Microencapsulation of Ruellia tuberosa L. Extracts Using Alginate: Preparation, Biological Activities, and Release
Andriana Kusuma Pertiwi(1), Choirin Annisa(2), Zubaidah Ningsih(3), Anna Safitri(4*)
(1) Department of Chemistry, Faculty of Mathematics and Natural Sciences, Brawijaya University, Jl. Veteran, Malang 65145, Indonesia
(2) Department of Chemistry, Faculty of Mathematics and Natural Sciences, Brawijaya University, Jl. Veteran, Malang 65145, Indonesia
(3) Department of Chemistry, Faculty of Mathematics and Natural Sciences, Brawijaya University, Jl. Veteran, Malang 65145, Indonesia
(4) Department of Chemistry, Faculty of Mathematics and Natural Sciences, Brawijaya University, Jl. Veteran, Malang 65145, Indonesia; Research Centre of SMONAGENES (Smart Molecules of Natural Genetic Resources), Brawijaya University, Jl. Veteran, Malang 65145, Indonesia
(*) Corresponding Author
Abstract
The bioactive compounds naturally present in plants have great importance due to their biological characteristics. These substances could lose their active characteristics since they are highly unstable. Microencapsulation is one of the techniques to improve stability and protect these compounds. In this work, Ruellia tuberosa L. ethanolic extracts microcapsules were prepared using a freeze-drying method by varying pH, alginate concentration, and stirring time. The encapsulation efficiency (EE), characteristics, alpha-amylase inhibition activity, and release behavior of the microcapsules were investigated. The results highlighted that the highest encapsulation efficiency for the microcapsules was obtained at pH 6, alginate concentration of 1% (w/v), and 30 min of stirring time (51.63% EE). The microcapsules mostly had spherical shapes with a mean diameter of 197.53 μm. The alpha-amylase inhibition assay from microcapsules resulted in the IC50 value of 46.66 ± 0.13 μg/mL, demonstrating high biological activity. The bioactive substances from microcapsules were released during intervals of 30–120 min at pH values of 1.2 and 7.4. Only 3.51% of the bioactive substances were released at pH 1.2 after 120 min, compared to 55.78% at pH 7.4. Overall, this work confirms the possibility of developing plant extracts with preserved biological activity using the produced microcapsules.
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[1] Sholikhah, E.N., 2016, Indonesian medicinal plants as sources of secondary metabolites for pharmaceutical industry, JMedSci, 48 (4), 226–239.
[2] Batubara, I., and Prastya, M.E., 2020, Potential use of Indonesian medicinal plants for cosmetic and oral health: A review, J. Kim. Valensi, 6 (1), 118–132.
[3] Khan, I., Jan, S., Shinwari, Z.K., Ali, M., Khan, Y., and Kumar, T., 2017, Ethnobotany and medicinal uses of folklore medicinal plants belonging to family acanthaceae: An updated review, MOJ Biol. Med., 1 (2), 34–38.
[4] Ramadhan, M., Sabarudin, A., and Safitri, A., 2019, In vitro anti-microbial activity of hydroethanolic extracts of Ruellia tuberosa L.: Eco-friendly based-product against selected pathogenic bacteria, IOP Conf. Ser.: Earth Environ. Sci., 239, 012028.
[5] Safitri, A., Roosdiana, A., Rosyada, I., Evindasari, C.A., Muzayyana, Z., and Rachmawanti, R., 2019, Phytochemicals screening and anti-oxidant activity of hydroethanolic extracts of Ruellia tuberosa L, IOP Conf. Ser.: Mater. Sci. Eng., 509, 012017.
[6] Roosdiana, A., Permata, F.S., Fitriani, R.I., Umam, K., and Safitri A., 2020, Ruellia tuberosa L. extract improves histopathology and lowers malondialdehyde levels and TNF alpha expression in the kidney of streptozotocin-induced diabetic rats, Vet. Med. Int., 2020, 8812758.
[7] Lucas, J., Ralaivao, M., Estevinho, B.N., and Rocha, F., 2020, A new approach for the microencapsulation of curcumin by a spray drying method, in order to value food products, Powder Technol., 362, 428–435.
