Rituximab biosimilar for the treatment of diffuse large B-cell lymphoma: a phase 3 randomized study in India.

PURPOSE: Very few studies have demonstrated the rituximab biosimilarity in terms of efficacy, safety, pharmacokinetics, pharmacodynamics, and immunogenicity in patients with diffuse large B-cell lymphoma (DLBCL) in India. Therefore, we compared the efficacy, safety, pharmacokinetic, pharmacodynamic, and immunogenicity of our biosimilar rituximab with the reference rituximab (Ristova, Roche products [India] Pvt. Ltd) in patients with DLBCL in India. METHODS: A phase 3, randomized, assessor-blind, parallel-group, two-arm study was conducted across 28 sites in India. A total of 153 newly diagnosed DLBCL patients were randomized to receive either biosimilar rituximab or reference rituximab. The study drugs were administered at a dose of 375 mg/m2 by intravenous infusion every 3 weeks for six cycles. The primary end point was objective response rate (ORR) at the end of Cycle 6. Secondary end points included: pharmacokinetic, pharmacodynamics, immunogenicity, and safety assessment. RESULTS: The ORR at the end of Cycle 6 was 82.14% in the biosimilar rituximab and 85.71% in the reference rituximab group. The risk difference (90% CIs) was - 3.57 (- 14.80, 7.66). It met the non-inferiority margin of - 20%. The pharmacokinetic and pharmacodynamic parameters were comparable between the two treatment groups. The incidence rate of immunogenicity was very low and similar in both the treatment groups. The safety profile of both the treatments was comparable with no major difference in terms of nature, frequency and severity of TEAEs. CONCLUSION: The study demonstrated the biosimilarity between the biosimilar rituximab and the reference rituximab. Our biosimilar rituximab could add to the cost-effective treatment alternatives for patients with DLBCL in India.

ZRC3308 Monoclonal Antibody Cocktail Shows Protective Efficacy in Syrian Hamsters against SARS-CoV-2 Infection.

We have developed a monoclonal antibody (mAb) cocktail (ZRC-3308) comprising of ZRC3308-A7 and ZRC3308-B10 in the ratio 1:1 for COVID-19 treatment. The mAbs were designed to have reduced immune effector functions and increased circulation half-life. mAbs showed good binding affinities to non-competing epitopes on RBD of SARS-CoV-2 spike protein and were found neutralizing SARS-CoV-2 variants B.1, B.1.1.7, B.1.351, B.1.617.2, and B.1.617.2 AY.1 in vitro. The mAb cocktail demonstrated effective prophylactic and therapeutic activity against SARS-CoV-2 infection in Syrian hamsters. The antibody cocktail appears to be a promising candidate for prophylactic use and for therapy in early COVID-19 cases that have not progressed to severe disease.

Efficacy and safety of pegylated interferon-α2b in moderate COVID-19: a phase 3, randomized, comparator-controlled, open-label study.

OBJECTIVE: To evaluate the efficacy and safety of pegylated interferon alpha-2b (PEG IFN-α2b) administered in conjunction with the standard of care (SOC) in subjects with moderate coronavirus disease-19 (COVID-19). METHODS: In this study, adult subjects with confirmed moderate COVID-19 were randomized in a 1:1 ratio to receive either PEG IFN-α2b + SOC or SOC alone. The primary endpoint was a two-point improvement in clinical status on Day 11, measured by the World Health Organization's seven-point ordinal scale. RESULTS: Of 250 subjects, 120 were randomized to the PEG IFN-α2b + SOC arm and 130 were randomized to the SOC arm. The results for the PEG IFN + SOC arms vs the SOC arm for the proportion of subjects with a two-point improvement in the seven-point ordinal scale were 80.36% vs 68.18% (P=0.037) on Day 8, 91.60% vs 92.56% (P=0.781) on Day 11, and 94.12% vs 95.93% (P=0.515) on Day 15. There was a time-dependent decrease in the biomarkers in both arms, and no clinically significant changes in laboratory parameters. The safety profile was similar in both arms. CONCLUSION: PEG IFN-α2b induced early viral clearance, improved the clinical status, and decreased the duration of supplemental oxygen. It provides a viable treatment option and can limit the spread of severe acute respiratory syndrome coronavirus-2.

A Phase 3, Randomized, Open-label, Noninferiority Trial Evaluating Anti-Rabies Monoclonal Antibody Cocktail (TwinrabTM) Against Human Rabies Immunoglobulin (HRIG).

BACKGROUND: Limited supply, cost and potential for severe adverse effects observed with the blood derived rabies immunoglobulin products has led to search for alternative therapies. This issue has been addressed by developing an anti-rabies monoclonal antibody cocktail. METHODS: This is a phase 3, randomized, open-label, noninferiority trial conducted in patients with World Health Organization (WHO) category III exposure with suspected rabid animal. Eligible patients were assigned to either the test arm, TwinrabTM (docaravimab and miromavimab) or the reference arm, human rabies immunoglobulin (HRIG; Imogam® Rabies-HT), in a ratio of 1:1. The primary endpoint was the comparison of responder rates between the 2 arms assessed as percentage of those with rabies virus neutralizing antibodies titers ≥0.5 IU/mL on day 14. RESULTS: A total of 308 patients were equally randomized into the 2 arms. In the per-protocol (PP) population, there were 90.21% responders in the TwinrabTM arm and 94.37% in the HRIG arm. The geometric mean of rapid fluorescent foci inhibition test titers in the PP on day 14 were 4.38 and 4.85 IU/mL, for the TwinrabTM and HRIG arms, respectively. There were no deaths or serious adverse events reported. CONCLUSIONS: This study confirmed that TwinrabTM is noninferior to HRIG in terms of providing an unbroken window of protection up to day 84. This trial in healthy adults with WHO category III exposure from suspected rabid animal also establishes the safety of TwinrabTM in patients with 1 WHO approved vaccine regimen (Essen). CLINICAL TRIALS REGISTRATION: CTRI/2017/07/009038.

Recent progress in polymeric gene delivery systems.

Considerable progress in polymeric gene delivery systems has been made over the last several years. First generation polymers have been replaced by safer and more efficient carrier systems through molecular functionalization, improving polymer biocompatibility, biological stability, cell-specificity, and intracellular trafficking. Many new polymers have moved from in vitro characterization to preclinical validation in animal models of cancer, diabetes, and cardiovascular disorders. Although the transfection efficiency of most polymeric carriers is still significantly lower than that of viral vectors, their structural flexibility allows for continued improvement in polymer activity. Also, simple manufacturing and scale-up schemes and the low cost of manufacturing are likely to eventually compensate for the performance gap between viral and polymeric vectors and establish clinical recognition and commercialization of polymer-based gene therapy drugs.