Biomolecules from Natural Sources

133 133 Browning, A.C., Gray, T., and Amoaku, W.M. (2005). Isolation, culture, and characterisation of human macular inner choroidal microvascular endothelial cells. British Journal of Ophthalmology 89 (10): 1343–1347.

134 134 Claudepierre, T., Manglapus, M.K., Marengi, N., Radner, S., Champliaud, M.F., Tasanen, K., Bruckner-Tuderman, L., Hunter, D.D., and Brunken, W.J. (2005). Collagen XVII and BPAG1 expression in the retina: evidence for an anchoring complex in the central nervous system. Journal of Comparative Neurology 487 (2): 190–203.

135 135 Cosar, C.B., Ceyhan, N., Sevim, S., Sakaoglu, N., Sirvanci, S., San, T., Kurtkaya, O., and Acar, S. (2005). Corneal perforation with minor trauma: Ehlers-Danlos syndrome type VI. Ophthalmic Surgery Lasers and Imaging 36 (4): 350–351.

136 136 Diamantopoulos, C., Delliou, E., Kapranou, A., Balatsouras, D., and Elemenoglou, I. (2005). Collagenous spherulosis in epithelial-myoepithelial carcinoma of the submandibular gland: histologic and immunohistochemical study of a case. Journal of Otolaryngology 34 (4): 265–266.

137 137 Zhang, X., Wu, X., and Xia, K. (2013). Cellulose-wheat gluten bulk plastic materials produced from processing raw powders by severe shear deformation. Carbohydrate Polymers 92 (2): 2206–2211.

138 138 Markgren, J., Hedenqvist, M., Rasheed, F., Skepo, M., and Johansson, E. (2020). Glutenin and gliadin, a piece in the puzzle of their structural properties in the cell described through Monte Carlo simulations. Biomolecules 10 (8): 1095.

139 139 McMaster, T.J., Miles, M.J., Wannerberger, L., Eliasson, A.-C., Shewry, P.R., and Tatham, A.S. (1999). Identification of microphases in mixed alpha- and omega-gliadin protein films investigated by atomic force microscopy. Journal of Agricultural and Food Chemistry 47 (12): 5093–5099.

140 140 Fisichella, S., Amato, M.E., Lafiandra, D., Mantarro, D., Palermo, A., Savarino, A., and Scarlata, G. (2004). Structural studies of wheat flour glutenin polymers by CD spectroscopy. Biopolymers 74 (4): 287–301.

141 141 Altenbach, S.B., Chang, H.C., Rowe, M.H., Yu, X.B., Simon-Buss, A., Seabourn, B.W., Green, P.H., and Alaedini, A. (2020). Reducing the immunogenic potential of wheat flour: silencing of alpha gliadin genes in a U.S. wheat cultivar. Frontiers of Plant Science 11: 20.

142 142 Feng, Y., Zhang, H., Fu, B., Iftikhar, M., Liu, G., and Wang, J. (2020). Interactions between dietary fiber and ferulic acid change the aggregation of glutenin, gliadin and glutenin macropolymer in wheat flour system. Journal of the Science of Food and Agriculture 101 (5): 1979–1988.

143 143 Erdem, B.G. and Kaya, S. (2021). Production and application of freeze dried biocomposite coating powders from sunflower oil and soy protein or whey protein isolates. Food Chemistry 339: 127976.

144 144 Huang, T., Tu, Z., Shangguan, X., Wang, H., Zhang, L., and Bansal, N. (2021). Characteristics of fish gelatin-anionic polysaccharide complexes and their applications in yoghurt: rheology and tribology. Food Chemistry 343: 128413.

145 145 Di Bari, M., Cavatorta, F., Deriu, A., and Albanese, G. (2001). Mean square fluctuations of hydrogen atoms and water-biopolymer interactions in hydrated saccharides. Biophysical Journal 81 (2): 1190–1194.

146 146 Petersson, M., Loren, N., and Stading, M. (2005). Characterization of phase separation in film forming biopolymer mixtures. Biomacromolecules 6 (2): 932–941.

147 147 Chengyao, X., Yan, Q., Chaonan, D., Xiaopei, C., Yanxin, W., Ding, L., Xianfeng, Y., Jian, H., Yan, H., Zhongli, C., and Zhoukun, L. (2020). Enzymatic properties of an efficient glucan branching enzyme and its potential application in starch modification. Protein Expression and Purification 178: 105779.

148 148 Kamaldeen, O.S., Ariahu, C.C., and Yusufu, M.I. (2020). Application of soy protein isolate and cassava starch based film solutions as matrix for ionic encapsulation of carrot powders. Journal of Food Science and Technology 57 (11): 4171–4181.

