Please use this identifier to cite or link to this item: http://ir.futminna.edu.ng:8080/jspui/handle/123456789/17349
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dc.contributor.authorAwojoyogbe, Bamidele-
dc.contributor.authorDada, Michael-
dc.contributor.authorOnwu, Samuel-
dc.contributor.authorIge, Abdallah Taofeeq-
dc.contributor.authorAkinwande, Niniola-
dc.date.accessioned2023-01-17T01:22:34Z-
dc.date.available2023-01-17T01:22:34Z-
dc.date.issued2016-02-18-
dc.identifier.citationAwojoyogbe, B. O., Dada, M. O., Onwu, S. O., Ige, T. A., & Akinwande, N. I. (2016). Computational diffusion magnetic resonance imaging based on time-dependent Bloch NMR flow equation and Bessel functions. Journal of medical systems, 40(4), 1-14.en_US
dc.identifier.otherDoi: 10.1007/s10916-016-0450-4-
dc.identifier.urihttp://repository.futminna.edu.ng:8080/jspui/handle/123456789/17349-
dc.descriptionhttps://link.springer.com/article/10.1007/s10916-016-0450-4en_US
dc.description.abstractMagnetic resonance imaging (MRI) uses a powerful magnetic field along with radio waves and a computer to produce highly detailed “slice-by-slice” pictures of virtually all internal structures of matter. The results enable physicians to examine parts of the body in minute detail and identify diseases in ways that are not possible with other techniques. For example, MRI is one of the few imaging tools that can see through bones, making it an excellent tool for examining the brain and other soft tissues. Pulsed-field gradient experiments provide a straightforward means of obtaining information on the translational motion of nuclear spins. However, the interpretation of the data is complicated by the effects of restricting geometries as in the case of most cancerous tissues and the mathematical concept required to account for this becomes very difficult. Most diffusion magnetic resonance techniques are based on the Stejskal-Tanner formulation usually derived from the Bloch-Torrey partial differential equation by including additional terms to accommodate the diffusion effect. Despite the early success of this technique, it has been shown that it has important limitations, the most of which occurs when there is orientation heterogeneity of the fibers in the voxel of interest (VOI). Overcoming this difficulty requires the specification of diffusion coefficients as function of spatial coordinate(s) and such a phenomenon is an indication of non-uniform compartmental conditions which can be analyzed accurately by solving the time-dependent Bloch NMR flow equation analytically. In this study, a mathematical formulation of magnetic resonance flow sequence in restricted geometry is developed based on a general second order partial differential equation derived directly from the fundamental Bloch NMR flow equations. The NMR signal is obtained completely in terms of NMR experimental parameters. The process is described based on Bessel functions and properties that can make it possible to distinguish cancerous cells from normal cells. A typical example of liver distinguished from gray matter, white matter and kidney is demonstrated. Bessel functions and properties are specifically needed to show the direct effect of the instantaneous velocity on the NMR signal originating from normal and abnormal tissues.en_US
dc.description.sponsorshipNilen_US
dc.language.isoenen_US
dc.publisherSpringer Nature Switzerlanden_US
dc.relation.ispartofseriesCurriculum Vitae;5-
dc.subjectBloch NMR flow equationsen_US
dc.subjectNMR advection-diffusion equationen_US
dc.subjectBrain tumoren_US
dc.subjectGray matteren_US
dc.subjectWhite matteren_US
dc.subjectCerebrospinal fluiden_US
dc.subjectBessel functionsen_US
dc.subjectSickle cell diseaseen_US
dc.subjectCancerous tissuesen_US
dc.subjectPhase shiften_US
dc.titleComputational Diffusion Magnetic Resonance Imaging Based on Time-Dependent Bloch NMR Flow Equation and Bessel Functionsen_US
dc.typeArticleen_US
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