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TitleEvaluation of the potential of fucoidan-based microparticles for diabetes treatment
Author(s)Reys, Lara Priscila Lopes
Silva, Simone Santos
Oliveira, Nuno M.
Costa, Diana Pereira Soares
Mano, J. F.
Reis, R. L.
Silva, Tiago José Quinteiros Lopes Henriques
KeywordsDiabetes treatment
Issue dateJul-2016
PublisherAO Research Institute Davos (ARI)
CitationReys L. L., Silva S. S., Soares da Costa D., Oliveira N. M., Mano J. F., Reis R. L., Silva T. H. Evaluation of the potential of fucoidan-based microparticles for diabetes treatment, European Cells & Materials, Vol. 1, Issue 1, pp. P349, 14732262, 2016
Abstract(s)Abstract INTRODUCTION: Marine organisms have in their constitution materials with a wide range of properties and characteristics inspiring their application within the biomedical field. One important example is fucoidan (Fu), an underexploited sulfated polysaccharide extracted from the cell wall of the brown seaweeds, with high solubility in water1. Fucoidan is composed of L- fucose and glucuronic acid including sulfate groups and has important bioactive properties such as antioxidative, anticoagulant, anticancer and in the reduction of blood glucose1,2. In this work, the biomedical potential of fucoidan was assessed by processing modified fucoidan (MFu) into microparticles by photocrosslinking using superhydrophobic surfaces and visible light3,4. Biological performance on the developed constructs using human pancreatic beta cells is currently under investigation. METHODS: To design the materials structures, fucoidan was modified by methacrylation reaction3. Briefly, Fu aqueous solution 4% w/v was mixed with methacrylated anhydride (MA) in volume of 12% v/v at 50oC to react for 6h. Further, MFu particles with and without insulin (0.5% w/v) were produced by pipetting a solution of 5% MFu v/v with triethanolamine and eosin-y (photoinitiators) onto superhydrophobic surfaces4 (Fig. 1A) and then photocrosslinking using visible light4. MFu and developed particles were characterized using 1HNMR, turbidimetry and SEM to assess their chemistry and morphology, respectively. Moreover, the insulin release was evaluated in phosphate buffered saline (PBS) solution at pH 7and simulated intestinal fluid (SIF) at pH 5. The ability of the developed materials to support adhesion and proliferation of cells was assessed by suspension culture of human pancreatic cells 1.1B4 (3.5x105 cells/ml) in contact with MFu microparticles during up to 7 days. RESULTS: The chemical modification performed on Fu was confirmed by the presence of vinyl and additional methyl peaks in the 1HNMR of modified fucoidan, not present in Fu spectrum. Methacrylated fucoidan was obtained with a methacrylation degree of 17%. The produced fucoidan particles have round shape and average diameter of 1.53 mm (Fig. 1B). The insulin release in PBS and SIF demonstrate that the particles can release insulin in a sustained manner under the studied period. It seems that the insulin release is slower for SIF (pH5, Fig. 1C), than for PBS. The biological tests regarding the culture of pancreatic beta cells demonstrate that cells show a round-like shape and tend to form pseudo-islets during the culture period studied (Fig. 1D). DISCUSSION & CONCLUSIONS: This work demonstrates the successful production of fucoidan- based-microparticles through the methacrylation of fucoidan, using visible light and superhydrophobic surfaces. The covalent crosslinking methacrylated fucoidan through visible light represents a promising method to obtain biocompatible fucoidan particles with a uniform round shape. The obtained insulin release profiles are sensitive to different pH (pH7 and pH5), mimicking the normal physiological pathway for insulin release. Furthermore, the results suggest these systems could be used for treatment of type I diabetes mellitus as they sustain beta cells viability and proliferation. The response also suggested, that the MFu particles could be a good candidate as drug delivery vehicles for the diabetes mellitus treatment. REFERENCES: 1 Silva TH et al (2012), Biomatter 2(4): 278:289. 2Sezer Alidemir et al (2011), Fucoidan: A versatile biopolymer for biomedical applicatons (Springer Ber.Heid).pp377-406. 3Mihaila al (2013), Adv. Health. Mat. 2(6): 895-907. 4Rial Hermida et al, Acta Biomater.(2014) 10(10) 4314-4322. ACKNOWLEDGEMENTS: This work was partially funded by projects 0687_NOVOMAR_1_P (POCTEP), CarbPol_u_Algae (EXPL/MAR- BIO/0165/2013), ComplexiTE (ERC-2012-ADG 20120216-321266). Portuguese Foundation for Science and Technology is also gratefully acknowledged for doctoral grants of L. Reys and N. Oliveira and post- doctoral grants of S.S. Silva and D. Soares da Costa
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