Hypoxia and platelet lysate sustain differentiation of primary horse articular chondrocytes in xeno-free supplementation culture

Currently, the main limitation for the use of adult differentiated chondrocytes in cell-based therapy and tissue engineering for the repair of articular cartilage is the difficulty of maintaining their state of differentiation during cell expansion. The adult articular cartilage has no direct blood supply, and local oxygen concentrations range from 5%-10% at the surface near the synovial fluid to less than 1% in the deep layer. Low oxygen tension is currently considered an important environmental condition for chondrocytes, and hypoxia has been explored as a signal potentially promoting differentiation and matrix deposition. In the present study, hypoxia and PL supplementation were studied to maintain differentiation in adult articular chondrocytes. Freshly isolated equine articular chondrocytes were grown in monolayer culture at a low seeding density (condition favoring prolifer-ation and dedifferentiation) and in alginate beads (3D culture condition maintaining chondrocyte differentiation) both in normoxic and hypoxic conditions and in various conditions of supplementation or deprivation (fetal bovine serum [FBS]-and PL-free; 10% FBS; 5% PL; 10% PL). Results demonstrated that hypoxia is a micro -environmental condition that reduces chondrocyte dedifferentiation or maintains differentiation during in vitro expansion, as shown by the sustained expression of differentiation markers (COL2, ACAN, SOX9, HIF1a) and the reduction of dedifferentiation marker expression (COL1, RUNX2). In association with hypoxia, PL supple-mentation demonstrated a positive effect on chondrocyte differentiation in association with hypoxia. This promising result should be confirmed in other conditions of chondrocyte differentiation before proposing PL as a complete alternative to xenogenic serum for the expansion of articular chondrocytes.

Automated summary

Currently, the main limitation for the use of adult differentiated chondrocytes in cell-based therapy and tissue engineering for the repair of articular cartilage is maintaining their state of differentiation during cell expansion. This study explores the effects of hypoxia and PL supplementation on chondrocyte differentiation in adult articular cartilage cells. The results show that hypoxia can reduce dedifferentiation and maintain differentiation during in vitro expansion, and PL supplementation has a positive effect on chondrocyte differentiation in association with hypoxia.