196,610 research outputs found

    Biobased materials for skin-contact products promoted by POLYBIOSKIN project

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    The skin is the body outermost tissue and acts as a barrier and defense line to protect our organs [...]

    Chitin and lignin waste in the circular economy

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    Food and packaging waste, produced by food industries and consumers, cause an increasing pollution if not correctly managed. Recycling opportunities must be exploited to maintain our health and wellbeing, preserving the planet' natural raw materials and biodiversity for the future generations. Thus, the necessity to transform the linear economy, cause of people inequality and waste, in a circular economy based on economic prosperity, cultural vitality, social equity and environmental sustainability. For a sustainable community development, it will be necessary to recycle the industrial and agricultural waste and redesign and manufacture new products taking into account their end of life management and considering, through Life Cycle Assessment investigations, to maintain a low consume of energy and water. Among the different waste materials recovered worldwide, chitin and lignin, obtainable from food and agroforestry by-products respectively, represent the greatest source of natural raw materials available at low cost and underutilized. By many studies it has been shown that both chitin, lignin and the relative complexes, may be electro-spun with other natural polysaccharides to obtain antibacterial, immunomodulant, antioxidant and skin-repairing non-woven tissues. These innovative tissues, embedded by selected active ingredients, may be used to make facial beauty masks and/or advanced medications

    Biobased and biodegradable rigid and flexible polymeric packaging

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    The present chapter is dedicated to the potentialities and opportunities of biobased and biodegradable polymeric materials currently available on the market for producing packaging. After some definitions considering regulatory and standardization aspects, these materials are described and classified. Biopolyesters and biopolymers are mainly used for these products in the form of blends or biocomposites, often in combination with additives based on biobased molecules. For flexible packaging blown film extrusion or flat die extrusion of poly(lactic acid) (PLA) based materials or starch based materials are currently the main options on the market. For rigid packaging, obtained mainly by injection molding or thermoforming, PLA blends or composites are the more promising alternatives, because of their good balance of properties and cost. The control of their processability and final properties is thus fundamental

    Polymeric Substrates Modification with Biobased Functional Compounds

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    Editorial to the Special Issue "Polymeric Substrates Modification with Biobased Functional Compounds

    An introduction to the circular economy

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    This book tries to debate on the significance of circular economy, underlying the necessity to change our way of producing, consuming, and traveling on a daily basis. The passage from a linear economy to a circular economy will help us to reduce the degradation of the environment for avoiding future disastrous consequences, such as depletion of biodiversity, scarcity of raw materials and drinking water, rising waters, etc. The circular economy, therefore, involves designing a product so that it can be recycled or its components reused. Reuse consists of introducing the product back into the economic circuit in its original condition; repair makes it possible to fix a broken good; and recovery consists of reusing its components. This is the significance of the so-called 3R strategy, illustrated in this book

    Structure and properties of extruded composites based on bio-polyesters and nano-chitin

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    A renewable feedstock on a worldwide scale is chitin waste material from the seafood industry, exceeding 25 billion tons/year. Recently, it has become possible to produce pure chitin crystals, named “chitin nanofibrils” (CN) for their needle-like shape and nanostructured average size 1. The CN are thus available on an industrial scale in water suspension. Biodegradable polyesters, such as poly(lactic acid) (PLA) are widely investigated for their potential applications in many sectors. The preparation of CN composites can result in improved mechanical and antimicrobial properties. These composites were melt extruded to achieve a good level of dispersion by employing suitable plasticizers to pre-disperse NC. The complete removal of water from the plasticizer/NC pre-composite was essential to avoid chain scission2 in the successive extrusion step. The electron microscopy investigation of materials showed the absence of micrometric agglomerates thanks to the adopted preparation method. The effect of plasticization, crystallinity evolution and reinforcement were kept into account to rationalize the results of tensile and DSC tests. (1) P. Morganti, G. Morganti, A. Morganti, Nanotechnology, Science and Applications, 2011:4 123–129 (2) F. Signori, M. B. Coltelli, S. Bronco, Polymer Degradation and Stability 2009: 94 74–82 Aknowledgements: Authors acknowledge the financial support of EC Seventh Framework Programme, SME-2012-1, grant agreement n° 315233, n-Chitopack project

    Biobased Tissues for Innovative Cosmetic Products: Polybioskin as an EU Research Project

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    Textiles and nonwoven tissues made of petrol-derived polymer fibers, interact with the skin functions in a dynamic pattern, and could provoke injury and inflammation. The safety aspects of polymer fibers, related to their biological characteristics, such as biodegradability, biocompatibility and antigenicity, indeed, are of great importance for biomedical applications [20,23,27].Therefore, the necessity of using biobased polymer fibers and nonwoven tissues, characterized for their protective effectiveness and free of undesirable side effects such as cytotoxicity or allergic, sensitizing and irritating reactions, drives the cosmetic market. These natural tissues, the production of which has been increased by the use of nanotechnology, are made of bio-fibers able to sense and hinder different stimuli elicited from outside and inside the skin. The production of these polymer fibers and non-woven tissue is the aim of the PolyBioSkin project that specifically focuses on the development and fabrication of innovative sanitary, cosmetic and wound care products provided with innovative behavior and functionality. Of course, the success of the proposed products will be connected with the advanced composite materials produced, their human safety and effectiveness, to be tested both in vitr
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