BOLD signal referanser

Detaljer

Sist oppdatert tirsdag 05. januar 2016 22:21

1. On the regulation of the blood-supply of the brain (C. Roy and C. Sherrington)

2. Brain magnetic resonance imaging with contrast dependent on blood oxygenation (S. Ogawa, T. M. Lee, a R. Kay, and D. W. Tank)

3. Time Course EPI of Human Brain Function during Task Activation (P. Bandettini, E. Wong, R. Hinks, R. Tikofsky, and J. Hyde)

4. Dynamic magnetic resonance imaging of human brain activity during primary sensory stimulation (K. K. Kwong, J. W. Belliveau, D. a Chesler, I. E. Goldberg, R. M. Weisskoff, B. P. Poncelet, D. N. Kennedy, B. E. Hoppel, M. S. Cohen, and R. Turner)

5. Intrinsic signal changes accompanying sensory stimulation: Functional brain mapping with magnetic resonance imaging (S. Ogawa, D. W. Tank, R. Menon, J. M. Ellermann, S. G. Kim, H. Merkle, and K. Ugurbil)

6. Functional Mapping of the Human Visual Cortex by Magnetic Resonance Imaging (J. Belliveau, D. Kennedy, R. McKinstry, B. Buchbinder, R. Weisskoff, M. Cohen, J. Vevea, T. Brady, and B. Rosen)

7. The role(s) of astrocytes and astrocyte activity in neurometabolism, neurovascular coupling, and the production of functional (C. R. Figley and P. W. Stroman)

8. The neurovascular unit - concept review (V. Muoio, P. B. Persson, and M. M. Sendeski)

9. Revisiting the role of neurons in neurovascular coupling (B. Cauli and E. Hamel)

10. The magnetic properties and structure of hemoglobin, oxyhemoglobin and carbonmonoxyhemoglobin (L. Pauling and C. Coryell)

11. Oxygenation dependence of the transverse relaxation time of water protons in whole blood at high Field (K. Thulborn, J. Waterton, P. M. Matthews, and G. Radda)

12. Blood oxygen saturation assessment in vivo using T2* estimation (D. Li, Y. Wang, and D. J. Waight)

13. Oxygenation-sensitive contrast in magnetic resonance image of rodent brain at high magnetic fields (S. Ogawa, T. M. Lee, a S. Nayak, and P. Glynn)

14. Magnetic resonance imaging of blood vessels at high fields: in vivo and in vitro measurements and image simulation (S. Ogawa and T. M. Lee)

15. The elusive initial dip (R. B. Buxton)

16. Dynamic models of BOLD contrast (R. B. Buxton)

17. The BOLD post-stimulus undershoot, one of the most debated issues in fMRI (P. C. M. van Zijl, J. Hua, and H. Lu)

18. Dynamics of blood flow and oxygenation changes during brain activation: the balloon model (R. B. Buxton, E. C. Wong, and L. R. Frank)

19. Poststimulus undershoots in cerebral blood flow and BOLD fMRI responses are modulated by poststimulus neuronal activity (K. Mullinger, S. Mayhew, A. Bagshaw, R. Bowtell, and S. Francis)

20. Nonlinear responses in fMRI: the Balloon model, Volterra kernels, and other hemodynamics (K. J. Friston, a Mechelli, R. Turner, and C. J. Price)

21. Hemodynamic changes after visual stimulation and breath holding provide evidence for an uncoupling of cerebral blood flow and volume from oxygen metabolism (M. J. Donahue, R. D. Stevens, M. de Boorder, J. J. Pekar, J. Hendrikse, and P. C. M. van Zijl)

22. Physiological origin for the BOLD poststimulus undershoot in human brain: vascular compliance versus oxygen metabolism (J. Hua, R. D. Stevens, A. J. Huang, J. J. Pekar, and P. C. M. van Zijl)

23. CBF/CMRO2 coupling measured with calibrated BOLD fMRI: sources of bias (O. Leontiev, D. J. Dubowitz, and R. B. Buxton)

24. Sustained poststimulus elevation in cerebral oxygen utilization after vascular recovery (H. Lu, X. Golay, J. J. Pekar, and P. C. M. Van Zijl)

25. MRI measurement of the temporal evolution of relative CMRO(2) during rat forepaw stimulation (J. B. Mandeville, J. J. Marota, C. Ayata, M. a Moskowitz, R. M. Weisskoff, and B. R. Rosen)

