Littérature scientifique sur le sujet « Biomedical materials »
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Articles de revues sur le sujet "Biomedical materials"
Barenberg, S. A., et E. P. Mueller. « Biomedical Materials ». MRS Bulletin 16, no 9 (septembre 1991) : 22–25. http://dx.doi.org/10.1557/s0883769400056001.
Texte intégralMikos, Antonios G. « Multiphase biomedical materials ». Journal of Controlled Release 16, no 3 (août 1991) : 366–67. http://dx.doi.org/10.1016/0168-3659(91)90016-7.
Texte intégralMikos, Antonios G. « Multiphase biomedical materials ». Journal of Controlled Release 17, no 2 (octobre 1991) : 207. http://dx.doi.org/10.1016/0168-3659(91)90060-q.
Texte intégralMohammed, Mohsin T., Zahid A. Khan et Arshad N. Siddiquee. « Corrosion in Biomedical Grade Titanium Based Materials : A Review ». Indian Journal of Applied Research 3, no 9 (1 octobre 2011) : 206–10. http://dx.doi.org/10.15373/2249555x/sept2013/65.
Texte intégralHelmus, Michael N. « Overview of Biomedical Materials ». MRS Bulletin 16, no 9 (septembre 1991) : 33–38. http://dx.doi.org/10.1557/s0883769400056025.
Texte intégralTANAKA, Mototsugu. « Forefront in Biomedical Materials ». Journal of the Society of Materials Science, Japan 68, no 8 (15 août 2019) : 656–61. http://dx.doi.org/10.2472/jsms.68.656.
Texte intégralMIZUTANI, Masayoshi, Yuichi OTSUKA et Shoichi KIKUCHI. « Forefront in Biomedical Materials ». Journal of the Society of Materials Science, Japan 68, no 9 (15 septembre 2019) : 723–29. http://dx.doi.org/10.2472/jsms.68.723.
Texte intégralHISAMORI, Noriyuki, Takuya ISHIMOTO et Takayoshi NAKANO. « Forefront in Biomedical Materials ». Journal of the Society of Materials Science, Japan 68, no 10 (15 octobre 2019) : 798–803. http://dx.doi.org/10.2472/jsms.68.798.
Texte intégralOYA, Kei, Shogo MIYATA et Yusuke MORITA. « Forefront in Biomedical Materials ». Journal of the Society of Materials Science, Japan 68, no 11 (15 novembre 2019) : 865–70. http://dx.doi.org/10.2472/jsms.68.865.
Texte intégralIKADA, YOSHITO. « Fibers as Biomedical Materials ». Sen'i Gakkaishi 47, no 3 (1991) : P120—P125. http://dx.doi.org/10.2115/fiber.47.p120.
Texte intégralThèses sur le sujet "Biomedical materials"
Cabanach, Xifró Pol. « Zwitterionic materials for biomedical applications ». Doctoral thesis, Universitat Ramon Llull, 2021. http://hdl.handle.net/10803/671831.
