Low-cost, highly reproducible coating that can be applied to many surfaces, including plastics and glass, and can be optimised for a wide range of use cases.

About

BACKGROUND Cell based studies are moving from two-dimensional (2D) culture to three-dimensional cell culture, due to the advantage of providing more psychologically relevant data, as all cells in our body actually grow in three dimensions. In addition 3D cell culture systems have gained increasing interest in drug discovery and tissue engineering. In addition cells grown in suspension or as spheroids are the mammalian host for large-scale commercial production of therapeutic proteins, such as monoclonal antibodies. The predicted compound annual growth rate of the 3-D cell culture market is more than 11%, which means the size of the market will double in less than 8 years, reaching USD 1.99 Billion by 2026. TECHNOLOGY To enable cells to grow as 3D cultures, a number of technologies have been developed, which differ widely in regards to the input of labour required and the output of cells produced. Our solution is a low-cost, highly reproducible coating that can be applied to many surfaces, including plastics and glass. This technology can be optimised for a wide range of use cases. It does not use any wet-lab processes and is readily scalable for large scale manufacturing.

Key Benefits

Does not require extensive wet-lab processing. Scalable. Adaptable to any surface-type and shape. Low production cost.

Applications

Laboratory Consumables; Life Sciences Reagents and Consumables; Plasticware, Glassware; Commercial production of therapeutic proteins.

Register for free for full unlimited access to all innovation profiles on LEO

  • Discover articles from some of the world’s brightest minds, or share your thoughts and add one yourself
  • Connect with like-minded individuals and forge valuable relationships and collaboration partners
  • Innovate together, promote your expertise, or showcase your innovations