Background:  Nanotechnology has the potential to produce innovations in drug formulation and drug delivery systems. Nanocosmetics and nanocosmeceuticals containing natural ingredients have been proven to overcome the weaknesses of traditional cosmetics and also add value to their formulations.

Objective: This study aims to analyze the application of nanocosmeceutical technology based on ethanol extract of butterfly pea flower (Clitoria Ternatea L) in the preparation of nanoemulsion spray as a skin antiaging agent for the growth of collagen, elastin and extracellular matrix.

Methods Method used true experimental design with posttest control group with random allocation to model mice given UVB radiation. The levels of collagen, elastin, and cellular matrix extract were assessed using Verhoef staining and observed by two experts,

Results: The results of this research show that a nanoemulsion spray preparation of ethanol extract of butterfly pea flower (Clitoria Ternatea L) improves skin damage in aging model mice by increasing the production of extra cellular matrix, collagen and elastin.

Conclusion: The preparation of butterfly pea flower flower extract nanoemulsion sprey (Clitoria Ternate L) has antiaging, collagen and elastin formation activities

Rattanawiwatpong P, Wanitphakdeedecha R, Bumrungpert A, Maiprasert MJJocd. Anti‐aging and brightening effects of a topical treatment containing vitamin C, vitamin E, and raspberry leaf cell culture extract: a split‐face, randomized controlled trial. 2020;19(3):671-6.

Orioli D, Dellambra EJC. Epigenetic regulation of skin cells in natural aging and premature aging diseases. 2018;7(12):268.

Fuchs EJCtidb. Epithelial skin biology: three decades of developmental biology, a hundred questions answered and a thousand new ones to address. 2016;116:357-74.

Luiten KAJARR. Oxidation events and skin aging. 2015;21:16-29.

Gu Y, Han J, Jiang C, Zhang YJArr. Biomarkers, oxidative stress and autophagy in skin aging. 2020;59:101036.

Koohgoli R, Hudson L, Naidoo K, Wilkinson S, Chavan B, Birch‐Machin MAJEd. Bad air gets under your skin. 2017;26(5):384-7.

Quan T, Fisher GJJG. Role of age-associated alterations of the dermal extracellular matrix microenvironment in human skin aging: a mini-review. 2015;61(5):427-34.

Poon F, Kang S, Chien ALJP, photoimmunology, photomedicine. Mechanisms and treatments of photoaging. 2015;31(2):65-74.

Ganceviciene R, Liakou AI, Theodoridis A, Makrantonaki E, Zouboulis CCJD-e. Skin anti-aging strategies. 2012;4(3):308-19.

Zingare ML, Zingare PL, Dubey AK, Ansari MAJIJoP, Sciences B. Clitoria ternatea (Aparajita): a review of the antioxidant, antidiabetic and hepatoprotective potentials. 2013;3(1):203-13.

Montenegro L, Sinico C, Castangia I, Carbone C, Puglisi GJIjop. Idebenone-loaded solid lipid nanoparticles for drug delivery to the skin: In vitro evaluation. 2012;434(1-2):169-74.

Ramos-e-Silva M, Celem LR, Ramos-e-Silva S, Fucci-da-Costa APJCid. Anti-aging cosmetics: Facts and controversies. 2013;31(6):750-8.

Kim J, Cho SY, Kim SH, Cho D, Kim S, Park C-W, et al. Effects of Korean ginseng berry on skin antipigmentation and antiaging via FoxO3a activation. Journal of ginseng research. 2017;41(3):277-83.

Zakaria NNAB. Evaluation of anti-ageing properties of Moringa oliefera Lam., Centella asiatica (L.) Urban, Clitoria ternatea L. and Cosmos caudatus Kunth. for potential application as cosmeceuticals: Newcastle University; 2019.

Abla M, Banga AJIjocs. Formulation of tocopherol nanocarriers and in vitro delivery into human skin. 2014;36(3):239-46.

Karim PL, Aryani IA. Anatomy and histologic of intrinsic aging skin. Bioscientia Medicina: Journal of Biomedicine and Translational Research. 2021;5(11):1065-77.

Panich U, Sittithumcharee G, Rathviboon N, Jirawatnotai S. Ultraviolet radiation-induced skin aging: the role of DNA damage and oxidative stress in epidermal stem cell damage mediated skin aging. Stem cells international. 2016;2016.

Tobin DJ. Introduction to skin aging. Journal of tissue viability. 2017;26(1):37-46.

de Araújo R, Lôbo M, Trindade K, Silva DF, Pereira N. Fibroblast growth factors: a controlling mechanism of skin aging. Skin pharmacology and physiology. 2019;32(5):275-82.

Muthusamy V, Piva TJ. The UV response of the skin: a review of the MAPK, NFκB and TNFα signal transduction pathways. Archives of dermatological research. 2010;302:5-17.

Quan T, Little E, Quan H, Voorhees JJ, Fisher GJ. Elevated matrix metalloproteinases and collagen fragmentation in photodamaged human skin: impact of altered extracellular matrix microenvironment on dermal fibroblast function. The Journal of investigative dermatology. 2013;133(5):1362.

Petruk G, Del Giudice R, Rigano MM, Monti DM. Antioxidants from plants protect against skin photoaging. Oxidative medicine and cellular longevity. 2018;2018.

Fu Y, Li C, Wang Q, Gao R, Cai X, Wang S, et al. The protective effect of collagen peptides from bigeye tuna (Thunnus obesus) skin and bone to attenuate UVB-induced photoaging via MAPK and TGF-β signaling pathways. Journal of Functional Foods. 2022;93:105101.

Mukherjee PK, Kumar V, Kumar NS, Heinrich M. The Ayurvedic medicine Clitoria ternatea—From traditional use to scientific assessment. Journal of ethnopharmacology. 2008;120(3):291-301.

Rai SS, Atanu B, Ankit S, Meenu S. Evaluation of anti-ulcer activity of aqueous and ethanolic extract of whole plant of Clitoria ternatea in albino wistar rats. International Journal of Pharmaceutical Sciences and Drug Research. 2015;7(1):33-9.

Davinelli S, Bertoglio JC, Polimeni A, Scapagnini GJCPD. Cytoprotective polyphenols against chronological skin aging and cutaneous photodamage. 2018;24(2):99-105.

Chuang S-Y, Lin Y-K, Lin C-F, Wang P-W, Chen E-L, Fang J-YJN. Elucidating the skin delivery of aglycone and glycoside flavonoids: How the structures affect cutaneous absorption. 2017;9(12):1304.

Ryeom GGM, Bang WJ, Kim YB, Lee GE. Gallotannin improves the photoaged-related proteins by extracellular signal-regulated kinases/c-Jun N-terminal kinases signaling pathway in human epidermal keratinocyte cells. Journal of medicinal food. 2018;21(8):785-92.