Texte intégralLa respuesta de nuestro cuerpo a los biomateriales supone un gran obstáculo para la efectividad de múltiples terapias basadas en los biomateriales. Accionados por la absorción de biomoléculas en la superficie del material, barreras como el sistema inmune o las superficies mucosas eliminan los materiales del cuerpo, evitando que lleguen a su destino y realicen su función. Los materiales zwitteriónicos han emergido en los últimos años como materiales antiadherentes prometedores para superar las barreras mencionadas. Aunque muchos sistemas utilizan materiales zwitteriónicos como recubrimientos, sus propiedades únicas de superhidrofilicidad i versatilidad química sugieren múltiples beneficios en utilizarlos como material principal. Aquí, dos sistemas basados en materiales zwitteriónicos son presentados. En primer lugar, una plataforma para la liberación de fármaco antiadherente basada en copolímeros de bloque amfifílicos (CBA) es desarrollada. Los CBA zwitteriónicos son sintetizados y optimizados para que se auto-organicen en nanopartículas zwitteriónicas. Las propiedades antiadherentes de estas nanopartículas son probadas, al igual que su potencial para convertirse en un sistema oral de liberación de fármaco. Seguidamente, el sistema se utiliza como portador para fármacos animalarios y anticancerígenos. Las nanopartículas muestran internalización en eritrocitos infectados por Plasmodio, y nanopartículas cargadas con curcumina demuestran su eficacia contra la malaria in vitro. Se observa la absorción oral de polímero y curcumina in vivo utilizando un modelo de ratón, indicando el potencial del sistema para convertirse en una terapia oral contra malaria. Cuando se optimiza el sistema para la terapia contra el cáncer, las nanopartículas cargadas con Paclitaxel exhiben actividad anticancerígena en modelos in vitro de células cancerosas. En segundo lugar, microrobots zwitteriónicos no-inmunológicos que pueden evitar el reconocimiento por parte del sistema inmune son introducidos. Se desarrolla una fotoresisténcia zwitteriónica para la microimpresión de microrobots zwitteriónicos a través de la polimerización de dos fotones con una amplia funcionalización: propiedades mecánicas variables, anti-bioadhesión i propiedades no-inmunogénicas, funcionalización para la actuación magnética, encapsulación de biomoléculas i modificación superficial para la liberación de fármaco. Los robots invisibles evitan que los macrófagos del sistema inmune innato los detecten después de una inspección exhaustiva (de más de 90 horas), hecho que no se ha conseguido hasta la fecha por ningún sistema microrobótico. Estos materiales zwitteriónicos versátiles eliminan uno de los grandes obstáculos en el desarrollo de microrobots biocompatibles, y servirán como una caja de herramientas de materiales no-inmunogénicos para crear robots biomédicos y otros dispositivos para la bioingeniería y para las aplicaciones biomédicas.
Body response to biomaterials suppose a major roadblock for the effectiveness of multiple biomaterial-based therapies. Triggered by unspecific absorption of biomolecules in the material surface, barriers such as immune system or mucosal surfaces clear foreign materials from the body, preventing them to reach their target and perform their function. Zwitterionic materials have emerged in the last years as promising antifouling materials to overcome the mentioned barriers. Although many systems have used zwitterionic materials as coatings, the unique properties of superhydrophilicity and chemical versatility suggest multiple benefits of using zwitterionic polymers as bulk materials. Here, two different systems based on zwitterionic materials are presented. In first place, an antifouling drug delivery platform based on zwitterionic amphiphilic polymers (ABC) is developed. Zwitterionic ABCs are synthetized and optimized to self-assemble in zwitterionic nanoparticles. The antifouling properties of zwitterionic nanoparticles are proved, together with their potential to become an oral drug delivery system. Next, the system is used as a drug carrier for antimalarial and anticancer drugs. Nanoparticles show internalization in Plasmodium infected erythrocytes, and curcumin-loaded nanoparticles prove their antimalarial efficacy in vitro. Oral absorption of polymer and curcumin is also observed in vivo using mice model, indicating the potential of this system to become oral therapy against malaria. When optimizing the system for anticancer therapy, Paclitaxel-loaded nanoparticles exhibit anticancer activity in in vitro cancer cell models. Second, non‐immunogenic stealth zwitterionic microrobots that avoid recognition from immune cells are introduced. Zwitterionic photoresist are developed for the 3D microprinting of zwitterionic hydrogel microrobots through 2-photon polymerization with ample functionalization: tunable mechanical properties, anti-biofouling and non-immunogenic properties, functionalization for magnetic actuation, encapsulation of biomolecules, and surface functionalization for drug delivery. Stealth microrobots avoid detection by macrophage cells of the innate immune system after exhaustive inspection (> 90 h), which has not been achieved in any microrobotic platform to date. These versatile zwitterionic materials eliminate a major roadblock in the development of biocompatible microrobots, and will serve as a toolbox of non-immunogenic materials for medical microrobot and other device technologies for bioengineering and biomedical applications.
Parker, Rachael N. « Protein Engineering for Biomedical Materials ». Diss., Virginia Tech, 2017. http://hdl.handle.net/10919/77416.
Texte intégralPh. D.
