Stem cells (SCs) can self-renew or differentiate into different cell types, which makes them an ideal cell source for therapies based on tissue engineering. Despite these characteristics, the employment of SCs in clinics has seen alternating fortunes because of our limited understanding of the signals governing SC functions and fate, which impairs our ability to engineer systems to deliver SCs in vivo and to guide their correct biological processes. However, experimental evidence demonstrated that SCs are able to recognize biochemical and biophysical signals displayed by material surfaces; most importantly, cells integrate these signals to elaborate fate decisions. Although the mechanisms underlying signal recognition and response have not been thoroughly characterized, there is a general consensus that the cell adhesion process plays a central role. Adhesion represents a communication gate between exogenous signals and intracellular signaling cascades involving the cytoskeleton and the nucleus. In this work we present recent findings on materials engineered to control cell functions through adhesion processes. In particular, we emphasize the role of material signals on SC behavior. Finally, we discuss a few sensing and transductive molecular mechanisms in an effort to draw out unifying elements concerning cell recognition of and reaction to biophysical/biochemical material signals aimed at controlling cell fate through cell adhesion.
Nanotechnologies for tissue engineering and regeneration: Nanoengineered/nanopatterned materials for cell and tissue guidance / Ventre, Maurizio; Coppola, Valerio; Iannone, Maria; Netti, Paolo A.. - (2017), pp. 93-130. [10.1016/B978-0-323-48063-5.00002-2]
Nanotechnologies for tissue engineering and regeneration: Nanoengineered/nanopatterned materials for cell and tissue guidance
Ventre, Maurizio;COPPOLA, VALERIO;Iannone, Maria;Netti, Paolo A.
2017
Abstract
Stem cells (SCs) can self-renew or differentiate into different cell types, which makes them an ideal cell source for therapies based on tissue engineering. Despite these characteristics, the employment of SCs in clinics has seen alternating fortunes because of our limited understanding of the signals governing SC functions and fate, which impairs our ability to engineer systems to deliver SCs in vivo and to guide their correct biological processes. However, experimental evidence demonstrated that SCs are able to recognize biochemical and biophysical signals displayed by material surfaces; most importantly, cells integrate these signals to elaborate fate decisions. Although the mechanisms underlying signal recognition and response have not been thoroughly characterized, there is a general consensus that the cell adhesion process plays a central role. Adhesion represents a communication gate between exogenous signals and intracellular signaling cascades involving the cytoskeleton and the nucleus. In this work we present recent findings on materials engineered to control cell functions through adhesion processes. In particular, we emphasize the role of material signals on SC behavior. Finally, we discuss a few sensing and transductive molecular mechanisms in an effort to draw out unifying elements concerning cell recognition of and reaction to biophysical/biochemical material signals aimed at controlling cell fate through cell adhesion.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.