Pengaruh Metode Nanoenkapsulasi terhadap Stabilitas Pigmen Karotenoid dan Umur Simpan Minyak dari Buah Merah (Pandanus conoideus L)
Ferdiansyah Ferdiansyah(1*), Heriyanto Heriyanto(2), Christofora Hanny Wijaya(3), Leenawaty Limantara(4)
(1) Departemen Ilmu dan Teknologi Pangan, Fakultas Teknologi Pertanian, Institut Pertanian Bogor, Jl. Raya Darmaga, Bogor 16002
(2) Ma Chung Research Center for Pigment Photosynthesis (MRCPP), Universitas Ma Chung, Jl. Villa Puncak Tidar N-01, Malang 65151
(3) Departemen Ilmu dan Teknologi Pangan, Fakultas Teknologi Pertanian, Institut Pertanian Bogor, Jl. Raya Darmaga, Bogor 16002
(4) Universitas Pembangunan Jaya, Jl. Cendrawasih Raya B7/P, Tangerang Selatan 15413
(*) Corresponding Author
Abstract
The utilization of carotenoid rich red fruit oil for food product development is still limited due to has low solubility in aqueous phase and unstable. Nanoencapsulation was proposed to improve the solubility as well as to retain the stability. This study aimed to determine the capability of nanoencapsulation process in maintaining the stability of carotenoid towards heat and light treatments and to estimate the shelf life of the encapsulant. Ionic gelation method was applied in the nanoencapsulation process using chitosan as a coating agent. Total carotenoid was calculated using Gross equation, while the estimation of shelf life of the product was predicted using Arrhenius model. Particle size of the best nanoencapsulation sample was 70.48 nm with a polydisperse index of 0.02 and zeta potential of 14.80 mV. These physical properties of nanoencapsulant agreed with the results of morphological measurement by TEM. The stability of carotenoid pigment in nanoencapsulant throughout several treatments, such as light (1700 lux, 12 hours), blanching (80 °C, 30 minutes), pasteurization (90 °C, 20 minutes), and sterilization (121 °C, 5 minutes) was higher compared to the stability of emulsion without treatment. The decreasing of total carotenoid in nanoencapsulant for each treatment was 6.92%; 13.51%; 17.77%; and 20.49%, while the reduction in emulsion was 26.33%; 45.25%; 54.46%; and 65.74%, respectively. Nanoencapsulation sample at room temperature (25 °C) has a shelf life of 5.2 months which was longer than the emulsion sample (0.5 months). Nanoencapsulation showed better protection on the stability of carotenoid pigment and increased the shelf life of red fruit oil.
ABSTRAK
Pemanfaatan minyak buah merah yang kaya akan pigmen karotenoid pada produk pangan masih terbatas karena sifatnya kurang larut dalam fase air dan memiliki stabilitas yang rendah. Nanoenkapsulasi diharapkan dapat memperbaiki kelarutan dalam air dan mempertahankan stabilitasnya. Penelitian ini bertujuan untuk mempelajari pengaruh proses nanoenkapsulasi dalam mempertahankan stabilitas pigmen karotenoid minyak buah merah dari pengaruh perlakuan panas dan cahaya, serta memperkirakan umur simpan nanoenkapsulat. Proses nanoenkapsulasi menggunakan metode gelasi dengan kitosan sebagai bahan enkapsulat. Total karotenoid diukur menggunakan persamaan Gross, dan prediksi umur simpan menggunakan model Arrhenius. Ukuran partikel nanoenkapsulasi terbaik mencapai 70,48 nm dengan polidispersi indeks 0,02 dan zeta potensial 14,80 mV. Kriteria fisik nanoenkapsulasi ini didukung oleh hasil pengukuran morfologi menggunakan TEM. Stabilitas pigmen karotenoid pada nanoenkapsulasi dengan perlakuan cahaya (1700 lux, 12 jam), blansir (80 °C, 30 menit), pasteurisasi (90 °C, 20 menit), dan sterilisasi (121 °C, 5 menit) lebih baik dibandingkan emulsi tanpa perlakuan dengan penurunan total karotenoid masing-masing perlakuan sebesar 6,92%; 13,51%; 17,77%; dan 20,49% pada nanoenkapsulasi, sedangkan pada emulsi mencapai 26,33%; 45,25%; 54,46%; dan 65,74%. Sampel nanoenkapsulasi pada suhu ruang (25 °C) memiliki umur simpan 5,2 bulan lebih lama dibandingkan sampel emulsi yang hanya mencapai 0,5 bulan. Metode nanoenkapsulasi dapat mempertahankan stabilitas pigmen karotenoid dan meningkatkan umur simpan minyak buah merah.Keywords
Full Text:
PDFReferences
Afandi, F.A. (2014). Pengaruh Nanoenkapsulasi terhadap Mutu Sensori, Fisikokimia, dan Fisiologiaktif Minuman Fungsional Berbasis Kumis Kucing (Orthosiphon aristatus BI. Miq). Tesis. Fakultas Teknologi Pertanian. Institut Pertanian Bogor. Bogor, Indonesia.
