The Effectiveness of Glycerol Solutions for Optical Clearing of the Intact Skin as Measured by Confocal Raman Microspectroscopy

Optics and Spectroscopy - The effect of glycerol solutions of different concentrations and exposure times on the optical clearing efficiency in intact pig skin has been studied in the analysis of...     

Ultrasound-assisted microencapsulation of jackfruit extract in eco-friendly powder particles: characterization and antiproliferative activity

The aim of the article was to develop stable and safe eco-friendly microcapsules and evaluate their physicochemical properties and their efficiency to protect a jackfruit extract. Eco-friendly microcapsules were produced by ultrasound and spray drying using only three safe ingredients: sucrose ester (SE), miglyol and maltodextrin (DE = 10). Some physicochemical properties, particle morphology, FT-IR, differential scanning calorimetry and antiproliferative activity were determined for microcapsules loaded or not with the jackfuit extract. The results revealed that the encapsulation process by spray drying produced stable microcapsules, with adequate physicochemical and fluid properties for a powder product. The cell viability on the proliferation of M12.C3.F6 cell line was not affected by powder microcapsules without jackfruit extract, indicating that capsules are not toxic for these cells. However, microcapsules with jackfruit extract (100 μg/ml) were able to inhibit significantly the proliferation of M12.C3.F6 cells. These microcapsules can be used for the protection of different compounds sensitive to light, oxygen and/or heat and displaying a very low aqueous solubility.     

Raman Scattering Study of Natural and Synthetic Compounds Containing Polyene Chains

Doklady Physics - The dependence of Raman spectra of the molecules containing polyene chains on the conjugation length, structure of side and end groups, and isomer type is analyzed theoretically.     

Cosmetic Formulations with Melaleuca alternifolia Essential Oil for the Improvement of Photoaged Skin: A Double-Blind,Randomized, Placebo-Controlled Clinical Study

This aim of this study was to evaluate the penetration depth, antioxidant capacity and the clinical efficacy of Melaleuca alternifolia pure essential oil and in a nanoemulsion to prevent skin photoaging. For this, 2% of pure essential oil or 2% of this essential oil in a nanoemulsion were vehiculated in a formulation. The skin penetration was evaluated using confocal Raman microspectroscopy. The radical protection factor was evaluated using electron paramagnetic resonance spectroscopy. For a clinical study, 40 male participants, aged 18–28 years, were enrolled, being divided into three groups: vehicle formulation, M. alternifolia pure essential oil and M. alternifolia Nanoemulsion. All the participants also received a sunscreen SPF 50 to use during the day. Before and after 90 days of study, skin hydrolipidics and morphological characteristics were performed by skin imaging and biophysical techniques. The nanoemulsion presented a lower antioxidant capacity and a higher penetration through the stratum corneum, reaching the viable epidermis, improving the stratum granulosum morphology. The groups presented an increase in the papillary depth, improving in the dermis echogenicity and the collagen fibers. Melaleuca alternifolia essential provides the potential to improve photoaged skin, being the application of nanoemulsion able to reach deeper skin layers.     

Influence of IR radiation on the carotenoid content in human skin

It is shown that the infrared irradiation decreases the content of β-carotene and lycopene carotenoids in human skin. A decrease in the content of β-carotene and lycopene may indicate that the IR radiation, as well as the UV radiation, is capable of forming free radicals in human skin. The investigations were performed in vivo using the technique of resonance Raman scattering developed by us for the noninvasive determination of antioxidant potential in skin.     

Lipid organization and stratum corneum thickness determined in vivo in human skin analyzing lipid–keratin peak (2820–3030 cm−1) using confocal Raman microscopy

While the intercellular lipid structure of the stratum corneum (SC) plays an important role in the skin barrier function, the depth‐dependent profile of the intercellular lipids contributes decisively to deepen the understanding of the skin barrier function, drug penetration, development of skin diseases and their medication. The depth‐dependent profile of the lipids' chemico‐physical properties, such as the solid–fluid phase transition and the order–disorder transition, can exclusively be measured in human skin in vivo by means of confocal Raman microscopy. In the present paper, the lipid–keratin peak (2820–3030 cm⁻¹) was investigated. The lipid‐related Raman peaks centered at 2850 cm⁻¹ and 2880 cm⁻¹ were deconvoluted using Gaussian functions and investigated for their depth‐dependent shape and positional changes. Different fitting procedures show that even an additional Gaussian function cannot be used to fully characterize the lipid's polymethylene chains around 2880 cm⁻¹, which justifies the introduction of the sharpness of the peak centered near 2880 cm⁻¹. The results show that the 2880 cm⁻¹ peak sharpness might be used for determining the SC thickness. The concentration of the lipids with long‐chain carbon backbone (free fatty acids and ceramides) semi‐quantitatively decreases from 10 µm to 20 µm (SC thickness is 19.8 µm). The maximum position and broadness of the Gaussian peak centered at 2850 cm⁻¹ show that near the surface and in the deeper layers of the SC, the state of the lipids is more fluid and disordered compared to the medium layers of the SC. Copyright © 2016 John Wiley & Sons, Ltd.     

