60                         3. DESIGN, SIMULATION, AND EXPERIMENTATION OF COLONIC STENTS

            [4] T.W. Duerig, A.R. Pelton, An overview of superelastic stent design, Mater. Sci. Forum 394-395 (2001) 1–8.
            [5] S. McMahon, N. Bertollo, E.D.O. Cearbhaill, J. Salber, L. Pierucci, P. Duffy, T. D€ urig, V. Bi, W. Wang, Bio-resorbable polymer stents: a review of
               material progress and prospects, Prog. Polym. Sci. 83 (2018) 79–96.
            [6] T. Hu, C. Yang, S. Lin, Q. Yu, G. Wang, Biodegradable stents for coronary artery disease treatment: recent advances and future perspectives,
               Mater. Sci. Eng. C 91 (2018) 163–178.
            [7] H. Hermawan, D. Dub  e, D. Mantovani, Developments in metallic biodegradable stents, Acta Biomater. 6 (2010) 1693–1697.
            [8] B. Heublein, R. Rohde, V. Kaese, M. Niemeyer, W. Hartung, A. Haverich, Biocorrosion of magnesium alloys: a new principle in cardiovascular
               implant technology? Heart 89 (2003) 651–656.
            [9] R. Waksman, R. Pakala, P.K. Kuchulakanti, R. Baffour, D. Hellinga, R. Seabron, F.O. Tio, E. Wittchow, S. Hartwig,
               C. Harder, R. Rohde, B. Heublein, A. Andreae, K.H. Waldmann, A. Haverich, Safety and efficacy of bioabsorbable magnesium alloy stents
               in porcine coronary arteries, Catheter. Cardiovasc. Interv. 68 (2006) 607–617. discussion 618-9.
           [10] H. Hermawan, A. Purnama, D. Dube, J. Couet, D. Mantovani, Fe–Mn alloys for metallic biodegradable stents: degradation and cell viability
               studies, Acta Biomater. 6 (2010) 1852–1860.
           [11] T.H. Baron, Colonic stenting: technique, technology, and outcomes for malignant and benign disease, Gastrointest. Endosc. Clin. N. Am.
               15 (2005) 757–771.
           [12] T.H. Baron, Technique of colonic stenting, Colon. Endoprosthet. 16 (2014) 108–111.
           [13] J. Ferlay, I. Soerjomataram, R. Dikshit, S. Eser, C. Mathers, M. Rebelo, D.M. Parkin, D. Forman, F. Bray, Cancer incidence and mortality world-
               wide: sources, methods and major patterns in GLOBOCAN 2012, Int. J. Cancer 136 (2015) E359–E386.
           [14] G.T. Deans, Z.H. Krukowski, S.T. Irwin, Malignant obstruction of the left colon, Br. J. Surg. 81 (1994) 1270–1276.
           [15] R. Frago, E. Kreisler, S. Biondo, E. Alba, J. Domínguez, T. Golda, D. Fraccalvieri, M. Millán, L. Trenti, Complications of distal intestinal occlusion
               treatment with endoluminal implants, Cir. Esp. 89 (2011) 448–455.
           [16] R.D. Gongaware, C.A. Slanetz, Hartmann procedure for carcinoma of the sigmoid and rectum, Ann. Surg. 178 (1973) 28–30.
           [17] C.S. McArdle, D.J. Hole, Emergency presentation of colorectal cancer is associated with poor 5-year survival, Br. J. Surg. 91 (2004) 605–609.
           [18] S. Biondo, J. Martí-Ragu  e, E. Kreisler, D. Par  es, A. Martín, M. Navarro, L. Pareja, E. Jaurrieta, A prospective study of outcomes of emergency and
               elective surgeries for complicated colonic cancer, Am. J. Surg. 189 (2005) 377–383.
           [19] S. Adamsen, S. Meisner, Expandable metal stents for malignant colorectal obstruction, in: Expandable Metal Stents in the Gastrointestinal Tract,
               vol. 3, 2001, pp. 103–107.
           [20] R. Castaño, J.D. Puerta, O.A. Alvarez, J. Lopera, E. Sanin, F. Erebrie, E. NuñEz, L.E. GarcíA, Self-expanding metal stents in malignant and benign
               colonic obstructions, in: DDW Abstract Issue 2008Digestive Disease Week 2008, vol. 67, 2008, p. AB151.
           [21] D.J. Boyle, C. Thorn, A. Saini, C. Elton, G.K. Atkin, I.C. Mitchell, K. Lotzof, A. Marcus, P. Mathur, Predictive factors for successful colonic stent-
               ing in acute large-bowel obstruction: a 15-year cohort analysis, Dis. Colon Rectum 58 (2015) 358–362.
           [22] N. Srinivasan, R.A. Kozarek, Stents for colonic strictures: materials, designs, and more, Colon. Endoprosthet. 16 (2014) 100–107.
