Analysis biomaterials

Gurny, R. Meyer, J.M. Peppas, N.A. Bioadhesive intraoral release systems design, testing, and analysis. Biomaterials 1984, 5, 336-340. 

Knowles JC, Gross K, Berndt CC, Bonfield W (1996) Stmctural changes of thermally sprayed hydroxylapatite investigated by Rietveld Analysis. Biomaterials 17 639-645 Kobayashi T, Nakamura S, Yamashita K (2001) Enhanced osteobonding by negative surface charges of electrically polarized hydroxylapatite. J Biomed Mater Res 57 477-484 Kokubo T (1998) Apatite formation on surfaces of ceramics, metals and polymers in body enviromnent. Acta Materi a 46 2519-27... 

Title A New Method for Analysis Biomaterial Surfaces of the Adsorbed Plasma Protein Layer on... 

Mao JS et al (2004) A preliminary study on chitosan and gelatin polyelectrolyte complex cytocompatibility by cell cycle and apoptosis analysis. Biomaterials 25(18) 3973-3981... 

Z. Zhang,R.Guidoin,M.W.King,T.V. How,Y.Marois and G.Laroche, Removing fresh tissue from explanted polyurethane prostheses which approach facilitates physico-chemical analysis . Biomaterials, vol. 16, no. 5, pp. 369-380,1995. 

Fraunhofer, X A. and Sichina, W. X (1992). Characterization of surgical suture materials using dynamic mechanical analysis. Biomaterials, 13 (10), 715-720. 

Ginebra M., Driessens F.C.M., and PlaneU [.A. Effect of the particle size on the micro and nano-structural features of a calcium phosphate cement a kinetic analysis. Biomaterials 2004 25 3453-3462. 

XPS has been used in almost every area in which the properties of surfaces are important. The most prominent areas can be deduced from conferences on surface analysis, especially from ECASIA, which is held every two years. These areas are adhesion, biomaterials, catalysis, ceramics and glasses, corrosion, environmental problems, magnetic materials, metals, micro- and optoelectronics, nanomaterials, polymers and composite materials, superconductors, thin films and coatings, and tribology and wear. The contributions to these conferences are also representative of actual surface-analytical problems and studies [2.33 a,b]. A few examples from the areas mentioned above are given below more comprehensive discussions of the applications of XPS are given elsewhere [1.1,1.3-1.9, 2.34—2.39]. 

Sundback CA, Shyu JY, Wang YD, Faquin WC, Danger RS, Vacanti JP, and Hadlock TA. Biocompatibility analysis of poly(glycerol sebacate) as a nerve guide material. Biomaterials, 2005, 26, 5454-5464. 

Green RJ, Frazier RA, Shakesheff KM, Davies MC, Roberts CJ, Tendler SJB (2000) Surface plasmon resonance analysis of dynamic biological interactions with biomaterials. Biomaterials 21 1823-1835... 

Ko I-K, Kato K, Iwata H (2005) Parallel analysis of multiple surface markers expressed on rat neural stem cells using antibody microarrays. Biomaterials 26 4882 -891... 

This presentation addresses tissue engineering and how it relates to biomaterials and medical devices. Consideration is given to risk analysis and risk management in tissue engineering, and current proposals are discussed for an approach to the regulation of tissue engineering products and regulatory processes in the European Union. EUROPEAN COMMUNITY EUROPEAN UNION UK WESTERN EUROPE... 

The enormous temperatures attained on resistively heated sample holders can also be used to intentionally enforce the decomposition of non-volatile samples, thereby yielding characteristic pyrolysis products. Pyrolysis mass spectrometry (Py-MS) can be applied to synthetic polymers, [54] fossil biomaterial, [55] food [56] and soil [57] analysis and even to characterize whole bacteria. [58]... 

Castillo, E. J., Koenig, J. L., Anderson, J. M., Kliment, C. K., and Lo, J. Surface analysis of biomedical polymers by attenuated total reflectance-fourier transform infra-red. Biomaterials 1984, 5(4), 186-193. 

The molecules produced by living organisms, natural products, are employed in our lives as flavors, fragrances, pharmaceuticals, nontraditional medicines, dyes, and pesticides, among other uses. The products of chemistry are employed in our food as preservatives, artificial sweeteners, thickeners, dyes, taste enhancers, flavors, and textnring agents. Chemistry creates such key materials as plastics, ceramics, fabrics, alloys, semiconductors, liquid crystals, optical media, and biomaterials. Chemistry also does many kinds of analysis and these include measurements of air quahty, water quality, food safety, and the search for substances that compromise the enviromnent or workplace safety. 

Smith JR, Kholodovych V, Knight D, Welsh WJ, Kohn J (2005) QSAR models for the analysis of bioresponse data from combinatorial libraries of biomaterials. QSAR Comb Sci 24 99-113... 

F.FI. Jones, B.M. Hutton, P.C. Hadley, A.J. Eccles, T.A. Steele, R.W. Billington, G. J. Pearson, Fluoride uptake by glass ionomer cements A surface analysis approach. Biomaterials 24 (2003) 107-119. 

This volume has been arranged in five chapters aimed at discussing nanostructured materials and methods of their characterization (Chapter I), advanced express-methods for detection and analysis of biological species (Chapter II), methods of protection (Chapter III) and medical treatment (Chapter IV) of patients with incorporated contaminants, and specifically extracorporeal methods of decontamination of the human body (Chapter V). All papers in this book have been peer reviewed prior to publication. We believe that this volume will be of major interest to researchers and students working in the area of materials science and engineering, chemistry, biosensors, biomaterials, extracorporeal methods, and therapeutics. 

Redox enzymes are the active component in many electrochemical enzyme electrode biosensor devices.1821 The integration of two different redox enzymes with an electrode support, in which one of the biocatalysts is photoswitchable between ON and OFF states, can establish a composite multisensor array. The biomaterial interface that includes the photoswitchable enzyme in the OFF state electrochemi-cally transduces the sensing event of the substrate corresponding to the nonphoto-switchable enzyme. Photochemical activation of the light-active enzyme leads to the full electrochemical response, corresponding to the analysis of the substrates of the two enzymes. As a result, the processing of the signals transduced by the composite biomaterial interface in the presence of the two substrates permits the assay of the... 

Szpunar, J., Ceulemans, M., Schmitt, VO., Adams, F.C. and Lobinski, R. (1996) Microwave-accelerated speciation analysis for butyltin compounds in sediments and biomaterials by large volume injection capillary gas chromatography quartz furnace atomic absorption spectrometry. Anal. Chim. Acta, 332, 225-232. 

Over the last 40 yr, an increasing number of researchers studied various methods of protein immobilization and have found widespread application for these methods in many biotechnology areas such as clinical analysis, therapeutic medicine, and the production of biomaterials (7). Among these techniques, adsorption of proteins is very simple, mild, and reversible, permitting reuse of both enzyme and the support (8). Applications of immobilized or adsorbed enzymes as specific catalysts have gained new routes in modern applied chemistry (9). 

Edwards, El. G. M. (2004). Forensic applications of Raman spectroscopy to the nondestructive analysis of biomaterials and their degradation, in Forensic Geoscience Principles, Techniques and Applications (K. Pye and D. J. Croft, Eds.). London Geological Society Special Publication 232,159-170. 

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