Meftah Mahmoud Mohamed, Jason Gu, and Jun Luo
[1] T.D. White, M.T. Black, and P.A. Folkens, Human osteology(Burlington, MA, USA: Academic Press, 2011). [2] C. Dean, An introduction to human evolutionary anatomy(Academic Press, 1990). [3] J.E. Risdall and D.K. Menon, Traumatic brain injury, Philo-sophical Transactions of the Royal Society of London B: Bi-ological Sciences, 366(1562), 2011, 241–250. Ruby. PremierPress. [4] K.U. Schmitt, P.F.N.E. Z¨urich, M.H. Muser, and F. Walz,Trauma biomechanics: introduction to accidental injury(New York, NY, USA: Springer Science & Business Media,2013). [5] G.M. Giles and J. Clark-Wilson, Brain injury rehabilitation:A neurofunctional approach (San Diego, CA, USA: Springer,2013). [6] J. Arata, H. Kenmotsu, M. Takagi, T. Hori, T. Miyagi,H. Fujimoto, and M. Hashizume, Surgical bedside masterconsole for the neurosurgical robotic system, InternationalJournal of Computer Assisted Radiology and Surgery, 8(1),2013, 75–86. [7] H. Marcus, D. Nandi, A. Darzi, and G. Yang, Surgical roboticsthrough a keyhole: From today’s translational barriers totomorrow’s ‘disappearing’ robots, in IEEE Transactions onBiomedical Engineering, vol. 60, no. 3, pp. 674–681, March2013. doi: 10.1109/TBME.2013.2243731 [8] P. Gambadauro and R. Torrej´on, The “tele factor in surgerytoday and tomorrow: Implications for surgical training andeducation, Surgery Today, 43(2), 2013, 115–122. [9] B. Morris, Robotic surgery: Applications, limitations, andimpact on surgical education, Medscape General Medicine,7(3), 2005, 72. [10] T. Litman, Transportation and public health, Annual Reviewof Public Health, 34, 2013, 217–233. [11] D. Hastings, Trauma prevention and intervention around theworld, In the Qatar International Trauma and EmergencyMedicine Conference, Doha, Qatar, 2002, 13–16. [12] N. Agarwal, I.O. Norrm´en-Smith, K.L. Tomei, C.J.Prestigiacomo, and C.D. Gandhi, Improving medical studentrecruitment into neurological surgery: A single institution’sexperience, World Neurosurgery, 80(6), 2013, 745–750. [13] P.K. Dempsey and S.W. Hwang, Management of closed headinjury, In Surgical Intensive Care Medicine (New York, NY,USA: Springer US, 2010), 129–136. [14] J. Truhl´aˇr, Evaluation of the Wi-Fi technique for use in anavigated orthopedic surgery, 2013. [15] S. Au, K. Ko, J. Tsang, and Y.C. Chan, Robotic endovascularsurgery, Asian Cardiovascular and Thoracic Annals, 22(1),2014, 110–114. [16] Y. Maddahi, K. Zareinia, N. Sepehri, and G. Sutherland,Surgical tool motion during conventional freehand and robot-assisted microsurgery conducted using neuroArm, AdvancedRobotics, 30(9), 2016, 621–633. [17] L. Emory and A. Schubert, Awake craniotomy, epilepsy, min-imally invasive and robotic surgery, Cottrell and Patel’s neu-roanesthesia, Elsevier Health Sciences, 2016. [18] C. Faria, W. Erlhagen, M. Rito, E. De Momi, G. Ferrigno,and E. Bicho, Review of robotic technology for stereotacticneurosurgery, IEEE Reviews in Biomedical Engineering, 8,2015, 125–137. [19] T. Sakaguchi, Percutaneous puncture with a robot, ActaUrologica Japonica, 1985, 31, 1265–1268. [20] P.L. Gildenberg, Robotic neurosurgery, in Textbook of Stereo-tactic and Functional Neurosurgery (Berlin Heidelberg:Springer, 2009), 583–597. [21] T.A. Mattei, A.H. Rodriguez, D. Sambhara, and E. Mendel,Current state-of-the-art and future perspectives of robotictechnology in neurosurgery, Neurosurgical Review, 37(3), 2014,357–366. [22] D. Glauser, H. Fankhauser, M. Epitaux, J.L. Hefti, andA. Jaccottet, Neurosurgical robot Minerva: First results andcurrent developments, Journal of Image Guided Surgery, 1(5),1995, 266–272. [23] J.J. Doulgeris, S.A. Gonzalez-Blohm, A.K. Filis, T.M. Shea,K. Aghayev and F.D. Vrionis, (2015). Robotics in neurosurgery:Evolution, current challenges, and compromises. Cancer Con-trol, 22 (3), 352–359. [24] G.R. Sutherland, S. Wolfsberger, S. Lama, and K. Zarei-nia,The evolution of neuroArm, Neurosurgery, 72, 2013, A27–A32. [25] J.A. Smith, J. Jivraj, R. Wong, and V. Yang, 30 years ofneurosurgical robots: Review and trends for manipulatorsand associated navigational systems, Annals of BiomedicalEngineering, 44(4), 2016, 836–846. [26] J.R. Adler, Jr, The future of robotics in radiosurgery. Neuro-surgery, 72(Suppl 1), 2013, 8–11. [27] S.R. Kantelhardt, M. Finke, A. Schweikard, and A. Giese,Evaluation of a completely robotized neurosurgical operatingmicroscope, Neurosurgery, 72(Suppl 1), 2013, 19–26. [28] G.R. Sutherland, S. Lama, L.S. Gan, S. Wolfsberger, andK. Zareinia, Merging machines with microsurgery: Clinicalexperience with neuroArm, Journal of Neurosurgery, 118, 2013,521–529. [29] W. Shen and J.J. Gu, Multi-criteria singularities robustnesskinematic control for PA10-7C robot arm, in Proc. Inter-national Conf. on Robotics and Biomimetics, Sanya, China,December 15–18, 2007, 1242–1248. [30] W. Shen, J. Gu, E.E. Milios, Self-configuration fuzzy systemfor inverse kinematics of robot manipulators in Proc. of theNorth American Fuzzy Information Processing Society AnnualConference (NAFIPS’06), Montreal, Canada, June 3–6, 2006,41–45.550 [31] M.A. Freese, Distributed control in robotics simulations: A casestudy of the V-REP simulator, in Developments of SimulationTools for Robotics & Biomechanics. [32] K.-H. Man, A No-Frills Introduction to LUA 5.1 VM Instruc-tions, V0.1, 2006. [Online]. Available: ftp://collectivecomputers.org:21212/Books/morebooks/ANoFrillsIntroToLua51VMInstructions.pdf (accessed Jan 2017). [33] K.W. Oosting, Simulation of control strategies for a two-degree-of-freedom lightweight flexible robotic arm, Thesis, GeorgiaInstitute of Technology, Dept. Of Mechanical Engineering,1987. [34] P. Lambrechts, M. Boerlage, and M. Steinbuch, Trajectoryplanning and feedforward design for electromechanical motionsystems, Control Engineering Practice, 13(2), 2005, 145–157.
Important Links:
Go Back