           [23] J.H. Kim, T.J. Kang, W.-R. Yu, Mechanical modeling of self-expandable stent fabricated using braiding technology, J. Biomech. 41 (2008)
               3202–3212.
           [24] S. Tzamtzis, J. Viquerat, J. Yap, M.J. Mullen, G. Burriesci, Numerical analysis of the radial force produced by the Medtronic-CoreValve and
               Edwards-SAPIEN after transcatheter aortic valve implantation (TAVI), Med. Eng. Phys. 35 (2013) 125–130.
           [25] M. Dohmoto, K.D. Rupp, G. Hohlbach, Endoscopically-implanted prosthesis in rectal carcinoma, Dtsch. Med. Wochenschr. 115 (1990) 915.
           [26] E. Tejero, A. Mainar, L. Fernández, R. Tobío, M.A. De Gregorio, New procedure for the treatment of colorectal neoplastic obstructions, Dis.
               Colon Rectum 37 (1994) 1158–1159.
           [27] R.M. Bashir, D.E. Fleischer, T.J. Stahl, S.B. Benjamin, Self-expandable nitinol coil stent for management of colonic obstruction due to a malignant
               anastomotic stricture, Gastrointest. Endosc. 44 (1996) 497–501.
           [28] R. Moroi, K. Endo, R. Ichikawa, H. Nagai, H. Shinkai, T. Kimura, F. Ishiyama, K. Yaguchi, S. Kayaba, T. Shimosegawa, The effectiveness of
               self-expandable metallic stent insertion in treating right-sided colonic obstruction: a comparison between SEMS and decompression tube
               placement and an investigation of the safety and difficulties of SEMS insertion in right colons, Gastroenterol. Res. Pract. 2014 (2014)
               372918.
           [29] Z. Lackberg, M.A. Abbas, Colonic stenting: when and how, Semin. Colon Rectal Surg. 28 (2017) 34–40.
           [30] D.G. Adler, Colonic strictures: dilation and stents, Gastrointest. Endosc. Clin. N. Am. 25 (2015) 359–371.
           [31] D. Stoeckel, A. Pelton, T. Duerig, Self-expanding nitinol stents: material and design considerations, Eur. Radiol. 14 (2004) 292–301.
           [32] Y. Zhang, J. Shi, B. Shi, C.Y. Song, W.F. Xie, Y.X. Chen, Comparison of efficacy between uncovered and covered self-expanding metallic stents in
               malignant large bowel obstruction: a systematic review and meta-analysis, Color. Dis. 14 (2012) e367–e374.
           [33] K.M. Lee, S.J. Shin, J.C. Hwang, J.Y. Cheong, B.M. Yoo, K.J. Lee, K.B. Hahm, J.H. Kim, S.W. Cho, Comparison of uncovered stent with covered
               stent for treatment of malignant colorectal obstruction, Gastrointest. Endosc. 66 (2007) 931–936.
           [34] J. Huo, R. Rojas, J. Bohlin, J. Hilborn, E.K. Gamstedt, Parametric elastic analysis of coupled helical coils for tubular implant applications: exper-
               imental characterization and numerical analysis, J. Mech. Behav. Biomed. Mater. 29 (2014) 462–469.
           [35] R. Rebelo, N. Vila, R. Fangueiro, S. Carvalho, S. Rana, Influence of design parameters on the mechanical behavior and porosity of braided
               fibrous stents, Mater. Des. 86 (2015) 237–247.
           [36] H. Isayama, Y. Nakai, Y. Toyokawa, O. Togawa, C. Gon, Y. Ito, Y. Yashima, H. Yagioka, H. Kogure, T. Sasaki,  T. Arizumi,
               S. Matsubara, N. Yamamoto, N. Sasahira, K. Hirano, T. Tsujino, N. Toda, M. Tada, T. Kawabe, M. Omata, Measurement of radial and axial
               forces of biliary self-expandable metallic stents, Gastrointest. Endosc. 70 (2009) 37–44.
           [37] A. Ratnovsky, N. Regev, S. Wald, M. Kramer, S. Naftali, Mechanical properties of different airway stents, Med. Eng. Phys. 37 (2015) 408–415.
           [38] J.A. Grogan, S.B. Leen, P.E. McHugh, Comparing coronary stent material performance on a common geometric platform through simulated
               bench testing, J. Mech. Behav. Biomed. Mater. 12 (2012) 129–138.
           [39] D.J. McGrath, B. O’Brien, M. Bruzzi, P.E. McHugh, Nitinol stent design – understanding axial buckling, J. Mech. Behav. Biomed. Mater. 40 (2014)
               252–263.
           [40] L. Petrini, F. Migliavacca, F. Auricchio, G. Dubini, Numerical investigation of the intravascular coronary stent flexibility, J. Biomech. 37 (2004)
               495–501.



                                                       I. BIOMECHANICS