Development of Probiotic Lactobacillus sporogenes Loaded Biological Macromolecules using Novel Assembly Design for Long-term Preservation as Bio-therapeutic Agent
DOI:
https://doi.org/10.37285/ijpsn.2021.14.3.5Abstract
The goal present investigation was to formulate and characterized of biological macromolecules of alginate (ALG) and carboxymethylcellulose sodium (CMC) containing probiotic bacteria of Lactobacillus sporogenes (LS) co-encapsulated with a prebiotics, Bioecolians (α-Gluco-oligosaccharides). The prepared beads were characterized in terms of yield, size, encapsulation efficiency, viabilities in simulated gastric (pH 1.2, 2 hours) and bile (1% w/v, 3 hours) conditions. The beads were also characterized by FTIR, DSC, SEM and XRD to investigate molecular structure, surface properties and morphology of beads. The results showed that spherical beads with size distribution ranging from 1.18 ± 0.11 to 1.45 ± 0.15 mm for ALG and from 1.3 ± 0.12 to 1.5 ± 0.16 mm for ALG-CMC with encapsulation efficiency higher than 90% were achieved. The results indicated that incorporation of carboxymethylcellulose sodium into alginate beads improved viability of the bacteria in simulated gastric conditions as well as bile conditions. According to our in vitro studies, Probiotic beads using combination of ALG-CMC are suitable encapsulating polymer for gastro-intestinal delivery as designed by novel assembly using peristaltic pump for automated production.
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Probiotic, L.Sporogenes, microencapsulation, peristaltic pump, automated productionDownloads
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Anal, A. K. and Singh, H. (2007). Recent advances in microencapsulation of probiotics for industrial applications and targeted delivery. Trends in Food Science & Technology, 18, 240–251.
Atara SA. and Soniwala MM. (2018). Preparation of Budesonide-Pectin Beads Using the Peristaltic Pump, International Journal of Pharmacy and Pharmaceutical Sciences, 10(1).
Boucher J, Daviaud D, Simeon-RM., et al., (2003). Effect of non-digestible gluco-oligosaccharides on glucose sensitivity in high fat diet fed mice. J Physiol Biochem; 59:169-73.
Brakhkova, M.I., Duarte, A., Pinto, J.F., (2009). Evaluation of the viability of Lactobacillus ssp. after the production of different solid dosage forms. J. Pharm. Sci. 98(9), 3329–3339.
Caballero, F., Foradada, M., Mi˜narro, M., et al., (2014). Characterization of alginate beads loaded with ibuprofen lysine salt and optimization of the preparation method. International Journal of Pharmaceutics, 460, 181– 188.
Champagne, C.P. and Fustier, P., (2007). Microencapsulation for the improved delivery of bioactive compounds into foods. Current Opinion in Biotechnology, 18(2), 184– 190.
Chandramouli, V., Kalasapathy, K., Peiris, P., and Jones, M. (2004). An improved method of microencapsulation and its evaluation to protect Lactobacillus spp. in simulated gastric conditions. Journal of Microbiological Methods, 56, 27-35.
Charteris, W.P., Kelly, P.M., Morelli, L., and Collins. J.K. (1998). Development and application of an in vitro methodology to determine the transit tolerance of potentially probiotic Lactobacillus and Bifidobacterium species in the upper human gastrointestinal tract. Journal of Applied Microbiology, 84, 759-768.
De Vrese, M. and Marteau, P.R., (2007). Probiotics and prebiotics: effects on diarrhea. J. Nutr., 137, 803 S–811 S.
Ding, W.K. and Shah, N.P., (2009). Effect of various encapsulating materials on the stability of probiotic bacteria. J. Food Science, 74, M100–M107.
Doleyres, Y. and Lacroix, C., (2005). Technologies with free and immobilized cells for probiotic bifidobacteria production and protection. Int. Dairy J,. 15, 973-988.
Fooks, L.J., Fuller, R. and Gibson, G.R., (1999). Prebiotics, probiotics and human gut microbiology. International Dairy Journal, 9(1), 53–61.
Fujimori S, Gudis K, Mitsui K, Seo T, Yonezawa M, Tanaka S, et al. (2009). A randomized controlled trial on the efficacy of synbiotic versus probiotic or prebiotic treatment to improve the quality of life in patients with ulcerative colitis. Nutrition; 25: 520-5.
