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FormalPara Regdanvimab (RegkironaTM): Key Points

A recombinant human monoclonal antibody being developed by Celltrion Inc. for the treatment of coronavirus disease 2019 (COVID-19).

Received its first approval on 17 September 2021 in South Korea.

Approved for use in COVID-19.

1 Introduction

Regdanvimab (Regkirona™) is a recombinant human monoclonal immunoglobulin G1 antibody targeted against the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), the causative virus of coronavirus disease 2019 (COVID-19). It is being developed by Celltrion Inc. for the treatment of COVID-19. In patients with confirmed COVID-19 and mild symptoms, early treatment can reduce the severity of the disease and associated hospitalization or ICU admittance [1]. Regdanvimab neutralizes SARS-CoV-2 by binding to the receptor binding domain (RBD) of the virus’ spike protein [2]. The blockade of spike protein interaction with the angiotensin-converting enzyme 2 (ACE2) receptor prevents subsequent viral entry into human cells and viral replication [2]. The antibody retains antiviral activity against newer SARS-CoV-2 variants, which are associated with increased transmissibility, immune evasion and mortality (Sect. 2.1). Regdanvimab was identified through screening of an antibody library constructed from peripheral blood mononuclear cells of a Korean convalescent patient and selecting those with the highest affinity to the RBD [1, 2].

Regdanvimab received its first full approval on 17 September 2021 in South Korea for the treatment of COVID-19 in elderly patients aged > 50 years with at least one underlying medical condition (obesity, cardiovascular disease, chronic lung disease, diabetes, chronic kidney disease, chronic liver disease, and patients on immunosuppressive agents) and mild symptoms of COVID-19 and in adult patients with moderate symptoms of COVID-19 [3, 4]. The recommended dosage is 40 mg/kg, administered as a single 60-min intravenous (IV) infusion [3, 4].

figure a

Key milestones in the development of regdanvimab. CHMP Committee for Medicinal Products for Human Use, CMA conditional marketing authorization, EUA emergency use authorization, IND investigational new drug application, MAA marketing authorization application, MFDS Ministry of Food and Drug Safety

In October 2021, a marketing authorization application for regdanvimab was submitted to the European Medicines Agency for the treatment of adults with COVID-19 who do not require supplemental oxygen therapy and who are at increased risk of progressing to severe COVID 19 [5, 6]. The agency commenced a rolling review of regdanvimab in February 2021 [7] and concluded in March 2021 that the antibody can be used for the proposed indication [8]. Regdanvimab has been filed for approval in Canada for the treatment of COVID-19 [9] and is eligible for consideration by Australia’s Therapeutic Goods Administration for the treatment of mild-to-moderate COVID-19 [10].

Celltrion is also developing a neutralising antibody cocktail with regdanvimab for COVID-19 [11]. In addition, a nebulised form of regdanvimab is being evaluated (in collaboration with Inhalon Biopharma) in a phase I study in healthy volunteers [12].

1.1 Company Agreements

In July 2021, Inhalon Biopharma and Celltrion entered in an agreement to develop a nebulised form of regdanvimab for the treatment of COVID-19, using Inhalon’s muco-trapping antibody platform [13]. The formulation is expected to work by directly trapping the virus in airway mucus which will prevent the local spread of the infection and eliminate the virus from the lungs through the body's natural ability to clear mucus [13].

2 Scientific Summary

2.1 Pharmacodynamics

Regdanvimab decreased viral load in the upper and lower respiratory tracts in animal models of SARS-CoV-2 infection [2]. The antibody showed antiviral activity against newly emerging variants of SARS-CoV-2 (Gamma, Delta and its associated variants [14] and 501Y.V2 or B.1.351 [15]). In vitro, regdanvimab was able to neutralize these variants, albeit showing reduced binding affinity to their RBD. In transgenic mouse models inoculated with these variants, regdanvimab at clinically relevant dosages improved survival rate, reduced weight loss and decreased viral load in the upper and lower respiratory tracts [14, 15].

