Three-Dimensional Scaffolds for Tissue Engineering Applications: Role of Porosity and Pore Size

Loh, Qiu Li; Choong, Cleo

doi:10.1089/ten.teb.2012.0437

Cited by 2,143 publications

(1,605 citation statements)

References 207 publications

(183 reference statements)

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“…BMSC recruitment also involves successful cellular migration into the scaffold, which may be limited by physical constraints within the implant (e.g., small pore size, limited pore connectivity). 101 By incorporating a donor stem cell population within an implant instead, these cellular recruitment challenges may be overcome.…”

Section: Incorporating Scbts Into the Designmentioning

confidence: 99%

Endochondral Ossification for Enhancing Bone Regeneration: Converging Native Extracellular Matrix Biomaterials and Developmental Engineering In Vivo

Dennis

Berkland

Bonewald

et al. 2015

Tissue Engineering Part B: Reviews

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Section: Incorporating Scbts Into the Designmentioning

confidence: 99%

Endochondral Ossification for Enhancing Bone Regeneration: Converging Native Extracellular Matrix Biomaterials and Developmental Engineering In Vivo

Dennis

Berkland

Bonewald

et al. 2015

Tissue Engineering Part B: Reviews

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“…The total porosity (Φ) of scaffolds is measured according to Eq. 1 (24): (1) Where ρ s is the ratio of scaffold mass to its volume and ρ t is total density of the components that contribute to fabricate the scaffold. …”

Section: Porosity and Pore Sizementioning

confidence: 99%

Osteogenic Differentiation and Mineralization on Compact Multilayer nHA-PCL Electrospun Scaffolds in a Perfusion Bioreactor

et al. 2016

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Background:Monolayer electrospun scaffolds have already been used in bone tissue engineering due to their high surface-tovolume ratio, interconnectivity, similarity to natural bone extracellular matrix (ECM), and simple production. Objectives: The aim of this study was to evaluate the dynamic culture effect on osteogenic differentiation and mineralizationi into a compact cellular multilayer nHA-PCL electrospun construct. The dynamic culture was compared with static culture. Materials and Methods:The calcium content, alkaline phosphatase (ALP) activity and cell viability were investigated on days 3 and 7. Results: When the dynamic culture compared to static culture, the mineralization and ALP activity were increased in dynamic culture. After 7 days, calcium contents were 41.24 and 20.44 μg.(cm 3 ) -1 , and also normalized ALP activity were 0.32 and 0.19 U.mg -1 in dynamic and static culture, respectively. Despite decreasing the cell viability until day 7, the scanning electron microscopy (SEM) results showed that, due to higher mineralization, a larger area of the construct was covered with calcium deposition in dynamic culture. Conclusions:The dynamic flow could improve ALP activity and mineralization into the compact cellular multilayer construct cultured in the perfusion bioreactor after 7 days. Fluid flow of media helped to facilitate the nutrients transportation into the construct and created uniform cellular construct with high mineralization. This construct can be applied for bone tissue engineering.

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“…2 For this purpose, several conventional fabrication techniques (e.g., freeze drying, electro spinning, etc.) have been used to fabricate 3D porous scaffolds, but not able to provide ideal or optimum 3D microenvironment by mimicking the targeted native tissues, in terms of controlling architecture of scaffold, pore-size and shape, degradation behavior (based on exposed surface area) for tissue regeneration process depending on particular cell or tissue type in vitro and in vivo.…”

Section: Introductionmentioning

confidence: 99%

Emergence of Bioprinting in Tissue Engineering: A Mini Review

Kumar

Han

2016

ATROA

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Tissue regeneration of damaged tissues or complete reconstruction of the organs is the major concern in the human health-care-systems. The role of scaffold, cell, and growth factors decide the final fate of engineered tissues similar to native tissues depending on how they are formulated, arranged and fabricated. In the last decade, 3D printing technique has attracted a great attention to print scaffolds quickly, efficiently, and mass production of fabricated scaffolds with reproducibility as compared to conventional techniques. Further, based on this concept, 3D bioprinting followed by 4D bioprinting have emerged by precise positioning of biomaterials, cells, and biochemical with spatial control in making 3D bio-construct. In this mini-review, the overview of the basic principles of emerged bioprinting techniques, applications, limitations and future perspectives in tissue engineering field are precisely reviewed.

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Three-Dimensional Scaffolds for Tissue Engineering Applications: Role of Porosity and Pore Size

Cited by 2,143 publications

References 207 publications

Endochondral Ossification for Enhancing Bone Regeneration: Converging Native Extracellular Matrix Biomaterials and Developmental Engineering In Vivo

Endochondral Ossification for Enhancing Bone Regeneration: Converging Native Extracellular Matrix Biomaterials and Developmental Engineering In Vivo

Osteogenic Differentiation and Mineralization on Compact Multilayer nHA-PCL Electrospun Scaffolds in a Perfusion Bioreactor

Emergence of Bioprinting in Tissue Engineering: A Mini Review

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