Cell Surface Engineering with Edible Protein Nanoshells

Drachuk, Irina; Shchepelina, Olga; Harbaugh, Svetlana; Kelley‐Loughnane, Nancy; Stone, Morley O.; Tsukruk, Vladimir V.

doi:10.1002/smll.201202992

Cited by 46 publications

(51 citation statements)

References 79 publications

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“…Silk-based biomaterials have been used for medical sutures and breast implant coatings [70][71][72], biosensing applications [73], and enzyme immobilization [74][75][76]. Recently, a silk-gelatin blend was used as a bioink [20,57].…”

Section: Established Bioinksmentioning

confidence: 99%

Biofabrication of 3D constructs: fabrication technologies and spider silk proteins as bioinks

DeSimone

Schacht

Jüngst

et al. 2015

Pure and Applied Chemistry

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Despite significant investment in tissue engineering over the past 20 years, few tissue engineered products have made it to market. One of the reasons is the poor control over the 3D arrangement of the scaffold's components. Biofabrication is a new field of research that exploits 3D printing technologies with high spatial resolution for the simultaneous processing of cells and biomaterials into 3D constructs suitable for tissue engineering. Cell-encapsulating biomaterials used in 3D bioprinting are referred to as bioinks. This review consists of: (1) an introduction of biofabrication, (2) an introduction of 3D bioprinting, (3) the requirements of bioinks, (4) existing bioinks, and (5) a specific example of a recombinant spider silk bioink. The recombinant spider silk bioink will be used as an example because its unmodified hydrogel format fits the basic requirements of bioinks: to be printable and at the same time cytocompatible. The bioink exhibited both cytocompatible (selfassembly, high cell viability) and printable (injectable, shear-thinning, high shape fidelity) qualities. Although improvements can be made, it is clear from this system that, with the appropriate bioink, many of the existing faults in tissue-like structures produced by 3D bioprinting can be minimized.

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Section: Established Bioinksmentioning

confidence: 99%

Biofabrication of 3D constructs: fabrication technologies and spider silk proteins as bioinks

DeSimone

Schacht

Jüngst

et al. 2015

Pure and Applied Chemistry

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“…The most intensively employed method in single‐cell nanocoating is the LbL deposition of various polymers and nanomaterials onto cell surfaces ( Figure a) . In addition to the classical, electrostatics‐based LbL deposition that might be cytotoxic because of positively charged polyelectrolytes, new strategies have been developed for more cytocompatible cell nanocoating, such as salting‐out‐ and hydrogen bonding‐based approaches. [4a,b,13] For example, Tsukruk and co‐workers formed tough, pH‐responsive LbL shells on individual yeast cells, by cross‐linking hydrogen‐bonded layers composed of poly( N ‐vinylpyrrolidone) (PVPON) and amine‐bearing poly(methacrylic acid) (PMAA‐ co ‐NH 2 ), to control cell function and metabolism without noticeable decrease in cell viability (Figure b).…”

Section: Progresses In Synthetic Strategies For “Cell‐in‐shell” Strucmentioning

confidence: 99%

“…[4a,b,13] For example, Tsukruk and co‐workers formed tough, pH‐responsive LbL shells on individual yeast cells, by cross‐linking hydrogen‐bonded layers composed of poly( N ‐vinylpyrrolidone) (PVPON) and amine‐bearing poly(methacrylic acid) (PMAA‐ co ‐NH 2 ), to control cell function and metabolism without noticeable decrease in cell viability (Figure b). [13a] The material scope for cell‐surface engineering also has been widened, including silk fibroin (SF), halloysite nanotubes (Figure c), and small peptides …”

Section: Progresses In Synthetic Strategies For “Cell‐in‐shell” Strucmentioning

confidence: 99%

Strategic Advances in Formation of Cell‐in‐Shell Structures: From Syntheses to Applications

et al. 2018

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Single-cell nanoencapsulation, forming cell-in-shell structures, provides chemical tools for endowing living cells, in a programmed fashion, with exogenous properties that are neither innate nor naturally achievable, such as cascade organic-catalysis, UV filtration, immunogenic shielding, and enhanced tolerance in vitro against lethal factors in real-life settings. Recent advances in the field make it possible to further fine-tune the physicochemical properties of the artificial shells encasing individual living cells, including on-demand degradability and reconfigurability. Many different materials, other than polyelectrolytes, have been utilized as a cell-coating material with proper choice of synthetic strategies to broaden the potential applications of cell-in-shell structures to whole-cell catalysis and sensors, cell therapy, tissue engineering, probiotics packaging, and others. In addition to the conventional "one-time-only" chemical formation of cytoprotective, durable shells, an approach of autonomous, dynamic shellation has also recently been attempted to mimic the naturally occurring sporulation process and to make the artificial shell actively responsive and dynamic. Here, the recent development of synthetic strategies for formation of cell-in-shell structures along with the advanced shell properties acquired is reviewed. Demonstrated applications, such as whole-cell biocatalysis and cell therapy, are discussed, followed by perspectives on the field of single-cell nanoencapsulation.

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“…One key property of silk protein is that its solubility can be adjusted by salting‐out in a proper ionic mixture complemented with shear‐thinning effect, with the transition from water‐soluble Silk I to non‐soluble β‐sheet‐rich Silk II, based on which, the silk‐based coating can be smartly put on or taken off. Hence, in this work, the yeast cells were coated with ultrathin silk shells, maintaining a high viability (∼97%), the ability of budding and replication, as well as the metabolic activity. Since the silk shell undergoes relatively rapid intracellular degradation, there is only a short‐term protection of the cells.…”

Section: Strategies For Single‐cell Coatingmentioning

confidence: 99%

Single‐Cell Nanometric Coating Towards Whole‐Cell‐Based Biodevices and Biosensors

Dai

Wang

et al. 2018

ChemistrySelect

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Living cells with different coatings, like polyelectrolytes, biomolecules, metal nanoparticles or oxides, have more functions compared with the original state, which would be beneficial to many potential applications. Amongst these applications, whole‐cell biosensors/devices are commonly used for high‐throughput disease diagnosis, detection of toxicities, biomedical imaging, environmental monitoring or microbial fuel cells. As a key factor of the fabrication of whole cell biosensors/devices, the techniques for cell immobilization and cell viability have obvious influence on the sensitivity, stability and reproducibility. Cell coatings not only can be helpful to maintain the cell viability, but also can offer multifunction to facilitate the cell immobilization or orientation in the construction of biosensors/devices. Therefore, in this review, we are going to discuss various coating methods and materials, with the focus on their applications in the whole‐cell based biosensors and bio‐devices.

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Cell Surface Engineering with Edible Protein Nanoshells

Cited by 46 publications

References 79 publications

Biofabrication of 3D constructs: fabrication technologies and spider silk proteins as bioinks

Biofabrication of 3D constructs: fabrication technologies and spider silk proteins as bioinks

Strategic Advances in Formation of Cell‐in‐Shell Structures: From Syntheses to Applications

Single‐Cell Nanometric Coating Towards Whole‐Cell‐Based Biodevices and Biosensors

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