Almeida, José Carlos Martins de. « Hybrid materials for biomedical applications ». Doctoral thesis, Universidade de Aveiro, 2016. http://hdl.handle.net/10773/15973.
Texte intégralThe increased longevity of humans and the demand for a better quality of life have led to a continuous search for new implant materials. Scientific development coupled with a growing multidisciplinarity between materials science and life sciences has given rise to new approaches such as regenerative medicine and tissue engineering. The search for a material with mechanical properties close to those of human bone produced a new family of hybrid materials that take advantage of the synergy between inorganic silica (SiO4) domains, based on sol-gel bioactive glass compositions, and organic polydimethylsiloxane, PDMS ((CH3)2.SiO2)n, domains. Several studies have shown that hybrid materials based on the system PDMS-SiO2 constitute a promising group of biomaterials with several potential applications from bone tissue regeneration to brain tissue recovery, passing by bioactive coatings and drug delivery systems. The objective of the present work was to prepare hybrid materials for biomedical applications based on the PDMS-SiO2 system and to achieve a better understanding of the relationship among the sol-gel processing conditions, the chemical structures, the microstructure and the macroscopic properties. For that, different characterization techniques were used: Fourier transform infrared spectrometry, liquid and solid state nuclear magnetic resonance techniques, X-ray diffraction, small-angle X-ray scattering, smallangle neutron scattering, surface area analysis by Brunauer–Emmett–Teller method, scanning electron microscopy and transmission electron microscopy. Surface roughness and wettability were analyzed by 3D optical profilometry and by contact angle measurements respectively. Bioactivity was evaluated in vitro by immersion of the materials in Kokubos’s simulated body fluid and posterior surface analysis by different techniques as well as supernatant liquid analysis by inductively coupled plasma spectroscopy. Biocompatibility was assessed using MG63 osteoblastic cells. PDMS-SiO2-CaO materials were first prepared using nitrate as a calcium source. To avoid the presence of nitrate residues in the final product due to its potential toxicity, a heat-treatment step (above 400 °C) is required. In order to enhance the thermal stability of the materials subjected to high temperatures titanium was added to the hybrid system, and a material containing calcium, with no traces of nitrate and the preservation of a significant amount of methyl groups was successfully obtained. The difficulty in eliminating all nitrates from bulk PDMS-SiO2-CaO samples obtained by sol-gel synthesis and subsequent heat-treatment created a new goal which was the search for alternative sources of calcium. New calcium sources were evaluated in order to substitute the nitrate and calcium acetate was chosen due to its good solubility in water. Preparation solgel protocols were tested and homogeneous monolithic samples were obtained. Besides their ability to improve the bioactivity, titanium and zirconium influence the structural and microstructural features of the SiO2-TiO2 and SiO2-ZrO2 binary systems, and also of the PDMS-TiO2 and PDMS-ZrO2 systems. Detailed studies with different sol-gel conditions allowed the understanding of the roles of titanium and zirconium as additives in the PDMS-SiO2 system. It was concluded that titanium and zirconium influence the kinetics of the sol-gel process due to their different alkoxide reactivity leading to hybrid xerogels with dissimilar characteristics and morphologies. Titanium isopropoxide, less reactive than zirconium propoxide, was chosen as source of titanium, used as an additive to the system PDMS-SiO2-CaO. Two different sol-gel preparation routes were followed, using the same base composition and calcium acetate as calcium source. Different microstructures with high hydrophobicit were obtained and both proved to be biocompatible after tested with MG63 osteoblastic cells. Finally, the role of strontium (typically known in bioglasses to promote bone formation and reduce bone resorption) was studied in the PDMS-SiO2-CaOTiO2 hybrid system. A biocompatible material, tested with MG63 osteoblastic cells, was obtained with the ability to release strontium within the values reported as suitable for bone tissue regeneration.
