LENZILUMAB EFFICACY AND SAFETY IN NEWLY HOSPITALIZED COVID-19 SUBJECTS: RESULTS FROM THE LIVE-AIR PHASE 3 RANDOMIZED DOUBLE-BLIND PLACEBO-CONTROLLED TRIAL

Zelalem Temesgen, Charles D Burger, Jason Baker, Christopher Polk, Claudia Libertin, Colleen Kelley, Vincent C Marconi, Robert Orenstein, Cameron Durrant, Dale Chappell, Omar Ahmed, Gabrielle Chappell, Andrew D Badley, Zelalem Temesgen, Charles D Burger, Jason Baker, Christopher Polk, Claudia Libertin, Colleen Kelley, Vincent C Marconi, Robert Orenstein, Cameron Durrant, Dale Chappell, Omar Ahmed, Gabrielle Chappell, Andrew D Badley

Abstract

Background: Severe COVID-19 pneumonia results from a hyperinflammatory immune response (cytokine storm, CS), characterized by GM-CSF mediated activation and trafficking of myeloid cells, leading to elevation of downstream inflammatory chemokines (MCP-1, IL-8, IP-10), cytokines (IL-6, IL-1), and other markers of systemic inflammation (CRP, D-dimer, ferritin). CS leads to fever, hypotension, coagulopathy, respiratory failure, ARDS, and death. Lenzilumab is a novel Humaneered ® anti-human GM-CSF monoclonal antibody that directly binds GM-CSF and prevents signaling through its receptor. The LIVE-AIR Phase 3 randomized, double-blind, placebo-controlled trial investigated the efficacy and safety of lenzilumab to assess the potential for lenzilumab to improve the likelihood of ventilator-free survival (referred to herein as survival without ventilation, SWOV), beyond standard supportive care, in hospitalized subjects with severe COVID-19.

Methods: Subjects with COVID-19 (n=520), ≥18 years, and ≤94% oxygen saturation on room air and/or requiring supplemental oxygen, but not invasive mechanical ventilation, were randomized to receive lenzilumab (600 mg, n=261) or placebo (n=259) via three intravenous infusions administered 8 hours apart. Subjects were followed through Day 28 following treatment.

Results: Baseline demographics were comparable between the two treatment groups: male, 64.7%; mean age, 60.5 years; mean BMI, 32.5 kg/m 2 ; mean CRP, 98.36 mg/L; CRP was <150 mg/L in 77.9% of subjects. The most common comorbidities were obesity (55.1%), diabetes (53.4%), chronic kidney disease (14.0%), and coronary artery disease (13.6%). Subjects received steroids (93.7%), remdesivir (72.4%), or both (69.1%). Lenzilumab improved the likelihood of SWOV by 54% in the mITT population (HR: 1.54; 95%CI: 1.02-2.31, p=0.041) and by 90% in the ITT population (HR: 1.90; 1.02-3.52, nominal p=0.043) compared to placebo. SWOV also relatively improved by 92% in subjects who received both corticosteroids and remdesivir (1.92; 1.20-3.07, nominal p=0.0067); by 2.96-fold in subjects with CRP<150 mg/L and age <85 years (2.96; 1.63-5.37, nominal p=0.0003); and by 88% in subjects hospitalized ≤2 days prior to randomization (1.88; 1.13-3.12, nominal p=0.015). Survival was improved by 2.17-fold in subjects with CRP<150 mg/L and age <85 years (2.17; 1.04-4.54, nominal p=0.040).

Conclusion: Lenzilumab significantly improved SWOV in hospitalized, hypoxic subjects with COVID-19 pneumonia over and above treatment with remdesivir and/or corticosteroids. Subjects with CRP<150 mg/L and age <85 years demonstrated an improvement in survival and had the greatest benefit from lenzilumab. NCT04351152.

Conflict of interest statement

Conflicts of interest

ZT, CDB have no conflicts of interest; JB has received research support from Gilead and research support from Humanigen, Inc.; CP, CL, CK have no conflicts of interest; VCM has received investigator-initiated research grants (to the institution) and consultation fees (both unrelated to the current work) from Eli Lilly, Bayer, Gilead Sciences and ViiV; RO has no conflicts of interest; CD, DC, OA, GC are employees of Humanigen, Inc.; ADB is supported by grants from NIAID (grants AI110173 and AI120698) Amfar (#109593) and Mayo Clinic (HH Sheik Khalifa Bib Zayed Al-Nahyan Named Professorship of Infectious Diseases). ADB is a paid consultant for Abbvie and Flambeau Diagnostics, is a paid member of the DSMB for Corvus Pharmaceuticals, Equilium, and Excision Biotherapeutics, has received fees for speaking for Reach MD, owns equity for scientific advisory work in Zentalis and Nference, and is founder and President of Splissen therapeutics.

Figures

Figure 1.. Enrollment and Randomization
Figure 1.. Enrollment and Randomization
Figure 2.. Kaplan Meier plot of Survival…
Figure 2.. Kaplan Meier plot of Survival Without Ventilation.
a. Plot for mITT population. b. Plot for mITT population with baseline CRP

Figure 3.. Prediction of Survival Without Ventilation…

Figure 3.. Prediction of Survival Without Ventilation by Level of CRP Cutoff.

The hazard ratio…

Figure 3.. Prediction of Survival Without Ventilation by Level of CRP Cutoff.
The hazard ratio for survival without ventilation was calculated for all patients regardless of age with CRP level below the cutoff value.

Figure 4.. Change in Serum CRP Following…

Figure 4.. Change in Serum CRP Following Treatment.

a. CRP in mITT population with baseline…

Figure 4.. Change in Serum CRP Following Treatment.
a. CRP in mITT population with baseline with CRP
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Figure 3.. Prediction of Survival Without Ventilation…
Figure 3.. Prediction of Survival Without Ventilation by Level of CRP Cutoff.
The hazard ratio for survival without ventilation was calculated for all patients regardless of age with CRP level below the cutoff value.
Figure 4.. Change in Serum CRP Following…
Figure 4.. Change in Serum CRP Following Treatment.
a. CRP in mITT population with baseline with CRP

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