Gibson, G.R., (2004). From probiotics to prebiotics and a healthy digestive system. Journal of Food Science, 69(5), M141–M143.
Heidebach, T., Leeb, E., Först, P. and Kulozik, U., (2010). Microencapsulation of probiotic cells. In: Colloids in Biotechnology. CRC-Press/Taylor and Francis, USA. ISBN: 9781439830802.
Ivanova, E., Chipeva, V., Ivanova, I., Dousset, X. and Poncelet, D., (2002). Encapsulation of lactic acid bacteria in calcium alginate beads for bacteriocin production. Journal of Culture Collections 3, 53–58.
Klayraung, S., Viernstein, H. and Okonogi, S., (2009). Developments of tablets containing probiotics: effect of formulation and processing parameters on bacterial viability. Int. J. Pharm. 370 (1–2), 54–60.
Lee, K., Heo, T. (2000). Survival of Bifidobacterium longum immobilized in calcium alginate beads in simulated gastric juices and bile salt solution. Applied and Environmental Microbiology, 66, 869-873.
Liong MT. (2008). Roles of probiotics and prebiotics in colon cancer prevention: postulated mechanisms and in-vivo evidence. Int J Mol Sci; 9: 854-63
Llanes F, Ryan DH and Marchessault RH., (2000). Magnetic nanostructured composites using alginates of different M/G ratios as polymeric matrix. Int J Biol Macromol., 27: 35–40.
Lopez-Rubio, A., Gavara, R., and Lagaron, J.M. (2006). Bioactive packaging: Turning foods into healthier foods through biomaterials. Trends in Food Science and Technology, 17, 567–575.
Malakar J and Nayak A., (2012). Formulation and statistical optimization of multiple-unit ibuprofen loaded buoyant system using 23-factorial design. Chemical Engineering research and design; 90(11): 1834.
Mandal, S., Puniya, A.K. and Singh, K., (2006). Effect of alginate concentrations on survival of microencapsulated Lactobacillus casei NCDC-298. International Dairy Journal 16, 1190–1195.
Patel YL, Sher P and Pawar AP., (2006). The effect of drug concentration and curing time on processing and properties of calcium alginate beads containing metronidazole by response surface methodology. AAPS PharmSciTech, 7(4): Article 86
Prajapati SK, Tripathi P, Ubaidulla U and Anand V., (2008). Design and development of gliclazide mucoadhesive microcapsules: in vitro and in vivo evaluation. AAPS PharmSciTech, 9(1): 224–30
Rane Y, Mashru R, Sankalia M and Sankalia J., (2007). Effect of hydrophilic swellable polymers on dissolution enhancement of carbamazepine solid dispersion studied using response surface methodology. AAPS PharmSciTech, 8(2): 1–11.
Rastall, R.A. and Maitin, V., (2002). Prebiotics and synbiotics: towards the next generation. Current Opinion in Biotechnology, 13(5), 490–496.
Roberfroid MB., (1998). Prebiotics and synbiotics: concepts and nutritional properties. Br J Nutr; 80: S197-202
Rokka, S. and Rantamaki, P., (2010). Protecting probiotic bacteria by microencapsulation: challenges for industrial applications. European Food Research and Technology, 231, 1–12
Rousseau V, Lepargneur JP, Roques C, Remaud-Simeon M and Paul F., (2005). Prebiotic effects of oligosaccharides on selected vaginal lactobacilli and pathogenic microorganisms. Anaerobe; 11:145-53
Saulnier DM, Gibson GR and Kolida S., (2008). In vitro effects of selected synbiotics on the human faecal microbiota composition. FEMS Microbiol Ecol; 66: 516-27
Sharma VK and Bhattacharya A., (2008). Release of metformin hydrochloride from ispaghula-sodium alginate beads adhered on cock intestinal mucosa, Ind J Pharm EduRes; 42: 365–372.
Sohail, A., Turner, M.S., Coombes, A., Bostrom, T. and Bhandari, B., (2011). Survivability of probiotics encapsulated in alginate gel microbeads using a novel impinging aerosols methods. International Journal of Food Microbiology 145, 162–168.
Solanki, H.K. and Shah, D.A., (2016). Formulation optimization and evaluation of probiotic Lactobacillus sporogenes-loaded sodium alginate with carboxymethyl cellulose mucoadhesive beads using design expert software. Journal of Food Processing 2016, 1-14.