Mechanism of cellulase action in textile processes

The effects on fabric caused by cellulase enzymes always result from a process in which strong mechanical action affecting the fabric is provided. This paper discusses the interaction between cellulase activities and mechanical agitation during textile processes. Possible mechanisms are suggested for depilling and ageing effects accounting for the presence of mechanical factors. The paper includes a review of the mechanisms of indigo backstaining during cellulase washing. (C) 1998 Elsevier Science Ltd. All rights reserved

Laccase-catalysed protein-flavonoid conjugates for flax fibre modification

The introduction of flavonoid compounds into proteins can improve the natural properties of proteins, being promising products which essentially require antioxidant property. The oxidative conjugation of protein–flavonoids was processed by laccase catalysis resulting in the synthesis of biologically functional polymers. The new reaction products were detected in terms of sodium dodecyl sulfate polyacrylamide gel electrophoresis and matrix-assisted laser desorption/ionisation-time of flight mass spectra, showing a greater molecular weight formation. Their characterisations were further carried out in terms of UV–Vis spectroscopy, photon correlation spectroscopy, differential scanning calorimetry and Fourier transform infrared (FT-IR) spectroscopy analysis. In addition, their application of protein–flavonoid conjugates onto flax fibres was exploited to supplement a suitable microorganism environment of protein-possessed fibres. The anchoring of conjugates onto cationised fibres was successfully performed by ionic interaction with negatively charged proteins. The level of anchoring efficiency was quantified in terms of measuring colour strength (k/s) and fluorescence microscopy analysis. The conjugates onto fibres presented acceptable durability in terms of washing resistance and the surface became hydrophilic when α-casein–catechin was applied (lower contact angle 48°). By the anchoring of protein–flavonoid conjugates onto flax fibres, the final products with new colour generation and antioxidant activity (>93%) were obtained

Liposomal formulations for rheumatoid arthritis

Book of Abstracts of CEB Annual Meeting 2017[Excerpt] Rheumatoid arthritis (RA) is the most common inflammatory rheumatic disease, affecting almost 1% of the world population. Although the cause of RA remains unknown, the complex interaction between immune mediators (cytokines and effector cells) is responsible for the joint damage that begins at the synovial membrane. Activated macrophages are critical in the pathogenesis of RA and showed specifically express a receptor for the vitamin folic acid (FA), folate receptor β (FRβ). This particular receptor allows internalization of FA-coupled cargo. [...]info:eu-repo/semantics/publishedVersio

Foreword: Advances in Polymer/Fibre Biotechnology

[Excerpt] Biotechnology has been applied as a valuable tool to produce useful bio-based products from non-petrochemical renewable resources. Biologically produced polymers present advantages related with the biodegradability, performance, cheapness of substrate and defined structural variability. Beyond that, enzymes, the most proficient catalysts, continue to offer the most competitive processes compared with the chemical ones. Advances in protein engineering technology and the environmental and economic requirements contribute for the continuous search of acceptable biotechnologicalsolutionsfortheareas,including,polymerandtextile, medical,pharmaceutical, amongothers.Newtrendsandstrategieshavebeen highlighted in recent studies leading to significant advances in enzyme biocatalysis. The 9th International Conference on Fiber and Polymer Biotechnology 2016 (IFPB 2016) was held in September 2016 in Osaka Seikei College, Osaka, Japan. IFPB16 was a joint conference with Textile Biotechnology Symposia 2016 (TBS) and the 40th Annual Meeting of Advanced Fiber Materials Research Committee (AFMc). Previous events of IFPB had taken place at: University of Minho, Portugal (INTB 2000); University of Georgia, USA (INTB 2002); Graz University of Technology, Austria (INTB 2004); Korea Institute of Industrial Technology, Korea (INTB 2006); Jiangnan University, Wuxi, China(INTB 2007); University ofGent, Belgium (IPTB 2009), Stazione Sperimentale perla Seta, Milan, Italy(IPTB 2011) and University of Minho, Portugal (IPFB 2014). The main topics covered by IFTB 2016 comprised industrial enzymes, natural and bio-based polymers and fibers, biofunctionalization of synthetic materials, sustainable processes, smart materials through bio-catalysis and nano/bio-materials and applications. Richard Gross from the Department ofChemistry andChemicalBiology, Rensselaer Polytechnic Institute, USA, wasinvited askeynote speaker. His remarkablelecture about “Engineered Cutinases for Textile Polymer Surface Modification and Recycling” provided an excellent opportunity to learn more about the potentialities of cutinases as efficient catalysts. Gross highlighted his recent work related with cutinase redesign, its biophysical and biochemical characterization and ability to recycle polyethylene terephthalate (PET) and cellulose acetate (CA). Thomas Rosenau from University of Natural Resources and Life Sciences in Austria and Kanji Kajiwara from the Faculty of Textile Science and Technology of Shinshu University in Japan were the invited speakers and enriched the conference with their new insights about cellulosic derivatives and fibers. [...]info:eu-repo/semantics/publishedVersio

The use of Keratin in biomedical applications

Keratins are naturally derived proteins that can be fabricated into several biomaterials morphologies including films, sponges and hydrogels. As a physical matrix, keratin biomaterials have several advantages of both natural and synthetic materials that are useful in tissue engineering and controlled released applications. Like other naturally derived protein biomaterials, such as collagen, keratin possess amino acid sequences, similar to the ones found on extracellular matrix (ECM), that may interact with integrins showing their ability to support cellular attachment, proliferation and migration. The ability of developing biomaterials that mimic ECM has the potential to control several biological processes and this is the case for keratin which has been used in a variety of biomedical applications due to its biocompatibility and biodegradability. This review describes the progress to date towards the use of keratin in the field of wound healing, tissue engineering and drug delivery applications, with highlight to reports of particular relevance to the development of the underlying biomaterials science in this area