O aumento da longevidade dos seres humanos e a procura de uma melhor qualidade de vida têm conduzido a uma pesquisa contínua de novos materiais para implantes. O desenvolvimento científico, juntamente com uma crescente multidisciplinaridade entre as ciências dos materiais e as ciências da vida deram origem a novas abordagens, como a medicina regenerativa e a engenharia de tecidos. A busca de um material com propriedades mecânicas próximas das do osso humano produziu uma nova família de materiais híbridos que tiram partido da sinergia entre os domínios inorgânicos de sílica (SiO4), com base em composições de vidros bioativos obtidos por sol-gel, e os domínios orgânicos de polidimetilsiloxano, PDMS ((CH3)2.SiO2)n. Vários estudos têm demonstrado que os materiais híbridos baseados no sistema PDMS-SiO2 constituem um grupo de biomateriais promissores com várias aplicações potenciais tais como a regeneração de tecido ósseo e a recuperação do tecido cerebral, passando por revestimentos bioativos e sistemas de libertação controlada de fármacos. O objetivo do presente trabalho foi preparar materiais híbridos para aplicações biomédicas com base no sistema PDMS-SiO2 e contribuir para uma melhor compreensão das relações entre as condições de processamento sol-gel, as estruturas químicas, a microestrutura e as propriedades macroscópicas. Para alcançar tal objetivo, foram usadas diferentes técnicas de caracterização: espectroscopia de infravermelho por transformada de Fourier, ressonância magnética nuclear no estado sólido e no estado líquido, difração de raios-X, dispersão de raios-X de baixo ângulo, dispersão de neutrões de baixo ângulo, análise da área de superfície pelo método de Brunauer–Emmett–Teller, microscopia eletrónica de varrimento e microscopia eletrónica de transmissão. A rugosidade e a molhabilidade das superfícies foram analisadas por perfilometria óptica 3D e por medidas de ângulo de contacto, respectivamente. A bioatividade in vitro foi avaliada através de testes de imersão em plasma sintético e posterior observação da superfície dos materiais e análise do líquido sobrenadante por espectrometria de emissão atômica por plasma acoplado Indutivamente. A biocompatibilidade in vitro foi avaliada usando células osteoblásticas MG63. Materiais do sistema PDMS-SiO2-CaO foram inicialmente preparados usando o nitrato como fonte de cálcio. Para eliminar os resíduos de nitrato no produto final, devido à sua potencial toxicidade, é necessária uma etapa de tratamento térmico (acima dos 400° C). A fim de aumentar a estabilidade térmica dos materiais submetidos a altas temperaturas, foi adicionado titânio ao sistema híbrido. Obteve-se assim um material híbrido contendo cálcio, sem vestígios de nitrato, mantendo-se uma quantidade significativa de grupos metilo. A dificuldade de obter amostras monolíticas de híbridos PDMS-SiO2-CaO por síntese sol-gel e posterior tratamento térmico para eliminação de nitratos, criou um novo objetivo: a procura de fontes alternativas de cálcio. Novas fontes de cálcio foram avaliadas para substituir o nitrato tendo-se escolhido o acetato de cálcio devido à sua boa solubilidade em água. Estabeleceram-se protocolos de preparação por sol-gel a partir dos quais se obtiveram amostras monolíticas homogéneas. Além de melhorar a bioatividade, o titânio e o zircónio influenciam as características estruturais e microestruturais dos sistemas binários SiO2-TiO2 e SiO2-ZrO2, bem como dos sistemas PDMS-TiO2 e PDMS-ZrO2. Neste contexto, foram estudadas diferentes condições experimentais no processo sol-gel, de modo a compreender o papel destes aditivos no sistema SiO2-PDMS. Concluiu-se que o titânio e o zircónio influenciam a cinética do processo sol-gel devido à diferente reatividade dos despectivos alcóxidos, conduzindo à obtenção de xerogéis híbridos com diferentes características e morfologias. O isopropóxido de titânio, menos reativo do que o propóxido de zircónio, foi escolhido como fonte de titânio, usado como aditivo no sistema PDMS-SiO2CaO. Dois procedimentos diferentes de preparação por sol-gel foram seguidos, utilizando a mesma composição de base e o acetato de cálcio como fonte de cálcio. Foram obtidas diferentes microestruturas muito hidrofóbicas e ambas mostraram ser biocompatíveis após serem testadas com células osteoblásticas MG63. Finalmente, foi avaliado o papel do estrôncio (conhecido nos biovidros por favorecer a formação de tecido ósseo e reduzir a sua reabsorção) no sistema híbrido PDMS-CaO-SiO2-TiO2. O material produzido revelou-se biocompatível, através de testes com células osteoblásticas MG63, e com a capacidade de libertar estrôncio dentro dos limites considerados adequados para a reparação do tecido ósseo.
