DEFEAT-COVID: Targeting de Novo Pyrimidine Biosynthesis by Leflunomide for the Treatment of COVID-19 Virus Disease

Study Description

Brief Summary

The global COVID-19 pandemic has caused unprecedented strain on health care services around the world.The absence of specific anti-viral medications to treat the underlying infection led to a proliferation of clinical studies and trials aimed at re-purposing existing medications.

Human dihydroorotate dehydrogenase (DHODH) is vital enzyme utilised by viruses to replicate in the host cell. Leflunomide, a drug that is already licenced to treat rheumatoid arthritis, is a potent inhibitor of the enzyme DHODH. Importantly, this drug has dual anti-viral and anti-inflammatory properties so it targets viral replication and suppresses host inflammatory response which plays a role at more progressive stages of infection.

DEFEAT-COVID is a multi-site, international, interventional, pragmatic, parallel group design, open label, randomised CTIMP with a pilot phase that will allow to adapt procedures and assessments if required.

A phase III clinical trial of leflunomide for treating COVID-19 has been registered in China, Registration number: ChiCTR2000030058). The current proposal extends the original clinical study of leflunomide in China (People's Hospital of Wuhan University) to the UK through a structured collaboration.

Detailed Description

Leflunomide is a potent inhibitor of the enzyme DHODH and is already licenced to treat rheumatoid arthritis. Importantly, this drug has dual anti-viral and anti-inflammatory properties which is advantageous in COVID-19 infected patients, as more progressive stages of the disease involve augmented responses from the host inflammatory mechanisms leading to serious complications and death.

Based on the current understanding of the pathogenesis of COVID-19 infection and its spectrum of clinical manifestation it is evident that a significant proportion of those infected develop pneumonia, systemic inflammatory response and cardiovascular complications with high morbidity and mortality. The progression from initial mild symptoms (usually fever, fatigue and cough) to severe pneumonia requiring oxygen support or mechanical ventilation often takes one to two weeks after the onset of symptoms. The progression leading to a such deterioration is thought to be related to the kinetics of viral replication culminating in an exaggerated surge in inflammatory mediator release, called "cytokine storm".

Host-targeting antiviral (HTA) strategies have many advantages to fight against a broad spectrum of viruses compared to direct-acting antiviral drugs. These include blocking the viral replication and overcoming the potential of viral mutagenesis simultaneously.

Concept The quest for optimal HTA strategies enabled the investigators to identify a crucial enzyme called human dihydroorotate dehydrogenase (DHODH) that limits pyrimidine synthesis. This is a vital metabolic process utilised by viruses for replication.

In preclinical models of cell and animal infection by SARS-CoV-2 the DHODH inhibitors exhibited multiple actions including attenuation of viral genome replication, suppression of the inflammatory reaction and the release of pro-inflammatory cytokines and chemokine. These drugs also offered protection against mortality in mice when administered at later stages of infection when direct acting antivirals offered no survival benefit. The hypothesis is that DHODH inhibitors may have the advantage in treatment of COVID-19 disease even at its advanced stage compared to the drugs with either standalone anti-viral or anti-inflammatory properties.

To this end, collaborators in China have conducted a pilot study in COVID-19 patients in Wuhan, the epicentre of China COVID-19 outbreak, with moderate clinical symptoms. This study has demonstrated feasibility with a favourable clinical outcome and good safety profile within the leflunomide treatment arm. Patients receiving leflunomide had a shorter clinical recovery time and a reduction in clinical inflammatory biomarkers with no side effects observed.

Leflunomide This is an immunosuppressive agent whose efficacy and safety profiles are well established in treatment of rheumatoid arthritis. In 76 000 patients treated with leflunomide there were 16 potential cases of pancytopenia and 9 cases of serious skin reactions. It has few GI side effects including derangement in liver function, associated with long-term use.

The recommended dosage of leflunomide in COVID-19 is a loading dose of 100 mg/day for 3 days, followed by 10-20 mg once daily depending on liver functions (patients with ALT/AST levels above upper limits of normal (ULN) reference range will have 10mg instead of 20mg). This regimen is routinely used in the treatment of rheumatoid arthritis providing effective blood concentration and few adverse reactions.

Leflunomide not only inhibits SARS-CoV-2 viral genome replication but also suppresses the release of pro-inflammatory cytokines and chemokines, suggesting its potential advantage in treating the SARS-CoV-2-induced COVID-19 disease compared to the drugs with standalone anti-viral or anti-inflammatory properties.

