Madaboosi, N.N.MadaboosiUhlig, K.K.UhligSchmidt, S.S.SchmidtVikulina, A.S.A.S.VikulinaMöhwald, H.H.MöhwaldDuschl, C.C.DuschlVolodkin, D.D.Volodkin2022-03-052022-03-052018https://publica.fraunhofer.de/handle/publica/25642810.1002/mabi.201700319Polyelectrolyte multilayers assembled from hyaluronic acid (HA) and poly&#8208;l&#8208;lysine (PLL) are most widely studied showing excellent reservoir characteristics to host molecules of diverse nature; however, thick (HA/PLL)n films are often found cell repellent. By a systematic study of the adhesion and proliferation of various cells as a function of bilayer number ""n"" a correlation with the mechanical and chemical properties of films is developed. The following cell lines have been studied: mouse 3T3 and L929 fibroblasts, human foreskin primary fibroblasts VH&#8208;Fib, human embryonic kidney HEK&#8208;293, human bone cell line U&#8208;2&#8208;OS, Chinese hamster ovary CHO&#8208;K and mouse embryonic stem cells. All cells adhere and spread well in a narrow ""cell&#8208;friendly"" window identify in the range of n = 12-15. At n < 12, the film is inhomogeneous and at n > 15, the film is cell repellent for all cell lines. Cellular adhesion correlates with the mechanical properties of the films showing that softer films at higher ""n"" number exhibiting a significant decrease of the Young's modulus below 100 kPa are weakly adherent to cells. This trend cannot be reversed even by coating a strong cell&#8208;adhesive protein fibronectin onto the film. This indicates that mechanical cues plays a major role for cell behavior, also in respect to biochemical ones.en610572620journal article