Preparation of hybrid biomaterials for bone tissue engineering

Costa, Vilma C.; Costa, Hermes S.; Vasconcelos, Wander L.; Pereira, Marivalda M.; Oréfice, Rodrigo Lambert; Mansur, Herman S.

doi:10.1590/s1516-14392007000100006

Cited by 42 publications

(14 citation statements)

References 27 publications

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“…The band at 932 cm − 1 corresponds to the Si-O-Si vibration (silanol groups in pure silica), which disappeared for the tested sample after the bioactivity evaluation due to the formations of an HCA layer. This finding is in agreement with the previous report [33].…”

Section: Resultssupporting

confidence: 94%

See 1 more Smart Citation

Rice husk derived bioactive glass-ceramic as a functional bioceramic: Synthesis, characterization and biological testing

Naghizadeh

Kadir

Doostmohammadi

et al. 2015

Journal of Non-Crystalline Solids

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Section: Resultssupporting

confidence: 94%

“…These bands are similar to the reported data for hybrid PVA/bioactive glass described by Costa V.C. et al [33]. The band at 932 cm − 1 corresponds to the Si-O-Si vibration (silanol groups in pure silica), which disappeared for the tested sample after the bioactivity evaluation due to the formations of an HCA layer.…”

Section: Resultssupporting

confidence: 89%

Rice husk derived bioactive glass-ceramic as a functional bioceramic: Synthesis, characterization and biological testing

Naghizadeh

Kadir

Doostmohammadi

et al. 2015

Journal of Non-Crystalline Solids

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“…Pure PVA (curve a) showed a broad peak at 3100-3600 cm −1 which corresponds to a stretching of -OH group in PVA. [26,28] In the case of the spectrum of PVA/POX NFs with different ratios, the main characteristic peaks of POX (C=O bond stretching) appeared in all PVA/POX NFs (curves c-g). It was found that POX is present in electrospun nanofibers.…”

Section: Resultsmentioning

confidence: 96%

Biodegradable poly(vinyl alcohol)/polyoxalate electrospun nanofibers for hydrogen peroxide-triggered drug release

Phromviyo

Lert-itthiporn

Swatsitang

et al. 2015

Journal of Biomaterials Science, Polymer Edition

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Release of drugs in a controlled and sustainable manner is of great interest for treating some inflammatory diseases, drug delivery, and cosmetics. In this work, we demonstrated the control release of a drug from composite nanofibers mediated by hydrogen peroxide. Composite nanofibers of polyvinyl alcohol (PVA)/polyoxalate (PVA/POX NFs) blended at various weight ratios were successfully prepared by electrospinning. Rhodamine B (RB) was used as a model of drug and was initially loaded into the POX portion. The morphology of NFs was characterized using scanning electron microscopy (SEM). The functional groups presented in the NFs were characterized using IR spectroscopy. In vitro release behavior and cell toxicity of nanofibers were also investigated using the MTT assay. The results indicated that POX content had a significant effect on the size and release profiles of nanofibers. Microstructure analysis revealed that sizes of PVA/POX NFs increased with increasing POX content, ranging from 214 to 422 nm. Release profiles of RB at 37 °C were non-linear and showed different release mechanisms. The mechanism of drug release depended on the chemical composition of the NFs. RB release from the NFs with highest POX content was caused by the degradation of the nanofiber matrix, whereas the RB release in lower POX content NFs was caused by diffusion. The NFs with POX showed a loss of structural integrity in the presence of hydrogen peroxide as seen using SEM. The MTT assay showed that composite nanofibers had minimal cytotoxicity. We anticipate that nanofibrous PVA/POX can potentially be used to target numerous inflammatory diseases that overproduce hydrogen peroxide and may become a potential candidate for use as a local drug delivery vehicle.

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“…However, natural materials often lack the mechanical integrity required whilst synthetic materials are often not biocompatible [50] . Some researchers have sought to overcome these issues by combining favourable elements from both categories to create hybrid materials [51,52] . Even so, not all of these materials are suited to 3D printing.…”

Section: Selecting Suitable Materials For 3d Bioprintingmentioning

confidence: 99%

3D bioprinting for tissue engineering: Stem cells in hydrogels

Mehrban¹,

Teoh²,

Birchall³

2016

International Journal of Bioprinting

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Surgical limitations require alternative methods of repairing and replacing diseased and damaged tissue. Regenerative medicine is a growing area of research with engineered tissues already being used successfully in patients. However, the demand for such tissues greatly outweighs the supply and a fast and accurate method of production is still required. 3D bioprinting offers precision control as well as the ability to incorporate biological cues and cells directly into the material as it is being fabricated. Having precise control over scaffold morphology and chemistry is a significant step towards controlling cellular behaviour, particularly where undifferentiated cells, i.e., stem cells, are used. This level of control in the early stages of tissue development is crucial in building more complex systems that morphologically and functionally mimic in vivo tissue. Here we review 3D printing hydrogel materials for tissue engineering purposes and the incorporation of cells within them. Hydrogels are ideal materials for cell culture. They are structurally similar to native extracellular matrix, have a high nutrient retention capacity, allow cells to migrate and can be formed under mild conditions. The techniques used to produce these materials, as well as their benefits and limitations, are outlined.

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Preparation of hybrid biomaterials for bone tissue engineering

Cited by 42 publications

References 27 publications

Rice husk derived bioactive glass-ceramic as a functional bioceramic: Synthesis, characterization and biological testing

Rice husk derived bioactive glass-ceramic as a functional bioceramic: Synthesis, characterization and biological testing

Biodegradable poly(vinyl alcohol)/polyoxalate electrospun nanofibers for hydrogen peroxide-triggered drug release

3D bioprinting for tissue engineering: Stem cells in hydrogels

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