3D Structure and Mechanics of Silk Sponge Scaffolds Is Governed by Larger Pore Sizes

Ferreira, Betina M. P.; Andersson, Niklas; Atterling, Erik; Engqvist, Jonas; Hall, Stephen A.; Dicko, Cedric

doi:10.3389/fmats.2020.00211

Cited by 13 publications

(7 citation statements)

References 56 publications

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“…Taken together, through the rational design of self-assembly proteins, the mechanical strength of recombinant keratin hydrogels could be regulated by the fabrication of robust keratin hydrogels. Compared with the reported pure keratin, ,− collagen, − silk, − and gelatin hydrogels, − our designed recombinant keratin hydrogels exhibited outstanding storage and compressive modulus, which were also comparable to or higher than that of most composited and chemically modified keratin hydrogels (Figure M). ,− …”

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confidence: 68%

Bioinspired Robust Keratin Hydrogels for Biomedical Applications

et al. 2022

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Although keratins are robust in nature, hydrogels producing their extracts exhibit poor mechanical properties due to the complicated composition and ineffective self-assembly. Here we report a bioinspired strategy to fabricate robust keratin hydrogels based on mechanism study through recombinant proteins. Homotypic and heterotypic self-assembly of selected type I and type II keratins in different combinations was conducted to identify crucial domain structures for the process, their kinetics, and relationship with the mechanical strength of hydrogels. Segments with best performance were isolated and used to construct novel assembling units. The new design outperformed combinations of native proteins in mechanical properties and in biomedical applications such as controlled drug release and skin regeneration. Our approach not only elucidated the critical structural domains and underlying mechanisms for keratin selfassembly but also opens an avenue toward the rational design of robust keratin hydrogels for biomedical applications.

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confidence: 68%

Bioinspired Robust Keratin Hydrogels for Biomedical Applications

et al. 2022

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“…The regenerated SF solution can be processed differently to produce different scaffold morphologies such as hydrogels, 130–132 foams 133 and sponges, 134,135 3D printed constructs, 136 micro‐ and nano‐particles, 137 electrospun membranes, 138 and 2D films (Figures 1B and 3). 139 This processing versatility allows it to adapt to the needs and requirements of different target tissues with diverse physicochemical and biological responses 36,113 .…”

Section: Silk As a Biomaterialsmentioning

confidence: 99%

“…Sponges and foams are interconnected porous structures whose properties can be controlled by the processing method. SF sponges can be produced by salt leaching, 147 freeze drying, 134 or gas foaming 133 . They have been widely used for orthopedic applications and soft tissue engineering due to their macroporous structure, which can be adjusted for tissue regeneration and vascularization 148 .…”

Section: Silk As a Biomaterialsmentioning

confidence: 99%

Biomedical applications of silk and its role for intervertebral disc repair

et al. 2022

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Intervertebral disc (IVD) degeneration (IDD) is the main contributor to chronic low back pain. To date, the present therapies mainly focus on treating the symptoms caused by IDD rather than addressing the problem itself. For this reason, researchers have searched for a suitable biomaterial to repair and/or regenerate the IVD. A promising candidate to fill this gap is silk, which has already been used as a biomaterial for many years. Therefore, this review aims first to elaborate on the different origins from which silk is harvested, the individual composition, and the characteristics of each silk type. Another goal is to enlighten why silk is so suitable as a biomaterial, discuss its functionalization, and how it could be used for tissue engineering purposes.The second part of this review aims to provide an overview of preclinical studies using silk-based biomaterials to repair the inner region of the IVD, the nucleus pulposus (NP), and the IVD's outer area, the annulus fibrosus (AF). Since the NP and the AF differ fundamentally in their structure, different therapeutic approaches are required.Consequently, silk-containing hydrogels have been used mainly to repair the NP, and silk-based scaffolds have been used for the AF.

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“…The researchers can determine the degradation rate through controlling dissolution, hydrolyzing conditions, and freeze-drying [57]. Different techniques allow 3-D scaffolds for bone and cartilage repair with particular reference to porosity and pore size [58].…”

Section: Hydrogelmentioning

confidence: 99%

The Silk, Versatile Material for Biological, Optical, and Electronic Fields: Review

Bibbò¹,

Khan²,

Tareen³

2021

GJRE

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Silk, seen as a material, is a fiber made from silkworm cocoons and spiders. They have standard structural components and hierarchical structures. Different manufacturing techniques allow obtaining silk in films, fibers, hydrogels, microspheres, and sponges. We can tune the properties through the structure of secondary proteins. The paper explores the application in biomedical, optics, and electronic fields by analyzing the technological trend.

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3D Structure and Mechanics of Silk Sponge Scaffolds Is Governed by Larger Pore Sizes

Cited by 13 publications

References 56 publications

Bioinspired Robust Keratin Hydrogels for Biomedical Applications

Bioinspired Robust Keratin Hydrogels for Biomedical Applications

Biomedical applications of silk and its role for intervertebral disc repair

The Silk, Versatile Material for Biological, Optical, and Electronic Fields: Review

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