Improved Cellular Infiltration in Electrospun Fiber via Engineered Porosity

Nam, Jin; Huang, Yan Yan Shery; Agarwal, Sudha; Lannutti, John J.

doi:10.1089/ten.2006.0306

Cited by 382 publications

(308 citation statements)

References 170 publications

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“…These include salt leaching techniques, where salt crystals are mixed with the fibers during fabrication and leached after spinning. 62 Similarly, researchers have induced the formation of ice crystals on the collecting plate, which leads to larger pores in the construct after melting the ice crystals. 63 A dual electrospinning setup has been created with the additional stream of polymer serving to create a sacrificial fiber that is eluted after spinning, increasing the void space in the construct.…”

Section: 54mentioning

confidence: 99%

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Polymeric Nanofibers in Tissue Engineering

Dahlin

Kasper

Mikos

2011

Tissue Engineering Part B: Reviews

297

198

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Polymeric nanofibers can be produced using methods such as electrospinning, phase separation, and selfassembly, and the fiber composition, diameter, alignment, degradation, and mechanical properties can be tailored to the intended application. Nanofibers possess unique advantages for tissue engineering. The small diameter closely matches that of extracellular matrix fibers, and the relatively large surface area is beneficial for cell attachment and bioactive factor loading. This review will update the reader on the aspects of nanofiber fabrication and characterization important to tissue engineering, including control of porous structure, cell infiltration, and fiber degradation. Bioactive factor loading will be discussed with specific relevance to tissue engineering. Finally, applications of polymeric nanofibers in the fields of bone, cartilage, ligament and tendon, cardiovascular, and neural tissue engineering will be reviewed.

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Section: 54mentioning

confidence: 99%

“…64 Although these strategies have successfully increased scaffold pore size, the mechanical strength of the constructs was reduced. 62 Recently, it was…”

Section: 54mentioning

confidence: 99%

Polymeric Nanofibers in Tissue Engineering

Dahlin

Kasper

Mikos

2011

Tissue Engineering Part B: Reviews

297

198

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“…13 Synthesizing scaffolds where cells penetrate within networks and interact in both horizontal and vertical directions is still challenging and underreported. [14][15][16] Ideally, to better facilitate cell connectivity in all directions, fibrous scaffolds should have an open structure while providing biomimicking tissue morphology on both a micro and submicron scale. Adequate cell-material compatibility can potentially guide and promote cell growth, cell-cell communication, and order within a 3D matrix.…”

Section: Introductionmentioning

confidence: 99%

Airbrushed Composite Polymer Zr-ACP Nanofiber Scaffolds with Improved Cell Penetration for Bone Tissue Regeneration

Hoffman

Škrtić²,

Sun³

et al. 2015

Tissue Engineering Part C: Methods

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Electrospun polymer nanofibers have multiple applications in the tissue engineering field despite limited cell penetration within the scaffolds and slow synthesis rates. Airbrushing, a proposed alternative to traditional electrospinning, is a technique capable of synthesizing open structure nanofiber scaffolds at high rates. In this study, three biocompatible polymers-poly-D,L-lactic acid (P-DL-LA), polycaprolactone (PCL), and poly (methyl methacrylate) (PMMA), were airbrushed to form networks for bone tissue regeneration. All three polymers were loaded with up to 20% (w/w) zirconium-modified amorphous calcium phosphate (Zr-ACP). A simple one-step mix and straightforward material deposition yielded open structure networks with welldistributed Zr-ACP. Cell penetration within the airbrushed scaffolds was found to be more than twice the cell penetration within conventional electrospun networks. The airbrushed polymer network supported cell growth and differentiation. Cells grown on the Zr-ACP in P-DL-LA fibers exhibited improved levels of osteocalcin protein with an increase in the Zr-ACP content by day 16. This airbrushing method promises to be a viable and attractive alternative to currently used electrospinning techniques in the formation of composite 3D nanofiber scaffolds for tissue engineering applications.

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“…116 Alternatively, pores may be introduced by including salt particles at the time of production and subsequently leaching the salt out. 121 In the former case, some increase in cell infiltration was observed, particularly when coupled with fluid flow through the scaffold thickness. In the latter case, salt crystals created planes of separation within the scaffold into which cells could migrate, though this compromised the overall structural integrity of the scaffold.…”

mentioning

confidence: 96%

Engineering on the Straight and Narrow: The Mechanics of Nanofibrous Assemblies for Fiber-Reinforced Tissue Regeneration

Mauck

Baker

Nerurkar

et al. 2009

Tissue Engineering Part B: Reviews

191

177

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Tissue engineering of fibrous tissues of the musculoskeletal system represents a considerable challenge because of the complex architecture and mechanical properties of the component structures. Natural healing processes in these dense tissues are limited as a result of the mechanically challenging environment of the damaged tissue and the hypocellularity and avascular nature of the extracellular matrix. When healing does occur, the ordered structure of the native tissue is replaced with a disorganized fibrous scar with inferior mechanical properties, engendering sites that are prone to re-injury. To address the engineering of such tissues, we and others have adopted a structurally motivated approach based on organized nanofibrous assemblies. These scaffolds are composed of ultrafine polymeric fibers that can be fabricated in such a way to recreate the structural anisotropy typical of fiber-reinforced tissues. This straight-and-narrow topography not only provides tailored mechanical properties, but also serves as a 3D biomimetic micropattern for directed tissue formation. This review describes the underlying technology of nanofiber production and focuses specifically on the mechanical evaluation and theoretical modeling of these structures as it relates to native tissue structure and function. Applying the same mechanical framework for understanding native and engineered fiber-reinforced tissues provides a functional method for evaluating the utility and maturation of these unique engineered constructs. We further describe several case examples where these principles have been put to test, and discuss the remaining challenges and opportunities in forwarding this technology toward clinical implementation.

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Improved Cellular Infiltration in Electrospun Fiber via Engineered Porosity

Cited by 382 publications

References 170 publications

Polymeric Nanofibers in Tissue Engineering

Polymeric Nanofibers in Tissue Engineering

Airbrushed Composite Polymer Zr-ACP Nanofiber Scaffolds with Improved Cell Penetration for Bone Tissue Regeneration

Engineering on the Straight and Narrow: The Mechanics of Nanofibrous Assemblies for Fiber-Reinforced Tissue Regeneration

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