Indonesian Journal of Pharmaceutical Science and Technology

Serisin yang merupakan salah satu protein yang terkandung dalam kepompong ulat sutera (Bombyx mori L.) diketahui memiliki kemampuan meningkatkan kelembaban kulit dalam sediaan kosmetik. Tujuan dari penelitian ini yaitu untuk menentukan formula lotion nanopartikel serisin dan efektivitas lotion nanopartikel serisin. Pembentukan nanopartikel serisin secara garis besar dilakukan dengan mekanisme pencampuran dan pengadukan menggunakan urea sebagai agen taut silang. Suhu dan kecepatan pengadukan dijaga konstan, sedangkan durasi pengadukan divariasikan. Nanopartikel serisin optimal yang diperoleh memiliki rata-rata ukuran 701 nm, yang diperoleh pada pengadukan 800 rpm dalam 30 menit di suhu ruang. Kemudian diformulasikan lotion nanopartikel serisin dengan konsentrasi nanopartikel sebesar 5% dan 10%. Hasil yang diperoleh mengindikasikan bahwa lotion dengan konsentrasi nanopartikel serisin 5% dan 10% mampu meningkatkan kelembaban kulit secara signifikan.

Engebretsen KA, Johansen JD, Kezic S, Linneberg A, Thyssen JP. The effect of environmental humidity and temperature on skin barrier function and dermatitis. J Eur Acad Dermatology Venereol. 2016;30(2):223-249.

Cao TT, Zhang YQ. Processing and characterization of silk sericin from Bombyx mori and its application in biomaterials and biomedicines. Mater Sci Eng C. 2016;61:940-952.

Joseph B, Raj SJ. Therapeutic applications and properties of silk proteins from Bombyx mori. Front Life Sci. 2012;6(3–4):55–60.

Padamwar MN, Pawar AP. Silk sericin and its applications: A review. J Sci Ind Res (India). 2004;63(4):323-329.

Takechi T, Wada R, Fukuda T, Harada K, Takamura H. Antioxidant activities of two sericin proteins extracted from cocoon of silkworm (Bombyx mori) measured by DPPH, chemiluminescence, ORAC and ESR methods. Biomed Reports. 2014;2(3):364–9.

Padamwar MN, Pawar AP, Daithankar A V, Mahadik KR. Silk sericin as a moisturizer: an in vivo study. J Cosmet Dermatol. 2005;4(4):250-257.

Zhou C, Shi Y, Sun C, Yu S, Liu M, Gao C. Thin-film composite membranes formed by interfacial polymerization with natural material sericin and trimesoyl chloride for nanofiltration. J Memb Sci. 2014;471:381–91.

Das SK, Dey T, Kundu SC. Fabrication of sericin nanoparticles for controlled gene delivery. RSC Adv. 2014;4(5):2137-2142.

Suktham K, Koobkokkruad T, Wutikhun T, Surassmo S. Efficiency of resveratrol-loaded sericin nanoparticles: Promising bionanocarriers for drug delivery. Int J Pharm. 2018;537(1-2):48-56.

Pushpa A, Vishnu BVG, S TRK. Preparation of Nano Silk Sericin Based Hydrogels From Silk Industry Waste. J Environ Res Dev. 2013;8(2):243-253.

Anarjan N, Jafarizadeh-Malmiri H, Nehdi IA, Sbihi HM, Al-Resayes SI, Tan CP. Effects of homogenization process parameters on physicochemical properties of astaxanthin nanodispersions prepared using a solvent-diffusion technique. Int J Nanomedicine. 2015;10:1109-1118.

Marinho R, Horiuchi L, Pires CA. Effect of stirring speed on conversion and time to particle stabilization of poly (vinyl chloride) produced by suspension polymerization process at the beginning of reaction. Brazilian J Chem Eng. 2018;35(2):631–9.

Mohanraj V, Chen Y. Nanoparticles – A Review. Trop J Pharm Res. 2006;5(1):561-573.

Gyawali R, Paudel N, Shrestha S, Silwal A. Formulation and Evaluation of Antibacterial and Antioxidant Polyherbal Lotion. J Inst Sci Technol. 2016;21(1):148-156.

Zulkarnain AK, Susanti M, Lathifa N. The Physical Stability Of Lotion O/W And W/O From Phaleria Macrocarpa Fruit Extract As Sunscreen And Primary Irritation Test On Rabbit. Tradit Med J. 2015;18(3):141-150.

Danby SG, Chalmers J, Brown K, Williams HC, Cork MJ. A functional mechanistic study of the effect of emollients on the structure and function of the skin barrier. Br J Dermatol. 2016;175(5):1011–9.

Kunz RI, Brancalhão RMC, Ribeiro LDFC, Natali MRM. Silkworm Sericin: Properties and Biomedical Applications. Biomed Res Int. 2016;2016.