[8] Rahayu, I., Zainuddin, A., and Hendrana, S., 2020, Improved maleic anhydride grafting to linear low density polyethylene by microencapsulation method, Indones. J. Chem., 20 (5), 1110–1118.
[9] Safitri, A., Roosdiana, A., Kurnianingsih, N., Fatchiyah, F., Mayasari, E., and Rachmawati, R., 2022, Microencapsulation of Ruellia tuberosa L. aqueous root extracts using chitosan-sodium tripolyphosphate and their in vitro biological activities, Scientifica, 2022, 9522463.
[10] Chaemsawang, W., Prasongchean, W., Papadopoulos, K.I., Sukrong, S., Kao, W.J., and Wattanaarsakit, P., 2018, Emulsion cross-linking technique for human fibroblast encapsulation, Int. J. Biomater., 2018, 9317878.
[11] Pedroso-Santana, S., and Fleitas-Salazar, N., 2020, Ionotropic gelation method in the synthesis of nanoparticles/microparticles for biomedical purposes, Polym. Int., 69 (5), 443–447.
[12] He, L., Shang, Z., Liu, H., and Yuan, Z.X., 2020, Alginate-based platforms for cancer-targeted drug delivery, Biomed Res. Int., 2020, 1487259.
[13] Alvarez-Berrios, M.P., Aponte-Reyes, L.M., Diaz-Figueroa, L., Vivero-Escoto, J., Johnston, A., and Sanchez-Rodriguez, D., 2020, Preparation and in vitro evaluation of alginate microparticles containing amphotericin B for the treatment of Candida infections, Int. J. Biomater., 2020, 2514387.
[14] Abasalizadeh, F., Moghaddam, S.V., Alizadeh, E., Akbari, E., Kashani, E., Fazljou, S.M.B., Torbati, M., and Akbarzadeh, A., 2020, Alginate-based hydrogels as drug delivery vehicles in cancer treatment and their applications in wound dressing and 3D bioprinting, J. Biol. Eng., 14 (1), 8.
[15] Pudziuvelyte, L., Marksa, M., Sosnowska, K., Winnicka, K., Morkuniene, R., and Bernatoniene, J., 2020, Freeze-drying technique for microencapsulation of Elsholtzia ciliata ethanolic extract using different coating materials, Molecules, 25 (9), 2237.
[16] Zhao, L., Duan, X., Cao, W., Ren, X., Ren, G., Liu, P., and Chen, J., 2021, Effects of different drying methods on the characterization, dissolution rate and antioxidant activity of ursolic acid-loaded chitosan nanoparticles, Foods, 10 (10), 2470.
[17] Cáceres, L.M., Velasco, G.A., Dagnino, E.P., and Chamorro, E.R., 2020, Microencapsulation of grapefruit oil with sodium alginate by gelation and ionic extrusion: Optimization and modeling of crosslinking and study of controlled release kinetics, Rev. Tecnol. Cienc., 39, 41–61.
[18] Bennacef, C., Desobry-Banon, S., Probst, L., and Desobry, S., 2021, Advances on alginate use for spherification to encapsulate biomolecules, Food Hydrocolloids, 118, 106782.
[19] Farooq, M.A., Ali, S., Hassan, A., Tahir, H.M., Mumtaz, S., and Muntaz, S., 2021, Biosynthesis and industrial applications of α-amylase: A review, Arch. Microbiol., 203 (4), 1281–1292.
[20] Mphahlele, M.J., Agbo, E.N., and Choong, Y.S., 2021, Synthesis, structure, carbohydrate enzyme inhibition, antioxidant activity, in silico drug-receptor interactions and drug-like profiling of the 5-styryl-2-aminochalcone hybrids, Molecules, 26 (9), 2692.
[21] Parhizkar, A., and Asgary, S., 2021, Local drug delivery systems for vital pulp therapy: A new hope, Int. J. Biomater., 2021, 5584268.
[22] Braim, S., Śpiewak, K., Brindell, M., Heeg, D., Alexander, C., and Monaghan, T., 2019, Lactoferrin-loaded alginate microparticles to target Clostridioides difficile infection, J. Pharm. Sci., 108 (7), 2438–2446.
