Silk-based blood stabilization for diagnostics

Kluge, Jonathan A.; Li, Adrian B.; Kahn, Brooke T.; Michaud, Dominique S.; Omenetto, Fiorenzo G.; Kaplan, David L.

doi:10.1073/pnas.1602493113

Cited by 75 publications

(70 citation statements)

References 38 publications

(43 reference statements)

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“…In the past two decades, silk has undergone a technological revolution with a large body of research focused on engineering new material formats using the natural protein (extracted from the gland, or from silk fibers) as well as genetically engineered ones (especially, recombinant spider silk proteins). Silk materials have been fabricated into various material formats for biomedical applications with successful demonstrations in tissue engineering, drug stabilization and controlled delivery, and implantable medical devices . Furthermore, silk has also been widely used in flexible electronics, optical and photonic devices owing to the great flexibility and optical properties.…”

Section: Introductionmentioning

confidence: 99%

Engineering the Future of Silk Materials through Advanced Manufacturing

et al. 2018

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Silk is a natural fiber renowned for its outstanding mechanical properties that have enabled the manufacturing of ultralight and ultrastrong textiles. Recent advances in silk processing and manufacturing have underpinned a re-interpretation of silk from textiles to technological materials. Here, it is argued that silk materials-optimized by selective pressure to work in the environment at the biotic-abiotic interface-can be harnessed by human micro- and nanomanufacturing technology to impart new functionalities and opportunities. A critical overview of recent progress in silk technology is presented with emphasis on high-tech applications enabled by recent innovations in multilevel modifications, multiscale manufacturing, and multimodal characterization of silk materials. These advances have enabled successful demonstrations of silk materials across several disciplines, including tissue engineering, drug delivery, implantable medical devices, and biodissolvable/degradable devices.

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Section: Introductionmentioning

confidence: 99%

Engineering the Future of Silk Materials through Advanced Manufacturing

et al. 2018

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“…In contrast to synthetic polymers based on chemical reactions, silkworm silk is a protein‐based material produced by silkworms at ambient conditions in an all‐aqueous reaction environment. Silk is thus produced in an environment‐friendly process, and due to biocompatibility and mechanical features shows potential for developing healthcare products, biomedical devices, and biosensors . The extraordinary mechanical properties of silk originate from the unique highly repetitive sequence in fibroin, along molecular self‐assembly and organization at nanoscale .…”

Section: Introductionmentioning

confidence: 99%

Comparative Study of Strain‐Dependent Structural Changes of Silkworm Silks: Insight into the Structural Origin of Strain‐Stiffening

Guo

Zhang

Wang

et al. 2017

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Structure–property relationships of silk is an intriguing topic for silk‐based biomaterials research since these features are related to biomimicking the processing in natural silk fiber formation which results in excellent mechanical properties. Strain‐stiffening is common for spider silks and nonmulberry silkworm silks. However, the structural origin of strain‐stiffening remains unclear. In this paper, the strain‐dependent structural change of Antheraea pernyi silkworm silk is studied by X‐ray fiber diffraction and Fourier transform infrared spectroscopy under stretching. Based on a combination of mechanical and structural analysis, the molecular origins of strain‐stiffening in A. pernyi silk were determined. The relatively high content of the β‐sheets within the amorphous domains in A. pernyi silk is responsible for strain‐stiffening, where “molecular spindles” enhance the extensibility and toughness of the fiber.

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“…Moreover, silk was functionalized with ECM components that are expressed in the physiological bone marrow structure [7]. Importantly, it was previously shown that silk preserves the activity of the encapsulated molecules [13,15,16]. …”

Section: Discussionmentioning

confidence: 99%

“…Finally, a third system, made by PDMS, was developed with a wide array of von Willebrand Factor-coated micropillars supposed to act as anchors on Mks, allowing them to extend proplatelets under a hydrodynamic shear [11]. Compared to these systems for platelet production, a critical feature of our flow chamber is the use of natural silk protein biomaterial to leverage its versatility such as programmable mechanical properties, and surface binding of growth factors and ECM components, while retaining their bioavailability [13,16]. In our previous BM model we used silk tubes and sponges to recreate the vascular niche where Mks release platelets [16].…”

Section: Discussionmentioning

confidence: 99%

Modular flow chamber for engineering bone marrow architecture and function

et al. 2017

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The bone marrow is a soft, spongy, gelatinous tissue found in the hollow cavities of flat and long bones that support hematopoiesis in order to maintain the physiologic turnover of all blood cells. Silk fibroin, derived from Bombyx mori silkworm cocoons, is a promising biomaterial for bone marrow engineering, because of its tunable architecture and mechanical properties, the capacity of incorporating labile compounds without loss of bioactivity and demonstrated ability to support blood cell formation. In this study, we developed a bone marrow scaffold consisting of a modular flow chamber made of polydimethylsiloxane, holding a silk sponge, prepared with salt leaching methods and functionalized with extracellular matrix components. The silk sponge was able to support efficient platelet formation when megakaryocytes were seeded in the system. Perfusion of the chamber allowed the recovery of functional platelets based on multiple activation tests. Further, inhibition of AKT signaling molecule, which has been shown to be crucial in regulating physiologic platelet formation, significantly reduced the number of collected platelets, suggesting the applicability of this tissue model for evaluation of the effects of bone marrow exposure to compounds that may affect platelet formation. In conclusion, we have bioengineered a novel modular system that, along with multi-porous silk sponges, can provide a useful technology for reproducing a simplified bone marrow scaffold for blood cell production ex vivo.

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Silk-based blood stabilization for diagnostics

Cited by 75 publications

References 38 publications

Engineering the Future of Silk Materials through Advanced Manufacturing

Engineering the Future of Silk Materials through Advanced Manufacturing

Comparative Study of Strain‐Dependent Structural Changes of Silkworm Silks: Insight into the Structural Origin of Strain‐Stiffening

Modular flow chamber for engineering bone marrow architecture and function

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