Browsing by Subject "Photostability"
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Item Open Access Antioxidant activity and photostability of α-tocopherol/β-cyclodextrin inclusion complex encapsulated electrospun polycaprolactone nanofibers(Elsevier, 2016-06) Aytaç, Zeynep; Uyar, TamerCyclodextrin inclusion complexes (CD-ICs) can be encapsulated into electrospun nanofibers in order to achieve delivery systems having high surface area and highly porous nanofibrous structures. In this study, a well-known antioxidant molecule, α-tocopherol (α-TC) (vitamin E) was chosen as an active agent for inclusion complexation with β-cyclodextrin. Polycaprolactone (PCL) nanofibers encapsulating α-tocopherol/β-cyclodextrin inclusion complex (α-TC/β-CD-IC) which has high antioxidant activity and photostability was produced via electrospinning (PCL/α-TC/β-CD-IC-NF). The formation of α-TC/β-CD-IC was confirmed by XRD. Phase solubility studies showed An-type complex formation between α-TC and β-CD. SEM revealed that bead-free nanofibers were successfully produced from PCL/α-TC/β-CD-IC system. PCL nanofibers encapsulating α-TC without CD-IC was also produced for comparison (PCL/α-TC-NF). Antioxidant test results showed that PCL/α-TC/β-CD-IC-NF had higher antioxidant activity as compared to PCL/α-TC-NF in methanol:water (1:1) system due to the stabilization and solubility increment of α-TC in the cavity of β-CD. PCL/α-TC/β-CD-IC-NF was more stable against UV-light when compared to PCL/α-TC-NF due to the presence of inclusion complexation. In brief, PCL/α-TC/β-CD-IC-NF with the advantages of having nanofibrous structure and encapsulating CD-ICs, may serve as a novel route for administration of α-TC due to its higher antioxidant activity and better UV-light stability.Item Open Access Antioxidant vitamin E/cyclodextrin inclusion complex electrospun nanofibers: enhanced water solubility, prolonged shelf life, and photostability of vitamin E(American Chemical Society, 2017) Çelebioğlu, Aslı; Uyar, TamerHere, we demonstrated the electrospinning of polymer-free nanofibrous webs from inclusion complex (IC) between hydroxypropyl-β-cyclodextrin (HPβCD) and Vitamin E (Vitamin E/HPβCD-IC NF). The inclusion complexation between HPβCD and Vitamin E was prepared by using two different molar ratios (Vitamin E/HPβCD; 1:2 and 1:1), which correspond to theoretical value of ∼13% (w/w) and 26% (w/w) loading of Vitamin E in the nanofiber (NF) matrix. After electrospinning and storage, a very high loading of Vitamin E (up to ∼11% w/w, with respect to fiber matrix) was preserved in Vitamin E/HPβCD-IC NF. Because of the cyclodextrin inclusion complexation, only a minimal weight loss (only ∼2% w/w) was observed. While pure Vitamin E is insoluble in water, Vitamin E/HPβCD-IC NF web has displayed fast-dissolving behavior. Because of the greatly enhanced water-solubility of Vitamin E, Vitamin E/HPβCD-IC NF web has shown effective antioxidant activity. Additionally, Vitamin E/HPβCD-IC NF web has provided enhanced photostability for the sensitive Vitamin E by the inclusion complexation in which Vitamin E/HPβCD-IC NF still kept its antioxidant activity even after exposure to UV-light. Moreover, a 3 year-old Vitamin E/HPβCD-IC NF sample has shown very similar antioxidant efficiency when compared with freshly prepared Vitamin E/HPβCD-IC NF indicating that long-term stability was achieved for Vitamin E in the CD-IC fiber matrix. In brief, our results suggested that polymer-free electrospun Vitamin E/HPβCD-IC nanofibrous webs could have potential applications in food, pharmaceuticals, and healthcare thanks to its efficient antioxidant activity along with enhanced water-solubility, prolonged shelf life, and high photostability of Vitamin E.Item Open Access Quercetin/β-cyclodextrin inclusion complex embedded nanofibres: slow release and high solubility(Elsevier, 2016-04) Aytac Z.; Kusku, S. I.; Durgun, Engin; Uyar, TamerElectrospinning of polyacrylic acid (PAA) nanofibres (NF) incorporating β-cyclodextrin inclusion complex (β-CD-IC) of quercetin (QU) was performed. Here, β-CD was used as not only the crosslinking agent for PAA nanofibres but also as a host molecule for inclusion of QU. The phase solubility test showed enhanced solubility of QU due to the inclusion complexation; in addition, the stoichiometry of QU/β-CD-IC was determined to be 1:1. Computational modelling studies confirmed that 1:1 and 1:2 complex formation are desirable; 1:1 complex formation was chosen to have higher weight loading of QU. SEM images showed that PAA/QU/β-CD-IC-NF were bead-free and uniform. XRD indicated that PAA/QU/β-CD-IC-NF were amorphous in nature without the crystalline peaks of QU. Comparative results revealed that the release profile of QU from PAA/QU/β-CD-IC-NF was much slower but greater in total than from PAA/QU/β-CD-IC-film. Moreover, high antioxidant activity and photostability of QU was achieved in PAA/QU/β-CD-IC-NF.