Extreme hyperferritinemia in the setting of acute myeloid leukaemia: a case report of hemophagocytic lymphohistiocytosis

Introduction Major hyperferritinemia is a rare feature in clinical laboratories associated with a wide variety of disorders, including hemophagocytic lymphohistiocytosis (HLH). The diagnosis of HLH is based on clinical and biological criteria, such as those proposed by the Histiocyte Society. However, several of these criteria are not relevant in the specific setting of hematologic malignancies. Materials and methods A 69-year-old male was treated for an acute myeloid leukaemia. On day 15 after the start of chemotherapy, he developed severe sepsis with high fever, low blood pressure and hepatosplenomegaly. Results Blood tests were marked by extreme hyperferritinemia (191,000 µg/L, reference range: 26-388 µg/L) with increased C-reactive protein (87.0 mg/L) and procalcitonin (1.94 µg/L) and aspartate aminotransferase (499 U/L 37 °C) in the setting of chemotherapy-induced aplasia. This unusual extreme ferritinemia led to suspect HLH triggered by an invasive infection. Under intensive treatment, the clinical status improved and ferritin levels significantly decreased. Conclusions The diagnosis of HLH is usually based on clinical and biological criteria, mainly fever, splenomegaly, cytopenias, hypertriglyceridemia, hypofibrinogenemia, hemophagocytosis and hyperferritinemia. In this patient, the diagnosis of HLH was challenging because several criteria, such as hypertriglyceridemia, hemophagocytosis and hypofibrinogenemia, were absent. In addition, some criteria of HLH are not relevant in the setting of hematologic malignancy, in which fever, splenomegaly, cytopenias and elevated lactate dehydrogenase are commonly observed independently of HLH. This unusual case of extremely high ferritinemia emphasizes the important weight of the ferritin level for the diagnosis of HLH in adult patients in the setting of hematologic malignancies.


Introduction
Ferritin is an iron storage protein which plays a major role in the regulation of iron metabolism (1). Ferritinemia is routinely used to assess iron status. While mild hyperferritinemia is commonly observed in inflammatory diseases and alcoholism, major hyperferritinemia is much more unusual. Major hyperferritinemia > 50,000 µg/L was recently reported to be associated with a wide variety of disorders such as renal failure, hepatocellular injury, infection, hematologic malignancy, rheumatologic disorders, iron overload, haemolytic anaemia and hemophagocytic lymphohistiocytosis (HLH) (2)(3)(4). HLH is a rare but life-threatening condition, caused by genetic mutations (familial HLH) or secondary to infections, malignancies or autoimmune dis-eases (acquired HLH) (5,6). HLH is characterized by an uncontrolled hyper activation of the immune system, leading to organ damages (6). Extremely high levels of ferritin may not only be a reflection of inflammation in HLH, but may also play a role in the pathogenesis of the disease (2). A prompt and accurate diagnosis of HLH is crucial to start treatment as soon as possible and therefore to enhance chances of survival. To date, the diagnosis of HLH is based on clinical and biological criteria, such as those proposed by the Histiocyte Society in their paediatric HLH-2004 diagnostic guidelines (7). These latter specify that at least 5 of the 8 following criteria are required for the diagnosis of HLH: fever, splenomegaly, cytopenia affecting 2 lineages (Hb < 90 g/L, Plt < 100 x 10 9 /L, neutrophil count < 1.0 x 10 9 /L ), hypertriglyceridemia and/or hypofibrinogenemia (> 3.0 mmol/L and < 1.5 g/L, respectively), hemophagocytosis (in the bone marrow aspirate, spleen or lymph node), hyperferritinemia > 500 µg/L, impaired NK cell function and sIL2R > 2400 U/mL (7). But, in the setting of hematologic malignancies, several important criteria for the diagnosis of HLH such as cytopenias, fever or splenomegaly may be commonly found as consequences of the disease or treatments in the absence of HLH. Here, we report a case of major hyperferritinemia, which is original because of the extremely high ferritin level, and because it emphasizes to what extent major hyperferritinemia is useful for the diagnosis of HLH in the specific setting of hematologic malignancies.

Subject
A 69-year-old male with no significant medical history was admitted for chest pain to the emergency department of the University Hospital Centre Dijon-Burgundy (France). Routine biochemical and haematological blood tests were performed. Informed consent was obtained from the patient, and all procedures were in accordance with our institutional Ethics Committee and with the Declaration of Helsinki.