Britton, G.S., Liaaen, H.P. dan Fander (1995). Carotenoids vol 1b: Spectroscopy. Hal: 16. Birkhauser Verlag Boston - Berlin.
Diab, M.A., Adel, Z.E., Mohamed, M. Al-Halawany, dan Dina. M.D.B. (2012). Thermal stability and degradation of chitosan modified by cinamic acid. Open Journal of Polymer Chemistry 2: 14–20.
Dimara, L., Ferdy, S.R. dan Leenawaty, L. (2008). Uji fisika kimia stabilitas pigmen karotenoid pada ekstrak kasar buah merah papua (Pandanus conoideus lam) potensi sebagai pewarna alami. Prodising Seminar Nasional Sains. Hal: 17 - 32. 1 November 2008. Bogor, Indonesia.
Fiedor, J., Fiedor, L., Haessner, R. dan Scheer, H. (2005). Cyclic endoperoxides of β-carotene, potential pro-oxidants, as products of chemical quenching of singlet oxygen. Biochimica et Biophysica Acta 1709: 1–4.
Greiner, R. (2009). Current and projected applications of nanotechnology in the food sector. Nutrire: rev. Soc. Bras. Alim. Nutr. J. Brazilian Soc. Food Nutr, São Paulo. 34: 243–260.
Grenha, A. (2012). Chitosan nanoparticles: a survey of preparation methods. Journal of Drug Targeting 20: 291–300.
Gross, J. (1991). Pigmen in Vegetables. Hal: 100. Van Nastrand Reinhold, New York.
Haryati, T.E., Feronika, H. dan Kgs. Ahmadi. (2015). Pendugaan umur simpan menggunakan metode Accelerated Shelft-life testing (ASLT) dengan pendekatan Arrhenius pada produk tape ketan hitam khas mojokerto hasil sterilisasi. Jurnal Pangan dan Agroindustri 3: 156–165.
Heriyanto, Brotosudarmo, T.H.P. dan Limantara, L. (2011). Spectral analysis in the absorption spectra of fucoxanthin: photo-stability and thermostability studies. Proceeding of HK-ICONS. Hal: 304 - 309. 09 - 11 Juli. Malang, Indonesia.
Hosseini, S.F., Mojgan, Z., Masoud, R. dan Farhid, F. (2013). Two-step method for encapsulation of oregano essential oil in chitosan nanoparticle: preparation, characterization, and in vitro release study. Carbohydrate Polymers 95: 50–56.
Ikawati, R. (2005). Optimasi ekstrasi karotenoid wortel (Daucus carota L.) menggunakan response surface technology (RSM). Jurnal Teknologi Pertanian 1: 14–22.
Indrawati, R., Helen, S., Indriatmoko, Retno, D.E.W. dan Leenawaty, L. (2015). Encapsulation of brown seaweed pigment by freeze drying: characterization and its stability during storage. Journal of Procedia Chemistry 14: 353–360.
John, S. (2014). Nano (micro) encapsulation to protect bioactivity and enhance bioavailbility of bioactive components. [http//:www.http://foodinnova.com]. 10 Mei 2016.
Labuza, T.P. dan Schmidl, M.K. (1985). Accelerated shelf life testing of food. Journal Food Technology 39: 57–62.
