Hantaviruses are globally distributed viruses that are transmitted to humans through the inhalation of viral particles found in the urine and faeces of infected rodents. In Europe, hantaviruses cause haemorrhagic fever with renal syndrome (HFRS), a disease characterised by acute kidney failure and, in some cases, significant bleeding complications. Despite advances in understanding HFRS, the mechanisms underlying these bleeding abnormalities remain poorly understood. Several hypotheses suggest that hantaviruses may interfere with the function of blood clotting factors, but definitive evidence is lacking.
Slovenia, a country in southern Europe, has one of the highest incidences of HFRS relative to its population, with recent years seeing large outbreaks. Discussions with leading hantavirus experts in Slovenia have highlighted the urgent need for further research, particularly to understand why some patients with HFRS develop severe bleeding complications. Currently, no licensed treatments exist for HFRS, raising concerns about future outbreaks, which are expected to become more frequent due to climate change. By investigating the mechanisms leading to clotting dysfunction, this study aims to identify potential targets for future therapeutic interventions.
This study will explore the pathological mechanisms driving clotting abnormalities and bleeding in hospitalised patients with HFRS. Additionally, it will assess whether different hantavirus types influence disease severity and haemorrhagic complications and evaluate the applicability of a severity scoring system-originally developed for HFRS cases in China-in predicting outcomes among Slovenian patients.
Patients with laboratory-confirmed HFRS will be prospectively recruited from University Medical Centre Ljubljana, Slovenia. Blood samples will be collected at multiple time points during their illness and tested for standard laboratory markers, including clotting factors, blood cell counts, kidney function, and liver function. Additionally, thromboelastography (TEG) will be performed to assess real-time clotting dynamics, providing a more detailed evaluation of clotting abnormalities.
An additional blood sample will undergo transcriptomic analysis using nanopore sequencing. This will identify the specific hantavirus strain in each patient and analyse gene expression patterns associated with disease severity and bleeding risk. Patients will also be assigned a severity score based on their clinical presentation, laboratory results, and symptoms, using a scoring system developed in China to predict HFRS-related mortality. This study will evaluate the reliability of this scoring system in a European cohort.
To better understand the factors contributing to bleeding in HFRS, patients will be categorised into two groups: those with haemorrhagic manifestations and those without. Statistical analyses will compare laboratory and clinical findings between these groups, aiming to identify key predictors of bleeding complications. The findings from this research may help inform future therapeutic strategies for HFRS.
