The effect of hydration on the material and mechanical properties of cellulose nanocrystal-alginate composites

Carbohydrate Polymers

Volumn 179, Issue , 2018, Pages 186-195

  Smyth, Megan ^a,b   M'Bengue, Marie Stella ^a,b   Terrien, Maxime ^a   Picart, Catherine ^b,c,d   Bras, Julien ^a,b,d   Foster, E Johan ^e  

^a CNRS   (France)

^b UNIV GRENOBLE ALPES   (France)

^c LABORATOIRE DES MATÉRIAUX ET DU GÉNIE PHYSIQUE   (France)

^d INSTITUT UNIVERSITAIRE DE FRANCE   (France)

^e Virginia Polytechnic Institute and State University   (United States)

Author keywords

Alginate; Cellulose nanocrystals; Humidity; Mechanical properties; Nanocomposite; Physiological conditions; Water immersion

Indexed keywords

ATMOSPHERIC HUMIDITY; CELL CULTURE; CELLULOSE; CELLULOSE DERIVATIVES; CELLULOSE FILMS; DEIONIZED WATER; LIQUIDS; MECHANICAL PROPERTIES; MECHANICAL TESTING; MEDICAL APPLICATIONS; NANOCOMPOSITES; NANOCRYSTALS; STEM CELLS;

BIOMEDICAL APPLICATIONS; CELLULOSE NANO-CRYSTALS; MECHANICAL AND MATERIAL PROPERTIES; MESENCHYMAL STEM CELL; OXIDIZED NANOCELLULOSE; PHOSPHATE BUFFER SOLUTIONS; PHYSIOLOGICAL CONDITION; WATER IMMERSION;

ALGINATE;

ALGINATES; CELLULOSE; COMPOSITES; HUMIDITY; MECHANICAL PROPERTIES;

EID: 85030482215     PISSN: 01448617     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.carbpol.2017.09.002     Document Type: Article

References (67)

