Immunomonitoring of Mold Invasive Infections — IMMUNOFIL  

Invasive Fungal Disease Clinical Trial

Official title: Immunomonitoring of Mold Invasive Infections

Status Not yet recruiting

Clinical Trial Summary

Mold invasive infections are associated with an important mortality despite optimization of the antifungal treatment. In a few case reports, immune checkpoints inhibitors, initially developed for neoplastic diseases, have shown a potential beneficial effect in such devastating infections by restoring an efficient immune response. The investigators propose a longitudinal monitoring of the adaptative immune response, notably immune checkpoint expression on T cells, during mold invasive infections to help identify the patients who could benefit from the adjunction of immunotherapy and the optimal timing of such strategy.

Clinical Trial Description

Invasive fungal diseases (IFD) still cause substantial morbidity and mortality. New therapeutic approaches are therefore urgently needed, notably for patients not responding to conventional antifungal treatment. One strategy to prevent treatment failure is to improve the immune functions of immunocompromised hosts. Indeed, antifungals therapeutic efficacy is limited without the help of host immune reactivity (Stevens et al., 2000). As several studies have suggested that IFD are associated with an impaired Th1 host immune response, various cytokines have been evaluated in experimental and human fungal infections. In particular, adjunction of recombinant IFNγ has been proposed as a treatment option in patients with poor prognosis IFD with partial success. More recently, it has been shown that, when T cells are exposed to persistent antigens and/or inflammatory signals due to inefficient control of persisting infections, or in the context of tumors, a deterioration of their functions is observed, a state called "exhaustion". Molecular pathways involved in exhaustion have been partially deciphered, highlighting the importance of molecules called immune checkpoint such as PD-1 or CTLA-4. Furthermore, it was shown that blockade of these molecules can reverse this dysfunctional state. Immune checkpoint inhibitors (such as anti-PD1 antibodies) have become major weapons in oncology. In infectious diseases, and more particularly IFDs, data are much more limited. In animal models of several IFD, such as aspergillosis, cryptococcosis and histoplasmosis, repetitive administration of anti-PD-1 monoclonal antibodies significantly improved fungal clearance and survival of lethally infected animals. In humans, three case-reports, including one published by our team, have reported the efficacy of anti-PD-1 therapy combined with IFN-γ in the treatment of refractory IFDs. Therefore, by reversing T cell exhaustion, immune checkpoint blockade represents a therapeutic perspective for IFD treatment. The use of immune checkpoint inhibitors may, however, entail severe, notably autoimmune off-target adverse effects and should be carefully balanced and monitored. The development of tools allowing identification of patients who could benefit from immunotherapy is of particular importance as well as assessment of the optimal timing of these innovative treatments. As such, a better understanding of the host immune response is one of the major approaches to developing new or improved antifungal strategies to control IFDs. Longitudinal data regarding the evolution of exhaustion markers expression in T cells of patients treated for an IFD are lacking. The goal is to better characterize the adaptative immune response directed against molds, notably immune checkpoint expression, in order to identify the patients who could benefit from the adjunction of immunotherapy and the optimal timing of such strategy. For this purpose, the investigators will include adult patients with mold IFD either at diagnosis or refractory to conventional therapy. They will measure activation and exhaustion markers on circulating T cells and monocytes by flow cytometry at three timepoints (enrollment, day 14 and week 6). Moreover, for patients with invasive aspergillosis or mucormycosis, they will evaluate the capacity of specific T cells to produce Th1, Th2 and Th 17 cytokines and to proliferate after specific antigenic stimulation, in the absence and in the presence of an anti-PD1 antibody in vitro (4 colors FLUOROSPOT) at two timepoint (enrollment and week 6). These data will provide a longitudinal assessment of the anti-fungal immune response. They will be correlated with the underlying diseases of the patients, the type of mold infection (aspergillosis, mucormycosis, fusariosis or scedosporiosis), the treatment received and the outcome. These results should help to better identify patients who could benefit from adjunctive anti PD-1 treatment and the optimal timing for such treatment. ;

Related Conditions & MeSH terms

• Infections
• Invasive Fungal Disease
• Invasive Fungal Infections
• Mycoses

• NCT number: NCT06285188
• Study type: Observational
• Source: Assistance Publique - Hôpitaux de Paris
• Contact: Alexandra SERRIS, MD, PhD
• Phone: +33 6 68 80 24 92
• Email: alexandra.serris@aphp.fr
• Status: Not yet recruiting
• Start date: March 2024
• Completion date: March 2026