Plasma Influence of Surface Texture of Silicone Rubber for Biomedical Application in Scala Tympani
Subject Areas : Bio MaterialsMohammad Ajal-Louian 1 , saeed golparvaran 2 , Hamid Mirzadeh 3 , Mohammad T. Khorasani 4
1 - New Hearing Technologies Research Center, Baqiyatallah University of Medical Sciences; Tehran, Iran
2 - Department of Otorhinolaryngology, School of Medicine, Tehran University of Medical Sciences, Tehran, Iran
3 - Department of Biopolymer, Faculty of Polymer Engineering, Amir Kabir University of Technology, Tehran, Iran
4 - Department of Biocompatible Polymers, Iran Polymer and Petrochemical Institute (IPPI), Tehran, Iran
Keywords: Plasma, Polydimethylsiloxane (PDMS), Catheter, Scala Tympani, Neurotrophin,
Abstract :
This study aims to fabricate an optimum interface surface for intracochlear catheter applications. The samples were first fabricated of two-component liquid dimethyl siloxane by designing and fabricating a mold, and then the assembly underwent surface treatment using a plasma irradiation device. The water contact angle test results showed an increase in the surface hydrophilicity of this material that water drop contact angle of origin silicone is 105° that after treatment decrease to 60°, which has the property of reducing the effect of cellular cutting in the inner ear when passing through the scala tympani. The surface engagement during passage was also minimized with an increase in surface roughness at the nanoscale. SEM and AFM photomicrographs and nano graphs show that the morphology of catheter surface in nanoscale changed and roughness increased, which is desirable for this purpose. The cell viability test results showed an improved adhesion and cell growth on the modified surface and origin silicone, and 95 % viability of cells confirmed, indicating the optimal biocompatibility of the modified silicone sample. This catheter can be used in cochlear implantation and drug delivery before surgery to enhance therapeutic efficiency
[1] J.T. Borenstein, "Intracochlear drug delivery systems". Expert opinion on drug delivery., vol. 8, 2011, pp. 1161-1174.
[2]A.M.H. Korver, R.J.H. Smith, G.V.C. Camp, "Congenital hearing loss", Nature reviews Disease primers., vol. 3, 2017, pp. 1-17.
[3] H. Liu, j. Hao, S. Li K, "Current strategies for drug delivery to the inner ear", Acta Pharmaceutica Sinica B., vol. 3, 2013, pp. 86-96.
[4] E.E.L. Swan, M.J. Mescher, W.F. Sewell, S.L. Tao, "Inner ear drug delivery for auditory applications", Advanced drug delivery reviews., vol. 60, 2008, pp. 583-1599.
[5] R. Glueckert, L.J. Chacko, Rask-Andersen, H.W. Liu, "Anatomical basis of drug delivery to the inner ear", Hearing research., vol. 368, 2018, pp. 10-27.
[6] A.M. Ayoob, J.T. Borenstein, "The role of intracochlear drug delivery devices in the management of inner ear disease", Expert opinion on drug delivery., vol. 12, 2015, pp. 465-479.
[7] N.K. Prenzler, R. Salcher, M. Timm, L. Gaertner, T. Lenarz, A.Warnecke, "Intracochlear administration of steroids with a catheter during human cochlear implantation: a safety and feasibility study", Drug delivery and translational research., vol. 8, 2018, pp. 1191-1199.
[8] Q. Yu, Q. Chang, X. Liu, Y. Wang, H. Li, "Protection of spiral ganglion neurons from degeneration using small-molecule TrkB receptor agonists", Journal of Neuroscience., vol. 33, 2013, pp. 13042-13052.
[9] W. Sun, R.J. Salvi, "Brain derived neurotrophic factor and neurotrophic factor 3 modulate neurotransmitter receptor expressions on developing spiral ganglion neurons", Neuroscience., vol. 164, 2009, pp. 1854-1866.
[10] L. Bren, L. English, J. Fogarty, R. Policoro, A. Zsidi, J. Vance, J. Drelich, C. White C, S. Donahue, Istephanous N., Rohly K. 7th World Biomaterials Congress, 2004.
[11] J. Park, R.S. Lakes, Biomaterials An Introduction. Springer London 2007.
[12] L.C. Xua, C.A. Siedlecki, "Effects of Surface Wettability and Contact Time on Protein Ahesion to Biomaterial Surfaces", Biomaterials., vol. 28, 2007, pp. 3273–3283.
[13] P. Van der Valk P, A.W. van Pelt, H.J. Busscher, H.P. de Jong, C.R. Wildevuur, J. Arends, "Interaction of fibroblasts and polymer surfaces: relationship between surface free energy and fibroblast spreading", J. Biomed. Mater. Res., vol. 17, 1983, pp. 807–817.
