مشخصات پژوهش

The field of tissue engineering has experienced transformative advancements with the emergenceofsmartscaffoldingsystemsthatnotonlyprovidemechanicalsupportbutalso deliver dynamic biofunctionality to actively influence cellular behavior and tissue regeneration. In this review, the term “smart” specifically refers to polymeric foams that integrate stimuli-responsive properties — such as sensitivity to mechanical, chemical, or thermal cues — with the controlled and sustained release of bioactive factors, thereby enabling dynamic modulation of the cellular microenvironment. Owing to these multifunctional characteristics, polymeric foams have become especially versatile platforms, distinguished by their highly interconnected porous architecture, tunable mechanical properties, and ease of chemical and biological functionalization. This comprehensive review consolidates recent developments in the design and fabrication of biofunctional polymeric foams tailored to deliver controlled mechanical and electrical stimulation and biochemical cues critical for directing cell fate and promoting regenerative outcomes. Foam materials are systematically categorized based on their polymeric origin and structural features, while biofunctionalization strategies—such as peptide conjugation, growth factor integration, and gene delivery—are critically analyzed. Advanced fabrication techniques enabling stimuli-responsive behavior and patient-specific customization, including 3D/4D bioprinting and supercritical fluid processing, are highlighted for their capacity to generate adaptive scaffold microenvironments. Mechanobiological interactions, especially mechanotransduction mechanisms elicited by foam elasticity and dynamic deformation, are discussed in detail, along with emerging dual-responsive systems that simultaneously deliver mechanical and biochemical stimuli. In addition, this review addresses key translational challenges, including immunocompatibility, degradation kinetics, mechanical resil