Click
here to close Hello! We notice that
you are using Internet Explorer, which is not supported by Echinobase
and may cause the site to display incorrectly. We suggest using a
current version of Chrome,
FireFox,
or Safari.
Polymers (Basel)
2023 Nov 14;1522:. doi: 10.3390/polym15224403.
Show Gene links
Show Anatomy links
Poly (ε-caprolactone)-Based Scaffolds with Multizonal Architecture: Synthesis, Characterization, and In Vitro Tests.
Lima TPL
,
Canelas CAA
,
Dutra JDCF
,
Rodrigues APD
,
Brígida RTSS
,
Concha VOC
,
da Costa FAM
,
Passos MF
.
Abstract
Tissue engineering is vital in treating injuries and restoring damaged tissues, aiming to accelerate regeneration and optimize the complex healing process. In this study, multizonal scaffolds, designed to mimic tissues with bilayer architecture, were prepared using the rotary jet spinning technique (RJS scaffolds). Polycaprolactone and different concentrations of alginate hydrogel (2, 4, and 6% m/v) were used. The materials were swollen in pracaxi vegetable oil (PO) (Pentaclethra macroloba) and evaluated in terms of surface morphology, wettability, functional groups, thermal behavior, crystallinity, and cytotoxicity. X-ray diffraction (XRD) showed the disappearance of the diffraction peak 2θ = 31.5° for samples from the polycaprolactone/pracaxi/alginate (PCLOA) group, suggesting a reduction of crystallinity according to the presence of PO and semi-crystalline structure. Wettability gradients (0 to 80.91°) were observed according to the deposition layer and hydrogel content. Pore diameters varied between 9.27 μm and 37.57 μm. Molecular interactions with the constituents of the formulation were observed via infrared spectra with Fourier transform (FTIR), and their influence was detected in the reduction of the maximum degradation temperature within the groups of scaffolds (polycaprolactone/alginate (PCLA) and PCLOA) about the control. In vitro tests indicated reduced cell viability in the presence of alginate hydrogel and PO, respectively.
Alves,
The Fatty Acid Composition of Vegetable Oils and Their Potential Use in Wound Care.
2019, Pubmed
Alves,
The Fatty Acid Composition of Vegetable Oils and Their Potential Use in Wound Care.
2019,
Pubmed
Bahú,
Rotary Jet Spinning (RJS): A Key Process to Produce Biopolymeric Wound Dressings.
2022,
Pubmed
,
Echinobase
Dodero,
Multilayer Alginate-Polycaprolactone Electrospun Membranes as Skin Wound Patches with Drug Delivery Abilities.
2020,
Pubmed
Echeverria Molina,
Novel Electrospun Polycaprolactone/Calcium Alginate Scaffolds for Skin Tissue Engineering.
2022,
Pubmed
Guidoni,
Development and evaluation of a vegetable oil blend formulation for cutaneous wound healing.
2019,
Pubmed
Jarrah,
Alginate hydrogels: A potential tissue engineering intervention for intervertebral disc degeneration.
2023,
Pubmed
Kang,
Functionally graded multilayer scaffolds for in vivo osteochondral tissue engineering.
2018,
Pubmed
Liu,
Fabrication of a bionic asymmetric wettable Cu-doped chitosan-laponite-PCL wound dressing with rapid healing and antibacterial effect.
2022,
Pubmed
Manhezi,
[The use of essential fatty acids in the treatments of wounds].
2008,
Pubmed
Masner,
Linoleic and oleic acids enhance cell migration by altering the dynamics of microtubules and the remodeling of the actin cytoskeleton at the leading edge.
2021,
Pubmed
Merchiers,
Influence of Polymer Concentration and Nozzle Material on Centrifugal Fiber Spinning.
2020,
Pubmed
Mo,
Nano-Hydroxyapatite Composite Scaffolds Loaded with Bioactive Factors and Drugs for Bone Tissue Engineering.
2023,
Pubmed
Morguette,
Hydrogel Containing Oleoresin From Copaifera officinalis Presents Antibacterial Activity Against Streptococcus agalactiae.
2019,
Pubmed
Nobre Lamarão,
Pentaclethra macroloba: A Review of the Biological, Pharmacological, Phytochemical, Cosmetic, Nutritional and Biofuel Potential of this Amazonian Plant.
2023,
Pubmed
Paranhos,
Chitosan Membrane Containing Copaiba Oil (Copaifera spp.) for Skin Wound Treatment.
2021,
Pubmed
Pegoraro,
Oleic acid exhibits an expressive anti-inflammatory effect in croton oil-induced irritant contact dermatitis without the occurrence of toxicological effects in mice.
2021,
Pubmed
Qu,
Biomaterials for bone tissue engineering scaffolds: a review.
2019,
Pubmed
Raddatz,
Development and Application of an Additively Manufactured Calcium Chloride Nebulizer for Alginate 3D-Bioprinting Purposes.
2018,
Pubmed
Rashtchian,
Fabricating alginate/poly(caprolactone) nanofibers with enhanced bio-mechanical properties via cellulose nanocrystal incorporation.
2020,
Pubmed
Santa-María,
Update on Anti-Inflammatory Molecular Mechanisms Induced by Oleic Acid.
2023,
Pubmed
Silva,
PCL/Andiroba Oil (Carapa guianensis Aubl.) Hybrid Film for Wound Healing Applications.
2021,
Pubmed
Simmons,
Use of a topical anhydrous silicone base containing fatty acids from pracaxi oil in a patient with a diabetic ulcer.
2015,
Pubmed
Tan,
Development of alginate-based hydrogels: Crosslinking strategies and biomedical applications.
2023,
Pubmed
Tappa,
Novel Biomaterials Used in Medical 3D Printing Techniques.
2018,
Pubmed
Wu,
Polymeric Scaffolds for Dental, Oral, and Craniofacial Regenerative Medicine.
2021,
Pubmed
Wubneh,
Current state of fabrication technologies and materials for bone tissue engineering.
2018,
Pubmed
Yao,
Biomimetic multilayer polycaprolactone/sodium alginate hydrogel scaffolds loaded with melatonin facilitate tendon regeneration.
2022,
Pubmed
Yu,
Recent development in multizonal scaffolds for osteochondral regeneration.
2023,
Pubmed
Yu,
Asymmetric Wettable Composite Wound Dressing Prepared by Electrospinning with Bioinspired Micropatterning Enhances Diabetic Wound Healing.
2020,
Pubmed
Zhang,
Alginate hydrogel dressings for advanced wound management.
2020,
Pubmed
da Silva,
Antihemorrhagic, antinucleolytic and other antiophidian properties of the aqueous extract from Pentaclethra macroloba.
2005,
Pubmed