[23] Fauzi, M.A.R.D., Hendradi, E., Pudjiastuti, P., and Widodo, R.T., 2021, Analysis of dissolution of salicylamide from carrageenan based hard-shell capsules: A study of the drug-matrix interaction, Indones. J. Chem., 21 (1), 148–156.
[24] Witzler, M., Vermeeren, S., Kolevatov, R.O., Haddad, R., Gericke, M., Heinze, T., and Schulze, M., 2021, Evaluating release kinetics from alginate beads coated with polyelectrolyte layers for sustained drug delivery, ACS Appl. Bio Mater., 4 (9), 6719–6731.
[25] Chuang, J.J., Huang, Y.Y., Lo, S.H., Hsu, T.F., Huang, W.Y., Huang, S.L., and Lin, Y.S., 2017, Effects of pH on the shape of alginate particles and its release behavior, Int. J. Polym. Sci., 2017, 3902704.
[26] Ramdhan, T., Ching, S.H., Prakash, S., and Bhandari, B., 2019, Time dependent gelling properties of cuboid alginate gels made by external gelation method: Effects of alginate-CaCl2 solution ratios and pH, Food Hydrocolloids, 90, 232–240.
[27] Perkasa, D.P., Erizal, E., Purwanti, T., and Tontowi, A.E., 2018, Characterization of semi-interpenetrated network alginate/gelatin wound dressing crosslinked at Sol Phase, Indones. J. Chem., 18 (2), 367–375.
[28] dos Santos de Macedo, B., de Almeida, T., da Costa Cruz, R., Netto, A.D.P., da Silva, L., Berret, J.F., and Vitorazi, L., 2020, Effect of pH on the complex coacervation and on the formation of layers of sodium alginate and PDADMAC, Langmuir, 36 (10), 2510–2523.
[29] Wibowo, A.A., Suryandari, A.S., Naryono, E., Pratiwi, V.M., Suharto, M., and Adiba, N., 2021, Encapsulation of clove oil within Ca-alginate-gelatine complex: Effect of process variables on encapsulation efficiency, JTKL, 5 (1), 71–77.
[30] Ningsih, Z., Lestari, M.L.A.D., and Maharin, S.A.R., 2021, Preparation and characterization of curcumin nanoemulsion in olive oil-tween 80 system using wet ball milling method, ICS Phys. Chem., 1 (1), 16–19.
[31] Panigrahi, D., Sahu, P.K., Swain, S., and Verma, R.K., 2021, Quality by design prospects of pharmaceuticals application of double emulsion method for PLGA loaded nanoparticles, SN Appl. Sci., 3 (6), 638.
[32] Safitri, A., Roosdiana, A., Hitdatania, E., and Damayanti, S.A., 2022, In vitro alpha-amylase inhibitory activity of microencapsulated Cosmos caudatus Kunth extracts, Indones. J. Chem., 22 (1), 212–222.
[33] Suratman, A., Purwaningsih, D.R., Kunarti, E.S., and Kuncaka, A., 2020, Controlled release fertilizer encapsulated by glutaraldehyde-crosslinked chitosan using freeze-drying method, Indones. J. Chem., 20 (6), 1414–1421.
[34] Oyedemi, S.O., Oyedemi, B.O., Ijeh, I.I., Ohanyerem, P.E., Coopoosamy, R.M., and Aiyegoro, O.A., 2017, Alpha-amylase inhibition and antioxidative capacity of some antidiabetic plants used by the traditional healers in southeastern Nigeria, Sci. World J., 2017, 3592491.
[35] Hsu, P.F., Sung, S.H., Cheng, H.M., Shin, S.J., Lin, K.D., Chong, K., Yen, F.S., Yu, B.H., Huang, C.T., and Hsu, C.C., 2018, Cardiovascular benefits of acarbose vs sulfonylureas in patients with type 2 diabetes treated with metformin, J. Clin. Endocrinol. Metab., 103 (10), 3611–3619.
