Producing ultrapure wood cellulose nanofibrils and evaluating the cytotoxicity using human skin cells

Carbohydrate Polymers

Volumn 150, Issue , 2016, Pages 65-73

  Nordli, Henriette Rogstad ^a   Chinga Carrasco, Gary ^b   Rokstad, Anne Mari ^a   Pukstad, Brita ^a,c  

^a NORWEGIAN UNIVERSITY OF SCIENCE AND TECHNOLOGY   (Norway)

^b Papir og fiberinstituttet AS   (Norway)

^c TRONDHEIM UNIVERSITY HOSPITAL   (Norway)

Author keywords

Cytotoxicity; Endotoxins; Fibroblasts; Keratinocytes; Ultrapure cellulose nanofibrils

Indexed keywords

AEROGELS; BIOMATERIALS; CELL CULTURE; CELL DEATH; CELLULOSE; CYTOTOXICITY; DISPERSIONS; FIBROBLASTS; HIGH RESOLUTION TRANSMISSION ELECTRON MICROSCOPY; METABOLISM; NANOFIBERS; SCANNING ELECTRON MICROSCOPY; TRANSMISSION ELECTRON MICROSCOPY;

CELLULOSE NANOFIBRILS; ENDOTOXINS; HUMAN EPIDERMAL KERATINOCYTES; KERATINOCYTES; MOISTURE HOLDING CAPACITY; NORMAL HUMAN DERMAL FIBROBLASTS; SCANNING TRANSMISSION ELECTRON MICROSCOPY; TEMPO-MEDIATED OXIDATION;

WOOD;

CELLULOSE; CELLULOSE FIBERS; OXIDATION; SURGICAL DRESSINGS;

CELLULOSE; CYTOKINE; CYTOTOXIN; NANOFIBER;

CHEMISTRY; CYTOLOGY; DOSE RESPONSE; DRUG EFFECTS; HUMAN; METABOLISM; SKIN; WOOD;

CELLULOSE; CYTOKINES; CYTOTOXINS; DOSE-RESPONSE RELATIONSHIP, DRUG; HUMANS; NANOFIBERS; SKIN; WOOD;

EID: 84969753338     PISSN: 01448617     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.carbpol.2016.04.094     Document Type: Article

References (59)

