NBTE (29). There is no definite evidence demonstrating the efficacy of fondaparinux, a synthetic pentassaccharide like heparin, for the treatment of NBTE. Instead, direct oral anticoagulants, such as rivaroxaban and edoxaban, are acceptable alternatives to LMWH but should be used carefully, due to the considerable risk of bleeding events (30). However, recently a case of metastatic pancreatic cancer underlying a NBTE was reported, highlighting the clinical improvement and tumor control obtained with LMWH and chemotherapy administration (31).

Unfortunately, in the present case, LMWH administration for the suspected PFO was not sufficient to avoid diffuse embolization, even at the curative dose. Although, the patient was a candidate for Pembrolizumab therapy due to locally advanced disease stage (IIIB) and high expression levels of PD-L1 (≥50%) (15), multi-organ failure due the multiple foci embolization did not allow sufficient time for specific anticancer therapy to be administered.

NBTE should be strongly suspected when a patient with underlying malignancy experiences multiple arterial thrombotic events. Diagnosis of NBTE should not be excluded if the TTE does not demonstrate cardiac anomalies and a TEE should still be performed, given the risk of false negatives (32). In hindsight, the precocious putative detection of a NBTE in the present patient could have sped up the diagnosis and improved patient care, for example prolonging hospitalization with close clinical monitoring. Moreover, the current availability of targeted and immunotherapy agents, such as tyrosine kinase inhibitors and pembrolizumab, respectively, are characterized by lacking significant pro-thrombotic effects compared with traditional cytotoxic agents. So, these drugs in the treatment of patients with NBTE and cancer are deemed safe (33).

On the other hand, due to the strong association between cancer and NBTE, an unknown neoplastic disease should be considered for patients who develop systemic embolisms from sterile cardiac vegetations. It should be mandatory to suspect NBTE in these cases. NBTE quickly worsens and can be fatal if left untreated and the early start of adequate anticoagulant and specific anticancer therapy may improve survival and risk of complications due to NBTE.