Scaffolds Containing Spirulina sp. LEB 18 Biomass: Development, Characterization and Evaluation of In Vitro Biodegradation

Schmatz, Daiane Angelica; Uebel, Lívia da Silva; Kuntzler, Suelen Goettems; Dora, Cristiana Lima; Costa, Jorge Alberto Vieira; Morais, Michele Greque de

doi:10.1166/jnn.2016.12331

Cited by 15 publications

(6 citation statements)

References 0 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Scaffold architecture for dental biomaterials: influence of process parameters on the structural morphology of chitosan electrospun fibers INTRoDuCTIoN T he electrospinning is a widely adopted technique used to produce polymeric nanofibers [1].These materials have different mechanical, electrical and thermal propertiesfunctionality [2], and demonstrate potential in many areas, with important structural characteristics for applications in biological systems [3,4].…”

Section: O R I G I N a L A R T I C L Ementioning

confidence: 99%

Scaffold architecture for dental biomaterials: influence of process parameters on the structural morphology of chitosan electrospun fibers

Souza

Sato

Borges

2017

BDS

View full text Add to dashboard Cite

Objective: The electrospinning is a widely adopted technique used to produce the polymeric fibers. The process depends on process parameters (voltage, flow rate and distance from capillary to the collector). The present study aimed to evaluate the influence of these parameters on chitosan fibers, a biopolymer used as scaffolds in dental and oral tissue engineering. Material and Methods: A solution of 7%(m/w) was prepared dissolving 0.7g of chitosan in 7 mL of trifluoroacetic acid (TFA) and 0.3mL of dichloromethane (DCM) (TFA/DCM - 70:30). After 12 hours, polymer solution (5 mL) was drawn into the syringe and pumped through needles of 0.4 mm internal diameter, at a rate of 0.8 mLh-1, different needle-tip-to-collector distances and voltages, for 10 min. Electrospun fibers micrographies were obtained using the Scanning Electron Microscope for morphological analysis. Results: All voltages showed significant difference (p < 0.0001) between them. At 15kV fibers showed higher concentration of beads. At 10 and 12 cm of distance there was no statistical significance (p > 0.0001) but at 15 cm beads formation increased significantly (p < 0.0001). At 12 cm fibers showed lowest fibers diameter in comparison to 10 and 15 cm (p < 0.0001). There was no difference between 10 and 12 cm (p > 0.0001) but in comparison to 15 cm both distances presented significantly difference (p < 0.0001). Conclusion: Thus, it can be concluded that morphology, in chitosan electrospun fibers, is influenced by the voltage and distance and this could describe the mohphological control of these structures. KeywordsChitosan; Fibers; Electrochemical.

show abstract

Section: O R I G I N a L A R T I C L Ementioning

confidence: 99%

Scaffold architecture for dental biomaterials: influence of process parameters on the structural morphology of chitosan electrospun fibers

Souza

Sato

Borges

2017

BDS

View full text Add to dashboard Cite

show abstract

“…PHB and PCL solutions have been combined to make electrospun nanofibers for incorporation of Spirulina sp. LEB 18 (Schmatz et al, 2016).…”

Section: Polymers Natural Polymersmentioning

confidence: 99%

“…Spirulina sp. LEB 18 improved the physical characteristics of the nanofibers, and provided the nanofiber scaffold with reduced healing times and stimulated cell growth (Schmatz et al, 2016). Spirulina biomass was also incorporated into PEO nanofibers, which were suggested as an extracellular matrix for stem-cell culture and future treatment of spinal cord injury (de Morais et al, 2010).…”

Section: Bacteria Fungi Stem Cells and Viruses In Nanofibers Bacteriamentioning

confidence: 99%

Electrospun Nanofibers as Carriers of Microorganisms, Stem Cells, Proteins, and Nucleic Acids in Therapeutic and Other Applications

Stojanov

Berlec

2020

Front. Bioeng. Biotechnol.

124

View full text Add to dashboard Cite

Electrospinning is a technique that uses polymer solutions and strong electric fields to produce nano-sized fibers that have wide-ranging applications. We present here an overview of the use of electrospinning to incorporate biological products into nanofibers, including microorganisms, cells, proteins, and nucleic acids. Although the conditions used during electrospinning limit the already problematic viability/stability of such biological products, their effective incorporation into nanofibers has been shown to be feasible. Synthetic polymers have been more frequently applied to make nanofibers than natural polymers. Polymer blends are commonly used to achieve favorable physical properties of nanofibers. The majority of nanofibers that contain biological product have been designed for therapeutic applications. The incorporation of these biological products into nanofibers can promote their stability or viability, and also allow their delivery to a desired tissue or organ. Other applications include plant protection in agriculture, fermentation in the food industry, biocatalytic environmental remediation, and biosensing. Live cells that have been incorporated into nanofibers include bacteria and fungi. Nanofibers have served as scaffolds for stem cells seeded on a surface, to enable their delivery and application in tissue regeneration and wound healing. Viruses incorporated into nanofibers have been used in gene delivery, as well as in therapies against bacterial infections and cancers. Proteins (hormones, growth factors, and enzymes) and nucleic acids (DNA and RNA) have been incorporated into nanofibers, mainly to treat diseases and enhance their stability. To summarize, incorporation of biological products into nanofibers has numerous advantages, such as providing protection and facilitating controlled delivery from a solid form with a large surface area. Future studies should address the challenge of transferring nanofibers with biological products into practical and industrial use.

show abstract

“…Adicionalmente, a exploração de polissacarídeos para fins de engenharia de tecidos torna a biomassa microalgal uma opção atraente para utilização como biomaterial, nanofibra ou scaffold para implantes, substituição ou reparo de tecidos (Steffens et al 2013;Schmatz et al, 2016). No entanto, a complexidade estrutural dessas macromoléculas dificulta a sua caracterização e consequentemente a elucidação concreta de suas aplicações (Delattre, Pierre, Laroche, & Michaud, 2016;Gaignard et al, 2019;Michaud, 2018;Pierre et al, 2019).…”

Section: Outros Biocompostos Emergentesunclassified

Microalgas e saúde: uma breve revisão / Microalgae and health: a short-review

Nascimento¹,

Lopes²,

Zepka³

2021

BJDV

View full text Add to dashboard Cite

Nos últimos anos tem se revelado uma tendência na busca de alimentos que apresentem, capacidades que vão além da nutrição básica. Nesse sentido a biomassa microalgal tornase uma alternativa promissora. Sua diversidade metabólica aliado ao seu elevado potencial biotecnológico permite a obtenção de diversos bioprodutos incluindo ácidos graxos, aminoácidos e carotenoides com atividades biológicas capazes de modular positivamente a saúde humana. Em face disto, visando avançar o conhecimento científico sobre a aplicação desta biofonte como um alimento/ingrediente funcional essa revisão descreve os principais aspectos relacionados aos biocompostos produzidos por esses microrganismos bem como seu impacto em termos de saúde.

show abstract

Scaffolds Containing Spirulina sp. LEB 18 Biomass: Development, Characterization and Evaluation of In Vitro Biodegradation

Cited by 15 publications

References 0 publications

Scaffold architecture for dental biomaterials: influence of process parameters on the structural morphology of chitosan electrospun fibers

Scaffold architecture for dental biomaterials: influence of process parameters on the structural morphology of chitosan electrospun fibers

Electrospun Nanofibers as Carriers of Microorganisms, Stem Cells, Proteins, and Nucleic Acids in Therapeutic and Other Applications

Microalgas e saúde: uma breve revisão / Microalgae and health: a short-review

Contact Info

Product

Resources

About