Dear Editor,

The COVID-19 pandemic has been deemed a global health emergency. Vaccination is considered the most important and effective strategy to prevent infection and eradicate the disease [1,2,3]. Since then, there is a significant interest in venous thromboembolism (VTE) and thrombocytopenia after COVID-19 vaccination. To date, there is only one report outlining a possible association between VTE and the COVID-19 mRNA vaccine days after the second dose in a patient with heterozygous Factor V Leiden (FVL) mutation [4]. Herein, we report a case of VTE and pulmonary embolism (PE) after administration of the COVID-19 mRNA vaccine as an acute phase reaction in a patient with thrombophilia.

A 24-year-old male patient was presented to our Hematology clinic for management of a recently diagnosed right lower extremity deep venous thrombosis (DVT) and PE. His medical history is unremarkable, with no previous thrombotic events reported. Two months earlier, he had received the second dose of Pfizer BioNTech mRNA COVID vaccine. Twenty-four hours post vaccination, the patient started to experience left sided pleuritic chest pain which was not relieved by paracetamol. The pain was associated with low-grade fever and right lower extremity edema, erythema, and pain with inability to bear weight on right leg. Upon presentation to the emergency room, laboratory studies showed elevated D-dimer of 800 ng/ml. Other blood tests (including complete blood count, international normalized ratio (INR), partial thromboplastin time (PTT), renal and hepatic panel) were normal. A venous duplex ultrasound of lower extremities showed thrombophlebitis extending from the right external iliac vein to the common femoral vein reaching the right popliteal vein with a fresh thrombus at the common femoral vein. A computed tomography scan of the chest with intravenous contrast showed the presence of bilateral filling defects in the right superior and inferior lobar arteries and in the lingular and left inferior lobar arteries. An echocardiography showed normal right ventricle and ejection fraction of 64%. The patient was started on enoxaparin 1 mg/kg every 12 h and admitted to the intensive care unit for observation. Thrombophilia screening showed FVL G169A heterozygous mutation and MTHFR A1298C homozygous mutation. His homocysteine level was also elevated (254 umol/L) with low folic acid (1 ng/ml) and vitamin B12 (123 pg/ml). There was no evidence of lupus anticoagulant. The patient was discharged home after few days on apixaban 5 mg twice daily.

Thrombophilia is a blood coagulation disorder that is associated with a higher risk of VTE and is identified in almost half of patients presenting with thrombosis [5]. The prevalence of FVL is about 3–7% in the general population with a relative risk of 3 to 5 for first VTE compared to the normal population, and the presence of MTHFR mutations was found to be a combined risk factor for hypercoagulability disorders [6, 7].

The Pfizer BioNTech vaccine was the first approved vaccine for the prevention of COVID-19 infection, with an efficacy reaching 95% and a favorable safety profile and no VTE cases reported [3]. However, the safety of this vaccine has not been investigated in patients with inherited thrombophilia and who are at increased risk of VTE. The trigger of VTE in our patient could be attributed to a very intense immunological response secondary to the second dose of the vaccine, a pathophysiological mechanism commonly identified in several clinical conditions such as infections, sepsis, and inflammation[8]. However, the presence of the FVL mutation has been shown to enhance the thrombophilia tendency during an inflammatory episode [9]. The co-presence of the MTHFR mutation might have caused the increased risk of VTE in this patient. Multiple studies investigating the association of MTHFR mutations and VTE have shown conflicting results. In a pooled analysis investigating the association between different genetic alterations and VTE, the risk of VTE was increased in patients with homozygous C677T MTHFR mutation who are heterozygous for FVL [9]. Venous thromboembolism such as portal vein thrombosis has also been reported in a patient with heterozygous A1298A MTHFR mutation [10]. The association of all these factors including heterozygous FVL, homozygous MTHFR, and a robust inflammatory response after the vaccine could explain the occurrence of VTE in our patient (Fig. 1).

Fig. 1
figure 1

Proposed pathophysiology of VTE after COVID-19 vaccination in the presence of hypercoagulable state. The combination of FVL heterozygous mutation leading to resistance to activated protein C, MTHFR A1298C homozygous mutation leading to increased homocysteine levels, and a severe acute inflammatory reaction after mRNA COVID-19 vaccine could be a trigger for venous thromboembolism

Interestingly, there have been serious concerns regarding an increased risk for varying types of thrombosis following vaccination for the COVID-19 virus including cerebral venous sinus thrombosis, arterial thrombosis, and splanchnic vein thrombosis [11]. One possible explanation could be related to the fact that antibodies against platelet factor 4 (PF4), as seen in heparin induced thrombocytopenia (HIT), form post vaccination and in turn contribute further to coagulopathy. In a case report describing a case of DVT and PE 7 days following the first dose of Pfizer BioNTech mRNA vaccine, laboratory tests were significant for positive HIT ELISA test with an elevated optical density assay of 0.617 [11]. Another study assessing the frequency of PF4 antibodies after COVID vaccination showed 5.6% antibodies with Pfizer BioNTech vaccine compared to 8% with Astrazeneca ChAdOx1vaccine. However, the clinical relevance of these antibodies was very minor [12].

In conclusion, we report a case of DVT and PE in a patient with a previously unknown FVL heterozygous mutation and MTHFR homozygous mutation, hours after the second dose of the Pfizer BioNTech mRNA COVID-19 vaccine. The COVID-19 mRNA vaccine has shown excellent efficacy with a favorable safety profile. However, we believe that in patients who are at an increased risk of thrombophilia especially those who carry multiple genetic abnormalities, the risk of VTE might be further increased due to the combination of these factors with an immune inflammatory response to the vaccine. It is advisable that patients with a previous history of unprovoked DVT or PE, who were not tested for genetic risk, to be offered testing prior to COVID-19 vaccination. Currently, there is no sufficient data to support the exemption of these patients from vaccination or to use anticoagulation prophylaxis. However, to date, mRNA vaccines appear to be safe, and anticoagulation should be discussed on a case-by-case basis. Clinicians shall be aware of this increased risk, and patients shall be well educated on benefits and possible risks behind the vaccine.