343 Application of Reverse Micelles in Cosmetic Formulations (38) P. Calandra, C. Giordano, A. Ruggirello, V.T. Liveri, Physicochemical investigation of acrylamide solubilization in sodium bis(2-ethylhexyl)sulfosuccinate and lecithin reversed micelles, Journal of Colloid Interface Science, 277(1), 206–214 (2004). (39) R. Bermejo, E.M. Talavera, C. delValle, J.M. Alvarez-Pez, C-phycocyanin incorporated into reverse micelles: a fluorescence study, Colloids and Surfaces B: Biointerfaces, 18 (1), 51–59 (2000). (40) Y. Liu, F. Zhao, J. Dun, X. Qi, D. Cao, Lecithin/isopropyl myristate reverse micelles as transdermal insulin carriers: Experimental evaluation and molecular dynamics simulation, Journal of Drug Delivery Science and Technology, 59, 101891 (2020). (41) J.L. Gębicki, M. Szymańska-Owczarek, B. Pacholczyk-Sienicka, S. Jankowski, Ascorbyl radical disproportionation in reverse micellar systems, Radiation Physics and Chemistry, 145, 174–179 (2018). (42) M.D.P. Garcia-Mendoza, F.A. Espinosa-Pardo, R. Savoire, C.H. Schiavo, M. Cansell, P. Subra-Paternault, Improvement of the oxidative stability of camelina oil by enrichment with phospholipid-quercetin formulations, Food Chemistry, 341(1), 128234 (2021). (43) D. Duscher, A.A. Trotsyuk, Z.N. Maan, S.H. Kwon, M. Rodrigues, K. Engel, Z.A.S. Buchbinder, C.A. Bonham, J. Barrera, A.J. Whittam, M.S. Hu, M. Inayathullah, J. Rajadas, G.C. Gurtner, Optimization of transdermal deferoxamine leads to enhanced efficacy in healing skin wounds, Journal of Control Release, 308, 232–239 (2019). (44) O. Fadel, L. Girard, D.G. Rodrigues, P. Bauduin, X.L. Goff, A.R. Castera, A.L. Hermitte, O. Diat, Micellization in vegetable oils: A structural characterisation, Colloids and Surfaces B: Biointerfaces, 154, 279–286 (2017). (45) E.P. Premarathne, D.N. Karunaratne, A.D. Perera, Controlled release of diclofenac sodium in glycolipid incorporated micro emulsions, International Journal of Pharmaceuticals, 511(2), 890–898 (2016). (46) J.S. Yuan, A. Yip, N. Nguyen, J. Chu, X.Y. Wen, E.J. Acosta, Effect of surfactant concentration on transdermal lidocaine delivery with linker microemulsions, International Journal of Pharmaceuticals, 392(1–2), 274–284 (2010). (47) C. Padula, S. Nicoli, P. Santi, Innovative formulations for the delivery of levothyroxine to the skin, Int J Pharm, 372(1–2), 12–16 (2009). (48) M. Varshney, T. Khanna, M. Changez, Effects of AOT micellar systems on the transdermal permeation of glyceryl trinitrate, Colloids and Surfaces B: Biointerfaces, 13(1), 1–11 (1999). (49) S.H. Seo, J.Y. Chang, Organogels from 1H-imidazole amphiphiles: Entrapment of a hydrophilic drug into strands of the self-assembled amphiphiles, Chemistry of Materials, 17(12), 3249–3254 (2005). (50) D-G. Park, E-J. Oh, E-A. Chu, K-S. Jin, S.K. Cho, H-Y. Lee, Effect of temperature on the reverse self- assembly of lecithin and sugar alcohol mixtures in a nonpolar solvent, Journal of Molecular Liquids, 347, 118384 (2022). (51) Y-G. Jung, C-R. Lee, H-J. Kim, M-g. Kim, K.S. Jin, H-Y. Lee, Effect of hydrocarbon chain length of aliphatic solvents on the reverse self-assembly of lecithin and monovalent ion mixtures, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 607, 125441 (2020). (52) M. Imai, K. Hashizaki, H. Taguchi, Y. Saito, S. Motohashi, A new reverse worm-like micellar system from a lecithin, multivalent carboxylic acid and oil mixture, Journal Colloid Interface Science, 403, 77–83 (2013). (53) E. Esposito, L. Ravani, P. Mariani, C. Puglia, S. Mazzitelli, N. Huang, R. Cortesi, C. Nastruzzi, Gelified reverse micellar dispersions as percutaneous formulations, Journal of Drug Delivery Science and Technology, 32, 270–282 (2016). (54) E.E. Simsolo, I. Eroglu, S.T. Tanriverdi, O. Özer, Formulation and evaluation of organogels containing hyaluronan microparticles for topical delivery of caffeine, AAPS PharmSciTech, 19(3), 1367–1376 (2018). (55) A. Bhatia, B. Singh, K. Raza, S. Wadhwa, O.P. Katare, Tamoxifen-loaded lecithin organogel (LO) for topical application: Development, optimization and characterization, International Journal of Pharmaceuticals, 444(1–2), 47–59 (2013). (56) O.P. Agrawal, S. Agrawal, An overview of new drug delivery system: microemulsion, Asian Journal of Pharmaceutical Science &Technology, 2(1), 5–12 (2012).