Methods
Ferritin, electrolytes, aspartate aminotransferase (AST), alanine aminotransferase (ALT), triglycerides, C-reactive protein (CRP) and troponin Ic were measured on Dimension Vista analyser (Siemens, Eschborn, Germany) with dedicated reagents. The ferritin assay on Dimension Vista is a sandwich chemiluminescent immunoassay with calibrators traceable to the WHO 3 rd IS 94/572 standard. Complete blood cell count and haemostasis tests were performed on Sysmex XN-9000 platform (Sysmex Corporation GmbH, Hamburg, Germany) and STA-R (Diagnostica Stago, Asnieres-sur-Seine, France), respectively. Procalcitonin was obtained with the Brahms Kryptor analyser (Thermo Scientific, Hennigsdorf, Germany). All instructions of manufacturers were followed.

Results
Blood tests allowed to exclude myocardial infarction based on negative troponin I (i.e. < 0.02 µg/L), con-firmed 6 hours later. Upon admission, laboratory investigations revealed anaemia (haemoglobin (Hb) = 87 g/L), thrombocytopenia (platelets (Plt) = 80 x 10 9 /L) and 20% blast cells in the white blood cell (WBC) count (9.3 x 10 9 L). The bone marrow aspirate contained 22% blasts (99% CD33 positive cells). All biological investigations taken together led to the diagnosis of acute myeloid leukaemia (AML) M5 with a mutation in the nucleophosmin (NPM1) gene. Then, the patient was rapidly started (day 0) on induction therapy with cytarabine, daunorubicin and anti-CD33 monoclonal antibody. In addition, posaconazole was administered to prevent invasive fungal infection in this patient colonized with Candida albicans. The chemotherapy-induced aplasia started on day 5 with Hb = 91 g/L, neutrophils = 0.37 x 10 9 /L and Plt = 21 x 10 9 /L. On day 15, the patient developed signs of severe sepsis with prolonged high fever > 39 °C and episodes of low blood pressure, associated with hepatosplenomegaly. The clinical and laboratory features on day 15 are shown in Table 1. These laboratory test results were mainly marked by extremely high ferritinemia around 191,000 µg/L (reference range: 26 -388 µg/L), confirmed the following day (compared with 1140 µg/L upon admission) associated with increased inflammatory markers and transaminases. HLH was primarily suspected considering the prolonged fever, hepatosplenomegaly and major hyperferritinemia in a context of predisposing underlying diseases, i.e. both AML and infection. It was suspected that an invasive fungal infection had triggered HLH in the light of repeated increases in β-D-glucan and procalcitonin levels, despite negative blood cultures in this patient preventively treated with posaconazole. Considering the life-threatening presentation, an intensive treatment was immediately started with support measures, and antifungal and antibiotic drugs, leading to a clinical improvement in the following days without use of steroids or etoposide.
On day 19, levels of inflammatory markers, CRP (21.4 mg/L) and procalcitonin (0.50 µg/L), had significantly decreased. On day 20, the patient's fever and aplasia had resolved (neutrophils = 1.4 x 10 9 /L, Hb = 94 g/L), but the severe thrombocytopenia persisted (Plt = 15 x 10 9 /L). This, however, was successfully treated with intravenous gamma globulin over the course of 4 days, suggesting that it was probably a post infection autoimmune condition. On day 23, hepatic cytolysis markers had fallen with 87 and 201 U/L for AST and ALT, respectively. Ferritin levels gradually decreased (33,900 and 4280 µg/L on days 22 and 34, respectively).

