Nanoscale control of silks for nanofibrous scaffold formation with an improved porous structure

Lin, Shasha; Lu, Guozhong; Liu, Shanshan; Bai, Shumeng; Liu, Xi; Lü, Qiang; Zuo, Baoqi; Kaplan, David L.; Zhu, Hesun

doi:10.1039/c4tb00019f

Cited by 45 publications

(72 citation statements)

References 55 publications

(110 reference statements)

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“…Recently, nanofibrous silk scaffold with 3-D porous structure and better biocompatibility was successfully prepared by a modified lyophilization method in our laboratory [34,35]. Silk nanofiber solution was firstly prepared via a slowly increasing concentration process [36,37].…”

Section: Introductionmentioning

confidence: 99%

“…Silk nanofiber solution was firstly prepared via a slowly increasing concentration process [36,37]. Then, scaffolds with porous structure instead of separate lamellar sheets were directly derived from the nanofiber solution after freeze-drying process [34]. However, methanol or water annealing treatments were required to achieve water insolubility, in which methanol was harmful for environment while water annealing partly sacrificed the porous structure [36].…”

Section: Introductionmentioning

confidence: 99%

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A mild process to design silk scaffolds with reduced β-sheet structure and various topographies at the nanometer scale

Pei

Liu

et al. 2015

Acta Biomaterialia

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Three-dimensional (3D) porous silk scaffolds with good biocompatibility and minimal immunogenicity, have promising applications in different tissue regenerations. However, a challenge remains to effectively fabricate their microstructures and mechanical properties to satisfy specific requirements of different tissues. In this study, silk scaffolds were fabricated to form extracellular matrix (ECM) mimetic nanofibrous architecture in a mild process. A slowly increasing concentration process was applied to regulate silk self-assembly into nanofibers in aqueous solution. Then glycerol was blended with the nanofiber solution and induced silk crystallization in lyophilization process, endowing freeze-dried scaffolds water-stability. The glycerol was leached from the scaffolds, leaving similar porous structure at a micrometer scale but different topographies at nanoscale. Compared to previous salt-leached and methanol annealed scaffolds, the present scaffolds showed lower β-sheet content, softer mechanical property, and improved cell growth and differentiation behaviors, implying their promising future as platforms for controlling stem cell fate and soft tissue regeneration.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A mild process to design silk scaffolds with reduced β-sheet structure and various topographies at the nanometer scale

Pei

Liu

et al. 2015

Acta Biomaterialia

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“…Different with BSF lm, the TSF lm showed layer structure as previous reports. 24,25 The specic nanostructure of BSF existed, and the layer structure of TSF disappeared in the blend lms. Furthermore, the morphological phase separation was not observed, which had been reported in the BSF/TSF, 26 and in the TSF/carboxymethyl chitosan blend lms prepared using water as a co-solvent.…”

Section: Morphologymentioning

confidence: 99%

A novel method to prepare tussah/Bombyx mori silk fibroin-based films

Yang

Wang

et al. 2018

RSC Adv.

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The possibility of using silk fibroin in biomaterials for tissue engineering is a subject of broad interest. In this study, Bombyx mori/tussah silk fibroin (BSF/TSF) blend films were prepared by solution casting using CaCl 2 / formic acid as a co-solvent and water as a rinse solvent. The morphology, crystallinity, thermal resistance, mechanical properties and water contact angle of the blend films as well as the biocompatibility were investigated. The BSF/TSF blend films displayed a smooth surface and specific nanostructure in their cross-section, originating from the nanofibril-preservation during fibroin dissolution. The water rinse process induced the formation of a stable b-sheet structure. The BSF film showed superior mechanical properties to the TSF film, and the blending with TSF led to a significant reduction in the strength and elasticity of blend films. However, adding the TSF component could regulate the hydrophilic properties and enhance cell growth on the blend films. The BSF/TSF blend films with specific nanostructure, stable secondary structure, appropriate mechanical properties, and good biocompatibility, are promising candidates for application in regenerative medicine.

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“…The DSC peaks of SF strongly depend on the measurement conditions such as the heating rate. 61 Based on previous studies under similar measurement conditions, 55,62 the degradation peak at 250–260 °C belongs to a random/silk I structure whereas the peaks at 260–280 °C are the beta-sheet formation. 63 The increase in temperature of the degradation peaks suggests a higher beta-sheet content.…”

Section: Resultsmentioning

confidence: 80%

“…63 The increase in temperature of the degradation peaks suggests a higher beta-sheet content. 62,63 Figure 2A illustrates the standard DSC curves for pure CS and SF scaffolds. Besides the water evaporation peaks at 50–100 °C, the CS scaffolds showed a significant nonisothermal crystallization peak at 247 °C whereas the SF scaffolds showed a nonisothermal crystallization peak at 214 °C and a degradation peak at 265 °C.…”

Section: Resultsmentioning

confidence: 99%

Simulation of ECM with silk and chitosan nanocomposite materials

Ding

et al. 2017

J. Mater. Chem. B

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Extracellular matrix (ECM) is a system used to model the design of biomaterial matrices for tissue regeneration. Various biomaterial systems have been developed to mimic the composition or microstructure of the ECM. However, emulating multiple facets of the ECM in these systems remains a challenge. Here, a new strategy is reported which addresses this need by using silk fibroin and chitosan (CS) nanocomposite materials. Silk fibroin was first assembled into ECM-mimetic nanofibers in water and then blended with CS to introduce the nanostructural cues. Then the ratios of silk fibroin and CS were optimized to imitate the protein and glycosaminoglycan compositions. These biomaterial scaffolds had suitable compositions, hierarchical nano-to-micro structures, and appropriate mechanical properties to promote cell proliferation in vitro, and vascularization and tissue regeneration in vivo. Compared to previous silk-based scaffolds, these scaffolds achieved improvements in biocompatibility, suggesting promising applications in the future in tissue regeneration.

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Nanoscale control of silks for nanofibrous scaffold formation with an improved porous structure

Cited by 45 publications

References 55 publications

A mild process to design silk scaffolds with reduced β-sheet structure and various topographies at the nanometer scale

A mild process to design silk scaffolds with reduced β-sheet structure and various topographies at the nanometer scale

A novel method to prepare tussah/Bombyx mori silk fibroin-based films

Simulation of ECM with silk and chitosan nanocomposite materials

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