Sanami, Mohammad. « Auxetic materials for biomedical applications ». Thesis, University of Bolton, 2015. http://ubir.bolton.ac.uk/785/.
Texte intégralCapuccini, Chiara <1979>. « Biomimetic Materials for Biomedical Applications ». Doctoral thesis, Alma Mater Studiorum - Università di Bologna, 2009. http://amsdottorato.unibo.it/1447/1/chiara_capuccini_tesi.pdf.
Texte intégralCapuccini, Chiara <1979>. « Biomimetic Materials for Biomedical Applications ». Doctoral thesis, Alma Mater Studiorum - Università di Bologna, 2009. http://amsdottorato.unibo.it/1447/.
Texte intégralNiu, Ye. « Microparticulate Hydrogel Materials Towards Biomedical Applications ». The Ohio State University, 2020. http://rave.ohiolink.edu/etdc/view?acc_num=osu1586094812805108.
Texte intégralLiong, Monty. « Biomedical applications of mesostructured silica materials ». Diss., Restricted to subscribing institutions, 2009. http://proquest.umi.com/pqdweb?did=1905693461&sid=1&Fmt=2&clientId=1564&RQT=309&VName=PQD.
Texte intégralHercus, Beth Justine. « Modelling T lymphocyte reactions to biomedical materials ». Thesis, Queen Mary, University of London, 2005. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.423016.
Texte intégralLeadley, Robert Stuart. « The surface characterisation of novel biomedical materials ». Thesis, University of Nottingham, 1994. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.259860.
Texte intégralLivres sur le sujet "Biomedical materials"
Narayan, Roger, dir. Biomedical Materials. Cham : Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-49206-9.
Texte intégralNarayan, Roger, dir. Biomedical Materials. Boston, MA : Springer US, 2009. http://dx.doi.org/10.1007/978-0-387-84872-3.
Texte intégralM, Williams J., Nichols M. F, Zingg Walter 1924- et Materials Research Society, dir. Biomedical materials. Pittsburgh, Pa : Materials Research Society, 1986.
Trouver le texte intégralNarayan, Roger. Biomedical Materials. Boston, MA : Springer-Verlag US, 2009.
Trouver le texte intégralTsuruta, T., et A. Nakajima. Multiphase Biomedical Materials. London : CRC Press, 2021. http://dx.doi.org/10.1201/9780429087592.
Texte intégralDolah, Frances M. Van. Biomedical test materials program. Charleston, S.C : U.S. Dept. of Commerce, National Oceanic and Atmospheric Administration, National Marine Fisheries Service, Southeast Fisheries Center, Charleston Laboratory, 1990.
Trouver le texte intégralHelmus, Michael Nevin. Outlook for biomedical materials. Burlington, Mass : Decision Resources, 1990.
Trouver le texte intégralDolah, Frances M. Van. Biomedical test materials program. Charleston, S.C : U.S. Dept. of Commerce, National Oceanic and Atmospheric Administration, National Marine Fisheries Service, Southeast Fisheries Center, Charleston Laboratory, 1990.
Trouver le texte intégralB, Galloway Sylvia, et Southeast Fisheries Center (U.S.). Charleston Laboratory., dir. Biomedical test materials program. Charleston, S.C : U.S. Dept. of Commerce, National Oceanic and Atmospheric Administration, National Marine Fisheries Service, Southeast Fisheries Center, Charleston Laboratory, 1989.
Trouver le texte intégralDolah, Frances M. Van. Biomedical test materials program. Charleston, S.C : U.S. Dept. of Commerce, National Oceanic and Atmospheric Administration, National Marine Fisheries Service, Southeast Fisheries Center, Charleston Laboratory, 1990.
