Spinning conditions affect structure and properties of Nephila spider silk

Young, Robert J.; Holland, Chris; Shao, Zhengzhong; Vollrath, Fritz

doi:10.1557/s43577-021-00194-1

Cited by 12 publications

(3 citation statements)

References 66 publications

(108 reference statements)

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“…7). This suggests, that the internal molecular structure is indeed affected by the reeling speed, which is in agreement with what has been found for native silk 46 .…”

Section: Resultssupporting

confidence: 91%

“…Second, with increasing reeling speed there is a trend toward lower strain at break (Fig. 5), a correlation which was also reported in the literature for native silk 43,46 , but since there is an opposite trend for the tensile strength, the toughness values are fairly constant for reeling speeds ≥29 cm/s and ≤58 cm/s. Again, excluding NaCl from the spinning buffer in this set-up results in fibers with better mechanical properties (Supplementary Fig.…”

Section: Resultssupporting

confidence: 82%

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Impact of physio-chemical spinning conditions on the mechanical properties of biomimetic spider silk fibers

et al. 2022

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Artificial spider silk has emerged as a biobased fiber that could replace some petroleum-based materials that are on the market today. Recent progress made it possible to produce the recombinant spider silk protein NT2RepCT at levels that would make the commercialization of fibers spun from this protein economically feasible. However, for most applications, the mechanical properties of the artificial silk fibers need to be improved. This could potentially be achieved by redesigning the spidroin, and/or by changing spinning conditions. Here, we show that several spinning parameters have a significant impact on the fibers’ mechanical properties by tensile testing more than 1000 fibers produced under 92 different conditions. The most important factors that contribute to increasing the tensile strength are fast reeling speeds and/or employing post-spin stretching. Stretching in combination with optimized spinning conditions results in fibers with a strength of >250 MPa, which is the highest reported value for fibers spun using natively folded recombinant spidroins that polymerize in response to shear forces and lowered pH.

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“…7). This suggests, that the internal molecular structure is indeed affected by the reeling speed, which is in agreement with what has been found for native silk 46 .…”

Section: Resultssupporting

confidence: 91%

Section: Resultssupporting

confidence: 82%

Impact of physio-chemical spinning conditions on the mechanical properties of biomimetic spider silk fibers

et al. 2022

View full text Add to dashboard Cite

show abstract

“…The above findings confirm that higher applied strain rates lead to an increased amount and degree of alignment of high ED structures, which is attributable to proteins in a silk II conformation [ 44 ] (S3, Supporting Information), which is supported by numerous bulk spectroscopic measurements. [ 45,46 ] Taken together, these observations provide evidence of the process in which nanocompartments convert into silk II nanofibrils aligned with the fiber axis as a result of imposed mechanical stress (a more detailed hypothesis is discussed in S8, Supporting Information).…”

Section: Resultsmentioning

confidence: 78%

Carbon Nanotubes Facilitate Silk Hierarchical Assembly by Dry Drawing

Wan,

Farr,

et al. 2024

Small Structures

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Biologically derived hierarchical structural materials not only boast energy‐efficient processing but also exhibit impressive mechanical performance. Silk stands as the gold standard in hierarchical fiber production, leveraging a unique combination of advantages. Nevertheless, the artificial replication of silk poses technical challenges related to precision processing and comprehensive molecular control. To address such issues, this study investigates the hierarchical assembly of solid regenerated silk in an air atmosphere, facilitated by the incorporation of carbon nanotube (CNT) seeding. Results obtained highlight that this CNT seeding facilitates multiscale structure development in response to post‐spin tensile stress. Such CNT bridged structure assembly bypasses some natural processing control variables (pH, ions) and the necessary solvent immersed state for conventional silk post‐drawing. Combining secondary electron hyperspectral imaging and 3D synchrotron X‐ray ptychotomography, this study reports silk protein conversion from a disordered as‐spun state to a longitudinal orientated semi‐crystalline nano structure during drawing. The development of microscale structure during the drawing process is attributed to the presence of CNTs, yielding mechanical properties comparable to, and frequently surpassing, those exhibited by native fibers. These findings collectively propose a framework for exploring novel processing routes and offer a practical means controlling self‐assembly in silk materials.

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Sustainable Spinning of Artificial Spider Silk Fibers with Excellent Toughness and Inherent Potential for Functionalization

Fan,

Knuuttila,

Schmuck

et al. 2024

Adv Funct Materials

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Despite impressive progress in the field, there are still several major bottlenecks in producing fibers from recombinantly produced spider‐silk‐like proteins to replicate the extraordinary mechanical properties of spider major ampullate silk. The conventional artificial fiber spinning processes rely primarily on organic solvents to coagulate proteins into fibers and require complex post‐treatments to obtain fibers with valuable properties. This is due to challenges in obtaining soluble silk proteins, but also because the native silk spinning process leading to the hierarchical organization of the silk proteins is not fully understood and is hard to replicate in a manner applicable to industrial settings. Here, recombinant spider‐silk fusion proteins are efficiently produced and processed into as‐spun fibers with a toughness modulus of 120 MJ m−3 and extensibility of 255% using solely aqueous solutions. The spider‐silk fusion proteins assemble in a manner similar to that reported for native spider silk: they phase separate induced by salting out, followed by alignment and a secondary structure transition triggered by shear forces and dehydration. Finally, the design of the fusion silk proteins enables straightforward functionalization of the fibers under mild all‐aqueous conditions via a simple biomolecular click reaction both pre‐ and post‐spinning.

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Spinning conditions affect structure and properties of Nephila spider silk

Cited by 12 publications

References 66 publications

Impact of physio-chemical spinning conditions on the mechanical properties of biomimetic spider silk fibers

Impact of physio-chemical spinning conditions on the mechanical properties of biomimetic spider silk fibers

Carbon Nanotubes Facilitate Silk Hierarchical Assembly by Dry Drawing

Sustainable Spinning of Artificial Spider Silk Fibers with Excellent Toughness and Inherent Potential for Functionalization

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