2.2 Pharmacokinetics

In a phase I trial (NCT04593641) in patients with mild SARS-CoV-2 infection, regdanvimab exhibited dose-proportional pharmacokinetics over a dose range of 20–80 mg/kg, with maximum plasma concentration (Cmax) increasing in a greater than dose-proportional manner [16]. The median time to Cmax was 2.5 h; regdanvimab remained detectable in blood for up to 14 days [16].

In a part 1 of a phase II/III trial (NCT04602000) (Sect. 2.3.2) in patients with mild-to-moderate SARS-CoV-2 infection, regdanvimab pharmacokinetics following a single 90-min IV infusion was characterized by a low clearance (0.227 mL/kg for 40 mg/kg), small volume of distribution (87.2 mL/kg for 40 mg/kg) and a terminal half-life of 12 days [1, 17]. Regdanvimab is likely to be eliminated through normal immunoglobulin degradation pathways and the clearance is not expected to be affected by renal or hepatic impairment [1]. Thus, regdanvimab has no or minimal drug-drug interaction potential [1].

Features and properties of regdanvimab

Alternative names

CT-P59; Regkirona

Class

Antivirals; Monoclonal antibodies

Mechanism of action

Virus internalisation inhibitors

Route of administration

Intravenous infusion

Pharmacodynamics

Neutralizes severe acute respiratory syndrome coronavirus 2 by binding to the receptor binding domain of the virus’ spike protein; decreases viral load in upper and lower respiratory tracts in animal models

Pharmacokinetics

Dose-proportional pharmacokinetics over a dose range of 20–80 mg/kg; median time to maximum plasma concentration 2.5 h; low clearance (0.227 mL/kg for 40 mg/kg); small volume of distribution (87.2 mL/kg for 40 mg/kg); terminal half-life 12 days; eliminated through normal immunoglobulin degradation pathways

Most frequent adverse events

Hypertriglyceridemia

ATC codes

 WHO ATC code

J05A-X (Other antivirals)

 EphMRA ATC code

J5B (Antivirals, excluding anti-HIV products)

CAS Registry Number

2444308-95-4

2.3 Therapeutic Trials

2.3.1 Phase I Trial

Regdanvimab demonstrated promising antiviral activity in adult patients with mild SARS-CoV-2 infection in a randomized, double-blind, placebo-controlled, single ascending dose (20, 40 and 80 mg/kg) phase I trial (NCT04593641; n = 18) [16]. The mean reduction from baseline in viral titers in nasopharyngeal swabs up to day 14 was generally greater with regdanvimab versus placebo. In patients with high titer levels at baseline (105 copies/mL), viral shedding was more rapid with regdanvimab versus placebo. All patients, except one placebo recipient, had clinical recovery from COVID-19 by day 14 and the mean time to recovery was 3.39 days with regdanvimab (all doses combined) and 5.25 days with placebo [16].

2.3.2 Phase II/III Trial

The efficacy of regdanvimab in the treatment of mild-to-moderate COVID-19 was evaluated in a randomized, double-blind, placebo-controlled, multinational phase II/III trial (NCT04602000), which was divided in two parts: part 1 (phase II) and part 2 (phase III). Currently, part 1 results are available and regdanvimab was effective in this part [17]. Eligibility criteria included: age ≥ 18 years; SARS-CoV-2 infection confirmed by quantitative reverse transcription polymerase chain reaction (RT-qPCR); > 94% oxygen saturation on room air and not requiring supplemental oxygen; and, onset of symptoms (feverishness, cough, shortness of breath, sore throat, body/muscle pain, nausea, fatigue, headache, chills, nasal congestion, loss of taste or smell, or diarrhoea) within 7 days prior to study drug administration. Patients were randomized to a single dose of regdanvimab 40 or 80 mg/kg, or placebo, administered as a 90-min IV infusion. The intent-to-treat (ITT) population included 105 and 111 patients in the regdanvimab 40 and 80 mg/kg groups, and 111 in the placebo group. Baseline demographic and disease characteristics were generally similar between the groups. In the ITT population, 87.5% of patients were white, 12.5% were Asian, 49.2% were female, median age was 51.0 years and 57.8% of patients had moderate disease. Efficacy was analysed in the ITT infected population, defined as all randomly assigned patients with confirmed SARS-CoV-2 infection assessed by pre-infusion RT-qPCR result on day 1 and receiving a partial or complete dose of study drug (101 and 103 in the regdanvimab 40 and 80 mg/kg groups, and 103 in the placebo group) [17].

