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. 2021 Jul 1;14(13):3691. doi: 10.3390/ma14133691

Table 4.

Method of Vitamin E detection when it is combined with biomaterials.

Technique Combined Material Molecule Detected Method Information Ref.
HPLC UHWMPE α-tocopherol HPLC connected to UV/Vis diode array detector at 297 nm, construction of calibration curve of HPLC peak area. Quantitative [108]
UHWMPE α-tocopherol HPLC connected to UV/Vis diode array detector, construction of calibration curve of absorbance peak area at 290 nm Quantitative [109]
Collagen mesh α-tocopherol HPLC connected to a fluorescence detector, detection at excitation wavelength of 290 nm and emission wavelength of 330 nm Quantitative [112]
Alginate and hyaluronate film α-tocopherol acetate HPLC connected to UV/Vis diode array detector, construction of calibration curve of absorbance peak area at 285 nm Quantitative [44]
Hyaluronic-acid-based β-cyclodextrin copolymer α-tocopherol HPLC connected to UV/Vis diode array detector Quantitative [64]
PNIPAM-b-PCL-b-PNIPAM copolymer α-tocopherol HPLC equipped with a differential refraction index detector Quantitative [65]
UV-VIS UHWMPE α-tocopherol Construction of calibration curve of absorbance peak area at 290 nm Quantitative [110]
UHWMPE α-tocopherol Analysis of reflectance spectra which presents a minimum around 290 nm and a decrease of reflectance at 400–500 nm. Detection [111]
Hyaluronic acid α-tocopherol succinate Construction of calibration curve of absorbance peak area at 285 nm Quantitative [116]
PLA+PCL α-tocopherol acetate Construction of calibration curve of absorbance peak area at 284 nm Quantitative [42]
Colorimetric Assay UHWMPE α-tocopherol The yellowing of the sample was analysed through three parameters (a,b,L) of CIELAB colour space, and a calibration curve of colour distances was constructed. Quantitative [111]
FTIR-ATR UHWMPE α-tocopherol Analysis of peaks.
For quantitative analysis, calibration curve of these peaks is needed.
Analysis of Vitamin E transformation products in polymer samples prior to extraction and quantitative. [108]
Collagen α-tocopherol Analysis of main peaks Characterization of film [45]
FTIR-ATR Magnetite α -tocopheryl succinate Analysis of main peaks Characterization of chemical modification of nanoparticles [71]
Chitosan α-tocopherol Analysis of peaks Physical bonds and chemical interactions are reflected by changes in characteristic spectral peaks. [115]
Chitosan α-tocopherol Analysis of peaks Characterization of nanoparticles [59]
PCL/PLA α-tocopherol acetate Analysis of peaks Characterization of membranes [42]
Soluplus α-tocopherol Analysis of peaks Analysis of bonding between Soluplus/vitamin E [114]
Polyethylene α-tocopherol Analysis of peaks from 600–4000 cm −1 Analysis of interaction between vitamin E and chitosan [113]
XPS Polyethylene α-tocopherol All binding energies were referenced to the C1s peak at 285 eV. Analysis of covalent bonding [113]
DPPH Polyethylene α-tocopherol The scavenging activity was estimated
RSA (%) =
(1 − (A sample/Acontrol)) × 100, measuring the adsorption at 515 nm after 30 min in dark condition.
Radical scavenging activity evaluation [113]
Chitosan α-tocopherol The scavenging activity was estimated
RSA (%) =
(1 − (A sample/Acontrol)) × 100, measuring the adsorption at 517 nm after 30 min in dark condition.
Radical scavenging activity evaluation [115]
Collagen/chitosan α-tocopherol DPPH were measured by the adsorption at 517 nm after 30 min in dark condition. DPPH loss which is a concentration of DPPH radicals reacted with antioxidants. Antioxidant activity [112]
Contact Angle Polyethylene α-tocopherol Contact angle titrations were performed by measuring sets of contact angles at each pH value. Analysis of hydrophobic behaviour as pH increases [106]
PLA α-tocopherol Static contact angle Analysis of material wettability change [48,49]