In vivo Raman spectroscopic analysis of the influence of UV radiation on carotenoid antioxidant substance degradation of the human skin

It is well known from the literature that carotenoid antioxidant substances decrease after the irradiation of the skin with UV light. Available literature has shown no information about the response time and total dynamics of degradation of carotenoid antioxidants after UV irradiation. The measurements were made with the HPLC method, which is time-consuming and does not give relevant information about the dynamics of degradation of carotenoids in the skin after UV irradiation. With the introduction of new noninvasive spectroscopic methods, it became possible to measure in vivo the behavior of carotenoid antioxidant substances, such as betacarotene and lycopene in the skin after UV light exposure. In the present study, the resonance Raman spectroscopy method was used as a fast and noninvasive optical method to measure the dynamics of degradation of beta-carotene and lycopene in living human skin after UV exposure. It was found that the beta-carotene and lycopene concentration in the skin does not decrease immediately after UV irradiation. There is a time delay, which varies from 30 up to 90 min for beta-carotene and from 0 up to 30 min for lycopene. A strong nonlinear correlation between the individual antioxidant level of volunteers and the magnitude of destruction of antioxidants in the skin was found.     

Copper(II) complexes of the antihypertensive drug nadolol

The complexation of the non-selective β-blocker nadolol, HL, 1 with copper(II) leads to formation of mono-and dinuclear complexes depending mainly on the metal-to-ligand molar ratio. The mononuclear violet complex CuL₂·2Solv, 2, was obtained in a soluble form at metal-to-ligand molar ratio Cu(II): HL ≤ 1: 10 in methanolic or slightly alkaline aqueous solutions. The dinuclear green complex Cu₂L₂Cl₂·H₂O, 3 was synthesized at Cu(II): HL ≥ 1: 2 molar ratio in methanolic solutions. The complexes were studied using spectral (UV-Vis, FT-IR, EPR), magnetochemical, thermogravimetric methods and elemental analysis. In the complexes nadolol acts as a monoanionic bidentate ligand coordinated to copper(II) through the NH-and the deprotonated OH-groups of its aminoalcohol fragment.      

Determination of blood flow to study the penetration of benzyl nicotinate topically applied in different vehicles

The penetration kinetics of topically applied drugs affecting the cutaneous blood flow can be studied by measuring the biological response to the drug using laser Doppler flowmetry noninvasively. In the present study, the kinetics of vasodilation caused by benzyl nicotinate topically applied in two different vehicles was studied by measuring the blood flows of the superficial dermal plexus and the larger deeper capillaries. The drug was topically applied in a balsam and a gel, respectively, on the flexor forearm of 6 male volunteers. Both blood flows measured were correlated with the time. The maximal value (y _max), the time to reach half of this value (t _rise), and the corresponding period Δt were determined. Significantly increased blood flows were measured in the application areas after treatment with both emulsions. No significant differences were observed for any of the parameters comparing the blood flow after application of the gel with that of the treatment using the balsam. These results indicate similar penetration kinetics and pathways of the drug into the skin independent of the vehicle.     

Photobleaching as a method of increasing the accuracy in measuring carotenoid concentration in human skin by Raman spectroscopy

It was shown experimentally that the effect of photobleaching in noninvasive measurement of the Raman spectra of light used in determining the carotenoid concentration in human skin can be used to increase measurement accuracy. Increased accuracy occurs as a consequence of a decrease in the measurable Raman spectra of the wideband fluorescent background intensity when a sample is irradiated by laser radiation. Furthermore, it was demonstrated that, for the spectra of skin from nine volunteers, the fluorescent background intensity can be decreased on average by a factor of 1.4, which leads to an increase in the signal-to-noise ratio for Raman lines of skin carotenoids by a factor of 1.2 on average. The kinetics of photobleaching of humans can be described by biexponential decay with a correlation coefficient close to unity, which agrees with the presented theoretical calculations.