Диссертация (Эластомерные материалы на основе бутадиен-стирольных термоэластопластов с повышенной устойчивостью к образованию бактериальных биопленок), страница 22
Описание файла
Файл "Диссертация" внутри архива находится в папке "Эластомерные материалы на основе бутадиен-стирольных термоэластопластов с повышенной устойчивостью к образованию бактериальных биопленок". PDF-файл из архива "Эластомерные материалы на основе бутадиен-стирольных термоэластопластов с повышенной устойчивостью к образованию бактериальных биопленок", который расположен в категории "". Всё это находится в предмете "технические науки" из Аспирантура и докторантура, которые можно найти в файловом архиве РТУ МИРЭА. Не смотря на прямую связь этого архива с РТУ МИРЭА, его также можно найти и в других разделах. Архив можно найти в разделе "остальное", в предмете "диссертации и авторефераты" в общих файлах, а ещё этот архив представляет собой кандидатскую диссертацию, поэтому ещё представлен в разделе всех диссертаций на соискание учёной степени кандидата технических наук.
Просмотр PDF-файла онлайн
Текст 22 страницы из PDF
Van Den Heuvel //Antimicrobial Agents and Chemotherapy. — 2012. — Vol.56. — Issue 9. — P.49614964.69. Chen, G. Bacterial adhesion to silica sand as related to Gibbs energyvariations / G. Chen, H. Zhu // Colloids and Surfaces B: Biointerfaces. — 2005. —Vol.44.
— Issue 1. — P.41-48.70. Zhao, Q. Effect of surface free energy of graded Ni-P-PTFE coatings onbacterial adhesion / Q. Zhao // Surface and Coatings Technology. — 2004. —Vol.185. — Issue 2-3. — P.199-204.71. Nill, P. Studying bacterial adhesion forces: Staphylococcus aureus onelastic poly(dimethyl)siloxane substrates / P. Nill, R. Loeffler, D.P. Kern, N.Goehring, A.
Peschel // 36th International Conference on Micro & NanoEngineering. Genoa, 19-22 September 2010. — P.178.72. Bayoudh, S. Quantification of the adhesion free energy between bacteriaand hydrophobic and hydrophilic substrata / S. Bayoudh, A. Othmane, F. Bettaieb, A.Bakhrouf, H.B. Ouada, L. Ponsonnet // Materials Science and Engineering: C.
—2006. — Vol. 26. — Issue 2-3. — P. 300-305.73. Satriano, C. Bacterial adhesion onto nanopatterned polymer surfaces / C.Satriano, G.M.L. Messina, S. Carnazza, S. Guglielmino, G. Marletta // MaterialsScience and Engineering: C. — 2006. — Vol. 26. — Issue 5-7. — P. 942-946.13574. Boks, N.P. Mobile and immobile adhesion of staphylococcal strains tohydrophilic and hydrophobic surfaces / N.P.
Boks, H.J. Kaper, W. Norde, H.C. vander Mei, H.J. Busscher // Journal of Colloid and Interface Science. — 2009. — Vol.331. — Issue 1. — P. 60-64.75. Tsibouklis, J. Preventing bacterial adhesion onto surfaces: the low-surfaceenergy approach / J. Tsibouklis, M. Stone, A.A. Thorpe, P. Graham, V. Peters, R.Heerlien, J.R. Smith, K.L. Green, T.G. Nevell // Biomaterials. — 1999. — Vol.20. —Issue 13.
— P. 1229-1235.76. Thorpe, A.A. Poly(methylpropenoxyfluoroalkylsiloxane)s: a class offluoropolymers capable of inhibiting bacterial adhesion onto surfaces / A.A. Thorpe,V. Peters, J.R. Smith, T.G. Nevell, J. Tsibouklis // Journal of Fluorine Chemistry. —2000. — Vol.104. — Issue 1. — P. 37-45.77. Yeniyol, C.O. Bacterial colonization of double J stents and bacteriuriafrequency / C.O. Yeniyol, A. Tuna, H. Yener, N. Zeyrek, A. Tilki, A.
Coskuner //International Urology and Nephrology. — 2002. — Vol. 34. — Issue 2. — P. 199202.78. Sohn, E.-H. Inhibition of bacterial adhesion on well ordered comb-likepolymer surfaces / E.-H. Sohn, J. Kim, B.G. Kim, J.I. Kang, J.-S. Chung, J. Ahn, J.Yoon, J.-C. Lee // Colloids and Surfaces B: Biointerfaces. — 2010. — Vol.77. —Issue 2. — P.191-199.79. Nejadnik, M.R. Bacterial adhesion and growth on a polymer brush-coating/ M.R. Nejadnik, H.C. van der Mei, W. Norde, H.J. Busscher // Biomaterials.
—2008. — Vol. 29. — Issue 30. — P. 4117-4121.80. Ostuni, E. Self-assembled monolayers that resist the adsorption of proteinsand the adhesion of bacterial and mammalian cells / E. Ostuni, R.G. Chapman, M.N.Liang, G. Meluleni, G. Pier, D.E. Ingber, G.M. Whitesides // Langmuir: the ACSjournal of surfaces and colloids. — 2001.