1. M. Čolić, D. Mihajlović, A. Mathew, N. Naseri, and V. Kokol Cytocompatibility and immunomodulatory properties of wood based nanofibrillated cellulose Cellulose 22 1 2015 763 778
2. L. Alexandrescu, K. Syverud, A. Gatti, and G. Chinga-Carrasco Cytotoxicity tests of cellulose nanofibril-based structures Cellulose 2013 1 11
3. J.C. Ansel, J.P. Tiesman, J.E. Olerud, J.G. Krueger, J.F. Krane, D.C. Tara, and et al. Human keratinocytes are a major source of cutaneous platelet-derived growth factor Journal of Clinical Investigation 92 2 1993 671 678
4. ®)) in wound care Therapeutics and Clinical Risk Management 6 2010 21 27
5. M. Bhattacharya, M.M. Malinen, P. Lauren, Y.-R. Lou, S.W. Kuisma, L. Kanninen, and et al. Nanofibrillar cellulose hydrogel promotes three-dimensional liver cell culture Journal of Controlled Release 164 3 2012 291 298
6. A. Bodin, S. Bharadwaj, S. Wu, P. Gatenholm, A. Atala, and Y. Zhang Tissue-engineered conduit using urine-derived stem cells seeded bacterial cellulose polymer in urinary reconstruction and diversion Biomaterials 31 34 2010 8889 8901
7. A. Burd, C.H. Kwok, S.C. Hung, H.S. Chan, H. Gu, W.K. Lam, and et al. A comparative study of the cytotoxicity of silver-based dressings in monolayer cell, tissue explant, and animal models Wound Repair and Regeneration 15 1 2007 94 104
8. B. Cherian, A. Leão, S. Souza, G. Olyveira, L. Costa, C. Brandão, and et al. Bacterial nanocellulose for medical implants S. Thomas, P.M. Visakh, A.P. Mathew, Advances in natural polymers 2013 Springer Berlin Heidelberg 337 359
9. N. Chiaoprakobkij, N. Sanchavanakit, K. Subbalekha, P. Pavasant, and M. Phisalaphong Characterization and biocompatibility of bacterial cellulose/alginate composite sponges with human keratinocytes and gingival fibroblasts Carbohydrate Polymers 85 3 2011 548 553
10. G. Chinga-Carrasco Cellulose fibres, nanofibrils and microfibrils: the morphological sequence of MFC components from a plant physiology and fibre technology point of view Nanoscale Research Letters 6 1 2011 1 7
11. G. Chinga-Carrasco, N. Averianova, O. Kondalenko, M. Garaeva, V. Petrov, B. Leinsvang, and et al. The effect of residual fibres on the micro-topography of cellulose nanopaper Micron 56 0 2014 80 84
12. G. Chinga-Carrasco, N. Kuznetsova, M. Garaeva, I. Leirset, G. Galiullina, A. Kostochko, and K. Syverud Bleached and unbleached MFC nanobarriers: properties and hydrophobisation with hexamethyldisilazane Journal of Nanoparticle Research 12 2012 1 10 14
13. G. Chinga-Carrasco, and K. Syverud Pretreatment-dependent surface chemistry of wood nanocellulose for pH-sensitive hydrogels Journal of Biomaterials Applications 3 2014 423 432 29
14. G. Chinga-Carrasco, Y. Yu, and O. Diserud Quantitative electron microscopy of cellulose nanofibril structures from Eucalyptus and Pinus radiata kraft pulp fibers Microscopy and Microanalysis 17 04 2011 563 571
15. W. Czaja, A. Krystynowicz, S. Bielecki, and R.M. Brown Jr. Microbial cellulose - the natural power to heal wounds Biomaterials 27 2 2006 145 151
16. K. Dana, and H. Nadine Large-scale production of BNC M. Gama, P. Gatenholm, D. Klemm, Bacterial NanoCellulose, a sophisticated multifunctianl material 2012 New York CRC Press 43 72
17. S. Franz, S. Rammelt, D. Scharnweber, and J.C. Simon Immune responses to implants-a review of the implications for the design of immunomodulatory biomaterials Biomaterials 32 28 2011 6692 6709
18. M.B. Gorbet, and M.V. Sefton Endotoxin: the uninvited guest Biomaterials 26 34 2005 6811 6817
19. O. Grimstad, O. Sandanger, L. Ryan, K. Otterdal, J.K. Damaas, B. Pukstad, and et al. Cellular sources and inducers of cytokines present in acute wound fluid Wound Repair and Regeneration 19 3 2011 337 347
20. G. Helenius, H. Bäckdahl, A. Bodin, U. Nannmark, P. Gatenholm, and B. Risberg In vivo biocompatibility of bacterial cellulose Journal of Biomedical Materials Research Part A 76A 2 2006 431 438
21. A. Helmy, K.L.H. Carpenter, J.N. Skepper, P.J. Kirkpatrick, J.D. Pickard, and P.J. Hutchinson Microdialysis of cytokines: methodological considerations, scanning electron microscopy, and determination of relative recovery Journal of Neurotrauma 26 4 2009 549 561
