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This article gives a review of materials and scaffold fabrications currently applied in esophageal tissue engineering research.
Bioreactor configurations are reviewed, and as bioreactor performance is intimately related to the scaffold, materials and scaffold architecture are described.
Hydroxyapatite (HAP) powder precursors have been used as starting material for biomedical applications, such as synthetic bone graft materials and scaffold for hard tissue engineering.
The lack of scaffolds that meet all of these criteria for soft tissue engineering (e.g., modulus <300 kPa) has prompted the development of alternative materials and scaffold fabrication techniques.
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QR codes were printed on paper prints to provide direct access to digital materials and scaffolded questions.
These findings are relevant to the design of materials and scaffolds for orthopedic tissue engineering, where both vasculogenesis and formation of a mineral phase are required for regeneration.
This chapter focuses mainly on articular hyaline cartilage and discusses the structure of cartilage, the need for cartilage repair, cell sources, growth factors, effects of loading, and some of the materials and scaffolds being developed for cartilage tissue engineering.
Mechanical performance of the produced porous calcium phosphate samples is interesting and dictates their potential use as low load-bearing implants for hard tissue replacement or as filling materials and scaffolds for cancellous bone defects repairs.
The use of such frameworks that convey both the correct mechanical support for tissue formation and stimulate cells through topographical cues may pave the way for future production of intelligent materials and scaffolds.
In the last part, we review the ongoing tissue engineering application of nanostructured materials and scaffolds in different fields such as neurology, cardiology, orthopedics, and skin tissue regeneration.
Tissue engineering aims to develop and mimic such architectures in vitro; various methods having been developed to simulate tissue complexity and allow interaction between different cell types, proteins, implanted materials, and scaffolds (Lee et al. 2009).
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