— Vol. 17. — Issue 20. — P. 6336-6343.81. Ki, D.P. Bacterial adhesion on PEG modified polyurethane surfaces / D.P.Ki, S.K. Young, K.H. Dong, H.K. Young, H.B.L. Eun, S. Hwal, S.C. Kyu //Biomaterials. — 1998. — Vol. 19. — Issue 7-9. — P. 851-859.13682. Bruinsma, G.M. Bacterial adhesion to surface hydrophilic and hydrophobiccontact lenses / G.M. Bruinsma, H.C.
van der Mei, H.J. Busscher // Biomaterials. —2001. — Vol. 22. — Issue 24. — P. 3217-3224.83. Herrero, M. Controlled wet-chemical modification and bacterial adhesionon PVC-surfaces / M. Herrero, R. Navarro, Y. Grohens, H. Reinecke, C. Mijangos //Polymer Degradation and Stability. — 2006. — Vol.
91. — Issue 9. — P. 19151918.84. Krsko, P. Spatially controlled bacterial adhesion using surface-patternedpoly(ethylene glycol) hydrogels / P. Krsko, J.B. Kaplan, M. Libera // ActaBiomaterialia. — 2009. — Vol. 5. — Issue 2. — P. 589-596.85. Saldarriaga Fernandez, I.C. The inhibition of the adhesion of clinicallyisolated bacterial strains on multi-component cross-linked poly(ethylene glycol)based polymer coatings / I.C. Saldarriaga Fernandez, H.C.
van der Mei, M.J.Lochhead, D.W. Grainger, H.J. Busscher // Biomaterials. — 2007. — Vol. 28. —Issue 28. — P. 4105-4112.86. Lee, H.J. Platelet and bacterial repellence on sulfonated poly(ethyleneglycol)-acrylate copolymer surfaces / H.J. Lee, K.D. Park, H.D. Park, W.K. Lee,D.K. Han, S.H. Kim, Y.H. Kim // Colloids and Surfaces B: Biointerfaces. — 2000.— Vol. 18. — Issue 3-4. — P. 355-370.87. Baumgartner, J.N. Physical property analysis and bacterial adhesion on aseries of phosphonated polyurethanes / J.N. Baumgartner, Z.Y. Chang, S.L.
Cooper //Biomaterials. — 1997. — Vol. 18. — Issue 12. — P. 831-837.88. Park, J.H. Assessment of PEO/PTMO multiblock copolymer/segmentedpolyurethane blends as coating materials for urinary catheters: in vitro bacterialadhesion and encrustation behavior / J.H. Park, Y.W.
Cho, I.C. Kwon, S.Y. Jeong,Y.H. Bae // Biomaterials. — 2002. — Vol. 23. — Issue 19. — P. 3991-4000.89. Karabanova, L.V. Semi-interpenetrating polymer networks based onpolyurethane and poly(vinyl pyrrolidone) obtained by photopolymerization:structure-property relationships and bacterial adhesion / L.V. Karabanova, L.M.137Sergeeva, S.V. Mikhalovska, S.T. Meikle, M. Helias, W. Lloyd // PolymerEngineering and Science. — 2004. — Vol. 44. — Issue 5. — P. 940-947.90.
Shi, L. Mucin coating on polymeric material surfaces to suppress bacterialadhesion / L. Shi, R. Ardehali, K.D. Caldwell, P. Valint // Colloids and Surfaces B:Biointerfaces. — 2000. — Vol. 17. — Issue 4. — P. 229-239.91. Chua, P.H. Surface functionalization of titanium with hyaluronicacid/chitosan polyelectrolyte multilayers and RGD for promoting osteoblastfunctions and inhibiting bacterial adhesion / P.H. Chua, K.G.
Neoh, E.T. Kang, W.Wang // Biomaterials. — 2008. — Vol. 29. — Issue 10. — P. 1412-1421.92. Cadieux, P. Potential application of polyisobutylene-polystyrene and alactobacillus protein to reduce the risk of device-associated urinary tract infections /P. Cadieux, J.D. Watterson, J. Denstedt, R.R. Harbottle, J. Puskas, J. Howard, B.S.Gan, G.
Reid // Colloids and Surfaces B: Biointerfaces. — 2003. — Vol. 28. — Issue2-3. — P. 95-105.93. DiTizio, V. A liposomal hydrogel for the prevention of bacterial adhesionto catheters / V. DiTizio, G.W. Ferguson, M.W. Mittelman, A.E. Khoury, A.W.Bruce, F. DiCosmo // Biomaterials. — 1998. — Vol. 19. — Issue 20. — P. 18771884.94. Arciola, C.R. Disposable contact lenses and bacterial adhesion. In vitrocomparison between ionic/high-water-content and non-ionic/low-water-contentlenses / C.R. Arciola, E.
Cenni, A. Pizzoferrato, M.C. Maltarello // Biomaterials. —1995. — Vol. 16. — Issue 9. — P. 685-690.95. Wei J. Stainless steel modified with poly(ethylene glycol) can preventprotein adsorption but not bacterial adhesion / J. Wei, D.B.
