Εξώφυλλο

Εφαρμογές των αργίλων στην κοσμητολογία και δερματοφαρμακολογία = Applications of clay use in cosmetology and dermatopharmacology.

Ισμήνη Παναγιώτης Ερμείδη

Περίληψη


Οι άργιλοι κατέχουν ύψιστη σημασία στον τομέα των καλλυντικών σκευασμάτων λόγω των ιδιαίτερων χαρακτηριστικών τους και των ευεργετικών ιδιοτήτων τους για την περιποίηση της επιδερμίδας. Για αιώνες, η χρήση αργίλων ήταν άρρηκτα συνυφασμένη με εφαρμογές όπως η απολέπιση, η απορρόφηση και ο καθαρισμός. Στην παρούσα εργασία θα αναλυθεί εκτενώς η εφαρμογή τους στα καλλυντικά σκευάσματα, στα οποία ο άργιλος δρα ως φυσικός καθαριστής, απομακρύνοντας αποτελεσματικά τους ρύπους, την περίσσεια λιπαρότητας και τις τοξίνες από την επιφάνεια της επιδερμίδας. Η ήπια απολεπιστική της δράση βοηθά στην απομάκρυνση των νεκρών κυττάρων του δέρματος, προάγοντας μια πιο λεία και λαμπερή επιδερμίδα. Επιπλέον, η πλούσια σε μεταλλικά στοιχεία σύνθεση του, θρέφει και αναζωογονεί το δέρμα, προάγοντας μια υγιή λάμψη και βοηθώντας στη διατήρηση της ισορροπημένης ενυδάτωσης. Η επιτυχία της εφαρμογής του έγκειται στην κολλοειδή δομή που ενισχύει την υφή και τη σταθερότητα των καλλυντικών σκευασμάτων, εξασφαλίζοντας μια ομαλή και συνεπή εφαρμογή. Η ευελιξία και η αποτελεσματικότητά τους στην αντιμετώπιση διαφόρων προβλημάτων του δέρματος καθιστούν τους αργίλους απαραίτητα συστατικά στα σύγχρονα καλλυντικά, συμβάλλοντας σημαντικά στη συνολική αποτελεσματικότητα των προϊόντων περιποίησης του δέρματος.

Clays are of great importance in the field of cosmetic formulations due to their special characteristics and their benefits for the skin care. For centuries, the use of clays has been inextricably linked to applications such as exfoliation, absorption and cleansing. In this thesis, their application in cosmetic formulations, in which clay acts as a natural cleanser, effectively removing dirt, excess oil and toxins from the surface of the skin, are presented. Its gentle exfoliating action helps to remove dead skin cells, promoting a smoother and more radiant complexion. In addition, the mineral-rich composition of the clay nourishes and rejuvenates the skin, promoting a healthy glow and helping to maintain balanced hydration. The sure success of their application lies in their colloidal structure that enhances the texture and stability of cosmetic formulations, ensuring a smooth and consistent application. Their versatility and effectiveness in treating various skin problems make clays invaluable and indispensable ingredients in modern cosmetics, contributing significantly to the overall effectiveness of skin care products.

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Αναφορές


Álvarez, A., Santarén, J., Esteban-Cubillo, A., & Aparicio, P. (2011, January 1). Chapter 12 - Current Industrial Applications of Palygorskite and Sepiolite (E. Galàn & A. Singer, Eds.).

Auerbach, S. M., Carrado, K. A., & Dutta, P. K. (2004). Handbook of Layered Materials. In Google Books. CRC Press.

Baek, M., Lee, J.-A., & Choi, S.-J. (2012). Toxicological effects of a cationic clay, montmorillonite in vitro and in vivo. Molecular & Cellular Toxicology, 8(1), 95–101.

Bloise, A., Kusiorowski, R., & Gualtieri, A. (2018). The Effect of Grinding on Tremolite Asbestos and Anthophyllite Asbestos. Minerals, 8(7), 274.

Boudriche, L., Hamdi, B., Kessaïssia, Z., Calvet, R., Chamayou, A., Dodds, J. A., & Balard, H. (2010). An Assessment of the Surface Properties of Milled Attapulgite Using Inverse Gas Chromatography. Clays and Clay Minerals, 58(2), 143–153.

C. del Hoyo, Vicente, M. A., & Rives, V. (1998). Application of phenyl salicylate-sepiolite systems as ultraviolet radiation filters. Clay Minerals, 33(3), 467–474.

Carretero, M. Isabel. (2002). Clay minerals and their beneficial effects upon human health. A review. Applied Clay Science, 21(3-4), 155–163.

Cervini-Silva, J., Ramírez-Apan, M. T., Kaufhold, S., Ufer, K., Palacios, E., & Montoya, A. (2016). Role of bentonite clays on cell growth. Chemosphere, 149, 57–61.

Deer, W. A., Howie, R. A., & Zussman, J. (2013). An Introduction to the Rock-Forming Minerals. In pubs.geoscienceworld.org. Mineralogical Society of Great Britain and Ireland.

Gaikwad, K. K., Singh, S., & Ajji, A. (2018). Moisture absorbers for food packaging applications. Environmental Chemistry Letters, 17(2), 609–628.

Genedy, M., Stormont, J., Matteo, E., & Taha, M. R. (2014). Examining Epoxy-based Nanocomposites in Wellbore Seal Repair for Effective CO2 Sequestration. Energy Procedia, 63, 5798–5807.

Gomes, C., & Rautureau, M. (2021). General Data on Clay Science, Crystallochemistry and Systematics of Clay Minerals, Clay Typologies, and Clay Properties and Applications. Springer EBooks, 195–269.