Discussion
The Histiocyte Society proposed that at least 5 of the 8 following criteria are required for the diagnosis of HLH: fever, splenomegaly, cytopenia affecting 2 lineages (Hb < 90 g/L, Plt < 100 x10 9 /L, neutrophil count < 1.0 x 10 9 /L), hypertriglyceridemia and/or hypofibrinogenemia (> 3.0 mmol/L and < 1.5 g/L, respectively), hemophagocytosis (in the bone marrow aspirate, spleen or lymph node), hyperferritinemia > 500 µg/L, impaired NK cell function and sIL2R > 2400 U/mL (7). Our patient met three of these criteria namely fever, splenomegaly and hyperferritinemia, which are reported in 96, 73 and 100% of HLH cases, respectively (3). Obviously, the presence of predisposing underlying disease in the patient, i.e. both malignancy and infection, which are reported in 49 and 33% of HLH cases, respectively, was an important feature for the diagnosis of acquired HLH (3).
The diagnosis of HLH was challenging in this patient for several reasons. First, several laboratory criteria from the HLH-2004 diagnostic guidelines were absent (7). In particular, there were no signs of hemophagocytosis in the bone marrow aspirate, no hypertriglyceridemia ≥ 3.0 mmol/L and no hypofibrinogenemia ≤ 1.5 g/L, even though they are reported in 85, 69 and 48% of cases of HLH, respectively (5). Second, other difficulties were due to limitations of the diagnostic criteria themselves. For instance, assessment of NK cell function, sIL2R and glycosylated ferritin are not available in routine practice, or results are returned late (8). In our case, these specialized tests could not be performed because not available in our facilities, but it reflects the everyday practice for most institutions. Moreover, there are no consensual validated diagnostic guidelines for adult HLH to date, thus leading to the use of paediatric criteria, like those from the HLH-2004 guidelines (7). Other criteria for HLH in adults were recently developed, but in the specific population of systemic juvenile idiopathic arthritis (9). Last but not least, another difficulty to diagnose HLH in our case was inherent to the specific context of hematologic malignancy. Indeed, several diagnostic criteria, such as cytopenias, fever, splenomegaly and elevated lactate dehydrogenase, are commonly found in this setting independently of HLH. Therefore, these criteria cannot be considered relevant in this context, although cytopenias, fever, organomegaly and elevated lactate dehydrogenase were considered important for the positive diagnosis of HLH for 100, 96, 92 and 75% of members of a panel of experts, respectively (10). Cytopenia affecting at least one lineage was even considered an absolute requirement for 89% of them (10).
In view of these difficulties, fever, marrow hemophagocytosis and very high ferritin level are considered as the cornerstones of the diagnosis in patients with AML (11). In our case, the high ferritin level appeared, in fact, as a preponderant criterion for the diagnosis of HLH. Elevated ferritinemia is a well-known hallmark of HLH.
A recent paper reported that mean ferritinemia on the presentation of HLH was 5316 µg/L (ranging from 321 to 9100 µg/L (3)), which is consistent with the mean value of 5140 µg/L reported in another adult cohort (12). Ferritinemia is a sensitive biomarker for the diagnosis of HLH. For instance, sensitivity was evaluated at 90-100 and 71% for thresholds of ferritinemia of 500 µg/L and 1000 µg/L, respectively (3,7). In other words, normal ferritinemia has an excellent negative predictive value for the diagnosis of HLH. On the other hand, the positive predictive value of major hyperferritinemia is a matter of debate. Schram et al. recently reported that major ferritinemia > 50,000 µg/L was associated with HLH in only 17% of cases (13). In contrast, another group considered that an extremely high ferritin level was predictive of HLH, because it was observed in very few disorders, such as HLH and adult-onset Still's disease (2). Likewise, Allen et al. found a specificity of 96% for HLH using a ferritin threshold of 10,000 µg/L (14). However, this latter study was conducted in a paediatric population, in which the spectrum of underlying disorders is quite different from than in adult populations. Either way, among all disorders associated with major hyperferritinemia, the likelihood of a diagnosis of HLH seems to be higher for very high ferritin levels (4,13). Indeed, Saeed et al. recently reported that, among all causes of hyperferritinemia, the specificity and the positive likelihood ratio for a diagnosis of HLH increased in parallel of the ferritin cut off in adult patients (15).
An HScore was recently developed to estimate the individual risk of having HLH (8). This HScore takes into account three clinical and five biological weighted variables, which are easily available, i.e. triglyceridemia, AST, fibrinogenemia, cytopenias and ferritinemia. The best cut off value of the HScore was estimated at 169, corresponding to a sensitivity of 93% and a specificity of 86% for HLH, with 90% of patients accurately classified (8). In our patient, we aimed to calculate the HScore based on features on day 15 (algorithm available online http://saintantoine.aphp.fr/score/), by considering values of haemoglobin, platelets and WBC as unknown in the model because there are not relevant in the context of chemotherapy-induced aplasia. In this manner, the HScore for our patient was 202, corresponding to an 89% probability of a diagnosis of HLH. By introducing ferritinemia lower than 2000 µg/L (threshold proposed by the algorithm) into the model, the HScore fell very significantly from 202 to 152, as did the probability of HLH from 89 to 28 %. This calculation emphasizes the important weight of the ferritin level for the diagnosis of HLH in the context in which hematologic parameters are not relevant.
In conclusion, this unusual case of extremely high ferritinemia highlights the preponderant contribution of an extreme ferritin level to the diagnosis of HLH in adult patients in the setting of AML.