Porous Biomaterials: Classification, Fabrication and Its Applications in Advanced Medical Science
American Journal of Nanosciences
Volume 4, Issue 2, June 2018, Pages: 16-20
Received: Sep. 4, 2018;
Accepted: Oct. 4, 2018;
Published: Oct. 23, 2018
Views 1000 Downloads 162
Mosammat Jesmin Sultana, Department of Materials Science and Engineering, Rajshahi University, Rajshahi, Bangladesh
Fazle Rabbi Shakil Ahmed, Department of Pharmacy, Khwaja Yunus Ali University, Sirajgonj, Bangladesh
Biomaterials are natural or synthetic, alive or lifeless, and usually made of multiple components that interact with biological systems. In this article, it has been reported the applications of porous biomaterials in living bodies and its biocompatibility. Biocompatibility is related to the behaviour of biomaterials in various environments under various chemical and physical conditions. The term may refer to specific properties of a material without specifying where or how the material is to be used. Here, declared different types of biomaterials and their fabrication methods. And also studied various applications of porous biomaterials in medical and biological sciences. Now a day, biomaterials are used to make devices to replace a part or a function of the body with the help of advance surgical technique and instruments in safe, reliably economically and physiologically acceptable manner. This study also reported that the biomaterials comprise a varieties of properties such as biocompatible, bioactive, surface reactive, biodegradable, sterilizability, adequate mechanical and physical properties, manufacture ability, low weight and reasonable cost etc. The main focuses of this review was the applications of biomaterials in different parts of body. Replacement parts were heart, lung, eye, ear, bone, kidney, bladder, nerve stimulator and dental applications. Therefore, this article is focusing on three specific topics such as classification, fabrication methods and suitable implant applications in advances medical science.
Mosammat Jesmin Sultana,
Fazle Rabbi Shakil Ahmed,
Porous Biomaterials: Classification, Fabrication and Its Applications in Advanced Medical Science, American Journal of Nanosciences.
Vol. 4, No. 2,
2018, pp. 16-20.
Barrère, F., Mahmood, T. A., de Groot K., van Blitterswijk C. A., Advanced biomaterials for skeletal tissueregeneration: Instructive and smart functions. Mater. Sci. Eng. R: Reports. 59(2008)538-71.
Yang, J., Xiang, H. J., A three-dimensional finite element study on the biomechanical behavior of an FGBM dental implant in surrounding bone, J. Biomech. 40(2007)2377-2385.
Stevens, M. M. Biomaterials for bone tissue engineering. Mater. Today 11(2008)18-25.
Meenakshi, Mour, Debarun, Das, Thomas, Winkler, Elisa, Hoenig Gabriela, Mielke Michael, M, Morlock, Arndt, F, Schilling, Advances in Porous Biomaterials for Dental and Orthopedic Applications, Materials. 3(2010)2947-2974.
A. Srivastav, An Overview of Metallic Biomaterials for Bone Support and Replacement, Biomedical Engineering, Trends in Materials Science, 153-168,
W, C, Billotte, Ceramic Biomaterials,(2006)339:1-39.
Tetsuya Tateish, Biomaterials in Asia: In Commemoration of the 1st Asian Biomaterials, ISBN: 13-978-981-283-574-1.
Anthony Atala, Principles of Regenerative Medicine, ISBN: 978-0-12-369410-2.
Hai, Bang, Lee, Gilson, Khang, Jin, Ho, Lee, Polymeric Biomaterials, book: Biomedical Engineering Fundamentals. 40(24) (2006)1-40.
Hermann Ehrlich, Biological Materials of Marine Origin, (2010) ISBN: 978-90-481-9129-1.
Thieme, M., Wieters, K. P., Bergner, F., Scharnweber, D., Worch, H., Ndop, J., Kim, T. J., Grill, W., Titanium powder sintering for preparation of a porous functionally graded material destined for orthopaedic implants, J. Mater. Sci. 12 (2001)225–231.
Miao X., Hu Y., Liu J., Tio B, Cheang P., Khor K. A., Highly interconnected and functionally graded porous Bioceramics, Key Eng. Mater. (2003)595–598.
Iwata, M., Shimono, A., Kishiro, K., Kunieda Y., Preparation of porous hydroxyapatite materials with a continuous porosity profile by use of a filtration method, J. Jpn. Inst. Metal. 62(1998)1088–1094.
Droschel, M., Hoffmann, M. J., Oberacker, R., Both, H. V., Schaller, W., Yang, Y. Y.; Munz, D. SiC-ceramicswith tailored porosity gradients for combustion chambers, Key Eng. Mater 175-176(2000)149–162.
Corbin, S. F.;, Zhao, X., Henein, H., Apte P. S., Functionally graded metal/ceramic composites by tape casting, lamination and infiltration., Mater. Sci. Eng. A. 262(1999)192–203.
Cichocki, F. R., Jr., Trumble, K. P., Rodel, J. Tailored porosity gradients via colloidal infiltration of compression-molded sponges, J. Amer. Ceram. Soc. 81(1998)1661–1664.
Werner, J. P., Linner-Krcmar, B., Friess, W., Greil, P., Mechanical properties and in vitro cell compatibility of hydroxyapatite ceramics with graded pore structure, Biomaterials. 23(2002)4285–4294
Elham Babaie and Sarit B. Bhaduri. Fabrication Aspects of Porous Biomaterials in Orthopedic Applications: A Review, ACS Biomater. Sci. Eng. 4(1)(2018)1–39.
McWilliam JA, (1899). "Electrical stimulation of the heart in man". BrMedJ 1 (1468):348. Doi:10.1136/bmj.1.1468.348. "Electrical Stimulation of the Heart in Man - 1899", Accessed Jan 27, (2014).
Pibarot, P., Dumesnil, J. G., Prosthetic Heart Valves: Selection of the Optimal Prosthesis and Long-Term Managemen, Circulation. 119(2009)1034–48.
J. Wei, K. K. Cheng, D. Y. Tung, C. Y. Chang, W. M. Wan, Y. C. Chuang: Successful Use of Phoenix-7 Total Artificial Heart. Transplantation Proceedings. 30(1998)3403-4.
Cardiotomy Suction: A Major Source of Brain Lipid Emboli During Cardiopulmonary Bypass" Ann Thorac Surg. 65(1998)1651-1655.
Sanders, Donald, Vukich, John A. Comparison of Implantable Collamer Lens (ICL) and Laser-assistedin Situ Keratomileusis (LASIK) for Low Myopia, Cornea. 25 (10) (2006)1139-46.
Lefaivre, K. A.; Guy, P.; Chan, H.; Blachut, P. A. Long-Term Follow-up of Tibial Shaft Fractures Treated with Intramedullary Nailing. Journal of Orthopaedic Trauma 22 (8) (2008)525-529.
Vogel, T, Shindelman, L., Nackman, G., Graham, A. Efficacious Use of Nitinol Stentsinthe Femoraland Popliteal Arteries, Journal of Vascular Surgery. 38(6)(2003)1178–1183.