[36] Chelladurai, G.R.M., and Chinnachamy, C., 2018, Alpha amylase and alpha glucosidase inhibitory effects of aqueous stem extract of Salacia oblonga and its GC-MS analysis, Braz. J. Pharm. Sci., 54 (1), e17151.
[37] Weng, J., Tong, H.H.Y., and Chow, S.F., 2020, In vitro release study of the polymeric drug nanoparticles: Development and validation of a novel method, Pharmaceutics, 12 (8), 732.
[38] Li, L., Li, J., Si, S., Wang, L., Shi, C., Sun, Y., Liang, Z., and Mao, S., 2015, Effect of formulation variables on in vitro release of a water-soluble drug from chitosan–sodium alginate matrix tablets, Asian J. Pharm. Sci., 10 (4), 314–321.
[39] Abbasnezhad, N., Zirak, N., Shirinbayan, M., Tcharkhtchi, A., and Bakir, F., 2021, On the importance of physical and mechanical properties of PLGA films during drug release, J. Drug Delivery Sci. Technol., 63, 102446.
[40] Sreekanth Reddy, O., Subha, M.C.S., Jithendra, T., Madhavi, C., and Chowdoji Rao, K., 2021, Curcumin encapsulated dual cross linked sodium alginate/montmorillonite polymeric composite beads for controlled drug delivery, J. Pharm. Anal., 11 (2), 191–199.
[41] Lengyel, M., Kállai-Szabó, N., Antal, V., Laki, A.J., and Antal, I., 2019, Microparticles, microspheres, and microcapsules for advanced drug delivery, Sci. Pharm., 87 (3), 20.
[42] Thomas, D., Latha, M.S., and Kurienthomas, K., 2018, Zinc-alginate beads for the controlled release of rifampicin, Orient. J. Chem., 34 (1), 428–433.
[43] Moayyedi, M., Eskandari, M.H., Rad, A., Ziaee, E., and Khodaparast, M., 2018, Effect of drying methods (electrospraying, freeze drying and spray drying) on survival and viability of microencapsulated Lactobacillus rhamnosus ATCC 7469, J. Funct. Foods, 40, 391–399.
[44] Makouie, S., Alizadeh, M., Maleki, O., and Khosrowshahi, A., 2019, Optimization of wall components for encapsulation of Nigella sativa seed oil by freeze-drying, IFSTJ, 3 (1), 1–9.
[45] Nandiyanto, A.B.D., Oktiani, R., and Ragadhita, R., 2019, How to read and interpret FTIR spectroscope of organic material, IJoST, 4 (1), 97–118.
[46] Abbas, O., Compère, G., Larondelle, Y., Pompeu, D., Rogez, H., and Baeten, V., 2017, Phenolic compound explorer: A mid-infrared spectroscopy database, Vib. Spectrosc., 92, 111–118.
[47] Kartini, K., Putri, L.A.D., and Hadiyat, M.A., 2020, FTIR-based fingerprinting and discriminant analysis of Apium graveolens from different locations, J. Appl. Pharm. Sci., 10 (12), 62–67.
[48] Nastaj, J., Przewłocka, A., and Rajkowska-Myśliwiec, M., 2016, Biosorption of Ni(II), Pb(II) and Zn(II) on calcium alginate beads: Equilibrium, kinetic and mechanism studies, Polish J. Chem. Technol., 18 (3), 81–87.
[49] Gerasimov, A.M., Eremina, O.V., Cherkasova, M.V., and Dmitriev, S.V., 2021, Application of particle-size analysis in various industries, J. Phys.: Conf. Ser., 1728, 012003.
[50] Pech-Canul, Á.C., Ortega, D., García-Triana, A., González-Silva, N., and Solis-Oviedo, R.L., 2020, A brief review of edible coating materials for the microencapsulation of probiotics, Coatings, 10 (3), 197.
[51] de Freitas Santos, P.D., Rubio, F.T.B., da Silva, M.P., Pinho, L.S., and Favaro-Trindade, C.S., 2021, Microencapsulation of carotenoid-rich materials: A review, Food Res. Int., 147, 110571.
DOI: https://doi.org/10.22146/ijc.76821
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