Laura Ribba scite author profile

Nanocomposites of cassava starch reinforced with waxy starch nanocrystals were prepared. They showed a 380% increase of the rubbery storage modulus (at 50 °C) and a 40% decrease in the water vapor permeability. X‐ray spectra show that the composite was more amorphous than the neat matrix, which was attributed to higher equilibrium water content in the composites. TGA confirmed this result and its thermal derivative suggested the formation of hydrogen bonding between glycerol and the nanocrystals. The reinforcing effect of starch nanocrystals was attributed to strong filler/matrix interactions due to the hydrogen bonding. The decrease of the permeability suggests that the nanocrystals were well dispersed, with few filler/filler interactions.

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Effect of glycerol on the morphology of nanocomposites made from thermoplastic starch and starch nanocrystals

García¹,

Ribba²,

Dufresne³

et al. 2011

Carbohydrate Polymers

218

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Disadvantages of Starch-Based Materials, Feasible Alternatives in Order to Overcome These Limitations

Ribba

García

D’Accorso

et al. 2017

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Electrospun Nanofibrous Mats: From Vascular Repair to Osteointegration

Ribba¹,

Parisi²,

D’Accorso³

et al. 2014

j biomed nanotechnol

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Electrospinning is a versatile technique for generating a mat of continuous fibers with diameters from a few nanometers to several micrometers. The diversity of electrospinnable materials, and the unique features associated with electrospun fibers make this technique and its resultant structures attractive for applications in the biomedical field. This article presents an overview of this technique focusing on its application for tissue engineering. In particular, the advantages and disadvantages of using an electrospinning mat for biomedical applications are discussed. It reviews the different available electrospinning configurations, detailing how the different process variables and material types determine the obtained fibers characteristics. Then a description of how nanofiber based scaffolds offer great promise in the regeneration or function restoration of damaged or diseased bones, muscles or nervous tissue is reported. Different methods for incorporating active agents on nanofibers and controlling their release mechanisms are also reviewed. The review concludes with some personal perspectives on the future work to be done in order to include electrospinning technique in the industrial development of biomedical materials.

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Laura Ribba

Physico‐Mechanical Properties of Biodegradable Starch Nanocomposites

Effect of glycerol on the morphology of nanocomposites made from thermoplastic starch and starch nanocrystals

Disadvantages of Starch-Based Materials, Feasible Alternatives in Order to Overcome These Limitations

Electrospun Nanofibrous Mats: From Vascular Repair to Osteointegration

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