CaspoNEB: Efficacy and Safety of Caspofungin Aerosols for the Curative Treatment of Pneumocystis Pneumonia

Phase 1

Not yet recruiting

• Conditions: Pneumocystis Pneumonia; Pneumocystis Jirovecii Infection; Pneumocystis Infections
• Interventions: Drug: Caspofungin Acetate 50 MG; Drug: Physiologic saline

• Registration Number: NCT06892951
• Lead Sponsor: University Hospital, Tours

Brief Summary

To assess the efficacy of administrating daily caspofungin aerosols versus placebo for seven days, in adjunction of conventional systemic antifungal therapy during curative treatment of Pneumocystis pneumonia, on the clinical outcome at the end of the nebulized therapy, in order to support a "GO / NO GO" decision towards a phase III trial of nebulized caspofungin in those patients.

Detailed Description

Pneumocystis jirovecii is an airborne-transmissible fungus which can induce pneumonia with severely impaired lung function, especially in immunocompromised patients. At least 1,000 new cases of Pneumocystis pneumonia occur each year in France with approximately 50% of cases suffering from hypoxemia. Around 15% HIV+ and 50% HIV- subjects require mechanical ventilation, and mean duration of hospitalization is about 30 days. Average mortality rate is ≈20% at 3 months, higher for critically ill patients (30%-60%).

To date, cotrimoxazole represents the gold standard anti-Pneumocystis treatment commonly associated with systemic corticosteroids in case of moderate-to-severe infection. However, treatment is long (several weeks) to achieve clearance of the fungus, which might favor lung sequelae like persistent inflammation or post-infectious fibrosis. Furthermore, therapeutic failures have been reported as high as 9-44% of patients. Five other drugs have been commonly used as curative alternatives to cotrimoxazole against P. jirovecii: pentamidine, primaquine + clindamycin, dapsone and atovaquone. Some are responsible for serious side effects, while others are complex to administer or less efficient. All exhibit clinically important drug-drug interactions. Therefore, in such a context, it is important to test new drugs and/or alternative delivery routes for existing therapies.

Echinocandin drugs, including caspofungin, are usually administered daily to treat invasive candidiasis and aspergillosis. They target the fungal cell wall, thus inhibiting the β-(1,3)-D glucan synthase enzyme. Intravenous (IV) echinocandins are generally well tolerated and are not responsibles for major drug-drug interactions. IV caspofungin was also proven effective in animal models of Pneumocystis infection and significantly improve the overall survival. Two human studies showed that in-hospital and 3-month mortality rates were similar between patients receiving daily IV echinocandin and those receiving co-trimoxazole alone. Several case reports also showed 47 successful outcomes with IV caspofungin, alone or in combination with standard treatment. A recent study reported better response and lower in-hospital mortality in patients receiving the combination of cotrimoxazole + IV caspofungin with no severe adverse events. Therefore, IV echinocandins are now recommended in the European therapeutic guidelines for non-HIV patients as a salvage therapy (CII-grade) in association with co-trimoxazole.

However, high molecular weight and elevated protein binding hamper optimal diffusion of IV caspofungin towards the lung alveoli (\<5% plasma concentration), where P. jirovecii thrives. Administration through an aerosol directly delivered into the lung may circumvent this limitation. Technical feasibility of echinocandin nebulization was demonstrated in vitro with several commercial nebulizers that provided aerosol particles with adequat size and pH to ensure lung tolerance. In vivo, nebulized caspofungin, at a dosage equivalent to the usual IV dosage, showed an excellent safety profile in rats. It also reduced the fungal burden by -99% and induced elevated and prolonged concentrations of the drug in the lungs (almost 50% of the total amounts of caspofungin initially deposited into the lungs of infected rats were still detectable at 48 hours) - largely above the usual minimal inhibitory concentrations of fungal pathogens -, while caspofungin detection was almost null in other organs and blood.

Therefore, we hypothesize herein the therapeutic interest of caspofungin aerosols in adjunction with conventional antifungal therapy, as first-line curative treatment, to enhance the clinical recovery and to reduce the morbidity due to Pneumocystis pneumonia. As no clinical trials have been worldwide initiated, human efficacy and safety data of nebulized caspofungin are still lacking and will be first investigated in this study in patients. Thus organized in two successive parts, this phase I/II clinical trial represents a mandatory prelude for this original administration modality of caspofungin.