Ravn, L. Gram, P.Kingshott // Colloids and Surfaces B: Biointerfaces. — 2003. — Vol. 32. — Issue 4.— P. 275-291.96. Kiil, S. Seawater-soluble pigments and their potential use in self-polishingantifouling paints: simulation-based screening tool / S. Kiil, K. Dam-Johansen, C.E.Weinell, M.S.
Pedersen // Progress in Organic Coatings. — 2002. — Vol. 45. —Issue 4. — P. 423-434.13897. Monfared, H. Design guidelines for development of tin-free antifoulingself-polishing coatings using simulation / H. Monfared, F. Sharif // Progress inOrganic Coatings. — 2008. — Vol. 63. — Issue 1. — P.
79-86.98. Yebra, D.M. Antifouling technology — past, present and future stepstowards efficient and environmentally friendly antifouling coatings / D.M. Yebra, S.Kiil, K. Dam-Johansen // Progress in Organic Coatings. — 2004. — Vol. 50. — Issue2. — P. 75-104.99.
Samui, A.B. Study on film forming organo-copper polymer / A.B. Samui,J.G. Chavan, V.R. Hande // Progress in Organic Coatings. — 2006. — Vol. 57. —Issue 4. — P. 301-306.100. Ananda Kumar, S. Studies on novel silicone/phosphorus/sulphurcontaining nano-hybrid epoxy anticorrosive and antifouling coatings / S. AnandaKumar, A. Sasikumar // Progress in Organic Coatings. — 2010. — Vol. 68. — Issue3. — P. 189-200.101. Joyce, T.J.
Quantification of self-polishing in vivo from explanted metalon-metal total hip replacements / T.J. Joyce, H. Grigg, D.J. Langton, A.V.F. Nargol //Tribology International. — 2011. — Vol. 44. — Issue 5. — P. 513–516.102. De La Rosa, V.R. Poly(2-oxazoline)s as materials for biomedicalapplications / V.R. De La Rosa // Journal of Materials Science: Materials inMedicine.
— 2014. — Vol. 25. — Issue 5. — P. 1211-1225.103. Valkirs, A.O. Measurement of copper release rates from antifouling paintunder laboratory and in situ conditions: implications for loading estimation to marinewater bodies / A.O. Valkirs, P.F. Seligman, E. Haslbeck, J.S. Caso // MarinePollution Bulletin. — 2003. — Vol. 46. — Issue 6. — P. 763-779.104. Camail, M. New acrylic titanium polymers: 1.
Synthesis andcharacterisation of new titanium trialkoxide methacrylate monomers prepared via theesterification of methacrylic acid by titanium tetraalkoxides / M. Camail, M.Humbert, A. Margaillan, A. Riondel, J.L. Vernet // Polymer. — 1998. — Vol. 39. —Issue 25. — P. 6525-6531.139105. Camail, M. New acrylic titanium polymers: 2. Synthesis andcharacterization of organotitanium polymers / M. Camail, M.
Humbert, A.Margaillan, J.L. Vernet // Polymer. — 1998. — Vol. 39. — Issue 25. — P. 65336539.106. Li, J. Antimicrobial cellulose modified with nanotitania and cyclic n halamine / J. Li, Y. Liu, Z. Jiang, K. Ma, X. Ren, T.-S. Huang // Industrial andEngineering Chemistry Research. — 2014.
— Vol. 53. — Issue 33. — P. 1305813064.107. Yonehara, Y. A new antifouling paint based on a zinc acrylate copolymer/ Y. Yonehara, H. Yamashita, C. Kawamura, K. Itoh // Progress in Organic Coatings.— 2001. — Vol. 42. — Issue 3-4. — P. 150-158.108. Mirabedini S.M. Comparison of drag characteristics of self-polishing copolymers and silicone foul release coatings: a study of wettability and surfaceroughness / S.M. Mirabedini, S.
Pazoki, M. Esfandeh, M. Mohseni, Z. Akbari //Progress in Organic Coatings. — 2006. — Vol. 57. — Issue 4. — P. 421-429.109. Bakhshi, H. Castor oil-based polyurethane coatings containing benzyltriethanol ammonium chloride: synthesis, characterization, and biological properties /H. Bakhshi, H. Yeganeh, A. Yari, S.K. Nezhad // Journal of Materials Science. —2014.
— Vol. 49. — Issue 15. — P. 5365-5377.110. Coma, V. Recent advances on the development of antibacterialpolysaccharide-based materials / V. Coma, V. Freire, A.J.D. Silvestre //Polysaccharides:Bioactivity andBiotechnology. — Springer InternationalPublishing, 2015. — P. 1751-1803.111. Yebra, D.M. Effects of marine microbial biofilms on the biocide releaserate from antifouling paints-a model-based analysis / D.M. Yebra, S. Kiil, C.E.Weinell, K. Dam-Johansen // Progress in Organic Coatings. — 2006. — Vol. 57.
