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Magnetic Resonance Microscopy

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Название:
Magnetic Resonance Microscopy
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unrecognised / на английском языке
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неизвестен
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Magnetic Resonance Microscopy: краткое содержание, описание и аннотация

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Magnetic Resonance Microscopy
Explore the interdisciplinary applications of magnetic resonance microscopy in this one-of-a-kind resource Magnetic Resonance Microscopy: Instrumentation and Applications in Engineering, Life Science and Energy Research,
Magnetic Resonance Microscopy: Instrumentation and Applications in Engineering, Life Science and Energy Research
Magnetic Resonance Microscopy: Instrumentation and Applications in Engineering, Life Science and Energy Research

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53 53Okorie, C.K., Ogbole, G.I., Owolabi, M.O.et al. (2015). Role of diffusion-weighted imaging in acute stroke management using low-field magnetic resonance imaging in resource-limited settings. The West African Journal of Radiology 22 (2): 61–66.

54 54Fassbender, K., Grotta, J.C., Walter, S.et al. (2017). Mobile stroke units for prehospital thrombolysis, triage, and beyond: Benefits and challenges. Lancet Neurology 16 (3): 227–237.

55 55 Fassbender, K., Walter, S., Grunwald, I.Q.et al. (2020). Prehospital stroke management in the thrombectomy era. Lancet Neurology 19 (7): 601–610.

56 56 Fassbender, K., Walter, S., Liu, Y.et al. (2003). “Mobile stroke unit” for hyperacute stroke treatment. Stroke 34 (6): e44.

57 57 Grunwald, I.Q., Phillips, D.J., Sexby, D.et al. (2020). Mobile stroke unit in the UK healthcare system: Avoidance of unnecessary accident and emergency admissions. Cerebrovascular Diseases 49 (4): 388–395.

58 58Walter, S., Ragoschke-Schumm, A., Lesmeister, M.et al. (2018). Mobile stroke unit use for prehospital stroke treatment – An update. Radiologe 58 (Suppl. 1): 24–28.

59 59Powers, W.J., Rabinstein, A.A., Ackerson, T.et al. (2019). Guidelines for the early management of patients with acute ischemic stroke: 2019 Update to the 2018 guidelines for the early management of acute ischemic stroke: A guideline for healthcare professionals from the American Heart Association/American Stroke Association. Stroke 50 (12): e344–e418.

60 60Powers, W.J., Rabinstein, A.A., Ackerson, T.et al. (2018). Guidelines for the early management of patients with acute ischemic stroke: A guideline for healthcare professionals from the American Heart Association/American Stroke Association. Stroke 49 (3): e46–e110.

61 61Schaefer, P.W., Souza, L., Kamalian, S.et al. (2015). Limited reliability of computed tomographic perfusion acute infarct volume measurements compared with diffusion-weighted imaging in anterior circulation stroke. Stroke 46 (2): 419–424.

62 62Leiva-Salinas, C.and Wintermark, M. (2010). Imaging of acute ischemic stroke. Neuroimaging Clinics of North America 20 (4): 455–468.

63 63Wintermark, M., Sanelli, P.C., Albers, G.W.et al. (2013). Imaging recommendations for acute stroke and transient ischemic attack patients: A joint statement by the American Society of Neuroradiology, the American College of Radiology and the Society of NeuroInterventional Surgery. Journal of the American College of Radiology 10 (11): 828–832.

64 64Li, L., Padhi, A., Ranjeva, S.L.et al. (2011). Association of bacteria with hydrocephalus in Ugandan infants. Journal of Neurosurgery: Pediatrics 7 (1): 73–87.

65 65Warf, B.C., Alkire, B.C., Bhai, S.et al. (2011). Costs and benefits of neurosurgical intervention for infant hydrocephalus in sub-Saharan Africa. Journal of Neurosurgery: Pediatrics 8 (5): 509–521.

66 66Kulkarni, A.V., Schiff, S.J., Mbabazi-Kabachelor, E.et al. (2017). Endoscopic treatment versus shunting for infant hydrocephalus in Uganda. The New England Journal of Medicine 377 (25): 2456–2464.

67 67Obungoloch, J., Harper, J.R., Consevage, S.et al. (2018). Design of a sustainable prepolarizing magnetic resonance imaging system for infant hydrocephalus. MAGMA 31 (5): 665–676.

68 68O’Reilly, T., Teeuwisse, W.M., and Webb, A.G. (2019). Three-dimensional MRI in a homogenous 27cm diameter bore Halbach array magnet. Journal of Magnetic Resonance 307: 106578.

69 69Diehl, J., Van Doesum, F., Bakker, M.et al. (2020). The embodiment of low-field MRI for the diagnosis of infant hydrocephalus in Uganda. IEEE Global Humanitarian Technology Conference (GHTC), virtual.

70 70O’Reilly, T., Wouter, T., Winter, L.et al. (2019). Design of a homogeneous large-bore Halbach array for low field MRI. Proceedings of the ISMRM, Montreal, Canada.