22. K. Hua, D.O. Carlsson, E. Ålander, T. Lindström, M. Strømme, A. Mihranyan, and et al. Translational study between structure and biological response of nanocellulose from wood and green algae RSC Advances 4 6 2014 2892 2903
23. M.S. Inder, and R.M. Brown Biosynthesis of bacterial cellulose M. Gama, P. Gatenholm, D. Klemm, Bacterial NanoCellulose a sophisticated multifunctional material 2012 CRC Press New York 1 18
24. M. Jorfi, and E.J. Foster Recent advances in nanocellulose for biomedical applications Journal of Applied Polymer Science 132 14 2015
25. D. Klemm, F. Kramer, S. Moritz, T. Lindström, M. Ankerfors, D. Gray, and et al. Nanocelluloses: a new family of nature-based materials Angewandte Chemie International Edition 50 24 2011 5438 5466
26. P. Kollar, V. Závalová, J. Hošek, P. Havelka, T. Sopuch, M. Karpíšek, and et al. Cytotoxicity and effects on inflammatory response of modified types of cellulose in macrophage-like THP-1 cells International Immunopharmacology 11 8 2011 997 1001
27. G. Kratz Modeling of wound healing processes in human skin using tissue culture Microscopy Research and Technique 42 5 1998 345 350
28. N. Lin, and A. Dufresne Nanocellulose in biomedicine: current status and future prospect European Polymer Journal 59 0 2014 302 325
29. Y.-R. Lou, L. Kanninen, T. Kuisma, J. Niklander, L.A. Noon, D. Burks, and et al. The use of nanofibrillar cellulose hydrogel as a flexible three-dimensional model to culture human pluripotent stem cells Stem Cells and Development 23 4 2014 380 392
30. P.O. Magalhães, A.M. Lopes, P.G. Mazzola, C. Rangel-Yagui, T. Penna, and A. Pessoa Jr. Methods of endotoxin removal from biological preparations: a review Journal of Pharmacy and Pharmaceutical Sciences 10 3 2007 388 404
31. M.M. Malinen, L.K. Kanninen, A. Corlu, H.M. Isoniemi, Y.-R. Lou, M.L. Yliperttula, and et al. Differentiation of liver progenitor cell line to functional organotypic cultures in 3D nanofibrillar cellulose and hyaluronan-gelatin hydrogels Biomaterials 35 19 2014 5110 5121
32. T. Maneerung, S. Tokura, and R. Rujiravanit Impregnation of silver nanoparticles into bacterial cellulose for antimicrobial wound dressing Carbohydrate Polymers 72 1 2008 43 51
33. J.A. Nagy, A.M. Dvorak, and H.F. Dvorak VEGF-A and the induction of pathological angiogenesis Annual Review of Pathology: Mechanisms of Disease 2 1 2007 251 275
34. Y. Nakagawa, T. Murai, C. Hasegawa, M. Hirata, T. Tsuchiya, T. Yagami, and et al. Endotoxin contamination in wound dressings made of natural biomaterials Journal of Biomedical Materials Research Part B: Applied Biomaterials 66B 1 2003 347 355
35. NovaMatrix Safety and toxicology of PRONOVA UP sodium alginates 2015 FMC Corporation Accessed: January 2015, Avaiable at: http://www.novamatrix.biz/Portals/novamatrix/Content/Docs/Technology/PIB-Safety%20and%20Tox%20of%20Pronova%20UP%20alginate%20093009.pdf
36. J.E. Paddle-Ledinek, Z. Nasa, and H.J. Cleland Effect of different wound dressings on cell viability and proliferation Plastic and Reconstructive Surgery 117 7S 2006 110S 118S
37. N. Petersen, and P. Gatenholm Bacterial cellulose-based materials and medical devices: current state and perspectives Applied Microbiology and Biotechnology 91 5 2011 1277 1286
38. V.K. Poon, and A. Burd In vitro cytotoxity of silver: implication for clinical wound care Burns 30 2 2004 140 147
39. O. Portal, W.A. Clark, and D.J. Levinson Microbial cellulose wound dressing in the treatment of nonhealing lower extremity ulcers Wounds: a Compendium of Clinical Research and Practice 21 1 2009 1 3
40. L.C. Powell, S. Khan, G. Chinga-Carrasco, C.J. Wright, K.E. Hill, and D.W. Thomas An investigation of Pseudomonas aeruginosa biofilm growth on novel nanocellulose fibre dressings Carbohydrate Polymers 137 2016 191 197
41. A. Rees, L.C. Powell, G. Chinga-Carrasco, D.T. Gethin, K. Syverud, K.E. Hill, and et al. 3D bioprinting of carboxymethylated-periodate oxidized nanocellulose constructs for wound dressing applications BioMed Research International 2014
