Revista nº 809

Actualidad Médica · Número 809 · Enero/Abril 2020 Páginas 12 a 17 Ferrer et al. Caracterización morfométrica y química de partículas óseas · 17 · 10. Martín-Piedra A, Martin-Piedra L. Matrices para Ingeniería del tejido óseo. Actual Médica. 2019;104(806):36-45. 11. Rodriguez IA, Rodriguez MA, Uribe Echevarria J. La biocompatibilidad en odontología regenerativa. Dental Tribune. 2019. 12. Figueiredo M, Henriques J, Martins G, Guerra F, Judas F, Figueiredo H. Physicochemical characterization of biomaterials commonly used in dentistry as bone substitutes—Comparison with human bone. J Biomed Mater Res B Appl Biomater. 2010;92(2):409-19. 13. Accorsi-Mendonça T, Conz MB, Barros TC, de Sena LA, Soares G de A, Granjeiro JM. Physicochemical characterization of two deproteinized bovine xenografts. Braz Oral Res. 2008;22(1):5-10. 14. Sánchez-Quevedo MC, Ceballos G, García JM, Rodríguez IA, Gómez de Ferraris ME, Campos A. Scanning electron microscopy and calcification in amelogenesis imperfecta in anterior and posterior human teeth. Histol Histopathol. 2001;16(3):827-32. 15. Sánchez-Quevedo MC, Ceballos G, García JM, Luna JD, Rodríguez IA, Campos A. Dentine structure and mineralization in hypocalcified amelogenesis imperfecta: a quantitative X-ray histochemical study. Oral Dis. 2004;10(2):94-8. 16. Sánchez-Quevedo C, Ceballos G, Rodríguez IA, García JM, Alaminos M. Acid-etching effects in hypomineralized amelogenesis imperfecta. A microscopic and microanalytical study. Med Oral Patol Oral Cirugia Bucal. 2006;11(1):E40-43. 17. Kalia P, Vizcay-Barrena G, Fan JP, Warley A, Di Silvio L, Huang J. Nanohydroxyapatite shape and its potential role in bone formation: an analytical study. J R Soc Interface. 2014;11(93):20140004. 18. González-Jaranay M, del Carmen Sánchez-Quevedo M, Moreu G, García JM, Campos A. Electron Microprobe Analysis in Guided Tissue Regeneration: A Case Report. Eur J Dent. enero de 2007;1(1):40-4. 19. Sigee DC, Morgan J, Sumner AT, Warley A. X-ray Microanalysis in Biology: Experimental Techniques and Applications. Cambridge University Press; 1993. 356 p. 20. Wright JT, Robinson C, Shore R. Characterization of the enamel ultrastructure and mineral content in hypoplastic amelogenesis imperfecta. Oral Surg Oral Med Oral Pathol. 1991;72(5):594-601. 21. Dominguez Lopez M, Martinez Almazaan E, Muñoz Romero C, Álvarez Martin A, Garcia Navarro JA. Interpretación de las pruebas de metabolismo calcio-fósforo. En: Tratado de geriatría para residentes. Sociedad Española de Geriatría y Gerontología; 2006. 816 p. 22. Yuan H, de Groot K. Calcium Phosphate Biomaterials: An Overview. En: Reis RL, Weiner S, editores. Learning from Nature How to Design New Implantable Biomaterialsis: From Biomineralization Fundamentals to Biomimetic Materials and Processing Routes. Springer Netherlands; 2005. p. 37-57. 23. Sapir-Koren R, Livshits G. Bone mineralization and regulation of phosphate homeostasis. IBMS BoneKEy. 2011;8(6):286- 300. 24. Lazáry A, Balla B, Kósa J, Bácsi K, Nagy Z, Takács I, et al. [Review of the application of synthetic bone grafts. The role of the gypsum in bone substitution: molecular biological approach, based on own research results]. Orv Hetil. 2007;148(51):2427-33. 