344 JOURNAL OF COSMETIC SCIENCE (57) K.A. Kosakowska, B.K. Casey, S.L. Kurtz, L.B. Lawson, S.M. Grayson, Evaluation of amphiphilic star/ linear–dendritic polymer reverse micelles for transdermal drug delivery: Directing carrier properties by tailoring core versus peripheral branching, Biomacromolecules, 19(8), 3163–3176 (2018). (58) J.S. Yuan, E.J. Acosta, Extended release of lidocaine from linker-based lecithin microemulsions, International Journal of Pharmaceutics, 368(1–2), 63–71 (2009). (59) Z-H. Cai, J-D. Wang, L-T. Wang, S Zhang, X-Y. Yan, Y-Q. Wang, P-Q. Zhao, L-N. Fu, C-J. Zhao, Q. Yang, D. Meng, Y-J. Fua, Green efficient octanoic acid based supramolecular solvents for extracting active ingredients from Zanthoxylum bungeanum Maxim. peels, Journal of Cleaner Production, 331, 129731 (2022). (60) X. Zhao, H. Liu, X. Zhang, H. Zhu, Comparison of structures of walnut protein fractions obtained through reverse micelles and alkaline extraction with isoelectric precipitation, International Journal of Biological Macromolecules, 125, 1214–1220 (2019). (61) S. Fathiyah Sy Mohamad, F. Mohd Said, M. Sakinah Abdul Munaim, S. Mohamad, W. Mohd. Azizi Wan Sulaiman, Fractional factorial analysis for identifying significant factors in extraction of jacalin from jackfruit seeds using anionic reverse micellar system, Materials Today: Proceedings, 19, 1638–1646 (2019). (62) J. Guo, Z. Miao, J. Wan, X. Guo, Pineapple peel bromelain extraction using gemini surfactant-based reverse micelle – Role of spacer of gemini surfactant, Separation and Purification Technology, 190, 156–164 (2018). (63) X. Zhao, X. Zhang, H. Liu, G. Zhang, Q. Ao, Functional, nutritional and flavor characteristic of soybean proteins obtained through reverse micelles, Food Hydrocolloids, 74, 358–366 (2018). (64) S. Li, X. Cao, Extraction of tea polysaccharides (TPS) using anionic reverse micellar system, Separation and Purification Technology, 122, 306–314 (2014). (65) X. Peng, X-Z. Yuan, G-M. Zeng, H-J. Huang, H. Wang, H. Liu, S. Bao, Y-J. Ma, K-L. Cui, L-J. Leng, Z-H. Xiao, Synchronous extraction of lignin peroxidase and manganese peroxidase from Phanerochaete chrysosporium fermentation broth, Separation and Purification Technology, 123, 164–170 (2014). (66) J. Shi, L. Chen, Determination of Rhodamine B in lipsticks by high performance liquid chromatography after extraction with AOT reversed micelles, Analytical Methods, 6(21), 8627–8632 (2014). (67) J.A. Gutierrez, J.J. Silber, R.D. Falcone, N.M. Correa, Modified reverse micelle method as facile way to obtain several gold nanoparticle morphologies, Journal of Molecular Liquids, 331, 115709 (2021). (68) M.G. Spirin, S.B. Brichkin, V.F. Razumov, Studies on absorption spectra of uniform gold nanoparticles prepared in Triton X-100 reverse micelles, Journal of Photochemistry and Photobiology A: Chemistry, 196 (2–3), 174–179 (2008). (69) F.A. Bezza, S.M. Tichapondwa, E.M.N. Chirwa, Synthesis of biosurfactant stabilized silver nanoparticles, characterization and their potential application for bactericidal purposes, Journal of Hazardous Materials, 393, 122319 (2020). (70) P.S. Popovetskiy, D.I. Beketova, Silver nanoparticles stabilized by AOT and Tergitol NP-4 mixture: Influence of composition on electrophoretic concentration, properties of concentrated organosols and conductivity of films, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 568, 51–58 (2019). (71) B.A. Çakır, L. Budama, Ö. Topel, N. Hoda, Synthesis of ZnO nanoparticles using PS-b-PAA reverse micelle cores for UV protective, self-cleaning and antibacterial textile applications, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 414, 132–139 (2012). (72) M.S. Orellano, C. Porporatto, J.J. Silber, R.D. Falcone, N.M. Correa, AOT reverse micelles as versatile reaction media for chitosan nanoparticles synthesis, Carbohydrate Polymers, 171, 85–93 (2017).