Development of Novel 2D Composites of Silk Sericin and Rice Starch and Application as Bio‐Compatible Scaffold for Cell Culturing

Dutta, Sikha; Dutta, Himjyoti; Devi, Dipali

doi:10.1002/star.201700270

Cited by 4 publications

(2 citation statements)

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“…Further molecular displacement in low-molecular-weight poly(ethylene glycol) (PEG) reduced water content and improved the tolerance temperature to the range of −70 to 120 °C. Enhanced antifreezing heat-resistant performances of SA hollow hydrogel tubes as well as their increased flexibility are achieved by the treatments in glycerol and PEG. , All details of the preparation of SA hollow hydrogel tubes and their functionalization for enhanced antifreezing heat-resistant performances, as well as the potential applications as carriers, are demonstrated and discussed. We report this new method for the creation of nontoxic, antifreezing heat-resistant hollow hydrogel tubes that may find promising applications in various extreme temperature environments in biomedical fields.…”

Section: Introductionmentioning

confidence: 99%

Antifreezing Heat-Resistant Hollow Hydrogel Tubes

Qing

Zhao

et al. 2019

ACS Appl. Mater. Interfaces

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Hollow hydrogel tubes that are capable of maintaining their flexibility and structural stability in extreme temperature conditions have potential for use in biomedical scaffolds, carriers, and soft robotics over a wide temperature range. However, the preparation of hollow hydrogel tubes still remains challenging because it normally requires templates or complex devices and it is hard to endow the hollow tubes with antifreezing heat-resistant capabilities. We report a protocol that does not require a template or complex devices, in which sodium alginate film strips are immersed in an aqueous mixture of CaCO3, CaCl2, NaHCO3, and HCl, which results in the manufacture of hollow tubes in 30 min. These hollow tubes are functionalized by glycerol and poly(ethylene glycol), which provides the tubes with antifreezing heat-resistant performances and enables them to keep their flexibility and hollow structures from −70 to 120 °C. This is the first report on antifreezing heat-resistant hollow hydrogel tubes, to the best of our knowledge. Such hollow tubes as carriers can control the sublimation of a mothball at a rate of 1.1 mg/h, which is one-tenth of the sublimating rate of an unloaded mothball. This sublimating rate reduces the hazard to environments along with maintaining the repellent effects. As the tube is a honey carrier, it enables the sustainable release of the honey over 800 min with a high efficacy for tricking and capturing ants. The simple applications demonstrate that the antifreezing heat-resistant hollow tubes might be feasible as carriers for the controlled release in extremely cold/hot environments.

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Section: Introductionmentioning

confidence: 99%

Antifreezing Heat-Resistant Hollow Hydrogel Tubes

Qing

Zhao

et al. 2019

ACS Appl. Mater. Interfaces

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“…Previous works have also explored the interaction between starch and protein from other different perspectives (Espinosa-Dzib, Ramírez-Gilly, & Tecante, 2012;Homer, Kelly, & Day, 2014;Ravindra, Genovese, Foegeding, & Rao, 2004). Dutta reported that silk sericin and rice starch can be thermo-mechanically conjugated and casted into continuous 2D films through evident molecular interaction between starch and sericin (Dutta, Dutta, & Devi, 2018). Both starch, protein, and their interaction are responsible for the macroscopic properties of food matrix (Jekle et al, 2016).…”

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confidence: 99%

Pasting, thermo, and Mixolab thermomechanical properties of potato starch–wheat gluten composite systems

Fen

Liu

et al. 2020

Food Science & Nutrition

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| INTRODUC TI ONPotato (Solanum tuberosum L.) is the world's fourth most important food crop after rice, wheat, and maize. Potato is also one of the main raw materials for starch extraction, and the starch content of potato is generally 9%~25%. Both the whole potato flour and the extracted potato starch are widely used in food industry due to their unique physicochemical properties. Studies showed that potato flour (potato starch as main composition) or potato starch supplements significantly influence the dough's processing performance (i.e., rheological, thermal, and thermomechanical properties) and the final products quality (i.e., color, texture, nutrition, and flavor) AbstractThis research investigated the viscosity, thermal, thermomechanical, and microstructural properties of potato starch-wheat gluten composite systems with different starch/gluten ratios under mechanical shear and heating conditions. Results showed that the peak, trough, and final viscosities increased with the increase in potato starch fraction. The breakdown and setback values of samples decreased with increasing gluten content, and the endothermic enthalpy showed a similar variation trend. The gelatinization temperature of the samples increased significantly as the gluten proportion increased. Morphological observation showed that the gluten protein was wrapped around potato starch granules and the starch granules have a diluting effect on gluten network. Moreover, gluten formed a water diffusion barrier out of the starch granules, this barrier effect and the competitive hydration between starch and gluten could primarily explain the delayed gelatinization temperatures. K E Y W O R D Sdough properties, gelatinization, microstructure, potato starch, rheology, wheat gluten

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