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Bibliografia

[1] Haacke E.M., Brown R.W., Thompson M.R., Venkatesan R.. (1999).

Magnetic Resonance Imaging – physical principles and sequence design. J.

Wiley & Sons, Inc., Publication.

[2] University of Aberdeen- Deparment of Bio.medical Physics and Bio- Engineering. (1998). Physical basis of MRI. Summer School Notes.

[3] Haase A., Frahm J., Matthaei D., Haenicke W., Merboldt K.D..(1986).

FLASH imaging – Rapid NMR imaging using low flip-angle pulses. Journal of Magn. Res. 67:258-266.

[4] Ernst R.R., Anderson W.A.. (1966). Application of Fourier Transform spectroscopy to magnetic Resonance. Rev. Sci. Instrum. 37:93-102.

[5] Frahm J., Haenicke W., Merboldt K.D. (1987). Transverse coherence in rapid FLASH NMR imaging. J. Magn. Reson. 72:307-314.

[6] Sodickson D.K., Manning W.J. (1997). Simultaneous acquisition of spatial harmonics (SMASH): fast imaging with radiofrequency coil arrays. Magnetic Res. Med. 38:591-603.

[7] Pruessmann K.P., Geiger M., Scheidegger M.B., Boesiger P. (1999). SENSE:

Sensitivity Encoding for fast MRI. Magn. Res. Med. 42:952-962.

[8] Debatin J.F., Spritzetr C.E., Grist T.M. et al. (1991). Imaging of the renal arteries. Value of MR angiography. AJR 157:981-990.

[9] Keller P.J. (1992). Time of flight Magnetic Resonance Angiography.

Neuroim Clin. NA 2(4): 639-656.

[10] Dumoulin C.L. (1992). Phase-Contrast Magnetic Resonance Angiography.

Neuroim clin. NA 2(4): 657-676.

[11] Turski P. , Korosec F. (1993). Phase Contrast Angiography. In: Anderson CM, Edelman R., Turski P. (eds). Clinical Magnetic Resonance angiography.

New York, Raven Press.

[12] Snidow J.J., Matthew S.J., Harris V.J. et al (1996) Three dimensional

gadolinium-enhanced MR angiography for aortoiliac inflow assessment plus renal artery screening in a single breath-hold. Radiology 198:725-732.

[13] Bloch F, Hanson WW, Packard M. Nuclear Induction. (1946) Phys Rev;

69: 127.

[14] Purcell EM, Torrey HC, Pound RV. Resonance Absorption by Nuclear Magnetic Moments in a Solid. (1946) Phys Rev; 69:37-38.

[15] Abragam A. The principles of nuclear magnetism. (1961).London, Oxford University Press.

[16] Allen PS. Some fundamental principles of nuclear magnetic resonance. In medical Physics monograph No. 21: The Physics of MRI: (1992) AAPM Summer School Proceedings, American Institute of Physics, 21:15.

[17] Lauterbur PC. Image formation by induced local interactions: examples employing nuclear magnetic resonance. (1973) Nature 242:190.

100

(2)

[18] Lauterbur PC. Image formation by induced local interactions: examples employing nuclear magnetic resonance. (1974) Pure Appl. Chem. 40: 149.

[19] Hinshaw WS, Bottomley PA, Holland GN, et al. Radiographic thin-section of the human wrist by nuclear Magnetic Resonance imaging. (1977) Nature 270:722.

[20] Mansfield P, Pykett IL. Biological and Medical imaging by NMR. (1978) Journal of Magn. Reson.. 29:355.

[21] Hedelstein WA, Hutchinson JMS, Johnson G et al. Spin-Warp NMR imaging and applications to human whole body imaging, Phys. (1980) Med. Biol.

25:751.

[22] Pykett IL, Mansfield P. A line scan image study of a tumorous rat leg by NMR. (1978) Phys Med. Biol. 23:961.

[22] Maudsley A. Multiple line-scanning spin-density imaging. (1980) Journal of Magn. Reson. 41:112.

[23] Makovski A. Volumetric NMR imaging with time-varying gradients. (1985) Magn. Reson. Med. 2:29.

[24] Mansfield P. Proton spin imaging by nuclear magnetic resonance. (1976) Contemp. Physics. 17:553.

[25] Magnetic Resonance in Medicine. The basic Textbook of the European Magnetic Resonance Forum. (1993). P. Rinck Ed. Third Edition. Oxford, UK:

Blackwell Scientific Pubblications,.

[26] Stark D.D, Bradley W.G. Magnetic Resonance Imaging. (1999). Mosby Edts.

[27] Magnetic resonance of the cardiovascular system. (1991) Richard Underwood and David Firmin Eds. London, Oxford, Edimburgh, Blackwell Scientific Publications,.

[28] Lombardi M., Santarelli F. Risonanza Magnetica Cardiovascolare. (2000) Da: Trattato di Cardiologia. ANMCO (Associazione Nazionale Medici Cardiologi Ospedalieri). Excerpta Medica Ed..

[29] Bruno Madore, Gary H. Glover, and Norbert J. Pelc Unaliasing by Fourier-Encoding the Overlaps Using the Temporal Dimension (UNFOLD), Applied to Cardiac Imaging and fMRI

101

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