1. Abdollahi, M., Alboofetileh, M., Rezaei, M., Behrooz, R., Comparing physico-mechanical and thermal properties of alginate nanocomposite films reinforced with organic and/or inorganic nanofillers. Food Hydrocolloids 32:2 (2013), 416–424.
2. Alsberg, E., Kong, H., Hirano, Y., Smith, M., Albeiruti, A., Mooney, D., Regulating bone formation via controlled scaffold degradation. Journal of Dental Research 82:11 (2003), 903–908.
3. Annamalai, P.K., Dagnon, K.L., Monemian, S., Foster, E.J., Rowan, S.J., Weder, C., Water-Responsive mechanically adaptive nanocomposites based on Styrene?Butadiene rubber and cellulose nanocrystals processing matters. ACS Applied Materials & Interfaces 6:2 (2014), 967–976.
4. Araki, J., Wada, M., Kuga, S., Steric stabilization of a cellulose microcrystal suspension by poly(ethylene glycol) grafting. Langmuir 17:1 (2001), 21–27.
5. Azizi Samir, M.A.S., Alloin, F., Dufresne, A., Review of recent research into cellulosic whiskers, their properties and their application in nanocomposite field. Biomacromolecules 6:2 (2005), 612–626.
6. Bajpai, S.K., Sharma, S., Investigation of swelling/degradation behaviour of alginate beads crosslinked with Ca2+ and Ba2+ ions. Reactive and Functional Polymers 59:2 (2004), 129–140.
7. Barnett, S., Varley, S., The effects of calcium alginate on wound healing. Annals of the Royal College of Surgeons of England, 69(4), 1987, 153.
8. Bilbao-Sainz, C., Bras, J., Williams, T., Sénechal, T., Orts, W., HPMC reinforced with different cellulose nano-particles. Carbohydrate Polymers 86:4 (2011), 1549–1557.
9. Boateng, J.S., Matthews, K.H., Stevens, H.N., Eccleston, G.M., Wound healing dressings and drug delivery systems: a review. Journal of Pharmaceutical Sciences 97:8 (2008), 2892–2923.
10. Bouhadir, K.H., Lee, K.Y., Alsberg, E., Damm, K.L., Anderson, K.W., Mooney, D.J., Degradation of partially oxidized alginate and its potential application for tissue engineering. Biotechnology Progress 17:5 (2001), 945–950.
11. Camarero-Espinosa, S., Boday, D.J., Weder, C., Foster, E.J., Cellulose nanocrystal driven crystallization of poly (d, l-lactide) and improvement of the thermomechanical properties. Journal of Applied Polymer Science, 132(10), 2015.
12. Cheng, F., Liu, C., Wei, X., Yan, T., Li, H., He, J., et al. Preparation and characterization of 2, 2, 6, 6-Tetramethylpiperidine-1-oxyl (TEMPO)-Oxidized cellulose Nanocrystal/Alginate biodegradable composite dressing for hemostasis applications. ACS Sustainable Chemistry & Engineering 5:5 (2017), 3819–3828.
13. Choi, B., Park, H.J., Hwang, S., Park, J., Preparation of alginate beads for floating drug delivery system: effects of CO 2 gas-forming agents. International Journal of Pharmaceutics 239:1 (2002), 81–91.
14. da Silva Perez, D., Montanari, S., Vignon, M.R., TEMPO-mediated oxidation of cellulose III. Biomacromolecules 4:5 (2003), 1417–1425.
15. Drury, J.L., Mooney, D.J., Hydrogels for tissue engineering: scaffold design variables and applications. Biomaterials 24:24 (2003), 4337–4351.
16. Drury, J.L., Dennis, R.G., Mooney, D.J., The tensile properties of alginate hydrogels. Biomaterials 25:16 (2004), 3187–3199.
17. Favier, V., Canova, G., Cavaillé, J., Chanzy, H., Dufresne, A., Gauthier, C., Nanocomposite materials from latex and cellulose whiskers. Polymers for Advanced Technologies 6:5 (1995), 351–355.
18. Favier, V., Dendievel, R., Canova, G., Cavaille, J., Gilormini, P., Simulation and modeling of three-dimensional percolating structures: case of a latex matrix reinforced by a network of cellulose fibers. Acta Materialia 45:4 (1997), 1557–1565.
19. Fukuzumi, H., Saito, T., Iwata, T., Kumamoto, Y., Isogai, A., Transparent and high gas barrier films of cellulose nanofibers prepared by TEMPO-Mediated oxidation. Biomacromolecules 10:1 (2008), 162–165.
20. George, M., Abraham, T.E., Polyionic hydrocolloids for the intestinal delivery of protein drugs: alginate and chitosan—a review. Journal of Controlled Release 114:1 (2006), 1–14.
21. Gombotz, W.R., Wee, S.F., Protein release from alginate matrices. Advanced Drug Delivery Reviews 64 (2012), 194–205.
22. Grant, G.T., Morris, E.R., Rees, D.A., Smith, P.J., Thom, D., Biological interactions between polysaccharides and divalent cations: the egg-box model. FEBS Letters 32:1 (1973), 195–198.