42. J. Reinke, and H. Sorg Wound repair and regeneration European Surgical Research. Europaische Chirurgische Forschung. Recherches Chirurgicales Europeennes 49 1 2011 35 43
43. K.S. Rogers Variable sulfhydryl activity toward silver nitrate by reduced glutathione and alcohol, glutamate and lactate dehydrogenases Biochimica Et Biophysica Acta (BBA) - Protein Structure 263 2 1972 309 314
44. A.M. Rokstad, O.-L. Brekke, B. Steinkjer, L. Ryan, G. Kolláriková, B.L. Strand, and et al. The induction of cytokines by polycation containing microspheres by a complement dependent mechanism Biomaterials 34 3 2013 621 630
45. A.M. Rokstad, I. Donati, M. Borgogna, J. Oberholzer, B.L. Strand, T. Espevik, and et al. Cell-compatible covalently reinforced beads obtained from a chemoenzymatically engineered alginate Biomaterials 27 27 2006 4726 4737
46. A.M. Rokstad, B.I. Gustafsson, T. Espevik, I. Bakke, R. Pfragner, B. Svejda, and et al. Microencapsulation of small intestinal neuroendocrine neoplasm cells for tumor model studies Cancer Science 103 7 2012 1230 1237
47. A.M. Rokstad, B. Strand, T. Espevik, and T.E. Mollnes Biocompatibility and biotolerability assessment of microspheres using a whole blood model Micro and Nano Syst 5 2013 177 185
48. T. Saito, Y. Nishiyama, J.-L. Putaux, M. Vignon, and A. Isogai Homogeneous suspensions of individualized microfibrils from TEMPO-catalyzed oxidation of native cellulose Biomacromolecules 7 6 2006 1687 1691
49. S. Saska, L.N. Teixeira, P. Tambasco de Oliveira, A.M. Minarelli Gaspar, S.J. Lima Ribeiro, Y. Messaddeq, and et al. Bacterial cellulose-collagen nanocomposite for bone tissue engineering Journal of Materials Chemistry 22 41 2012 22102 22112
50. K. Sugiyama, G. Ishii, A. Ochiai, and H. Esumi Improvement of the breaking strength of wound by combined treatment with recombinant human G-CSF, recombinant human M-CSF, and a TGF-β1 receptor kinase inhibitor in rat skin Cancer Science 99 5 2008 1021 1028
51. K. Syverud, H. Kirsebom, S. Hajizadeh, and G. Chinga-Carrasco Cross-linking cellulose nanofibrils for potential elastic cryo-structured gels Nanoscale Research Letters 6 1 2011 1 6
52. K. Syverud, S. Pettersen, K. Draget, and G. Chinga-Carrasco Controlling the elastic modulus of cellulose nanofibril hydrogels - scaffolds with potential in tissue engineering Cellulose 22 1 2015 473 481
53. Z. Tehrani, H.R. Nordli, B. Pukstad, D.T. Gethin, and G. Chinga-Carrasco Translucent and ductile nanocellulose-PEG bionanocomposites - a novel substrate with potential to be functionalized by printing for wound dressing applications Industrial Crops and Products 2016 10.1016/j.indcrop.2016.02.024 in press
54. United States Pharmacopeia, and National Formulary <85> Bacterial endotoxins test.In United States Pharmacopeia and National Formulary (USP 29-NF 24, pp. 2521) 2006 United States Pharmacopeia Convention Rockville, MD
55. United States Pharmacopeia, and National Formulary <161> Transfusion and infusion assemblies and similar medical devices. In United States Pharmacopeia and National Formulary (USP 29-NF 24,pp. 2547) 2006 United States Pharmacopeia Convention Rockville, MD
56. J. Vartiainen, T. Pöhler, K. Sirola, L. Pylkkänen, H. Alenius, J. Hokkinen, and et al. Health and environmental safety aspects of friction grinding and spray drying of microfibrillated cellulose Cellulose 18 3 2011 775 786
57. L. Wågberg, G. Decher, M. Norgren, T. Lindström, M. Ankerfors, and K. Axnäs The build-up of polyelectrolyte multilayers of microfibrillated cellulose and cationic polyelectrolytes Langmuir 24 3 2008 784 795
58. C. Wiegand, J. Tittelbach, P. Elsner, and U.-C. Hipler Clinical efficacy of dressings for treatment of heavily exuding chronic wounds Chronic Wound Care Management and Research 2 2015 101 111
59. D. Yang, Q. Chen, D.M. Hoover, P. Staley, K.D. Tucker, J. Lubkowski, and et al. Many chemokines including CCL20/MIP-3α display antimicrobial activity Journal of Leukocyte Biology 74 3 2003 448 455