25. Varanasi VG, Velten MF, Odatsu T, Ilyas A, Iqbal SM, Aswath PB. Chapter 9 - Surface Modifications and Surface Characterization of Biomaterials Used in Bone Healing. En: Bose S, Bandyopadhyay A, editores. Materials for Bone Disorders. Academic Press; 2017. p. 405-52. 26. Zoricic S, Bobinac D, Lah B, Maric I, Cvijanovic O, Bajek S, et al. Study of the healing process after transplantation of pasteurized bone grafts in rabbits. Acta Med Okayama. 2002;56(3):121-8. 27. Sbordone C, Toti P, Guidetti F, Califano L, Pannone G, Sbordone L. Volumetric changes after sinus augmentation using blocks of autogenous iliac bone or freeze-dried allogeneic bone. A non-randomized study. J Cranio- Maxillo-fac Surg Off Publ Eur Assoc Cranio-Maxillo-fac Surg. 2014;42(2):113-8. 28. Wang C, Duan Y, Markovic B, Barbara J, Howlett CR, Zhang X, et al. Phenotypic expression of bone-related genes in osteoblasts grown on calcium phosphate ceramics with different phase compositions. Biomaterials. 2004;25(13):2507-14. 29. Fan Y-P, Lu J-F, Xu A-T, He F-M. Physiochemical characterization and biological effect of anorganic bovine bone matrix and organic-containing bovine bone matrix in comparison with Bio-Oss in rabbits. J Biomater Appl. 2018;33(4):566-75. 30. Traini T, Degidi M, Sammons R, Stanley P, Piattelli A. Histologic and elemental microanalytical study of anorganic bovine bone substitution following sinus floor augmentation in humans. J Periodontol. 2008;79(7):1232-40. 31. Slater N, Dasmah A, Sennerby L, Hallman M, Piattelli A, Sammons R. Back-scattered electron imaging and elemental microanalysis of retrieved bone tissue following maxillary sinus floor augmentation with calcium sulphate. Clin Oral Implants Res. 2008;19(8):814-22. 32. Ramírez-Fernández MP, Calvo-Guirado JL, Maté-Sánchez Del Val JE, Delgado-Ruiz RA, Negri B, Barona-Dorado C. Ultrastructural study by backscattered electron imaging and elemental microanalysis of bone-to-biomaterial interface and mineral degradation of porcine xenografts used in maxillary sinus floor elevation. Clin Oral Implants Res. 2013;24(5):523-30. 33. Martínez Álvarez O, Barone A, Covani U, Fernández Ruíz A, Jiménez Guerra A, Monsalve Guil L, et al. Injertos óseos y biomateriales en implantología oral. Av En Odontoestomatol. 2018;34(3):111-9. 34. Artzi Z, Weinreb M, Givol N, Rohrer MD, Nemcovsky CE, Prasad HS, et al. Biomaterial resorption rate and healing site morphology of inorganic bovine bone and beta-tricalcium phosphate in the canine: a 24-month longitudinal histologic study and morphometric analysis. Int J Oral Maxillofac Implants. 2004;19(3):357-68. 35. Kon K, Shiota M, Ozeki M, Yamashita Y, Kasugai S. Bone augmentation ability of autogenous bone graft particles with different sizes: a histological and micro- computed tomography study. Clin Oral Implants Res. 2009;20(11):1240-6. 36. Chackartchi T, Iezzi G, Goldstein M, Klinger A, Soskolne A, Piattelli A, et al. Sinus floor augmentation using large (1-2 mm) or small (0.25-1 mm) bovine bone mineral particles: a prospective, intra-individual controlled clinical, micro- computerized tomography and histomorphometric study. Clin Oral Implants Res. 2011;22(5):473-80. 37. Malinin TI, Carpenter EM, Temple HT. Particulate bone allograft incorporation in regeneration of osseous defects; importance of particle sizes. Open Orthop J. 2007;1:19-24.