Errata to: “New biotextiles for tissue engineering: Development, characterization and in vitro cellular viability” [Acta Biomaterialia 9 (2013) 8167–8181]

Almeida, Lília R.; Martins, Ana Maria; Fernandes, Emanuel M.; Oliveira, Mariana B.; Correlo, Vítor M.; Pashkuleva, Iva; Marques, A. P.; Ribeiro, Ana Sofia; Durães, Nelson; Silva, Carla Joana; Bonifácio, Graça; Sousa, Rui A.; Oliveira, Ana; Reis, Rui L.

doi:10.1016/j.actbio.2013.08.028

Cited by 1 publication

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“…46,49 Studies showed several methods to produce tendon scaffolds, including emulsion freeze-drying phase separation, gas foaming, and porogen leaching. 50 Still, these methods are limited in controlling the pore size, interconnectivity, and mechanical properties. 51 Conversely, using electrochemical alignment or electrospinning methods 52,53 to form scaffolds made of fibers have been proven to control cellular proliferation and collagen matrix deposition.…”

Section: Development Of 3d Tendon Scaffolds and Their Different Typesmentioning

confidence: 99%

“…This approach allows for the creation of structures with complex mechanical and physical properties that more closely resemble those found in nature 46,49 . Studies showed several methods to produce tendon scaffolds, including emulsion freeze‐drying phase separation, gas foaming, and porogen leaching 50 . Still, these methods are limited in controlling the pore size, interconnectivity, and mechanical properties 51 .…”

Section: D‐printing Of Tendon Scaffolds (Table 2)mentioning

confidence: 99%

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Advancements in 3D‐printed artificial tendon

Alhaskawi,

Zhou,

Dong

et al. 2024

J Biomed Mater Res

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Millions of people have been reported with tendon injuries each year. Unfortunately, Tendon injuries are increasing rapidly due to heavy exercise and a highly aging population. In addition, the introduction of 3D‐printing technology in the area of tendon repair and replacement has resolved numerous issues and significantly improved the quality of artificial tendons. This advancement has also enabled us to explore and identify the most effective combinations of biomaterials that can be utilized in this field. This review discusses the recent development of the 3D‐printed artificial tendon; where recently, some research investigated the most suitable pore sizes, diameter, and strength for scaffolds to have high tendon cells ingrowth and proliferation, giving a better understanding of the effects of densities and structure patterns on tendon's mechanical properties. In addition, it presents the divergence between 3D‐printed tendons and other tissue and how the different 3D‐printing techniques and models participated in this development.

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