Study Timeline

• Study First Submitted: 2024-01-18
• Status Verified: 2025-03
• Study First Submitted QC: 2025-03-17
• Last Update Submitted: 2025-03-17
• Study First Posted: 2025-03-25
• Last Update Posted: 2025-03-25
• Study Start: 2025-06
• Primary Completion: 2026-06
• Study Completion: 2028-12

Recruitment & Eligibility

• Status: NOT_YET_RECRUITING
• Sex: All
• Target Recruitment: 100

Inclusion Criteria

Not provided

Exclusion Criteria

Not provided

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: PARALLEL

Arm && Interventions

Group	Intervention	Description
Part 2 - randomized study (group 1)	Caspofungin Acetate 50 MG	Conventional systemic antifungal treatment (systemic co-trimoxazole or systemic second line anti-Pneumocystis salvage therapy) + aerosols of echinocandin (50 mg caspofungin) during one to seven days (according to the regimen retained from the results of part 1 from day-1 to d-7) using vibrating mesh nebulization device
Part 2 - randomized study (group 2)	Physiologic saline	Control group: (in part 2 only) Conventional systemic antifungal treatment (systemic co-trimoxazole or systemic second-line anti-Pneumocystis salvage therapy) + aerosols of placebo (0.9% saline in a volume equivalent to the experimental group) during one to seven days (according to the regimen retained from part 1 results) using vibrating mesh nebulization device
Part 1 - open study	Caspofungin Acetate 50 MG	open-label non-randomized group, with ascending scheme regarding the dose and rhythm of administration over one week, depending on the tolerance, and closely monitored in ICU to ensure that caspofungin is well tolerated via the inhaled route, and to provide data supporting the proposed administration scheme for part 2. * the first two patients (included one by one) will receive two aerosols (5 mg) during the first week, four days apart on d-1 and d-5 (level 1); * the third and fourth will receive two aerosols (15 mg) during the first week, four days apart on d-1 and d-5 (level 2); * the fifth and sixth will receive two aerosols (50 mg) during the first week, four days apart on d-1 and d-5 (level 3); * the seventh and eighth patients will receive four aerosols (50 mg) two days apart during one week, at d-1, then d-3, d-5 and d-7 (level 4); * the last two patients will have daily aerosols during the first week, from d-1 to d-7 (level 5)

Primary Outcome Measures

Name	Time	Method
Part 1: safety of inhaled caspofungin	D-7 (day-7)	* frequency of adverse events; * severity of adverse events
Part 2: proportion of patients alive and with a favorable clinical course* at the seventh day (day-7) after the first administration.	D7 (day-7)	Composite outcome defined by at least one of the two following items persisting ≥24 hours in alive patients: * Relative reduction (de-escalation or withdrawal) of respiratory assistance due to clinical improvement (depending on the initial support): * extubation, or; * weaning of non-invasive ventilatory support, or; * weaning of nasal high-flow or low-flow oxygen therapy; (NB: all participating centers will implement uniform protocols for ventilatory assistance weaning); * Occurrence of a +50% increase in oxygenation (PaO2 / FiO2 ratio vs. the worst value observed after inclusion).

