Zentek Ltd. announced that its wholly-owned subsidiary Triera Biosciences Ltd. has prioritized the development of a prophylaxis and therapeutic for highly pathogenic avian influenza and reports initial test results. The recent avian influenza H5N1 outbreak which began in 2020, has reached a critical stage, according to the World Health Organization. Recently, the world has been placed on watch as H5N1 has crossed into livestock in the U.S. and H5N1 RNA sequences have been detected in the milk supply.

The chief scientist of the World Health Organization, Dr. Jeremy Farrar, has expressed "enormous concern" to public health as the transmission of the virus has increased amongst livestock. H5N1 has the potential to lead to a severe pandemic with a historic mortality rate as high as 52% in the limited human cases to date. Over the last few years, H5N1 has led to the death of millions of poultry with wild birds and land and marine mammals also infected.

Government agencies have expressed their concern of an H5N1 outbreak and their interest to develop further assets that could either treat or prevent further transmission of H5N1 to the human population. There is also interest for new options to mitigate the spread of H5N1 amongst livestock as this could have a potentially devastating impact on the food supply and the economy - along with providing an opportunity for the virus to better adapt to mammals, which increases risk to humans. Due to the growing concern of HPAI, Triera has recently prioritized the development of a universal aptamer for influenza.

The mechanism of neutralizing the H5N1 virus is comparable to the mechanism used by C19HBA against the SARS-CoV-2 virus. More specifically, the aptamer is believed to bind to and neutralize multiple subtypes of the HA surface protein (e.g., H1, H2, H5, etc.), preventing the virus from entering healthy cells and spreading infection. Lead aptamer sequences for influenza have already been selected by the Li Lab at McMaster University for the creation of a universal influenza aptamer.

These lead candidates have been tested using a dot blot assay and biolayer interferometry to assess the binding affinity to the H5 protein for avian influenza. The lead monomer candidates for influenza are binding with an affinity less than one nanomolar, which compares favourably to the monomer used to form C19HBA. The team at McMaster have used the proprietary multivalent aptamer technology to synthesize lead therapeutic and prophylactic candidates.

In the coming weeks, the neutralization and therapeutic potential of these lead candidates will be assessed through in vitro and in vivo tests conducted by the Miller Laboratory. These results will be used to guide further optimization with the goal of having a final lead therapeutic candidate ready for pre-clinical testing as soon as possible. If the H5N1 high binding aptamer program generates promising results, Triera will provide regular updates to government agencies responsible for the management and response to H5N1.

Triera's ultimate goal is to develop an avian flu infectious management system that combines the use of diagnostics, prophylaxis and therapeutics leading to a simple strategy that detects, protects and treats based on the same multivalent aptamer agent.