Limbongan, J. dan Afrizal, M. (2009). Peluang pengembangan buah merah (Pandanus conoideus Lamk) di Provinsi Papua. Jurnal Litbang Pertanian 28: 134–141.
Lobato, K.B.S, Karina, P., Joana, C.F., Silvia, S.G., Andrea, J. dan Alessandro, O.R. (2013). Characterisation and stability evaluation of bixin carotenoid nanocapsules. Journal Food Chemistry 144: 3906–3912.
Luo, Y., Thomas, T.Y.W, Zi, T., Pei, C., Jianghao, S. dan Qin, W. (2013). Encapsulation of indole-3-carbonil and 3,3-diindolymethane inzein/carboxymethly chitosan nanoparticles with controlled release property and improved stability. Journal Food Chemistry 139: 224–230.
Malvern (2008). A basic guide to particle characterization. Malvern instrument limited inform white paper. http://www.malvern.com/pdf. [14 Mei 2016].
Mohanraj, V.J. dan Chen, Y. (2006). Nanoparticles a review. Tropical Journal of Pharmaceutical Research Article 5: 561–573.
Murkovic, M., Mulleder, U. dan Neunteufl (2002). Carotenoid content in different varieties of pumpkins. Journal of Food Composition and Analysis 15: 633–638.
Parize, A.L., Tereza, C.R.S., Ines, M.C.B., Valfredo, T.F., Mauro, C.M.L., Adaiane, S., dan Elson, L. (2008). Microencapsulation of the natural urucum pigment with chitosan by spray drying in different solvents. African Journal of Biotechnology 7: 3107–3114.
Perdana, F.A., Malik, A.B. dan Mashuri, D. (2011). Sintesis nanopartikel Fe2O3 dengan template PED - 1000 dan karakterisasi sifat magnetiknya. Jurnal Material dan Energi Indonesia 1: 17–23.
Ramadhyastari, A. dan Purwiyanto, H. (2014). Carotene degradation kinetics of carotenoids rich fat powder made from red palm oil. International Joint Seminar and Symposium Tri-University. Hal: 1–4. 2–7 November 2014. Thailand.
Reis, C.P., Ronald, J.N., Antonio, J.R., Francisco, V. (2006). Nanoencapsulation I. Methods for preparation of drug-loaded polymeric nanoparticles. Nanomedicine Journal 2: 8–21.
Sarungallo, Z.L., Purwiyanto, H., Nuri, A., Eko, H.P. dan Mirshuro, W. (2015). Analysis of α-cryptoxanthin, β-cryptoxanthin, α-carotene, and β-carotene of Pandanus conoideus oil by high - performance liquid chromatography (HPLC). Procedia Food Science 3: 231–243.
Syahputra, M.R., Ferry, F.K. dan Leenawaty, L. (2008). Analisis komposisi dan kandungan karotenoid total dan vitamin A fraksi cair dan padat minyak sawit kasar (CPO) menggunakan KCKT detektor PDA. Jurnal Nature Indonesia 10: 89–97.
Tensiska, Nurhadi, B. dan Isfron, A.F. (2012). Kestabilan warna kurkumin terenkapsulasi dari kunyit dalam minuman ringan dan jelly pada berbagai kondisi penyimpanan. Jurnal Ilmu Hayati dan Fisik 14: 196–208.
Wu, Y., Yaguang, L. dan Qin, W. (2012). Antioxidant and antimicrobial properties of essensial oils encapsulated in zein nanoparticles prepared by liquid-liquid dispersion method. Journal Food Science and Technology 48: 283–290.
DOI: https://doi.org/10.22146/agritech.15467
Article Metrics
Abstract views : 6293 | views : 7391Refbacks
- There are currently no refbacks.
Copyright (c) 2017 Ferdiansyah Ferdiansyah, Heriyanto Heriyanto, Christofora Hanny Wijaya, Leenawaty Limantara
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.
agriTECH has been Indexed by:
agriTECH (print ISSN 0216-0455; online ISSN 2527-3825) is published by Faculty of Agricultural Technology, Universitas Gadjah Mada in colaboration with Indonesian Association of Food Technologies.