Fibers Obtained from Alginate, Chitosan and Hybrid Used in the Development of Scaffolds

Furuya, Daniela Camargo; Costa, Sérgio E. Gouvêa da; Oliveira, Rodrigo Cardoso de; Ferraz, Humberto Gomes; Pessoa, Adalberto; Costa, Sirlene Maria da

doi:10.1590/1980-5373-mr-2016-0509

Cited by 36 publications

(17 citation statements)

References 27 publications

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“…In case of active agent loaded NCS, crystallization endotherm was registered at 158°C which was not very different from blank NCS. This observation confirmed that very low amount of active agent was present between alginate and chitosan layer (Furuya et al, 2017 ). Once alginate layer degraded at high temperature, it exposed more amorphous content (nisin and chitosan), which increased the temperature value for crystalline endotherm.…”

Section: Resultssupporting

confidence: 78%

Polyelectrolyte Multicomponent Colloidosomes Loaded with Nisin Z for Enhanced Antimicrobial Activity against Foodborne Resistant Pathogens

et al. 2018

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Food grade micro- or nano-carrier systems (NCS) are being developed to improve the controlled release of antimicrobial agents. To augment the stability of liposomal NCS and to overcome the limitations associated with the use of free bacteriocin (nisin) in the food system, multi-component colloidosomes (MCCS) were developed by electrostatic interactions between anionic alginate and cationic chitosan (multilayer) around phospholipids based liposomes (core). Zeta-sizer results revealed the average diameter of 145 ± 2 nm, 596 ± 3 nm, and 643 ± 5 nm for nano-liposome (NL), chitosomes (chitosan coated NL) and MCCS, respectively. Zeta potential values of NCS varied from −4.37 ± 0.16 mV to 33.3 ± 6 mV, thus both chitosomes (CS) and MCCS were positively charged. Microstructure analysis by scanning electron microscope (SEM) revealed relatively higher size of MCCS with smooth and round morphology. TGA and DSC based experiments revealed that MCCS were thermally more stable than uncoated liposomes. Encapsulation efficiency of nisin in MCCS was observed to be 82.9 ± 4.1%, which was significantly higher than NL (56.5 ± 2.5%). FTIR analyses confirmed the cross-linking between sodium alginate and chitosan layer. Both qualitative (growth kinetics) and quantitative (colony forming unit) antimicrobial assays revealed that nisin loaded MCCS have superior potential to control resistant foodborne pathogens including Staphylococcus aureus, Listeria monocytogenes, and Enterococcus faecalis, (5.8, 5.4, and 6.1 Log CFUmL−1 reduction, respectively) as compared to free nisin, loaded NL or CS. Controlled release kinetics data fitted with Korsmeyer–Peppas model suggested that nisin release from MCCS followed Fickian diffusion. Cytotoxic studies on human blood cells and HepG2 cell lines revealed hemocompatibility and non-toxicity of MCCS. Thus, due to enhanced controlled release, stability and biocompatibility; these multi-component colloidosomes can be useful for incorporating antimicrobial agents into functional foods, beverages and pharmaceutical products to combat pathogenic and spoilage bacteria.

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Section: Resultssupporting

confidence: 78%

Polyelectrolyte Multicomponent Colloidosomes Loaded with Nisin Z for Enhanced Antimicrobial Activity against Foodborne Resistant Pathogens

et al. 2018

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“…The use of a coaxial flow in a non-microfluidic device allows for the production of fiber diameters that are comparable to those obtained in microfluidic devices (150–500 μm [27]), but with a processing speed that is one order of magnitude higher (0.5 mL/min versus 50 μL/min typically observed in microfluidic devices [27]). Furthermore, cohesive scaffolds are prepared within a very short time, for the benefit of cell survival, with a one-step procedure, avoiding the need for an additional step that is required to assemble discrete fibers that are produced in similar systems [24,37,38,39].…”

Section: Resultsmentioning

confidence: 99%

3D Encapsulation Made Easy: A Coaxial-Flow Circuit for the Fabrication of Hydrogel Microfibers Patches

