Nanocellulose based asymmetric composite membrane for the multiple functions in cell encapsulation

Carbohydrate Polymers

Volumn 158, Issue , 2017, Pages 133-140

  Park, Minsung ^a,b   Shin, Sungchul ^a   Cheng, Jie ^a   Hyun, Jinho ^a,b,c  

^a Seoul National University   (South Korea)

^b Seoul National University   (South Korea)

^c Seoul National University   (South Korea)

Author keywords

Bacterial cellulose; Cell encapsulation; Nanocomposite; Permeability

Indexed keywords

BIOMECHANICS; CELL ADHESION; CELLS; CELLULOSE; CYTOLOGY; MECHANICAL PERMEABILITY; MEMBRANES; MOLECULES; NANOCOMPOSITES; PORE SIZE; SCANNING ELECTRON MICROSCOPY;

BACTERIAL CELLULOSE; CELL ENCAPSULATIONS; CELL IMPLANTATION; IMMUNE REJECTION; MULTIPLE FUNCTION; NANO-COMPOSITE MEMBRANES; SMALL MOLECULES; TRANSPLANTED CELLS;

COMPOSITE MEMBRANES;

CELLS; COLLAGEN; ENCAPSULATION; MEMBRANES; MOLECULES;

BACTERIAL POLYSACCHARIDE; CELLULOSE; COLLAGEN; NANOCOMPOSITE;

ANIMAL; CHEMISTRY; HYDROGEL; PC12 CELL LINE; RAT; SCANNING ELECTRON MICROSCOPY;

ANIMALS; CELLULOSE; COLLAGEN; HYDROGELS; MICROSCOPY, ELECTRON, SCANNING; NANOCOMPOSITES; PC12 CELLS; POLYSACCHARIDES, BACTERIAL; RATS;

EID: 85006124145     PISSN: 01448617     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.carbpol.2016.12.007     Document Type: Article

References (29)

