441–452 (2014).
35. K.J. Robson, M.E. Steward, S. Michelsen, N.D. Lazo, and D.T. Downing, 6-Hydroxy-4-sphingenine in human epidermal ceramides, J. Lipid Res., 35, 2060–2068 (1994).
36. J. van Smeden, M. Janssens, G.S. Gooris, and J.A. Bouwstra, The important role of stratum corneum lipids for the cutaneous barrier function, Biochim. Biophys. Acta, 1841, 295–313 (2014).
37. M.A. Lampe, A.L. Burlingame, J. Whitney, M.L. Williams, B.E. Brown, E. Roitman, and P. Elias, Human stratum corneum lipids: characterization and regional variations, J. Lipid Res., 24, 120–130 (1983).
38. J. van Smeden, M. Janssens, E.C. Kaye, P.J. Caspers, A.P. Lavrijsen, R.J. Vreeken, and J.A. Bouwstra, The importance of free fatty acid chain length for the skin barrier function in atopic eczema patients, Expl. Dermatol., 23, 45–52 (2014).
39. S. Ito, J. Ishikawa, A. Naoe, H. Yoshida, A. Hachiya, T. Fujimura, T. Kitahara, and Y. Takema, Ceramide synthase 4 is highly expressed in involved skin of patients with atopic dermatitis, J. Eur. Acad. Dermatol. Venereol., 31, 135–141 (2017).
40. E. Tamura, J. Ishikawa, A. Naoe, and T. Yamamoto, The roughness of lip skin is related to the ceramide profile in the stratum corneum, Int. J. Cosmet. Sci., 38, 615–621 (2016).
41. R. Hikima, S. Igarashi, N. Ikeda, M. Matsumoto, A. Hanyama, Y. Egawa, T. Horikoshi, and S. Hayashi, Development of lip treatment on the basis of desquamation mechanism, Int. J. Cosmet. Sci., 26, 165 (2004).
42. A. R. Shah and P. M. Kennedy, The aging face, Medical Clinics North America, 102, 1041–1054 (2018).
43. U. Wollina, R. Wetzker, M. B. Abdel-Naser, and I. L. Kruglikov, Role of adipose tissue in facial aging, Clinical Interventions in Aging, 12, 2069–2076 (2017).
44. N. A. Fenske and C. W. Lober, Structural and functional changes of normal aging skin, J. Am. Acad. Dermatol., 15, 571–585 (1986).
45. F. G. Fedok, The aging face, Facial Plast. Surg., 12, 107–115 (1996).
46. S. R. Coleman and R. Grover, The anatomy of the aging face: volume loss and changes in 3-dimensional topography, Aesthetic Surg. J., 26, S4-S9 (2006).
47. S. A. Goldstein and S. M. Goldstein, Anatomic and aesthetic considerations in midfacial rejuvenation, Facial Plast. Surg., 22, 105–111 (2006).
48. K. Sveikata, I. Balciuniene, and J. Tutkuviene, Factors influencing face aging. Literature review., Stomatologia, 13, 113–116 (2011).
49. T. Michaud, V. Gassia, and L. Belhaouari, Facial dynamics and emotional expressions in facial aging treatments, J. Cosmet. Dermatol., 14, 9–21 (2015).
50. B. Mendelson and C.H. Wong, Changes in the facial skeleton with aging: implications and clinical applications in facial rejuvenation, Aesthetic Plast. Surg., 36, 753–760 (2012).
51. L. Ramaut, P. Tonnard, A. Verpaele, K. Verstraete, and P. Blondeel, Aging of the upper lip: Part I: A retrospective analysis of metric changes in soft tissue on magnetic resonance imaging, Plast. Reconstr. Surg., 143, 440–446 (2019).
52. K. R. Beer, Rejuvenation of the lip with injectables, Skin Therapy Lett., 12 (3), 5–7 (2007).
53. U. Wollina, Perioral rejuvenation: restoration of attractiveness in aging females by minimally invasive procedures, Clinical Interventions in Aging, 8, 1149–1155 (2013).