The median time to conversion to negative RT-qPCR (threshold < 2.33 log10 copies/mL) up to day 28 (coprimary endpoint) in regdanvimab 40 and 80 mg/kg was 12.75 and 11.89 days versus 12.94 days with placebo; the improvement rate ratios (95% CI) versus placebo were 1.346 (1.001–1.810; p = 0.048) and 1.215 (0.90–1.63; p = 0.198) for the 40 and 80 mg/kg groups, and 1.275 (0.99–1.65; p = 0.063) for the combined regdanvimab groups [17]. In a post hoc analysis, when a < 3.0 log10 copies/mL threshold was applied, the median time to conversion to negative RT-qPCR up to day 28 improved further: 5.94, 6.08 and 5.96 days with regdanvimab 40 mg/kg, 80 mg/kg and combined regdanvimab groups, respectively, versus 8.92 days with placebo; the corresponding improvement rate ratios (95% CI) versus placebo were: 1.599 (1.185–2.158), 1.317 (0.976–1.777) and 1.451 (1.120–1.882). Furthermore, regdanvimab recipients had a 3 log10 copies/mL reduction in viral load between baseline and day 7, whereas a similar reduction was not seen in placebo recipients until day 10. The proportion of patients achieving conversion to negative RT‑qPCR up to day 28 was 92.1% and 87.4% in the regdanvimab 40 and 80 mg/kg groups, compared with 83.5% in the placebo group [17].

The median time to clinical recovery up to day 14 was significantly (p ≤ 0.039) shorter for regdanvimab 40 and 80 mg/kg versus placebo (5.35 and 6.23 days vs 8.77 days) [coprimary endpoint] [17]. Up to day 28, 87.4% and 85.9% of patients in the regdanvimab 40 and 80 mg/kg groups, compared with 71.4% in the placebo group, achieved clinical recovery. The proportion of patients requiring hospitalization or oxygen therapy up to day 28 was 4.0% and 4.9% in the regdanvimab 40 and 80 mg/kg groups, compared with 8.7% in the placebo group; a similar trend was observed in patients with moderate infection (6.5% and 7.9% vs 15.8%) and those with moderate infection and aged ≥ 50 years (7.5% and 10.0% vs 23.7%) [17].

Preliminary positive topline results from the phase III part (n = 1315) of the NCT04602000 trial have been reported by Celltrion. Regdanvimab significantly (p < 0.0001) reduced the risk of hospitalisation or death by 72% versus placebo in patients with mild-to-moderate COVID-19 symptoms who were considered at high risk of progressing to severe COVID-19 up to day 28 (3.1 vs. 11.1%; primary endpoint). The trial also met other key secondary endpoints [18].

2.3.3 Supportive Studies

A Cochrane Database systematic review revealed that treatment with regdanvimab (solely based on NCT04602000 data) may decrease the risk of hospital admissions or death in outpatients with mild-to-moderate COVID-19 versus placebo [risk ratios (95% CIs) 0.45 (0.14–1.42) for 40 mg/kg; 0.56 (0.19–1.60) for 80 mg/kg] [19].

In a single-centre, retrospective, propensity score-matched (PSM) cohort study of patients with high-risk mild or moderate COVID-19, regdanvimab treatment was associated with a significant (p < 0.001) reduction in the proportion of patients reaching the composite of death or disease aggravation versus no regdanvimab treatment (5.0% vs 21.5%; n = 377 in each group; primary endpoint) [20]. The odds ratios (95% CI) were 0.194 (0.112–0.320) and 0.169 (0.095–0.287) in univariate and multivariable-adjusted analyses, respectively (p < 0.001 for both). Significantly (p < 0.001) fewer patients in the regdanvimab than in the no regdanvimab group were treated with remdesivir (2.7 vs 16.4%), azithromycin (5.6 vs 62.3%), lopinavir/ritonavir (0 vs 15.6%) or corticosteroids (23.9 vs 47.7%). Increased age, male gender, higher body mass index and concurrent pneumonia were associated with increased odds of reaching the primary endpoint. Results for the overall cohort (n = 377 for regdanvimab and 520 for no regdanvimab) were generally similar to those for the PSM cohort [20].

