Background and aims: High-throughput in vitro pharmacological toxicity testing is essential for drug discovery. Precision-cut liver slices (PCLS) provide a robust system for screening that is more representative of the complex 3D structure of the whole liver than isolated hepatocytes. However, PCLS are not available as off-the-shelf products, significantly limiting their translational potential. Cryopreservation could solve this bottleneck by effectively preserving PCLS indefinitely until their time of use. Conventional cryopreservation (slow cooling in DMSO-forming ice) results in poor PCLS viability and function and, therefore, has proven unsuitable. Here, we explore an "ice-free" cryopreservation approach called vitrification and focus on culturing and assessing PCLS for 3 days post-vitrification and rewarming, given that most acute drug toxicity tests are conducted over 24h.
Methods: Rat liver slices were diffusively loaded with a cryoprotective agent (CPA) cocktail consisting of EG and Sucrose. The CPA-loaded PCLS were placed on a polymer cryomesh, vitrified in liquid nitrogen (LN2), and rapidly rewarmed in CPA. The vitrified and rewarmed PCLS were subsequently cultured in a controlled volume of serum-free, chemically defined media for 3 days.
Results: The cryopreserved PCLS maintained high viability, morphology, function, enzymatic activity, and drug toxicity response. Results show that the vitrified PCLS perform comparably to untreated controls and significantly outperform conventionally cryopreserved PCLS in all assessments ( p < 0.05).
Conclusions: Rapid vitrification and rewarming of PCLS using cryomesh enabled successful preservation and culture. This approach maintained high viability, function, enzymatic activity, and drug response for 3 days in culture, similar to controls.
Impact and implications: The implications of using vitrification to store PCLS are extensive. This technology provides an exciting opportunity for the development of an "off-the-shelf" cold supply chain of human PCLS from organs declined for transplant, which are sliced, cryopreserved, and stored in a repository and available for on-demand shipping for industrial and academic biomedical research. This would also allow PCLS to become a scalable, reproducible, wide-ranging, and population-representative source of tissue that can accurately mimic in-vivo conditions of the human liver. These transformative technologies could revolutionize our practice in studying not just the metabolism of drugs but also increase our capacity to study the zonal progression of many liver diseases and conduct other exciting biomedical research.