26. Evidence of a cerebrovascular postarteriole windkessel with delayed compliance (J. Mandeville, J. Marota, C. Ayata, G. Zaharchuk, M. Moskowitz, B. Rosen, and R. Weisskoff)

27. Oxygenation and hematocrit dependence of transverse relaxation rates of blood at 3T (J. M. Zhao, C. S. Clingman, M. J. Närväinen, R. a Kauppinen, and P. C. M. van Zijl)

28. In vivo blood T(1) measurements at 1.5 T, 3 T, and 7 T (X. Zhang, E. T. Petersen, E. Ghariq, J. B. De Vis, a G. Webb, W. M. Teeuwisse, J. Hendrikse, and M. J. P. van Osch)

29. Fast scan proton density imaging by NMR (P. Mansfield, A. Maudsley, and T. Baines)

30. Ultra-fast imaging (M. Cohen and R. Weisskoff)

31. Spin-echo and gradient-echo EPI of human brain activation using BOLD contrast: a comparative study at 1.5 T (P. Bandettini, E. Wong, A. Jesmanowicz, R. Hinks, and J. Hyde)

32. Brain or vein--oxygenation or flow? On signal physiology in functional MRI of human brain activation (J. Frahm, K. D. Merboldt, W. Hänicke, a Kleinschmidt, and H. Boecker)

33. Physiological noise in oxygenation-sensitive magnetic resonance imaging (G. Krüger and G. H. Glover)

34. Comparison of physiological noise at 1.5 T, 3 T and 7 T and optimization of fMRI acquisition parameters (C. Triantafyllou, R. D. Hoge, G. Krueger, C. J. Wiggins, a Potthast, G. C. Wiggins, and L. L. Wald)

35. Mathematical analysis of random noise (S. O. Rice)

36. Effect of temporal autocorrelation due to physiological noise and stimulus paradigm on voxel-level false-positive rates in fMRI (P. L. Purdon and R. M. Weisskoff)

37. Power spectrum analysis of functionally- weighted MR data: What’s in the Noise? (R. Weisskoff, J. Baker, J. Belliveau, T. Davis, K. Kwong, M. Cohen, and B. Rosen)

38. Generalized autocalibrating partially parallel acquisitions (GRAPPA) (M. a Griswold, P. M. Jakob, R. M. Heidemann, M. Nittka, V. Jellus, J. Wang, B. Kiefer, and A. Haase)

39. SENSE: sensitivity encoding for fast MRI (K. P. Pruessmann, M. Weiger, M. B. Scheidegger, and P. Boesiger)

40. Enhanced sensitivity with fast three-dimensional blood-oxygen-level-dependent functional MRI : comparison of SENSE – PRESTO and 2D-EPI at 3 T (S. F. W. Neggers, E. J. Hermans, and N. F. Ramsey)

41. A functional MRI technique combining principles of echo-shifting with a train of observations (PRESTO) (G. Liu, G. Sobering, J. H. Duyn, and C. T. W. Moonen)

42. Detection of BOLD changes by means of a frequency‐sensitive trueFISP technique: preliminary results (K. Scheffler, E. Seifritz, D. Bilecen, R. Venkatesan, J. Hennig, M. Deimling, and E. Haacke)

43. Signal and noise characteristics of SSFP FMRI: a comparison with GRE at multiple field strengths (K. L. Miller, S. M. Smith, P. Jezzard, G. C. Wiggins, and C. J. Wiggins)

44. On the timing characteristics of the apparent diffusion coefficient contrast in fMRI (S. L. Gangstead and A. W. Song)

45. Sources of functional apparent diffusion coefficient changes investigated by diffusion-weighted spin-echo fMRI (T. Jin, F. Zhao, and S.-G. Kim)

46. Enhanced Spatial Localization of Neuronal Activation Using Simultaneous Apparent-Diffusion-Coefficient and Blood-Oxygenation Functional Magnetic Resonance Imaging (A. W. Song, M. G. Woldorff, S. Gangstead, G. R. Mangun, and G. McCarthy)

47. Transient decrease in water diffusion observed in human occipital cortex during visual stimulation (a Darquié, J. B. Poline, C. Poupon, H. Saint-Jalmes, and D. Le Bihan)

