Nanocomposite gelatin

Kniep R, Simon P (2007) Fluorapatite-Gelatine-Nanocomposites Self-Organized Morphogenesis, Real Structure and Relations to Natural Hard Materials. 270 73-125 Koenig BW (2007) Residual Dipolar Couplings Report on the Active Conformation of Rhodopsin-Bound Protein Fragments. 272 187-216 Kolusheva S, see Jelinek R (2007) 277 155-180... [Pg.261]

Fig. 1.7 Scanning electron micrographs showing fractal pattern formation by hierarchical growth of fluorapatite-gelatin nanocomposites (A) half of a dumbbell aggregate viewed along the central seed axis, (B) dumbbell aggregate at an intermediate growth state, and (C) central seed exhibiting tendencies of splitting at both ends ( small dumbbell). Adapted from [119], reproduced by permission ofWiley-VCH.

$Fig. 1.7 Scanning electron micrographs showing fractal pattern formation by hierarchical growth of fluorapatite-gelatin nanocomposites (A) half of a dumbbell aggregate viewed along the central seed axis, (B) dumbbell aggregate at an intermediate growth state, and (C) central seed exhibiting tendencies of splitting at both ends ( small dumbbell). Adapted from [119], reproduced by permission ofWiley-VCH.$

Fig. 1.18 (A) Schematic representation of gelatin-perovskite bio-nanocomposite. (B) TEM image ofTBA-modified perovskite and (C) SEM image of this TBA-perovskite after assembly...

Fig. 5.17 Scanning (A) and transmission (B) electron micrographs of Au-gelatin nanocomposites (Adapted from [78]).

Allouche, J., Boissiere, M., Helary, C., Livage, J. and Coradin, T. (2006) Biomimetic core-shell gelatine/silica nanoparticles a new example of biopolymer-based nanocomposites. Journal of Materials Chemistry, 16, 3121-3131. [Pg.186]

Brayner, R., Coradin, T., Vaulay, M.-J., Mangeney, C., Livage, J. and Fievet, F. (2005) Preparation and characterization of metal (Au)- and bimetallic alloys (AuNi)-gelatin nanocomposites. Colloids and Surface Science A, 256, 191-197. [Pg.189]

Gelatin/Si02 gel AOT/isooctane/gelatin/ water [/ = 30, 14% w/v gelatin (referred to the aqueous pseudophase) TM0S/H20 (0.1 M HCl or 0.1 M NaOH) water/TMOS molar ratio = 4 Product silica-gelatin nanocomposites, sl30 nm silica particles (53)... [Pg.154]

Rosseeva EV, Buder J, Simon P, Schwarz U, Frank-Kamenetskaya OV, Kniep R (2008) Synthesis, characterization, and morphogenesis of carbonated fluorapatite-gelatine nanocomposites a complex biomimetic approach toward the mineralization of hard tissues. Chem Mater 20(19) 6003-6013... [Pg.61]

Huang Z-M, Zhang Y-Z, Kotaki M, Ramakrishna S (2003) A review on polymer nanofibers by electrospinning and their applications in nanocomposites. Compos Sci Technol 63 2223-2253 Huang ZM, Zhang YZ, Ramakrishna S, Lim CT (2004) Electrospinning and mechanical characterization of gelatin nanofibers. Polymer 45 5361-5368... [Pg.111]

Rajan, M., Raj, V., Al-Arfaj, A. A., Murugan, A. M. (2013). H3raluronidase enzyme core-5-fluorouracil-loaded chitosan-PEG-gelatin polymer nanocomposites as targeted and controlled drug delivery vehicles, Int r. Pharm.. 453(2), 514-522. [Pg.582]

D. Lamprou, P. Zhdan, F. Labeed, C. Lekakou, Gelatine and gela-tine/elastin nanocomposites for vascular grafts processing and characterization, J. Biomater. Appl. 26 (2) (2011) 209-226. [Pg.366]

Most of the recent reported polymer/CW nanocomposites were prepared by this method. The reported polymer matrixes contain poly(styrene-co-butyl acrylate) [36], poly(caprolactone) [37], natural rubber [39,140,141], soy protein isolate [38], poly(vinyl alcohol) [42, 44], chitosan [41, 141], silk fibroin, [142], alginate [44], starch [143], hyaluronan-gelatin [55], and waterborne polyurethane [144, 145]. [Pg.87]

The functions of the fourth hierarchical level are associated with capsulation of nanocomposites to maintain their properties and prolong the action of dmgs. Nanocapsulation is carried out with dextran, gelatin, polyvinyl alcohol, and polyvinyl pyrrolidone. [Pg.305]

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