Groenendyk, D. G., Ferré, T. P. A., Thorp, K. R., & Rice, A. K. (2015). Hydrologic-Process-Based Soil Texture Classifications for Improved Visualization of Landscape Function. PLOS ONE, 10(6), e0131299.

Ivanić, M., Vdović, N., Barreto, S. de, Bermanec, V., & Sondi, I. (2015). Mineralogy, surface properties and electrokinetic behaviour of kaolin clays from the naturally

occurring pegmatite deposits. Geologia Croatica, 68(2), 139–145.

Jayasekera, S., Mewett, J., & Hall, S. (2004). Effects of electrokinetic treatments on the properties of a salt affected soil.

Kumari, N., & Mohan, C. (2021). Basics of Clay Minerals and Their Characteristic Properties.

Liu, P., Du, M., Clode, P. L., Li, H., Liu, J., & Leong, Y.-K. (2020). Surface Chemisty, Microstructure, and Rheology of Thixotropic 1-D Sepiolite Gels. Clays and Clay Minerals, 68(1), 9–22.

Lopezgalindo, A., Viseras, C., & Cerezo, P. (2007). Compositional, technical and safety specifications of clays to be used as pharmaceutical and cosmetic products. Applied Clay Science, 36(1-3), 51–63.

López-Galindo, A., Viseras, C., Aguzzi, C., & Cerezo, P. (2011, January 1). Chapter 13 - Pharmaceutical and Cosmetic Uses of Fibrous Clays (E. Galàn & A. Singer, Eds.).

M Governa, Valentino, M., Visonà, I., Francesca Roversi Monaco, Amati, M., G. Scancarello, & G Scansetti. (1995). In vitro biological effects of clay minerals advised as substitutes for asbestos. Cell Biology and Toxicology, 11(5), 237–249.

M. Schiffenbauer, & G. Stotzky. (1982). Adsorption of coliphages T1 and T7 to clay minerals. Applied and Environmental Microbiology, 43(3), 590–596.

Marchuk, S. (2015). The Dynamics of Potassium in some Australian soils.

Marcos, C., Arango, Y. C., & Rodríguez, I. (2009). X-ray diffraction studies of the thermal behaviour of commercial vermiculites. 42(3-4), 368–378.

McConnochie, K., Bevan, C., Newcombe, R. G., Lyons, J. P., Skidmore, J. W., & Wagner, J. C. (1993). A study of Spanish sepiolite workers. Thorax, 48(4), 370–374.

Mohan, C., & Kumari, N. (2021). Basics of Clay Minerals and Their Characteristic Properties.

Moraes, J. D. D., Bertolino, S. R. A., Cuffini, S. L., Ducart, D. F., Bretzke, P. E., & Leonardi, G. R. (2017). Clay minerals: Properties and applications to dermocosmetic products and perspectives of natural raw materials for therapeutic purposes—A review. International Journal of Pharmaceutics, 534(1-2), 213–219.

Mouzon, J., Bhuiyan, I. U., & Hedlund, J. (2016). The structure of montmorillonite gels revealed by sequential cryo-XHR-SEM imaging. Journal of Colloid and Interface Science, 465, 58–66.

Naman Kantesaria, & Sharma, S. (2020). Exfoliation and Extraction of Nanoclay from Montmorillonite Mineral Rich Bentonite Soil. Springer EBooks, 1–12.

Nascimento, G. M. D. (2021). Clay and Clay Minerals. In Google Books.

Nones, J., Riella, H. G., Trentin, A. G., & Nones, J. (2015). Effects of bentonite on different cell types: A brief review. Applied Clay Science, 105-106, 225–230.

Oliviera, T. R.C., & Paiva, M. P. (2017). Technological Characterization of talc ore from Cacapava Do Sul, RS-BRAZIL for development of a process route.

Park, S.-S., Suh, E.-H., Chae, K.-H., Jang, S. K., & Kim, J.-H. (2015). A Study on Soil Cementation and Calcite Precipitation with Clay as a Medium. Journal of the Korean Geotechnical Society, 31(12), 17–27.

Renier, A., Fleury, J., Monchaux, G., Nebut, M., Bignon, J., & Jaurand, M. C. (1989). Toxicity of an attapulgite sample studied in vivo and in vitro. IARC Scientific Publications, (90), 180–184.

Saidian, M., Godinez, L. J., & Prasad, M. (2016). Effect of clay and organic matter on nitrogen adsorption specific surface area and cation exchange capacity in shales (mudrocks). Journal of Natural Gas Science and Engineering, 33, 1095–1106.

Schaller, C. (2020). Structure & Reactivity: Network Solids.

Sen Gupta, S., & Bhattacharyya, K. G. (2012). Adsorption of heavy metals on kaolinite and montmorillonite: a review. Physical Chemistry Chemical Physics, 14(19), 6698.

Shinsha, H., & Kumagai, T. (2018). Material properties of solidified soil grains produced from dredged marine clay. Soils and Foundations, 58(3), 678–688.

Singer, A., & Huertos, E. G. (2011). Developments in Palygorskite-Sepiolite Research: A New Outlook on These Nanomaterials. In Google Books. Elsevier.

Viseras, C., Sánchez-Espejo, R., Palumbo, R., Liccardi, N., García-Villén, F., Borrego-Sánchez, A., López-Galindo, A. (2021). CLAYS IN COSMETICS AND PERSONAL-CARE PRODUCTS. 69(5), 561–575.

Wang, L., Cho, D.-W., Tsang, D. C. W., Cao, X., Hou, D., Shen, Z., Poon, C. S. (2019). Green remediation of As and Pb contaminated soil using cement-free clay-based stabilization/solidification. Environment International, 126, 336–345.


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