Title:Recent Advancements in Hierarchically Porous Polymeric Scaffolds for Stem Cell Engineering and Regenerative Medicine
Volume: 16
Author(s): Dilpreet Singh*, Akshay Thakur and Kuldeep Singh
Affiliation:
- School of Pharmaceutical Sciences, CT University, Ferozepur Rd, Sidhwan Khurd, Punjab 142024, India
Keywords:
Hierarchically porous scaffolds, stem cell engineering, stimuli-responsive materials, tissue regeneration, computa-tional modeling, regenerative medicine.
Abstract: Hierarchically porous polymer scaffolds have gained significant attention in the field of stem cell-based tissue engineering due to their ability to replicate the complex microstructure of natural extracellular matrices. These scaffolds, with pores ranging from microscale to mac-roscale, facilitate cellular infiltration, migration, and differentiation, making them ideal for supporting stem cell proliferation and regenerative applications. The design and fabrication of these scaffolds involve a variety of polymeric materials, such as synthetic, natural, and hybrid polymers, which are chosen based on their biodegradability, mechanical properties, and ability to support cellular activities. Additionally, the integration of biophysical cues, such as mechanical stiffness, pore size, and alignment, plays a critical role in directing stem cell behavior, including adhesion, proliferation, and differentiation. Recent advances in stimuli-responsive materials have further enhanced the functionality of these scaffolds, allowing for dynamic control of stem cell differentiation through external stimuli, like temperature, pH, and electrical or magnetic fields. Moreover, the application of computational modeling and machine learning techniques has revolutionised scaffold design by optimizing material properties and predicting cellular interactions. This review provides an in-depth analysis of the fabrication techniques, functionalization strategies, and regenerative applications of hierarchically porous polymer scaffolds, highlighting their potential in the treatment of various degenerative diseases and tissue repair. The ongoing developments in this area offer promising pathways for advancing personalized regenerative therapies.