71 71Blumich, B., Blumler, P., Eidmann, G.et al. (1998). The NMR-mouse: Construction, excitation, and applications. Magnetic Resonance Imaging 16 (5–6): 479–484.

72 72Perlo, J., Casanova, F., and Blumich, B. (2005). Profiles with microscopic resolution by single-sided NMR. Journal of Magnetic Resonance 176 (1): 64–70.

73 73Hurlimann, M.D.and Heaton, N.J. (2016). NMR well logging. In: Mobile NMR and MRI: Developments and Applications (eds. M. Johns, E.O. Findjonson, S. Vogt, and A. Haber), 11–79. Cambridge, UK: Royal Society of Chemistry.

74 74Douglas-Escobar, M.and Weiss, M.D. (2015). Hypoxic-ischemic encephalopathy: A review for the clinician. JAMA Pediatrics 169 (4): 397–403.

75 75Finer, N.N., Robertson, C.M., Richards, R.T.et al. (1981). Hypoxic-ischemic encephalopathy in term neonates: Perinatal factors and outcome. Journal of Pediatrics 98 (1): 112–117.

76 76Oorschot, D.E., Sizemore, R.J., and Amer, A.R. (2020). Treatment of neonatal hypoxic-ischemic encephalopathy with erythropoietin alone, and erythropoietin combined with hypothermia: history, current status, and future research. International Journal of Molecular Sciences 21 (4): 1487.

77 77Gluckman, P.D., Wyatt, J.S., Azzopardi, D.et al. (2005). Selective head cooling with mild systemic hypothermia after neonatal encephalopathy: Multicentre randomised trial. Lancet 365 (9460): 663–670.

78 78Bano, S., Chaudhary, V., and Garga, U.C. (2017). Neonatal hypoxic-ischemic encephalopathy: A radiological review. Journal of Pediatric Neurosciences 12 (1): 1–6.

79 79Arthurs, O.J., Edwards, A., Austin, T.et al. (2012). The challenges of neonatal magnetic resonance imaging. Pediatric Radiology 42 (10): 1183–1194.

80 80Hinshaw, W.S., Andrew, E.R., Bottomley, P.A.et al. (1978). Internal structural mapping by nuclear magnetic resonance. Neuroradiology 16: 607–609.

81 81 Hinshaw, W.S., Bottomley, P.A., and Holland, G.N. (1977). Radiographic thin-section image of the human wrist by nuclear magnetic resonance. Nature 270 (5639): 722–723.

82 82 Edelman, R.R. (2014). The history of MR imaging as seen through the pages of radiology. Radiology 273 (2 Suppl.): S181–S200.

83 83Feinberg, D.A., Mills, C.M., Posin, J.P.et al. (1985). Multiple spin-echo magnetic resonance imaging. Radiology 155 (2): 437–442.

84 84Sarracanie, M.and Salameh, N. (2020). Low-field MRI: How low can we go? A fresh view on an old debate. Frontiers in Physics 8: 172.

85 85Kraus, R.H., Espy, M.A., Magnelind, P.E.et al. (2014). Ultra-Low Field Nuclear Magnetic Resonance, a New MRI Regime. Oxford, UK: Oxford University Press.

86 86Macovski, A.and Conolly, S. (1993). Novel approaches to low-cost MRI. Magnetic Resonance in Medicine 30 (2): 221–230.

87 87Clarke, J.C., Hatridge, M., and Mossle, M. (2007). SQUID-detected magnetic resonance imaging in microtesla fields. Annual Review of Biomedical Engineering 9: 389–413.

88 88 Inglis, B., Buckenmaier, K., Sangiorgio, P.et al. (2013). MRI of the human brain at 130 microtesla. Proceedings of the National Academy of Sciences of the United States of America 110 (48): 19194–19201.

89 89 Lin, F.H., Vesanen, P.T., Nieminen, J.O.et al. (2013). Noise amplification in parallel whole-head ultra-low-field magnetic resonance imaging using 306 detectors. Magnetic Resonance in Medicine 70 (2): 595–600.

90 90Savukov, I.M., Zotev, V.S., Volegov, P.L.et al. (2009). MRI with an atomic magnetometer suitable for practical imaging applications. Journal of Magnetic Resonance 199 (2): 188–191.

91 91Tsai, L.L., Mair, R.W., Rosen, M.S.et al. (2008). An open-access, very-low-field MRI system for posture-dependent 3He human lung imaging. Journal of Magnetic Resonance 193 (2): 274–285.

92 92Sarracanie, M., LaPierre, C.D., Salameh, N.et al. (2015). Low-cost high-performance MRI. Scientific Reports 5: 15177.

93 93Volegov, P.L., Mosher, J.C., Espy, M.A.et al. (2005). On concomitant gradients in low-field MRI. Journal of Magnetic Resonance 175 (1): 103–113.