![]() ![]() Int J Biol Macromol 110:97–109Īisenbrey EA, Tomaschke A, Kleinjan E, Muralidharan A, Pascual-Garrido C, McLeod RR, Ferguson VL, Bryant SJ (2018) A stereolithography-based 3D printed hybrid scaffold for in situ cartilage defect repair. Springer, New York, NY, pp 33–54Īhsan SM, Thomas M, Reddy KK, Sooraparaju SG, Asthana A, Bhatnagar I (2018) Chitosan as biomaterial in drug delivery and tissue engineering. In: Characterization and development of biosystems and biomaterials. KeywordsĪbdelaal OA, Darwish SM (2013) Review of rapid prototyping techniques for tissue engineering scaffolds fabrication. As a result, in this chapter, we’ve presented the fabrication scaffold techniques for tissue engineering applications. The established scaffolding can be used as a personalized medication to treat the patient due to its high precision. Considerable pore size, mechanical strength, surface topography, cell proliferation, and cell adhesion are all provided by these methods. For the fabrication of biomaterials for tissue engineering applications, the freeze-drying process, solvent casting and particulate leaching, gas foaming, 3D bioprinting, electrospinning, and thermal-induced phase separation are constantly used. Various scaffolding fabrication techniques were used for the construction of artificial tissue. Scaffolding systems can help the target tissues by acting as an extracellular matrix. Materials, cells, growth factors, and other small molecules play a role in the artificial tissue’s construction. Tissue engineering is a new field of study that seeks to create artificial tissue that can heal and replace damaged or diseased tissue. ![]()
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