[14] K. Birdi, Cell adhesion on solids and the role of surface forces, J.Theor Biol., vol. 93, 1981, pp. 1-5.
[15] M. Naeimi, A. Karkhaneh, J. Barzin, M.T. Khorasani, A.R. Ghaffarieh, "Novel PDMS-Based Membranes: Sodium Chloride and Glucose Permeability", Journal of Applied Polymer Science., vol. 31, 2013, pp. 1509-1518.
[16] L.C. Xua, C.A. Siedlecki, "Effects of Surface Wettability and Contact Time on Protein Ahesion to Biomaterial Surfaces, Biomaterials., vol. 28, 2007, pp. 3273–3283.
[17] M. Morra, C. Cassinelli, "Surface studies on a model cell-resistant system", Langmuir., vol. 15, 1999, pp. 4658–4663.
[18] M.T. Khorasani, S. MoemenBellah, H. Mirzadeh, B. Sadatnia, "Effect of surface charge and hydrophobicity of polyurethanes and silicone rubbers on L929 cells response", Colloids and Surfaces B: Biointerfaces., vol. 51, 2006, pp. 112–119.
[19] R.W. Koch, H.M. Ladak, M. Elfarnawany, S.K. Agrawal, "Measuring cochlear duct length–a historical analysis of methods and results", Journal of Otolaryngology-Head & Neck Surgery., vol. 46, 2017, pp. 1-11.
[20] S. Hatsushika, R.K. Shepherd, Y.C. Tong, G.M. Clark, S. Funasaka, "Dimensions of the scala tympani in the human and cat with reference to cochlear implants", Annals of Otology, Rhinology & Laryngology., vol. 99, 1990, pp. 871-876.
[21] J. Stone, H. Francis. Immune-mediated inner ear disease. Curr Opin Rheumatol., vol.
12, 2000, pp. 32-40.
[22] F. Everaerts, M. Gillissen, M. Torrianni, P. Zilla, P. Human, M. Hendriks, "Reduction of calcification of carbodiimide-processed heart valve tissue by prior blocking of amine groups with monoaldehydes", J Heart Valve Dis., vol. 15, 2006, pp. 77–269.
[23] R. Bakhshi, A. Darbyshire, J.E. Evans, Z. You, J. Lu, A.M. Seifalian, "Polymeric coating of surface modified nitinol stent with POSS-nanocomposite polymer", Colloids and Surfaces B: Biointerfaces., vol. 86, 2011, pp. 93–105.
[24] D. Bezuidenhout, D.F. Williams, P. Zilla, "Polymeric heart valves for surgical implantation, catheter-based technologies and heart assist devices", Biomaterials., vol. 36, 2015, pp. 6–25.
[25] J.B. Park, J.D. Bronzino, Biomaterials Principles and Applications. CRC press, Boca Raton london New York Washington, 2007.
[26] M.T. Khorasani, H. Mirzadeh, "Effect of oxygen plasma treatment on surface charge and wettability of PVC blood bag—In vitro assay", Radiation Physics and Chemistry., vol. 76, 2007, pp. 1011–1016.
[27] S. Nag, A. Sachan, M. Castro, V. Choudhary, J. Feller, "Spray layer-by-layer assembly of POSS functionalized CNT quantum chemo-resistive sensors with tuneable selectivity and ppm resolution to VOC biomarkers", Sensors and Actuators B: Chemical., vol. 222, 2007, pp. 362–73.
[28] F. Garbasi, M. Morra, E. Occhiello, "Polymer surfaces from physics to technology", John Wiley London, 1994.
[29] P.T. Knight, K.M. Lee, H. Qin, P.T. Mather, "Biodegradable Thermoplastic Polyurethanes Incorporating Polyhedral Oligosilsesquioxane", Biomacromolecules., vol. 9, 2008, pp. 2458–67.
[30] F. Vaghef Davari F., P. Khashayar, M.T. Khorasani, M.R. Zafarghandi, "Innovation of a New Silicone Prosthesis for Inguinal Hernioplasty: New Method for silicone Prosthesis Production, A Preliminary Study", Arch Iran Med., vol. 18, 2015, pp. 24 – 27.
[31] Z. Shourgashti, M.T. Khorasani, S. Khosroshahi, "Plasma-induced grafting of polydimethylsiloxane onto polyurethane surface: Characterization and in vitro assay", Radiation Physics and Chemistry., vol. 79, 2010, pp. 947–952.
[32] S. Bahrami, A. Solouk, H. Mirzadeh, A.M. Seifalian, "Electroconductive polyurethane/graphene nanocomposite for biomedical applications", Composites Part B: Engineering., vol. 168, 2019, pp. 421–31.