Abstract
Cultured primary cells have a limited life span and undergo dedifferentiation. Tissue engineering (TE) approaches require high cell numbers, but availability of human derived cells is limited and animal cells show inter-species differences. The advantages of immortalized cells are delayed senescence and phenotypic stability. The present study was undertaken to validate key properties of immortalized human anterior cruciate ligament (ACL) fibroblasts in direct comparison with non-immortalized cells from the same donor to assess their applicability as TE model. Human ACL ligamentocytes (40 years old female donor) were either immortalized using repeated transient transfection with a simian virus SV40 plasmid or remained untreated. Both cell populations were analyzed for cell survival, DNA content, tendon marker, extracellular matrix (ECM) and cytoskeletal protein expression. Cell spheroids of both populations were seeded on scaffolds embroidered either from polylactic acid (PLA) threads alone or combined PLA- and PLA-co-caprolacton-(P(LA-CL)) threads, functionalized with fluor treatment and collagen foams. Cell survival on the scaffolds was monitored for up to 5 weeks. In contrast to non-immortalized ligamentocytes, immortalized cells reflected some chaotic and incomplete cell divisions, higher DNA content, numbers of dying cells and nucleoli, reduced vimentin and vinculin-associated focal adhesions. Analysed markers, other cytoskeletal and ECM components were similarly expressed. Compared to the non-immortalized ligamentocytes immortalized formed instable spheroids and died on the scaffolds after 21 d. Both cell populations reflected superior growth on the PLA-P(LA-CL) compared with PLA scaffolds. Immortalized cells share crucial properties with their non-immortalized counterparts, but TE is only possible for limited culturing periods.