Role of PEG on the formation of polyphenols with laccase enzymes

Laccase catalyzes the polymerization of phenolic compounds in the presence of Laccase catalyzes the polymerization of phenolic compounds in the presence of oxygen. It is known that polyethylene glycol (PEG) enhances transformation of the phenols. oxygen. It is known that polyethylene glycol (PEG) enhances transformation of the phenols. High conversation rates and high yields are obtained in presence of PEG. PEG is believed to High conversation rates and high yields are obtained in presence of PEG. PEG is believed to protect the enzyme of being entrapped inside the formed polymer. However the mechanisms protect the enzyme of being entrapped inside the formed polymer. However the mechanisms by what the PEG enhances the reaction are not completely clear. The structure and by what the PEG enhances the reaction are not completely clear. The structure and aggregation of the polyphenols are different when obtained in the presence of PEG. PEG aggregation of the polyphenols are different when obtained in the presence of PEG. PEG seems to play an important role as interfacial agent on the region selectivity in the seems to play an important role as interfacial agent on the region selectivity in the polymerization reaction catalyzed by laccase enzymes.info:eu-repo/semantics/updatedVersio

Nanotechnology: definitions and concepts

NANOFOL NanoDiaRA Conference in the 7th Framework Programme: Nanoparticles for Early Diagnostics of Inflammatory Diseases | New approaches in the field of soft and hard nanoparticlesMassive amount of funds have been allocated for the research in Nanotechnology. It is not always clear the boundaries between Micro and Nano areas. Definitions are very broad depending on the disciplinary area. Bold names from several disciplines exist like bionanotechnology, nanomedicine, nanomaterials, nanoformulation, nanoelectronics, nanofluidics, nanoparticles, nanosensors and others. In spite of view of the huge impact of definitions on research funding, regulations, toxicity, investigation and accreditation of new products, it is important to know and to understand the origin and reasons for these different approaches to those definitions. Definitions and examples from the literature as well as from the own research are given. This tutorial aims to clarify those misconceptions.info:eu-repo/semantics/publishedVersio

Effect of ultrasound on protein functionality

The review focus on the effect of ultrasound on protein functionality. The presence of transient ultrasonic mechanical waves induce various sonochemical and sonomechanical effects on a protein. Sonochemical effects include the breakage of chains and/or the modification of side groups of aminoacids. Sonomechanical modifications by enhanced molecular agitation, might lead to the transient or permanent modification of the 3D structure of the folded protein. Since the biological function of proteins depends on the maintenance of its 3D folded structure, both sonochemical and sonomechanical effects might affect its properties. A protein might maintain its 3D structure and functionality after minor sonochemical effects, however, the enhanced mass transfer by sonomechanical effects might expose internal hydrophobic residues of the protein, making protein unfolding to an irreversible denatured state. Ultrasound enhanced mass transport effects are unique pathways to change the 3D folded structure of proteins which lead to a new functionality of proteins as support shield materials during the formation microspheres. Enzymes are proteins and their reactions should be conducted in a reactor set-up where enzymes are protected from sonic waves to maximize their catalytic efficiency. In this review, focused examples on protein dispersions/emulsions and enzyme catalysis are given.National Natural Science Foundation of China (No.52003108) and the Fundamental Research Funds for the Central Universities (JUSRP121027). This research was also supported by the Portuguese Foundation for Science and Technology (FCT) under the scope of the strategic funding of UID/BIO/04469/2013 unit and COMPETE 2020 (POCI-01-0145-FEDER-006684) and BioTecNorte operation (NORTE-01-0145-FEDER-000004) funded by European Regional Development Fund under the scope of Norte2020 – Programa Operacional Regional do Norteinfo:eu-repo/semantics/publishedVersio

Developing scaffolds for tissue engineering using the Ca2+-induced cold gelation by an experimental design approach

The Ca2+-induced cold gelation technique was found suitable to prepare highly porous biodegradable scaffolds based on bovine serum albumin (BSA) and alpha-casein from bovine milk for tissue engineering. A 23 full factorial design was used to study the influence and impact of each factor on the several responses of the scaffolds. In vitro degradation (ID), swelling ratio (SR), porosity (PO), and pore size (PS) as well cytotoxicity (CT) were evaluated and shown to be dependent on the pH of sample preparation and on the amount of BSA and casein present, making these scaffolds tunable structures. Under optimized working conditions (4.19% of BSA, 0.69% of Casein, pH 7.07), the ID attained was 37.97%, the SR observed was 11.87, the PO was 82.11%, the PS measured was 180.63 μm at surface, and 175.91 μm at fracture, whereas maximum cell viability was 84% in comparison to controls. Moreover, the scaffold supported cell adhesion and proliferation. These results, consistent with the prediction by the experimental design approach, support the use of this methodology to develop tunable scaffolds for tissue engineering using the Ca2+-induced cold gelation.Contract grant sponsor: FEDER through POFC-COMPETE and by national funds from FCT; contract grant number: PEst-C/BIA/UI4050/201

Multifunctional proteins for hair protection and coloring

Book of Abstracts of CEB Annual Meeting 2017info:eu-repo/semantics/publishedVersio