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Nanomedicine scaffolding

Firth, A., Aggeli, A., Burke, J.L., Yang, X.B., and Kirkham, J. "Biomimetic self-assembling peptides as injectable scaffolds for hard tissue engineering". Nanomedicine 1(2), 189-199... [Pg.41]

Bennet D, Marimuthu M, Kim S, An J. Dual drug-loaded nanoparticles on self-integrated scaffold for controlled delivery. Int J Nanomedicine. 2012 7 3399-3419. [Pg.760]

A. Asefnejad, A. Behnamghader, M. Khorasani, B. Farsadzadeh, Polyurethane/fluor-hydroxyapatite nanocomposite scaffolds for bone tissue engineering. Part I morphological, physical, and mechanical characterization, Int. J. Nanomedicine 6 (2011) 93-100. [Pg.144]

Nanomedicine envelops a wide variety of structures— nanoparlicles, nanofibers, nanoporous scaffolds, nanocages, nanoposts, nanodots, nanotubes, and nanowires, among other newly defined and developing configurations. Integration of... [Pg.388]

Firth A, Aggeli A, Burke JL, Yang X, Krrkham J. Biomimetic self-assembling peptides as injectable scaffolds for hard tissue engineering. Nanomedicine (Land) 2006 1(2) 189-199. [Pg.370]

TonneUi FMP, Santos AK, Gomes KN, Lorencon E, Guatimosim S, Ladeira LO, et al. Carbon nanotube interaction with extracellular matrix proteins producing scaffolds for tissue engineering. Int J Nanomedicine 2012 7 4511—29. [Pg.167]

Weightman, A., Jenkins, S., Pickard, M., Chari, D., Yang, Y., 2013. Alignment of multiple glial cell populations in 3D nanofiber scaffolds toward the development of multicellular implantable scaffolds for repair of neural injury. Nanomedicine 10 (2), 291-295. [Pg.117]

Hajiali, H., Shahgasempour,., Naimi-Jamal, M.R., and Peirovi, H. (2011) Electrospun PGA/gelatin nanofibrous scaffolds and their potential application in vascular tissue engineering. InL J. Nanomedicine, 6, 2133-2141. [Pg.188]

Guo J, Su H, Zeng Y et al (2007) Reknitting the injured spinal cord by self-assembling peptide nanofiber scaffold. Nanomedicine 3 311-321... [Pg.82]

Masaeli, E., Wieringa, P.A., Morshed, M., Nasr-Esfahani, M., Sadri, S., van Blitterswijk, C.A., Moroni, L., 2014. Peptide functionalised polyhydroxyalkanoate nanofibrous scaffolds enhance Schwann cells activity. Nanomedicine Nanotechnology, Biology and Medicine 10 (7), 1559-1569. [Pg.274]

Crowder, S.W, Liang, Y, Rath, R., Park, A.M., Maltais, S., Pintauro, P.N., Hofmeister, W., Lim, C.C., Wang, X., Sung, H.J., 2013. Poly(E-caprolactone)-carbon nanotube composite scaffolds for enhanced cardiac differentiation of human mesenchymal stem cells. Nanomedicine (London, England) 8. http //dx.doi.org/10.2217/nnm.12.204. [Pg.409]

Sirivisoot, S., Harrison, B.S., 2011. Skeletal myotube formation enhanced by electrospun polyurethane carbon nanotube scaffolds. International Journal of Nanomedicine 6,2483—2497. [Pg.415]

Zhan XD, Gao MY, Jiang YW, Zhang WW, Wong WM, Yuan QJ, et al. Nanofiber scaffolds facilitate functional regeneration of peripheral nerve injury. Nanomedicine 2012 9 305-15. [Pg.627]

Lu T, Li Y, Chen T. Techniques for fabrication and construction of three-dimensional scaffolds for tissue engineering. Int J Nanomedicine 2013 8 337-50. [Pg.199]

Kamath, M.S., Ahmed, S.S., Dhanasekaran, M., Santosh, S.W., 2014. Polycaprolactone scaffold engineered for sustained release of resveratrol therapeutic enhancement in bone tissue engineering. Int. J. Nanomedicine 9, 183—195. [Pg.490]

Green, D.W., Ben-Nissan, B., 2010. Biomimetic applications in regenerative medicine scaffolds, transplantation modules, tissue homing device and stem cells. Chapter 21. In Tochilin, V., Amiji, M. (Eds.), Handbook of Materials for Nanomedicine. Pan Stanford Publishing Pte Ltd, Singapore, pp. 821-850. ISBN 978-981-4267-55-7. [Pg.30]

Dong, W., T. Zhang, M. McDonald, C. PadUla, J. Epstein, and Z. R. Tian (2006). Biocompatible nanofiber scaffolds on metal for controlled release and cell colonization. Nanomedicine Nanotechnology, Biology and Medicine 2(4) 248-252. [Pg.338]

Zhang, Y., Su, B., Venugopal, J., Ratnakrishna, S., Lim, C., 2007. Bioiniinetic and bioactive nanofibrous scaffolds from electrospun composite nanofibers. Intemational Journal of Nanomedicine 2, 623—638. [Pg.80]

Liu, H., Slamovich, E.B., Webster, T.J., 2006. Less harmful acidic degradation of poly(lacticco-glycolic acid) bone tissue engineering scaffolds through titania nanoparticle addition. International Journal of Nanomedicine 1, 541-545. [Pg.118]

Chen, M., Le, D., Hein, S., et al., 2012. Fabrication and characterization of a rapid prototyped tissue engineering scaffold with embedded multicomponent matrix for controlled drug release. International Journal of Nanomedicine 7,4285-4297. [Pg.183]

Lau, T.T., Wang, D.-A. BioresfX)nsive hydrogel scaffolding systems for 3D constructions in tissue engineering and regenerative medicine. Nanomedicine 8, 655-668 (2013)... [Pg.212]

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See also in sourсe #XX -- [ Pg.392 ]



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