2019

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To fully exploit the potential of hydrogel micro-fibers in the design of regenerative medicinal materials, we designed a simple, easy to replicate system for cell embedding in degradable fibrous scaffolds, and validated its effectiveness using alginate-based materials. For scaffold fabrication, cells are suspended in a hydrogel-precursor and injected in a closed-loop circuit, where a pump circulates the ionic cross-linking solution. The flow of the cross-linking solution stretches and solidifies a continuous micro-scaled, cell-loaded hydrogel fiber that whips, bends, and spontaneously assembles in a self-standing, spaghetti-like patch. After investigation and tuning of process- and solution-related parameters, homogeneous microfibers with controlled diameters and consistent scaffolds were obtained from different alginate concentrations and blends with biologically favorable macromolecules (i.e., gelatin or hyaluronic acid). Despite its simplicity, this coaxial-flow encapsulation system allows for the rapid and effortless fabrication of thick, well-defined scaffolds, with viable cells being homogeneously distributed within the fibers. The reduced fiber diameter and the inherent macro-porous structure that is created from the random winding of fibers can sustain mass transport, and support encapsulated cell survival. As different materials and formulations can be processed to easily create homogeneously cell-populated structures, this system appears as a valuable platform, not only for regenerative medicine, but also, more in general, for 3D cell culturing in vitro.

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“…Soluble protein concentration was determined by the colorimetric method of Bradford [36] which is based on the color change of the acidic solution of Coomassie Brilliant Blue G 250, when binding to a protein the maximum absorbance changes from 465 to 595 nm, and calculations were performed by Eq. 1 [5]: RP = Protein yield (%); P0 = Protein available for immobilization (mg), and Pads = (P 0 − P s − P f ) the amount of protein adsorbed to the support was determined as the difference between P 0 the proteins and remaining in the supernatant P s in the filtered and P f at the end of the immobilization process (mg).The yield of the immobilization process was calculated by Eq. 2:…”

Section: Bromelain Immobilizationmentioning

confidence: 99%

“…Heart valve rings, vascular grafts, percutaneous devices, and hernia repair meshes can be found. Also, the fibers have been used in regenerative medicine [4,5]. Use of fibers in bone tissue engineering offers clear advantages such as good porosity, lightness, and a better adjustable elastic modulus than a metallic product, which improves bone tissue regeneration [6].…”

Section: Introductionmentioning

confidence: 99%

Fibers of cellulose sugarcane bagasse with bromelain enzyme immobilized to application in dressing

2020

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The enzymes have been gaining more importance in different fields, among the most important the pharmaceutical field. However, due to the protein nature of the enzymes, a significant part of them presents high instability under certain conditions of use. A great way to stabilize them is to use immobilization techniques. Bromelain from pineapple has shown potential to be used in the treatment of burn-like skin injuries and superficial injuries. Biocatalytic textile fibers from cellulose of sugarcane bagasse were prepared using surface functionalization with epichlorohydrin (4% v/v) and glutaraldehyde (0.5% v/v), and 1-ethyl-(3-dimethylaminopropyl) carbodiimide and bromelain immobilization by covalent bonding in the fibers. The best immobilization results for the bromelain enzyme immobilization were using the aminopropyltriethoxysilane and glutaraldehyde activating agent at pH 7 to values of 68.97% and 88.14% for total protein content and enzyme activity, respectively. Considering the approach described in this paper, others advanced materials from pulp fibers and bioprocesses might be developed using bromelain and other enzymes for the target applications.

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Fibers Obtained from Alginate, Chitosan and Hybrid Used in the Development of Scaffolds

Cited by 36 publications

References 27 publications

Polyelectrolyte Multicomponent Colloidosomes Loaded with Nisin Z for Enhanced Antimicrobial Activity against Foodborne Resistant Pathogens

Polyelectrolyte Multicomponent Colloidosomes Loaded with Nisin Z for Enhanced Antimicrobial Activity against Foodborne Resistant Pathogens

3D Encapsulation Made Easy: A Coaxial-Flow Circuit for the Fabrication of Hydrogel Microfibers Patches

Fibers of cellulose sugarcane bagasse with bromelain enzyme immobilized to application in dressing

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