1. An, D., Ji, Y.W., Chiu, A., Lu, Y.C., Song, W., Zhai, L., et al. Developing robust, hydrogel-based, nanofiber-enabled encapsulation devices (NEEDs) for cell therapies. Biomaterials 37 (2015), 40–48.
2. Beck, J., Angus, R., Madsen, B., Britt, D., Vernon, B., Nguyen, K.T., Islet encapsulation: Strategies to enhance islet cell functions. Tissue Engineering 13:3 (2007), 589–599.
3. Boontheekul, T., Kong, H.J., Mooney, D.J., Controlling alginate gel degradation utilizing partial oxidation and bimodal molecular weight distribution. Biomaterials 26:15 (2005), 2455–2465.
4. Czaja, W.K., Young, D.J., Kawecki, M., Brown, R.M., The future prospects of microbial cellulose in biomedical applications. Biomacromolecules 8:1 (2007), 1–12.
5. Dufrane, D., Goebbels, R.M., Gianello, P., Alginate macroencapsulation of pig islets allows correction of streptozotocin-induced diabetes in primates up to 6 months without immunosuppression. Transplantation 90:10 (2010), 1054–1062.
6. Ghidoni, I., Chlapanidas, T., Bucco, M., Crovato, F., Marazzi, M., Vigo, D., et al. Alginate cell encapsulation: New advances in reproduction and cartilage regenerative medicine. Cytotechnology 58:1 (2008), 49–56.
7. Isogai, A., Saito, T., Fukuzumi, H., TEMPO-oxidized cellulose nanofibers. Nanoscale 3:1 (2011), 71–85.
8. Jacobs-Tulleneers-Thevissen, D., Chintinne, M., Ling, Z., Gillard, P., Schoonjans, L., Delvaux, G., et al. Sustained function of alginate-encapsulated human islet cell implants in the peritoneal cavity of mice leading to a pilot study in a type 1 diabetic patient. Diabetologia 56:7 (2013), 1605–1614.
9. Kang, K.S., Lee, S.I., Hong, J.M., Lee, J.W., Cho, H.Y., Son, J.H., et al. Hybrid scaffold composed of hydrogel/3D-framework and its application as a dopamine delivery system. Journal of Controlled Release 175 (2014), 10–16.
10. Lathuiliere, A., Cosson, S., Lutolf, M.P., Schneider, B.L., Aebischer, P., A high-capacity cell macroencapsulation system supporting the long-term survival of genetically engineered allogeneic cells. Biomaterials 35:2 (2014), 779–791.
11. Ma, M.L., Chiu, A., Sahay, G., Doloff, J.C., Dholakia, N., Thakrar, R., et al. Core-shell hydrogel microcapsules for improved islets encapsulation. Advanced Healthcare Materials 2:5 (2013), 667–672.
12. Nyitray, C.E., Chang, R., Faleo, G., Lance, K.D., Bernards, D.A., Tang, Q.Z., et al. Polycaprolactone thin-film micro- and nanoporous cell-encapsulation devices. ACS Nano 9:6 (2015), 5675–5682.
13. Onoe, H., Okitsu, T., Itou, A., Kato-Negishi, M., Gojo, R., Kiriya, D., et al. Metre-long cell-laden microfibres exhibit tissue morphologies and functions. Nature Materials 12:6 (2013), 584–590.
14. Orive, G., De Castro, M., Kong, H.J., Hernandez, R., Ponce, S., Mooney, D.J., et al. Bioactive cell-hydrogel microcapsules for cell-based drug delivery. Journal of Controlled Release 135:3 (2009), 203–210.
15. Orive, G., Santos, E., Poncelet, D., Hernandez, R.M., Pedraz, J.L., Wahlberg, L.U., et al. Cell encapsulation: Technical and clinical advances. Trends in Pharmacological Sciences 36:8 (2015), 537–546.
16. Park, M., Chang, H., Jeong, D.H., Hyun, J., Spatial deformation of nanocellulose hydrogel enhances SERS. Biochip Journal 7:3 (2013), 234–241.
17. Park, M., Lee, D., Hyun, J., Nanocellulose-alginate hydrogel for cell encapsulation. Carbohydrate Polymers 116 (2015), 223–228.
18. Pedraz, J.L., Orive, G., Therapeutic applications of cell microencapsulation. 2010, Springer Science+Business Media; Landes Bioscience, New York, Austin, Tex.
19. Ruvinov, E., Cohen, S., Alginate biomaterial for the treatment of myocardial infarction: Progress, translational strategies, and clinical outlook from ocean algae to patient bedside. Advanced Drug Delivery Reviews 96 (2016), 54–76.
20. Sarker, B., Papageorgiou, D.G., Silva, R., Zehnder, T., Gul-E-Noor, F., Bertmer, M., et al. Fabrication of alginate-gelatin crosslinked hydrogel microcapsules and evaluation of the microstructure and physico-chemical properties. Journal of Materials Chemistry B 2:11 (2014), 1470–1482.
21. Sarker, B., Rompf, J., Silva, R., Lang, N., Detsch, R., Kaschta, J., et al. Alginate-based hydrogels with improved adhesive properties for cell encapsulation. International Journal of Biological Macromolecules 78 (2015), 72–78.
22. Saska, S., Teixeira, L.N., de Oliveira, P.T., Gaspar, A.M.M., Ribeiro, S.J.L., Messaddeq, Y., et al. Bacterial cellulose-collagen nanocomposite for bone tissue engineering. Journal of Materials Chemistry 22:41 (2012), 22102–22112.
23. Shah, N., Ul-Islam, M., Khattak, W.A., Park, J.K., Overview of bacterial cellulose composites: A multipurpose advanced material. Carbohydrate Polymers 98:2 (2013), 1585–1598.
24. Ul-Islam, M., Khan, S., Ullah, M.W., Park, J.K., Bacterial cellulose composites: Synthetic strategies and multiple applications in bio-medical and electro-conductive fields. Biotechnology Journal 10:12 (2015), 1847–1861.
25. Vaithilingam, V., Tuch, B.E., Islet transplantation and encapsulation: An update on recent developments. The Review of Diabetic Studies 8:1 (2011), 51–67.
26. Wang, T., Lacik, I., Brissova, M., Anilkumar, A.V., Prokop, A., Hunkeler, D., et al. An encapsulation system for the immunoisolation of pancreatic islets. Nature Biotechnology 15:4 (1997), 358–362.
27. Weir, G.C., Islet encapsulation: Advances and obstacles. Diabetologia 56:7 (2013), 1458–1461.
28. Wilson, J.T., Chaikof, E.L., Challenges and emerging technologies in the immunoisolation of cells and tissues. Advanced Drug Delivery Reviews 60:2 (2008), 124–145.
29. Zanin, M.P., Pettingill, L.N., Harvey, A.R., Emerich, D.F., Thanos, C.G., Shepherd, R.K., The development of encapsulated cell technologies as therapies for neurological and sensory diseases. Journal of Controlled Release 160:1 (2012), 3–13.