149 149 Jabar, J.M., Alabi, K.A., and Lawal, A.K. (2020). Synthesis, characterization and application of novel 1, 3-bis[(furan-2-l)methylene]thiourea functional dye on wool and cotton fabrics. SN Applied Sciences 2 (11): 1850.

150 150 Jin, K., Tang, Y., Liu, J., Wang, J., and Ye, C. (2020). Nanofibrillated cellulose as coating agent for food packaging paper. International Journal of Biological Macromolecules 168: 331–338.

151 151 Kalia, S., Dufresne, A., Cherian, B.M., Kaith, B.S., Averous, L., Njuguna, J., and Nassiopoulos, E. (2011). Cellulose-based bio- and nanocomposites: a review. International Journal of Polymer Science 2011: 1–35.

152 152 Ferrari, R.R., Onuferko, T.M., Monckton, S.K., and Packer, L. (2020). The evolutionary history of the cellophane bee genus Colletes Latreille (Hymenoptera: Colletidae): molecular phylogeny, biogeography and implications for a global infrageneric classification. Molecular Phylogenetics and Evolution 146: 106750.

153 153 Abeer, M.M., Mohd Amin, M.C.I., and Martin, C. (2014). A review of bacterial cellulose-based drug delivery systems: their biochemistry, current approaches and future prospects. Journal of Pharmacy and Pharmacology 66 (8): 1047–1061.

154 154 Amin, M.C.I.M., Abadi, A.G., and Katas, H. (2014). Purification, characterization and comparative studies of spray-dried bacterial cellulose microparticles. Carbohydrate Polymers 99: 180–189.

155 155 Ciecholewska-Jusko, D., Zywicka, A., Junka, A., Drozd, R., Sobolewski, P., Migdal, P., Kowalska, U., Toporkiewicz, M., and Fijalkowski, K. (2020). Superabsorbent crosslinked bacterial cellulose biomaterials for chronic wound dressings. Carbohydrate Polymers 253: 117247.

156 156 Gao, G., Cao, Y., Zhang, Y., Wu, M., Ma, T., and Li, G. (2020). In situ production of bacterial cellulose/xanthan gum nanocomposites with enhanced productivity and properties using Enterobacter sp. FY-07. Carbohydrate Polymers 248: 116788.

157 157 Islam, S.U., Ul-Islam, M., Ahsan, H., Ahmed, M.B., Shehzad, A., Fatima, A., Sonn, J.K., and Lee, Y.S. (2020). Potential applications of bacterial cellulose and its composites for cancer treatment. International Journal of Biological Macromolecules 168: 301–330.

158 158 Phomrak, S., Nimpaiboon, A., Newby, B.Z., and Phisalaphong, M. (2020). Natural rubber latex foam reinforced with micro- and nanofibrillated cellulose via Dunlop method. Polymers (Basel) 12 (9): 1959.

159 159 Santos, T.A. and Spinace, M.A.S. (2021). Sandwich panel biocomposite of thermoplastic corn starch and bacterial cellulose. International Journal of Biological Macromolecules 167: 358–368.

160 160 Wang, F.P., Zhao, X.J., Wahid, F., Zhao, X.Q., Qin, X.T., Bai, H., Xie, Y.Y., Zhong, C., and Jia, S.R. (2021). Sustainable, superhydrophobic membranes based on bacterial cellulose for gravity-driven oil/water separation. Carbohydrate Polymers 253: 117220.

161 161 Kochumalayil, J.J., Zhou, Q., Kasai, W., and Berglund, L.A. (2013). Regioselective modification of a xyloglucan hemicellulose for high-performance biopolymer barrier films. Carbohydrate Polymers 93 (2): 466–472.

162 162 Butler, M.F., Clark, A.H., and Adams, S. (2006). Swelling and mechanical properties of biopolymer hydrogels containing chitosan and bovine serum albumin. Biomacromolecules 7 (11): 2961–2970.

163 163 Di Martino, A., Sittinger, M., and Risbud, M.V. (2005). Chitosan: a versatile biopolymer for orthopaedic tissue-engineering. Biomaterials 26 (30): 5983–5990.

164 164 Khan, R. and Dhayal, M. (2009). Chitosan/polyaniline hybrid conducting biopolymer base impedimetric immunosensor to detect Ochratoxin-A. Biosensors and Bioelectronics 24 (6): 1700–1705.

165 165 Xu, Z., Gao, N., Chen, H., and Dong, S. (2005). Biopolymer and carbon nanotubes interface prepared by self-assembly for studying the electrochemistry of microperoxidase-11. Langmuir 21 (23): 10808–10813.