Key clinical trials of regdanvimab (Celltrion Inc.)

Drug

Indication

Phase

Status

Location(s)

Identifier

Regdanvimab

COVID-19 infections

II/III

Completed

Multinational

NCT04602000, EudraCT2020-003369-20, CT-P59 3.2

Regdanvimab

COVID-19 infections

I

Completed

South Korea, Romania

NCT04593641, EudraCT2020-003165-19, CT-P59 1.2

Regdanvimab

COVID-19 infections

I

Completed

South Korea

NCT04525079, EudraCT2020-003065-19, CT-P59 1.1

2.4 Adverse Events

In the phase II/III trial (NCT04602000), the overall incidence of treatment-emergent adverse events (TEAEs) was similar between the treatment groups (29.5% and 24.5% with regdanvimab 40 and 80 mg/kg vs 30.9% with placebo) [17]. Treatment-related TEAEs occurred in 6.7% and 4.5% versus 4.5% of patients in the respective groups and the most common was hypertriglyceridemia (2.9% with regdanvimab 40 mg/kg vs 1.8% with placebo). Most TEAEs were of grade 1 or 2 severity. Grade 3 TEAEs occurred in 4.8% and 3.6% of patients in the regdanvimab 40 and 80 mg/kg groups and 1.8% of patients in the placebo group, including one treatment-related event in the regdanvimab 40 mg/kg group. There were no grade 4 or 5 TEAEs up to day 28, no serious TEAEs or TEAEs leading to treatment discontinuation or deaths. The incidence of infusion-related reactions, an adverse event (AE) of special interest, was low (1% and 0% with regdanvimab 40 and 80 mg/kg vs 1.8% with placebo). The incidence of antidrug antibodies (ADAs) through day 28 was 0% and 2.7% versus 4.5% [17].

In the phase I trial (NCT04593641), 16 AEs were reported in 10 regdanvimab recipients and none were treatment related [16]. Grade 3 AEs occurred in two regdanvimab recipients (hepatocellular injury and increased ALT) and one placebo recipient (COVID-19 pneumonia). There were no infusion-related reactions, serious AEs or AEs leading to treatment discontinuation. Regdanvimab was not associated with any clinically meaningful changes in vital signs, hypersensitivity, ECG, radiography, physical examination or SARS-CoV-2 infection-related signs and symptoms. ADAs were not detected in any patient [16].

The Cochrane Database systematic review estimated that regdanvimab treatment may increase the risk of developing grades 3–4 AEs versus placebo [risk ratios (95% CIs) 2.62 (0.52–13.12) for 40 mg/kg; 2.00 (0.37–10.70) for 80 mg/kg] [19].

In the PSM cohort study, regdanvimab treatment was associated with significantly (p < 0.001 vs no regdanvimab treatment) lower incidences of white blood cells increased (> 10 × 103/µL; 5.0 vs 11.9%) or decreased (< 4 × 103/µL; 7.7 vs 14.9%), decreased platelet counts (< 130 × 103/µL; 2.4 vs 5.8%) and decreased absolute lymphocyte count (< 800/µL; 2.9 vs 11.9%) [20]. The two groups did not differ significantly for other investigated adverse reactions (renal and liver toxicity, gastrointestinal toxicity, fever or systemic pain, hypersensitivity, haemoglobin, absolute neutrophil count, and serum sodium and potassium abnormalities) [20].

2.5 Ongoing Clinical Trials

A post-marketing surveillance study of regdanvimab (CT-P59 4.1) is ongoing.

3 Current Status

Regdanvimab received its first full approval on 17 September 2021 for the treatment of COVID-19 in South Korea [3].