Trouver le texte intégralChapitres de livres sur le sujet "Biomedical materials"
Wong, Sharon Y., Mario Cabodi et Catherine M. Klapperich. « Biomedical Microdevices ». Dans Molecular Materials, 271–88. Boca Raton, FL : CRC Press, [2017] : CRC Press, 2017. http://dx.doi.org/10.1201/9781315118697-11.
Texte intégralPilliar, Robert M. « Metallic Biomaterials ». Dans Biomedical Materials, 1–47. Cham : Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-49206-9_1.
Texte intégralJin, Chunming, et Wei Wei. « Wear ». Dans Biomedical Materials, 365–81. Cham : Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-49206-9_10.
Texte intégralDoherty, Patrick. « Inflammation, Carcinogenicity, and Hypersensitivity ». Dans Biomedical Materials, 383–97. Cham : Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-49206-9_11.
Texte intégralMcKenzie, Janice L., Thomas J. Webster et J. L. McKenzie. « Protein Interactions at Material Surfaces ». Dans Biomedical Materials, 399–422. Cham : Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-49206-9_12.
Texte intégralPeters, Kirsten, Ronald E. Unger et C. James Kirkpatrick. « Biocompatibility Testing ». Dans Biomedical Materials, 423–53. Cham : Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-49206-9_13.
Texte intégralBhaduri, Sarit B., et Prabaha Sikder. « Biomaterials for Dental Applications ». Dans Biomedical Materials, 455–93. Cham : Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-49206-9_14.
Texte intégralWilliams, Rachel L., et David Wong. « Ophthalmic Biomaterials ». Dans Biomedical Materials, 495–515. Cham : Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-49206-9_15.
Texte intégralRabiei, Afsaneh. « Hip Prostheses ». Dans Biomedical Materials, 517–35. Cham : Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-49206-9_16.
Texte intégralFlynn, Lauren E., et Kimberly A. Woodhouse. « Burn Dressing Biomaterials and Tissue Engineering ». Dans Biomedical Materials, 537–80. Cham : Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-49206-9_17.
Texte intégralActes de conférences sur le sujet "Biomedical materials"
Huttunen, Assi, Petri Laakso, Ville Ellä, Riku Heikkilä et Minna Kellomäki. « Picosecond laser micromachining of biomedical materials ». Dans ICALEO® 2007 : 26th International Congress on Laser Materials Processing, Laser Microprocessing and Nanomanufacturing. Laser Institute of America, 2007. http://dx.doi.org/10.2351/1.5061131.
Texte intégralTommasini, Giuseppina, Francesca Di Maria, Mattia Zangoli, Marika Iencharelli, Mariarosaria De Simone, Angela Tino, Maria Moros et Claudia Tortiglione. « Engineered Living Materials for Biomedical Application ». Dans Advanced materials and devices for nanomedicine. València : Fundació Scito, 2022. http://dx.doi.org/10.29363/nanoge.amamed.2022.018.
Texte intégralFonash, Stephen J., J. Cuiffi, D. Hayes, W. J. Nam, Sanghoon Bae, Handong Li et A. K. Kalkan. « Nanostructured silicon for biomedical application ». Dans Smart Materials and MEMS, sous la direction de Derek Abbott, Vijay K. Varadan et Karl F. Boehringer. SPIE, 2001. http://dx.doi.org/10.1117/12.418778.
Texte intégralLiu, Kuo Kang, Z. H. Du, F. G. Tseng, Min-Chieh Chou, J. Y. Fang et C. C. Chieng. « Electroplated microneedle array for biomedical applications ». Dans Smart Materials and MEMS, sous la direction de Derek Abbott, Vijay K. Varadan et Karl F. Boehringer. SPIE, 2001. http://dx.doi.org/10.1117/12.418774.
Texte intégralPopovic, Dejan B., et Richard B. Stein. « Sensors and actuators for biomedical applications ». Dans Smart Structures & Materials '95, sous la direction de William B. Spillman, Jr. SPIE, 1995. http://dx.doi.org/10.1117/12.207666.