54. H. S. Bui, M. Kanji, and L. Esposito, Shine-imparting hydrating and moisturizing emulsion lipstick composition, US Patent 8597621B2, assigned to L’Oreal SA (2013).
55. G. Kasparaviciene, A. Savickas, Z. Kalveniene, S. Velziene, L. Kubiliene, and J. Bernatoniene, Evaluation of beeswax influence on physical properties of lipstick using instrumental and sensory methods, Evidence-Based Complement. Altern. Med., 8, 1-8 (2016).
56. Standard test method for needle penetration of petroleum waxes, ATSM D1321 (2016).
57. Standard test method for cone penetration of petrolatum, ASTM D937 (2012).
58. C. Richard, B. Tillé-Salmon, and Y. Mofid, Contribution to interplay between a delamination test and a sensory analysis of mid-range lipsticks, Int. J. Cosmet. Sci., 38, 100-108 (2016).
59. B. S. Patel, P. J. Cooper, R. J. Kenny, and G. D. Cook, Method and apparatus for testing semisolid materials, US Patent 20050081607A1, assigned to Wyeth LLC (2004).
60. Beaulax, “What is BIOSKIN?,” 2017. [Online]. Available: http://www.beaulax.co.jp/en/about-bioskin/. [Accessed: 22-Apr-2019].
61. PerkinElmer Inc., “Thermal Analysis of Lipsticks Utilizing DSC,” 2012. [Online]. Available: https://www.perkinelmer.com/lab-solutions/resources/docs/APP_009913B_01_Thermal_Analysis_of_Lipsticks_Utilizing_DSC.pdf. [Accessed: 09-May-2019].
62. J. Latreille, E. Mauger, L. Ambroisine, M. Tenenhaus, M. Vincent, S. Navarro, and C. Guinot, Measurement of the reliability of sensory panel performances, Food Quality and Preference, 17, 369-375 (2005).
63. K. C. Yap and A. Aminah, Sensory analysis of lipstick, Int. J. Cosmet. Sci., 33, 245-250 (2011).
64. T. Jacks and B. Mattox, Solvent-based non-drying lipstick, US Patent 5690918A, assigned to Maybelline Inc. (1997).
65. D.W. Rafferty, L. Dupin, J. Zellia, and A. Giovannitti-Jensen, Predicting lipstick sensory properties with laboratory tests, Int. J. Cosmet. Sci., 40, 451–460 (2018).
66. N. M. P. Videos, “Man. Lip. Vertical section. 100X.” [Online]. Available: https://www.nature-microscope-photo-video.com/en/photos/animal-histology/comparative-histology-of-vertebrates/integumentary-system/mammals/lip/010505c01050505d-man-lip-vertical-section-100x.html.
*Corresponding author: [email protected]
2
Effect of Cosmetic Oils on Lipstick Structure and Its Deposit
Momoko Suzumeji Shimizu1*, Yuta Nomura1 and Hy Si Bui2
1L’Oréal Research and Innovation, Kawasaki, Kanagawa, Japan
2L’Oréal Research and Innovation, Clark, NJ, USA
Abstract
This chapter will review the properties of some common natural waxes, their crystallization behaviors in oil-wax systems and their potential applications for long-lasting properties in cosmetics. Specifically, the impact of oil polarity and viscosity on the lipstick structure and the effect of the wax amount on the deposit will be discussed. Due to the complex and inhomogeneous chemical composition of natural waxes, for a systematic study polyethylene wax was used in an oil-wax system as a simple model to investigate the effect of oil viscosity and oil polarity on the lipstick structure. The results showed that the hardness of the lipstick was affected by both the oil polarity and oil viscosity at a fixed amount of wax. With increasing the oil polarity and viscosity, the oil-wax stick was harder with smaller or close-packed crystals as observed by SEM. These results were found to be very similar to the natural wax-oil gel systems reported in literature. In addition, with increasing oil viscosity, the sensorial perception changed from smooth to watery to sticky, and it did not depend on the oil polarity.
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