48. Direct and fast detection of neuronal activation in the human brain with diffusion MRI (D. Le Bihan, S. Urayama, T. Aso, T. Hanakawa, and H. Fukuyama)

49. An intrinsic diffusion response function for analyzing diffusion functional MRI time series (T. Aso, S. Urayama, C. Poupon, N. Sawamoto, H. Fukuyama, and D. Le Bihan)

50. Water-diffusion slowdown in the human visual cortex on visual stimulation precedes vascular responses (S. Kohno, N. Sawamoto, S.-I. Urayama, T. Aso, K. Aso, A. Seiyama, H. Fukuyama, and D. Le Bihan)

51. Diffusion, confusion and functional MRI (D. Le Bihan)

52. Evidence for a vascular contribution to diffusion FMRI at high b value (K. L. Miller, D. P. Bulte, H. Devlin, M. D. Robson, R. G. Wise, M. W. Woolrich, P. Jezzard, and T. E. J. Behrens)

53. Functional changes of apparent diffusion coefficient during visual stimulation investigated by diffusion-weighted gradient-echo fMRI (T. Jin and S. G. Kim)

54. Impact of hemodynamic effects on diffusion-weighted fMRI signals (U. Rudrapatna, A. Van Der Toorn, M. Van Meer, and R. Dijkhuizen)

55. High b-value diffusion-weighted fMRI in a rat forepaw electrostimulation model at 7 T (J. a a Autio, J. Kershaw, S. Shibata, T. Obata, I. Kanno, and I. Aoki)

56. Reduction of eddy-current-induced distortion in diffusion MRI using a twice-refocused spin echo (T. Reese, O. Heid, R. Weisskoff, and V. Wedeen)

57. Cross-term-compensated pulsed-gradient stimulated echo MR with asymmetric gradient pulse lengths (J. Finsterbusch)

58. BOLD background gradient contributions in diffusion-weighted fMRI--comparison of spin-echo and twice-refocused spin-echo sequences (A. Pampel, T. H. Jochimsen, and H. E. Möller)

59. Functional MR angiography with 7.0 T Is direct observation of arterial response during neural activity possible? (Z.-H. Cho, C.-K. Kang, J.-Y. Han, S.-H. Kim, C.-A. Park, K.-N. Kim, S.-M. Hong, C.-W. Park, and Y.-B. Kim)

60. CBF changes during brain activation: fMRI vs. PET (C.-M. Feng, S. Narayana, J. L. Lancaster, P. a Jerabek, T. L. Arnow, F. Zhu, L. H. Tan, P. T. Fox, and J.-H. Gao)

61. Coupling of cerebral blood flow and oxygen consumption during physiological activation and deactivation measured with fMRI (K. Uludağ, D. J. Dubowitz, E. J. Yoder, K. Restom, T. T. Liu, and R. B. Buxton)

62. Temporal jitter of the BOLD signal reveals a reliable initial dip and improved spatial resolution (Watanabe M, Bartels A, Macke JH, Murayama Y, Logothetis NK.)

63. Attention but not awareness modulates the BOLD signal in the human V1 during binocular suppression (Watanabe M, Cheng K, Murayama Y, Ueno K, Asamizuya T, Tanaka K, Logothetis N.)

64. The underpinnings of the BOLD functional magnetic resonance imaging signal (Logothetis NK.)

65. Neurophysiological investigation of the basis of the fMRI signal (Logothetis NK, Pauls J, Augath M, Trinath T, Oeltermann A.)

66. Insights from neuroenergetics into the interpretation of functional neuroimaging: an alternative empirical model for studying the brain's support of behavior (Shulman RG, Hyder F, Rothman DL.)

67. Quantitative fMRI and oxidative neuroenergetics (Hyder F, Rothman DL.)

68. Neurovascular and Neurometabolic Couplings in Dynamic Calibrated fMRI: Transient Oxidative Neuroenergetics for Block-Design and Event-Related Paradigms (Hyder F, Sanganahalli BG, Herman P, Coman D, Maandag NJ, Behar KL, Blumenfeld H, Rothman DL.)

69. Weighing brain activity with the balance: Angelo Mosso's original manuscripts come to light (Sandrone S1, Bacigaluppi M, Galloni MR, Cappa SF, Moro A, Catani M, Filippi M, Monti MM, Perani D, Martino G)