Lijin Xia scite author profile

Advances in materials science and engineering through bio-inspiration, at both the micro-and nanoscales, have flourished over recent years. By understanding principles used in nature to produce adhesives and other substances of interest, the field of bio-inspired engineering has emerged as an important area of innovation. In this review, we will focus on bio-adhesives based on three main mechanisms of generating attachment: dry, wet, and chemical adhesion. Dry adhesion, involving micro-to nanoscale filamentous structures, is used by many insects and reptiles to rapidly climb surfaces. Tree frogs and some insects make use of wet adhesion by leveraging capillary forces through the design of attaching structures that increases liquid drainage, and hence increases frictional contact. Finally, chemical adhesion is used by many plants and mollusks, which secrete adhesives composed of proteins, polysaccharides and carbohydrates to generate the strong forces necessary for adhesion. This paper reviews recent discoveries in animal and plant bio-adhesives, and details the mechanisms used in several representative biological systems. We extend the review to include the fundamental principles functioning in each form of adhesion at the micro-and nanoscales. This fast emerging research area has significant implications in the future design of bio-inspired adhesives, and offers further potential for a variety of applications.

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Tea Nanoparticles for Immunostimulation and Chemo-Drug Delivery in Cancer Treatment

Yi¹,

Wang²,

Huang³

et al. 2014

Journal of Biomedical Nanotechnology

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Naturally occurring nanoparticles from English ivy: an alternative to metal-based nanoparticles for UV protection

et al. 2010

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BackgroundOver the last decade safety concerns have arisen about the use of metal-based nanoparticles in the cosmetics field. Metal-based nanoparticles have been linked to both environmental and animal toxicity in a variety of studies. Perhaps the greatest concern involves the large amounts of TiO2 nanoparticles that are used in commercial sunscreens. As an alternative to using these potentially hazardous metal-based nanoparticles, we have isolated organic nanoparticles from English ivy (Hedera helix). In this study, ivy nanoparticles were evaluated for their potential use in sunscreens based on four criteria: 1) ability to absorb and scatter ultraviolet light, 2) toxicity to mammalian cells, 3) biodegradability, and 4) potential for diffusion through skin.ResultsPurified ivy nanoparticles were first tested for their UV protective effects using a standard spectrophotometric assay. Next the cell toxicity of the ivy nanoparticles was compared to TiO2 nanoparticles using HeLa cells. The biodegradability of these nanoparticles was also determined through several digestion techniques. Finally, a mathematical model was developed to determine the potential for ivy nanoparticles to penetrate through human skin. The results indicated that the ivy nanoparticles were more efficient in blocking UV light, less toxic to mammalian cells, easily biodegradable, and had a limited potential to penetrate through human skin. When compared to TiO2 nanoparticles, the ivy nanoparticles showed decreased cell toxicity, and were easily degradable, indicating that they provided a safer alternative to these nanoparticles.ConclusionsWith the data collected from this study, we have demonstrated the great potential of ivy nanoparticles as a sunscreen protective agent, and their increased safety over commonly used metal oxide nanoparticles.

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CRISPR/Cas9 Initiated Transgenic Silkworms as a Natural Spinner of Spider Silk

Zhang¹,

Xia²,

Day³

et al. 2019

Biomacromolecules

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Using transgenic silkworms with their natural spinning apparatus has proven to be a promising way to spin spider silk-like fibers. The challenges are incorporating nativesize spider silk proteins and achieving an inheritable transgenic silkworm strain. In this study, a CRISPR/Cas9 initiated fixed-point strategy was used to successfully incorporate spider silk protein genes into the Bombyx mori genome. Native-size spider silk genes (up to 10 kb) were inserted into an intron of the fibroin heavy or light chain (FibH or FibL) ensuring that any sequence changes induced by the CRISPR/Cas9 would not impact protein production. The resulting fibers are as strong as native spider silks (1.2 GPa tensile strength). The transgenic silkworms have been tracked for several generations with normal inheritance of the transgenes. This strategy demonstrates the feasibility of using silkworms as a natural spider silk spinner for industrial production of high-performance fibers.

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Nanofibers and nanoparticles from the insect-capturing adhesive of the Sundew (Drosera) for cell attachment

Zhang

Lenaghan

Xia

et al. 2010

Journal of Nanobiotechnology

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BackgroundThe search for naturally occurring nanocomposites with diverse properties for tissue engineering has been a major interest for biomaterial research. In this study, we investigated a nanofiber and nanoparticle based nanocomposite secreted from an insect-capturing plant, the Sundew, for cell attachment. The adhesive nanocomposite has demonstrated high biocompatibility and is ready to be used with minimal preparation.ResultsAtomic force microscopy (AFM) conducted on the adhesive from three species of Sundew found that a network of nanofibers and nanoparticles with various sizes existed independent of the coated surface. AFM and light microscopy confirmed that the pattern of nanofibers corresponded to Alcian Blue staining for polysaccharide. Transmission electron microscopy identified a low abundance of nanoparticles in different pattern form AFM observations. In addition, energy-dispersive X-ray spectroscopy revealed the presence of Ca, Mg, and Cl, common components of biological salts. Study of the material properties of the adhesive yielded high viscoelasticity from the liquid adhesive, with reduced elasticity observed in the dried adhesive. The ability of PC12 neuron-like cells to attach and grow on the network of nanofibers created from the dried adhesive demonstrated the potential of this network to be used in tissue engineering, and other biomedical applications.ConclusionsThis discovery demonstrates how a naturally occurring nanofiber and nanoparticle based nanocomposite from the adhesive of Sundew can be used for tissue engineering, and opens the possibility for further examination of natural plant adhesives for biomedical applications.

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Lijin Xia

Inspiration from the natural world: from bio-adhesives to bio-inspired adhesives

Tea Nanoparticles for Immunostimulation and Chemo-Drug Delivery in Cancer Treatment

Naturally occurring nanoparticles from English ivy: an alternative to metal-based nanoparticles for UV protection

CRISPR/Cas9 Initiated Transgenic Silkworms as a Natural Spinner of Spider Silk

Nanofibers and nanoparticles from the insect-capturing adhesive of the Sundew (Drosera) for cell attachment

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