Rapidly replicating viruses rely on the de novo pyrimidines biosynthesis to acquire sufficient pyrimidines for genome replication. By inhibiting the host target DHODH, leflunomide can block the de novo pyrimidine biosynthesis by inhibiting the rate limiting step for the viral nucleic acid (DNA and RNA) replication process. The in-vitro data have shown it to be effective against a broad-spectrum of viruses.

Objectives and Outcome Measures/ Endpoints The main trial objective is to evaluate the clinical efficacy and safety of 10 days oral leflunomide treatment starting within 2 weeks of moderate to critical illness symptoms' onset in patients with confirmed COVID-19 infection.

Additionally, the study will evaluate the impact of leflunomide on:

1. the rate of viral clearance

2. the extent of lung injury, based on CT imaging and on the need of invasive/non-invasive ventilation and respiratory support.

3. myocardial, kidney, and liver function based on the need for inotropic/vasoactive and mechanical support and renal replacement therapy.

4. assessment of respiratory, myocardial and kidney injury assessed by standardised physiological and biomarker criteria including emerging molecular and inflammatory footprints of COVID-19 disease Based on the measured variables models to predict the severity of the disease as well as clinical outcomes will be built.

Trial Design The World Health Organisation (WHO) "master protocol" i.e. the R&D blueprint Therapeutic Trial Synopsis for COVID-19 was taken into account when designing the trial. This is illustrated in how the trial is conducted i.e. i) using a 2 stage approach of including a pilot phase before a main trial, ii) target population, ii) participant eligibility, iv) primary and secondary outcomes / endpoints, and v) the trial assessments needed to meet the objectives of ensuring clinical benefit and patient safety of the new therapy being investigated.

The number of patient visits and assessments conducted are kept to a minimum but sufficient to address both the immediate and long term risk to public health. This takes into account conventional standard operating procedures, Good Clinical Practice (GCP), national and international clinical trial regulations.

DEFEAT-COVID is a multi-site, international, interventional, pragmatic, parallel group design, open label, randomised CTIMP with a pilot phase that will allow us to adapt procedures and assessments if required.

Trial Setting The study is primarily conducted at secondary and tertiary healthcare settings in England and India. At each local clinical centre (LCC), the principal investigator (P)I will be responsible for trial activities but much of the work will be carried out by medical staff providing care to patients with COVID-19 within the hospital and by hospital research nurses, medical students and other staff when delegated and with appropriate education, training, and experience.

The landscape of the COVID infection in London and other regions in the UK is being monitored. Additional sites will be invited to contribute to the trial upon recommendation by the Steering and Trial Management Committees taking into consideration of developing national hotspots, second wave of the pandemic etc.

Study Design

Outcome Measures

Primary Outcome Measures

1. Time to clinical improvement [28 days from randomisation]

   TTCI is defined as the time (in days) from initiation of study treatment until a decline of two categories from status at randomisation on a 7 category ordinal scale of clinical status which ranges from 1 (discharged) to 7 (death) as per WHO R&D Blueprint expert group.

2. Incidence of adverse events [28 days from randomisation]

   All adverse events will be recorded and classified and incidence of serious adverse events, and adverse events grade 3 and 4 will be reported.

Secondary Outcome Measures

1. Changes in virological load over time [7,11 and 15 days post randomisation]

   Comparing changes in virological load at predefined time periods by comparing proportions of SARS-CoV-2 negativity by RT-PCR and changes in viral load in upper respiratory tract specimens.

Eligibility Criteria

Criteria

Inclusion Criteria:

1. Age ≥18 years,

2. Patients with onset of symptoms >15 days,

3. Laboratory (RT-PCR) confirmed infection with 2019-nCoV.

Exclusion Criteria:

1. Pregnant or breast feeding,

2. On specific monoclonal antibodies, or other drug trial treatment for COVID-19 within one week prior to study enrolment,

3. Liver function tests >2 fold of upper limits of normal (ULN) reference levels of the respective testing assay,

4. Patients with known hypersensitivity to leflunomide,

5. Patients with severe immunodeficiency syndrome and hypoalbuminaemia.

Contacts and Locations

Locations

Sponsors and Collaborators

• Ashford and St. Peter's Hospitals NHS Trust

Investigators

• Study Chair: Zhong Chen, CI, Ashford and St Peters Hospital NHS Foundation Trust
• Study Director: Isaac John, Ashford and St Peters Hospital NHS Foundation Trust
• Principal Investigator: Sharma Shashank, PI, Ashford and St Peters Hospital NHS Foundation Trust

Study Documents (Full-Text)

More Information

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