23. Hoeng, F., Denneulin, A., Neuman, C., Bras, J., Charge density modification of carboxylated cellulose nanocrystals for stable silver nanoparticles suspension preparation. Journal of Nanoparticle Research, 17(6), 2015, 244.
24. Hubbe, M.A., Rojas, O.J., Lucia, L.A., Sain, M., Cellulosic nanocomposites: a review. BioResources 3:3 (2008), 929–980.
25. Huq, T., Salmieri, S., Khan, A., Khan, R.A., Le Tien, C., Riedl, B., et al. Nanocrystalline cellulose (NCC) reinforced alginate based biodegradable nanocomposite film. Carbohydrate Polymers 90:4 (2012), 1757–1763.
26. Huq, T., Fraschini, C., Khan, A., Riedl, B., Bouchard, J., Lacroix, M., Alginate based nanocomposite for microencapsulation of probiotic: effect of cellulose nanocrystal (CNC) and lecithin. Carbohydrate Polymers 168 (2017), 61–69.
27. Jorfi, M., Foster, E.J., Recent advances in nanocellulose for biomedical applications. Journal of Applied Polymer Science, 132(14), 2015, 41719.
28. Jorfi, M., Roberts, M.N., Foster, E.J., Weder, C., Physiologically responsive, mechanically adaptive bio-nanocomposites for biomedical applications. ACS Applied Materials & Interfaces 5:4 (2013), 1517–1526.
29. Kanjanamosit, N., Muangnapoh, C., Phisalaphong, M., Biosynthesis and characterization of bacteria cellulose?alginate film. Journal of Applied Polymer Science 115:3 (2010), 1581–1588.
30. Kuo, C.K., Ma, P.X., Ionically crosslinked alginate hydrogels as scaffolds for tissue engineering: part 1. Structure, gelation rate and mechanical properties. Biomaterials 22:6 (2001), 511–521.
31. Lee, K.Y., Mooney, D.J., Hydrogels for tissue engineering. Chemical Reviews 101:7 (2001), 1869–1880.
32. Lee, K.Y., Mooney, D.J., Alginate: properties and biomedical applications. Progress in Polymer Science 37:1 (2012), 106–126.
33. Lee, K.Y., Rowley, J.A., Eiselt, P., Moy, E.M., Bouhadir, K.H., Mooney, D.J., Controlling mechanical and swelling properties of alginate hydrogels independently by cross-linker type and cross-linking density. Macromolecules 33:11 (2000), 4291–4294.
34. Lemahieu, L., Bras, J., Tiquet, P., Augier, S., Dufresne, A., Extrusion of nanocellulose-Reinforced nanocomposites using the dispersed nano-Objects protective encapsulation (DOPE) process. Macromolecular Materials and Engineering 296:11 (2011), 984–991.
35. Li, Z., Ramay, H.R., Hauch, K.D., Xiao, D., Zhang, M., Chitosan–alginate hybrid scaffolds for bone tissue engineering. Biomaterials 26:18 (2005), 3919–3928.
36. Lin, N., Dufresne, A., Surface chemistry, morphological analysis and properties of cellulose nanocrystals with gradiented sulfation degrees. Nanoscale 6:10 (2014), 5384–5393.
37. Lin, N., Bruzzese, C., Dufresne, A., TEMPO-oxidized nanocellulose participating as crosslinking aid for alginate-based sponges. ACS Appl Mater Interfaces 4:9 (2012), 4948–4959.
38. Ma, X., Li, R., Zhao, X., Ji, Q., Xing, Y., Sunarso, J., et al. Biopolymer composite fibres composed of calcium alginate reinforced with nanocrystalline cellulose. Composites Part A: Applied Science and Manufacturing 96 (2017), 155–163.
39. Mariano, M., El Kissi, N., Dufresne, A., Cellulose nanocrystals and related nanocomposites: review of some properties and challenges. Journal of Polymer Science Part B: Polymer Physics 52:12 (2014), 791–806.
40. Mariano, M., El Kissi, N., Dufresne, A., Cellulose nanocrystal reinforced oxidized natural rubber nanocomposites. Carbohydrate Polymers 137 (2016), 174–183.
41. Mathew, A.P., Oksman, K., Sain, M., The effect of morphology and chemical characteristics of cellulose reinforcements on the crystallinity of polylactic acid. Journal of Applied Polymer Science 101:1 (2006), 300–310.
42. Montanari, S., Roumani, M., Heux, L., Vignon, M.R., Topochemistry of carboxylated cellulose nanocrystals resulting from TEMPO-mediated oxidation. Macromolecules 38:5 (2005), 1665–1671.
43. Moon, R.J., Martini, A., Nairn, J., Simonsen, J., Youngblood, J., Cellulose nanomaterials review: structure, properties and nanocomposites. Chemical Society Reviews 40:7 (2011), 3941–3994.
44. Oksman, K., Mathew, A., Bondeson, D., Kvien, I., Manufacturing process of cellulose whiskers/polylactic acid nanocomposites. Composites Science and Technology 66:15 (2006), 2776–2784.