Secondary Outcome Measures

Name	Time	Method
Individual components of the composite primary outcome at day-7 (d-7)	D7 (day-7)	* All-cause mortality and Pneumocystis pneumonia-related mortality; * Improvement of respiratory function: * Proportion of patients alive and with relative reduction (de-escalation or withdrawal) of respiratory assistance (in percentage); * Proportion of patients alive and with a +50% increase in oxygenation (PaO2 / FiO2 ratio vs. the worst value observed after inclusion) (in percentage)
Safety of nebulized caspofungin in patients with Pneumocystis pneumonia through	day-1 (d-1), d-2, d-3, d-4, d-5, d-6, and d-7	* Occurrence of serious and non-serious pulmonary adverse events and adverse effects at day-1 (d-1), d-2, d-3, d-4, d-5, d-6, and d-7 (with active monitoring of the nebulization procedure), and serious pulmonary adverse events and adverse effects at hospital discharge, d-28 and d-90; * Occurrence of other serious adverse events and adverse effects at day-1 (d-1), d-2, d-3, d-4, d-5, d-6, d-7, hospital discharge, d-28 and d-90; * Liver and kidney markers at day 1 (d-1), d-3, d-7, d-28 and d-90; * transaminases (in international units/liter); * glutamate transferase (in international units/liter); * alkaline phosphatase (in international units/liter); * serum creatinine (in micromol/liter); * urea (in millimol/liter); * Blood counts (same dates); * complete blood count (in giga/liter); * platelets (in giga/liter); * Serum electrolytes (same dates); * sodium (in mmol/liter); * potassium (in mmol/liter); * chloride (in mmol/liter); * bicarbonates (in mmol/liter)
Pharmacokinetics of nebulized caspofungin	0, 2, 4, 6, 12, 24 hours, plus residual concentration at day (d-3) and d-7	in blood at 0, 2, 4, 6, 12, 24 hours, plus residual concentration at day-3 (d-3) and d-7 for the five first included patients receiving caspofungin, and in tracheo-bronchial aspirates at 4, 6, 24 h, at day-3 (d-3) and d-7 (or just before extubation if still alive at time of extubation) for the five first included patients receiving caspofungin and who are intubated. Caspofungin concentration measurements (in milligram/liter) will be centrally carried out at Tours university hospital at the end of the study only for patients who received nebulized caspofungin (intervention group), once the blind process will be lifted).
Mortality	day-28 (d-28) and d-90	* All-cause at hospital discharge, day-28 (d-28) and d-90; * Pneumocystis pneumonia-related at hospital discharge, day-28 (d-28) and d-90
Morbidity	day-1 (d-1), d-7 and d-21	* Number of days alive without any ventilatory / oxygen support; * Duration to clinical stability (from inclusion to hospital discharge: * maximum daily temperature ≤ 37.8 °C; * maximum daily heart pace ≤ 100 bpm; * maximum daily respiratory pace ≤ 24 cpm; * minimum daily systolic blood pressure ≥ 90 mmHg; * arterial oxygenation saturation ≥ 90% or PaO2 ≥ 60 mmHg while breathing room air, or PaO2/FiO2 ratio ≥ 285 mmHg, without an increase in the intensity of the ventilatory support; * normal mental status; * Duration of invasive ventilatory support; * Duration of invasive and non-invasive ventilatory support; * Duration to clinical healing : * clinical stability (cf. above); * 24h weaning of mechanical respiratory support due to patient's clinical improvement; * Duration of hospital stay (in days); * Duration of ICU stay (in days); * Change in the sepsis-related organ failure assessments (SOFA) score; * Requirement of a second-line (salvage) anti-Pneumocystis curative therapy (yes or no)
Pulmonary and systemic markers of lung infection (to assess the fungal clearance)	day-1 (d-1), d-3, d-7, d-28 and d-90	* Evolution of hypoxemia: • alveolar-to-arterial oxygen gradient, ratio of arterial partial pressure in oxygen and pulsed oxymetry to fraction of inspired oxygen (in millimeter Hg); * LDH enzyme in blood (in international units/liter); * BDG fungal antigen in blood (in pigogram / milliliter); * RT-qPCR for P jirovecii nucleic acids in blood and in tracheal aspirates (in number of amplification cycles); * Impact on the micro-organism diversity in respiratory airways and infections; * monitoring the expression of specific genes for distinguishing the relative representativeness between P. jirovecii asci and trophic forms from trachea-bronchial aspirates; * identification and counting of fungal colonies from trachea-bronchial aspirates (in number of colony-forming units (CFU)); * identification and counting of bacterial colonies from trachea-bronchial aspirates (in CFU); * Genotyping of P. jirovecii strains based on microsatellites markers and sequencing of DHPS/DHFR genes in respiratory fluids

Trial Locations

Locations (1)

CHU Tours; 🇫🇷 Tours, France