Texte intégralHattenhorst, Birk, Malte Mallach, Christoph Baer, Thomas Musch, Jan Barowski et Ilona Rolfes. « Dielectric phantom materials for broadband biomedical applications ». Dans 2017 First IEEE MTT-S International Microwave Bio Conference (IMBIOC). IEEE, 2017. http://dx.doi.org/10.1109/imbioc.2017.7965802.
Texte intégralDe Cola, Luisa. « Nanoparticles and hybrid materials for biomedical applications ». Dans Advanced materials and devices for nanomedicine. València : Fundació Scito, 2022. http://dx.doi.org/10.29363/nanoge.amamed.2022.004.
Texte intégralKirchhof, Johannes, Sonja Unger et Anka Schwuchow. « Fiber lasers : materials, structures and technologies ». Dans Biomedical Optics 2003, sous la direction de Israel Gannot. SPIE, 2003. http://dx.doi.org/10.1117/12.498062.
Texte intégralNowak, Michael D. « Combined Mechanical Engineering Materials Lecture and Mechanics of Materials Laboratory : Cross-Disciplinary Teaching ». Dans ASME 2005 International Mechanical Engineering Congress and Exposition. ASMEDC, 2005. http://dx.doi.org/10.1115/imece2005-82008.
Texte intégralShahidi, Mehran, Bernhard Pichler et Christian Hellmich. « Micromechanics of Viscous Interfaces in Hydrated (Bio-)Materials ». Dans Biomedical Engineering. Calgary,AB,Canada : ACTAPRESS, 2013. http://dx.doi.org/10.2316/p.2013.791-172.
Texte intégralRapports d'organisations sur le sujet "Biomedical materials"
Chait, Richard, et Julius Chang. Roundtable on Biomedical Engineering Materials and Applications. Fort Belvoir, VA : Defense Technical Information Center, septembre 2001. http://dx.doi.org/10.21236/ada396606.
Texte intégralChait, Richard, Teri Thorowgood et Toni Marechaux. Roundtable on Biomedical Engineering Materials and Applications. Fort Belvoir, VA : Defense Technical Information Center, septembre 2002. http://dx.doi.org/10.21236/ada407761.
Texte intégralChait, Richard, Toni Marechaux et Emily A. Meyer. Roundtable on Biomedical Engineering Materials and Application. Fort Belvoir, VA : Defense Technical Information Center, septembre 2003. http://dx.doi.org/10.21236/ada417008.
Texte intégralChait, Richard. Roundtable on Biomedical Engineering Materials and Applications. Fort Belvoir, VA : Defense Technical Information Center, septembre 2000. http://dx.doi.org/10.21236/ada391253.
Texte intégralHall, Dale, et John Tesk. Workshop on standards for biomedical materials and devices, June 13-14, 2001. Gaithersburg, MD : National Institute of Standards and Technology, 2001. http://dx.doi.org/10.6028/nist.ir.6791.
Texte intégralBrow, R. K., D. R. Tallant et S. V. Crowder. Advanced materials for aerospace and biomedical applications : New glasses for hermetic titanium seals. Office of Scientific and Technical Information (OSTI), novembre 1996. http://dx.doi.org/10.2172/510597.
Texte intégralStepanyuk, Alla V., Liudmyla P. Mironets, Tetiana M. Olendr, Ivan M. Tsidylo et Oksana B. Stoliar. Methodology of using mobile Internet devices in the process of biology school course studying. [б. в.], juillet 2020. http://dx.doi.org/10.31812/123456789/3887.
Texte intégralWilkinson, Annie, Hayley MacGregor, Ian Scoones, Megan Schmidt-Sane, Melissa Leach, Peter Taylor, Santiago Ripoll, Shandana Khan Mohmand, Syed Abbas et Tabitha Hrynick. Pandemic Preparedness for the Real World : Why We Must Invest in Equitable, Ethical and Effective Approaches to Help Prepare for the Next Pandemic. Institute of Development Studies, mars 2023. http://dx.doi.org/10.19088/cc.2023.002.
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