Glen A. Hagemann and Joseph R. Cummins
1.
An Introduction to the Physics of Diagnostic Radiology;
Edward E. Christensen, Thomas S. Curry, III, James E. Dowdey, Second Edition; Lea an d Febiger; Philadelphia, 1978.
2.
Computerized Axial Tomography
; by J. Gambarelli, G. Guerinel, L. Chevrot, M. Mattei; Springer-Verlag; Berlin Heidelberg, New York, 1977.
3.
Computerized Tomography 1977;
Edited by David Norman, Melvyn Korobkin, Thomas H. Newton, M.D.S.; Distributed by The C.U. Mosby Company, 11830 Westline Industrial Drive, St. Louis, Missouri 63141.
4.
Computed Tomography, Ultrasound and X-ray
; An Integrated Approach 1980; Edited by Albert A. Moss, M.D., Henry I. Goldberg, M.Y.; Academic Fress Inc., New York.
5. Doyle FH. Pennock JM. Banks LM., McDonnell MJ, Bydder GM, Steiner RE, Young IR, Clarke GJ, Pasmore T, Gilderdale DJ:
Nuclear Magnetic Resonance (NMR) Imaging of the Liver
; AJR 138:193, 1982.
6.
Introduction to Practical High Resolution Nuclear Magnetic
Resonance Spectroscopy;
by William H. Oldendorf; New York, 1982.
7. Lauterbur PC:
Image Formation by Induced Local Interactions
: examples employing nuclear magnetic resonance; Nature 242: 190, 1973.
8.
Mathematic of Radiology and Nuclear Medicine
; by Herbert L. Jackson, Ph.D.; Warren H. Green Inc.; St. Louis, Missouri, 1971.
9. Moran, Jim;
The Wonders of Magic Squares
; New York; Vintage Books, 1982.
10.
NMR Imaging in Medicine
; I.L. Pykett in Scientific American; Volume 246, No. 5, pages 2-12; May, 1982.
11.
Principles of NMR Imaging
; I.L. Pykett, J.H. Newhouse, F.S. Buonanna, T.J. Brady, M.R. Goldman, J.F. Kistler and G.M. Fohost in Radiology; Volume 143, pages 157-168; April, 1982.
12.
Shaw, D. Fourier Transform NMR Spectroscopy; Elsevier;
Amsterdam, 1976.
Diagram “A” Numerical value of tissue density of the brain.
(figure available in print form)
Diagram “B” “Gray Scale” For computed Tomography of the Brain
(figure available in print form)
Diagram “C” “Original EMI Scanner”
(figure available in print form)
Diagram “D” An example of an iterative reconstruction technique
(figure available in print form)
Diagram “E” showing the linear and rotary motions of a CT scanner
(figure available in print form)
Diagram “E1” First generation scanner (the original EMI unit)
(figure available in print form)
Diagram “F”
(figure available in print form)
Diagram “G-1”
(figure available in print form)
Diagram “G-2”
(figure available in print form)
Diagram “G-3”
(figure available in print form)
Diagram “G-4”
(figure available in print form)
Diagram #1 Magnetic nuclei behave like small bar magnets.
(figure available in print form)
Reproduced with permission from General Electric, August, 1983.
Diagram #2 Spins are randomly oriented without presentation of an external magnetic field.
(figure available in print form)
Reproduced with permission from General Electric, August, 1983.
Diagram #3 Realignment of the nuclei when placed into a magnetic field.
(figure available in print form)
Reproduced with permission from General Electric, August, 1983.
Diagram #4 Nuclei align themselves with the magnetic lines of induction.
(figure available in print form)
Diagram #5 Precession of a magnetic nucleus.
(figure available in print form)
Diagram #6 The net magnetic moment of each nucleus is displaced when bombarded by the radiofrequency pulse.
(figure available in print form)
Diagram #7 Schematic diagram illustrating NMR apparatus.
(figure available in print form)
Diagram #9—A. CT scan of the normal brain.
(figure available in print form)
B. NMR image of the normal brain.
(figure available in print form)
Diagram #10—A. CT scan of multiple sclerosis showing a brain lesion.
(figure available in print form)
B. NMR image of multiple sclerosis showing more pronounced brain lesions.
(figure available in print form)
Diagram “H” A CT gantry
(figure available in print form)
Diagram “I” A CT computer console
(figure available in print form)