References
- Tung, P.P., Olmsted, E., Kopelnik, A., Banki, N.M., Drew, B.J., Ko, N., Lawton, M.T., Smith, W., Foster, E., and Young, W.L., 2005, Plasma B-type natriuretic peptide levels are associated with early cardiac dysfunction after subarachnoid hemorrhage. Stroke, 36, 1567–1569
- Broderick, J.P., 2004, William M. Feinberg Lecture: Stroke Therapy in the Year 2025 Burden, Breakthroughs, and Barriers to Progress. Stroke, 35, 205–211
- Strong, K., Mathers, C., and Bonita, R., 2007, Preventing stroke: Saving lives around the world. The Lancet Neurology, 6, 182–187
- Johnston, S.C., Mendis, S., and Mathers, C.D., 2009, Global variation in stroke burden and mortality: Estimates from monitoring, surveillance, and modelling. The Lancet Neurology, 8, 345–354
- Jansen, O., von Kummer, R., Forsting, M., Hacke, W., and Sartor, K., 1995, Thrombolytic therapy in acute occlusion of the intracranial internal carotid artery bifurcation. American Journal of Neuroradiology, 16, 1977–1986
- Chambers, B.R., Norris, J.W., Shurvell, B.L., and Hachinski, V.C., 1987, Prognosis of acute stroke. Neurology, 37, 221–221
- Brandt, T., von Kummer, R., Müller-Küppers, M., and Hacke, W., 1996, Thrombolytic therapy of acute basilar artery occlusion variables affecting recanalization and outcome. Stroke, 27, 875–881
- Lyden, P.D., 2005, Thrombolytic therapy for acute stroke (New York: Springer)
- Khush, K., Kopelnik, A., Tung, P., Banki, N., Dae, M., Lawton, M., Smith, W., Drew, B., Foster, E., and Zaroff, J., 2005, Age and aneurysm position predict patterns of left ventricular dysfunction after subarachnoid hemorrhage. Journal of the American Society of Echocardiography, 18, 168–174
- Friedman, H.S., Koroshetz, W., and Qureshi, N., 1996, Tissue plasminogen activator for acute ischemic stroke. New England Journal of Medicine, 334, 1405–1406
- Nogueira, R.G., Liebeskind, D.S., Sung, G., Duckwiler, G., and Smith, W.S., 2009, Predictors of good clinical outcomes, mortality, and successful revascularization in patients with acute ischemic stroke undergoing thrombectomy pooled analysis of the Mechanical Embolus Removal in Cerebral Ischemia (MERCI) and Multi MERCI Trials. Stroke, 40, 3777–3783
- Dilraj, A., Botha, J.H., Rambiritch, V., Miller, R., and van Dellen, J.R., 1992, Levels of catecholamine in plasma and cerebrospinal fluid in aneurysmal subarachnoid hemorrhage. Neurosurgery, 31, 42–51
- Smith, W.S., Sung, G., Saver, J., Budzik, R., Duckwiler, G., Liebeskind, D.S., Lutsep, H.L., Rymer, M.M., Higashida, R.T., and Starkman, S., 2008, Mechanical thrombectomy for acute ischemic stroke final results of the multi MERCI trial. Stroke, 39, 1205–1212
- Langer, D., Alexander, M., Janardhan, V., Hartmann, M., Jansen, O., Sit, S.P., Yavagal, D., Stingele, R., DeMuth, G., and Bose, A., 2009, The Penumbra Pivotal Stroke Trial Safety and Effectiveness of a New Generation of Mechanical Devices for Clot Removal in Intracranial Large Vessel Occlusive Disease. Stroke, 40, 2761–2768
- Nguyen-Huynh, M., and Johnston, S., 2011, Is mechanical clot removal or disruption a cost-effective treatment for acute stroke? American Journal of Neuroradiology, 32, 244–249
- Kim, A.S., Nguyen-Huynh, M., and Johnston, S.C., 2011, A cost-utility analysis of mechanical thrombectomy as an adjunct to intravenous tissue-type plasminogen activator for acute large-vessel ischemic stroke. Stroke, 42, 2013–2018
- Meyer, J.S., Stoica, E., Pascu, I., Shimazu, K., and Hartmann, A., 1973, Catecholamine concentrations in CSF and plasma of patients with cerebral infarction and haemorrhage. Brain, 96, 277–288
- White, R.A., and Fogarty, T.J., 1999, Peripheral endovascular interventions (New York: Springer)
- Perna, F., Heist, E.K., Danik, S.B., Barrett, C.D., Ruskin, J.N., and Mansour, M., 2011, Assessment of catheter tip contact force resulting in cardiac perforation in swine atria using force sensing technology. Circulation: Arrhythmia and Electrophysiology, 4, 218–224
- Fu, Y., Liu, H., Huang, W., Wang, S., and Liang, Z., 2009, Steerable catheters in minimally invasive vascular surgery. The International Journal of Medical Robotics and Computer Assisted Surgery, 5, 381–391
- Judkins, M., Mitchell, W., Simmons, C., and Gander, M., 1972, Vascular catheters, smooth and rough. The New England Journal of Medicine, 287, 1100–1101
- Jones, D.S., Garvin, C.P., and Gorman, S.P., 2004, Relationship between biomedical catheter surface properties and lubricity as determined using textural analysis and multiple regression analysis. Biomaterials, 25, 1421–1428
- Ho, S.P., Nakabayashi, N., Iwasaki, Y., Boland, T., and LaBerge, M., 2003, Frictional properties of poly (MPC-co-BMA) phospholipid polymer for catheter applications. Biomaterials, 24, 5121–5129
- Guarnieri, M., Carson, B.S., Khan, A., Penno, M., and Jallo, G.I., 2005, Flexible versus rigid catheters for chronic administration of exogenous agents into central nervous system tissues. Journal of Neuroscience Methods, 144, 147–152
- Lynn, S., 2013, Considerations and complexitites of catheter design & development (Gurnee: Medical Design Technology)
- Buntz, B., 2011, Addressing catheter testing challenges (Santa Monica: Medical Device And Diagnostic Industry)
- French, P., Tanase, D., and Goosen, J., 2003, Sensors for catheter applications. Sensors Update, 13, 107–153
- Condino, S., Ferrari, V., Freschi, C., Alberti, A., Berchiolli, R., Mosca, F., and Ferrari, M., 2012, Electromagnetic navigation platform for endovascular surgery: How to develop sensorized catheters and guidewires. The International Journal of Medical Robotics and Computer Assisted Surgery, 8, 300–310
- Werner, C., Rössler, K., and Deckert, F., 1995, [Testing methods for the characterization of catheter balloons and lumina]. Biomedizinische Technik. Biomedical Engineering, 40, 276–281
- Chun, Y., Hur, S.C., Kealey, C.P., Levi, D.S., Mohanchandra, K., Di Carlo, D., Eldredge, J.D., Vinuela, F., and Carman, G.P., 2011, Intra-aneurysmal flow reductions in a thin film nitinol flow diverter. Smart Materials and Structures, 20, 055021