45. Olivas, G.I., Barbosa-Cánovas, G.V., Alginate–calcium films: water vapor permeability and mechanical properties as affected by plasticizer and relative humidity. LWT-Food Science and Technology 41:2 (2008), 359–366.
46. Pereira, R., Carvalho, A., Vaz, D.C., Gil, M., Mendes, A., Bártolo, P., Development of novel alginate based hydrogel films for wound healing applications. International Journal of Biological Macromolecules 52 (2013), 221–230.
47. Peresin, M.S., Habibi, Y., Zoppe, J.O., Pawlak, J.J., Rojas, O.J., Nanofiber composites of polyvinyl alcohol and cellulose nanocrystals: manufacture and characterization. Biomacromolecules 11:3 (2010), 674–681.
48. Peyre, J., Pääkkönen, T., Reza, M., Kontturi, E., Simultaneous preparation of cellulose nanocrystals and micron-sized porous colloidal particles of cellulose by TEMPO-mediated oxidation. Green Chemistry 17:2 (2015), 808–811.
49. Phisalaphong, M., Suwanmajo, T., Tammarate, P., Synthesis and characterization of bacterial cellulose/alginate blend membranes. Journal of Applied Polymer Science 107:5 (2008), 3419–3424.
50. Rånby, B., Ribi, E., Über den feinbau der zellulose. Experientia 6:1 (1950), 12–14.
51. Reid, M.S., Villalobos, M., Cranston, E.D., Benchmarking cellulose nanocrystals: from the laboratory to industrial production. Langmuir 33:7 (2016), 1583–1598.
52. Remunan-Lopez, C., Bodmeier, R., Mechanical, water uptake and permeability properties of crosslinked chitosan glutamate and alginate films. Journal of Controlled Release 44:2 (1997), 215–225.
53. Roman, M., Winter, W.T., Effect of sulfate groups from sulfuric acid hydrolysis on the thermal degradation behavior of bacterial cellulose. Biomacromolécules 5:5 (2004), 1671–1677.
54. Roohani, M., Habibi, Y., Belgacem, N.M., Ebrahim, G., Karimi, A.N., Dufresne, A., Cellulose whiskers reinforced polyvinyl alcohol copolymers nanocomposites. European Polymer Journal 44:8 (2008), 2489–2498.
55. Salminen, R., Reza, M., Pääkkönen, T., Peyre, J., Kontturi, E., TEMPO-mediated oxidation of microcrystalline cellulose: limiting factors for cellulose nanocrystal yield. Cellulose 24:4 (2017), 1657–1667.
56. Segal, L., Creely, J., Martin, A. Jr., Conrad, C., An empirical method for estimating the degree of crystallinity of native cellulose using the X-ray diffractometer. Textile Research Journal 29:10 (1959), 786–794.
57. Shoichet, M.S., Li, R.H., White, M.L., Winn, S.R., Stability of hydrogels used in cell encapsulation: an in vitro comparison of alginate and agarose. Biotechnology and Bioengineering 50:4 (1996), 374–381.
58. Simmons, C.A., Alsberg, E., Hsiong, S., Kim, W.J., Mooney, D.J., Dual growth factor delivery and controlled scaffold degradation enhance in vivo bone formation by transplanted bone marrow stromal cells. Bone 35:2 (2004), 562–569.
59. Siqueira, G., Fraschini, C., Bras, J., Dufresne, A., Prud'homme, R., Laborie, M.-P., Impact of the nature and shape of cellulosic nanoparticles on the isothermal crystallization kinetics of poly (ε-caprolactone). European Polymer Journal 47:12 (2011), 2216–2227.
60. Siqueira, G., Abdillahi, H., Bras, J., Dufresne, A., High reinforcing capability cellulose nanocrystals extracted from Syngonanthus nitens (Capim Dourado). Cellulose 17:2 (2010), 289–298.
61. Siqueira, G., Bras, J., Dufresne, A., Cellulosic bionanocomposites: a review of preparation, properties and applications. Polymers 2:4 (2010), 728–765.
62. Smetana, K., Cell biology of hydrogels. Biomaterials 14:14 (1993), 1046–1050.
63. Stockwell, A., Davis, S., Walker, S., In vitro evaluation of alginate gel systems as sustained release drug delivery systems. Journal of Controlled Release 3:1 (1986), 167–175.
64. Tønnesen, H.H., Karlsen, J., Alginate in drug delivery systems. Drug Development and Industrial Pharmacy 28:6 (2002), 621–630.
65. Tiquet, P. 2009. Gelled, freeze-dried capsules or agglomerates of nanoobjects or nanostructures, nanocomposite materials with polymer matrix comprising them, and methods for preparation thereof. Google Patents.
66. Ureña-Benavides, E.E., Brown, P.J., Kitchens, C.L., Effect of jet stretch and particle load on cellulose nanocrystal- alginate nanocomposite fibers. Langmuir 26:17 (2010), 14263–14270.
67. Wang, L.-F., Shankar, S., Rhim, J.-W., Properties of alginate-based films reinforced with cellulose fibers and cellulose nanowhiskers isolated from mulberry pulp. Food Hydrocolloids 63 (2017), 201–208.