Background-suppressed myelin water imaging

What is claimed: 1. A method of acquiring a myelin water image comprising: applying RF pulses to suppress signals from long T 1 components so that a short T 1 signal including a myelin water component dominates a resulting image of a region of interest; applying an excitation RF pulse to the region of interest; and acquiring image data in the region of interest for display of a myelin water image. 2. The method of claim 1 , wherein said RF suppression pulses suppress T1 signals longer than 400 ms for 1.5 T or 3 T fields or longer than 500 ms for 7 T fields. 3. The method of claim 1 , wherein the RF suppression pulses comprise double or multiple inversion RF pulses sufficient to remove long T1 water signals unrelated to myelin water. 4. The method of claim 3 , wherein the applying steps apply a pulse sequence, satisfying either the following equation for two inversion pulses: M xy =M 0 (1−(2−(2−ε −TD/T 1 )ε −T1 1 /T 1 )ε −T1 2 /T 1 )ε −TE/T 2 * where M 0 is a fully relaxed magnetization value, T1 1 is a time duration from a first inversion RF pulse to a second inversion RF pulse, T1 2 is a time duration from the second inversion RF pulse to the excitation RF pulse, and TD is a time duration from the excitation RF pulse to a first inversion RF pulse in a subsequent pulse sequence M xy , TE is an echo pulse duration, and M xy is a transverse magnetization after the excitation RF at TE; or the following equation for three inversion pulses: M xy =M 0 (1−(2−(2−(2−ε −TD/T 1 )ε −T1 1 /T 1 )ε −T1 2 /T 1 )ε −TI 3 /T 1 )ε −TE/T 2 * where M 0 is a fully relaxed magnetization value, T1 1 is a time duration from a first inversion RF pulse to a second inversion RF pulse, T1 2 is a time duration from the second inversion RF pulse to the third inversion RF pulse, TI 3 is a time duration from the third inversion RF pulse to the excitation RF pulse, and TD is a time duration from the excitation RF pulse to a first inversion RF pulse in a subsequent pulse sequence, TE is an echo pulse duration, and M xy is a transverse magnetization after the excitation RF at TE; or the following equation for four inversion pulses: M xy =M 0 (1−(2−(2−(2−(2−ε −TD/T 1 )ε −T1 1 /T 1 )ε −T1 2 /T 1 )ε −TI 3 /T 1 )ε −TI 4 /T 1 )ε −TE/T 2 * where M 0 is a fully relaxed magnetization value, T1 1 is a time duration from a first inversion RF pulse to a second inversion RF pulse, T1 2 is a time duration from the second inversion RF pulse to the third inversion RF pulse, TI 3 is a time duration from the third inversion RF pulse to the fourth inversion RF pulse, TI 4 is a time duration from the fourth inversion RF pulse to the excitation RF pulse, and TD is a time duration from the excitation RF pulse to a first inversion RF pulse in a subsequent pulse sequence, TE is an echo pulse duration, and M xy is a transverse magnetization after the excitation RF at TE. 5. The method of claim 1 , wherein the excitation RF pulse comprises a 90° excitation RF pulse. 6. The method of claim 1 , wherein the region of interest is a slice of or a part or whole brain of a subject. 7. A system for acquiring a myelin water image, comprising: an RF pulse generator that generates RF pulses adapted to suppress signals from long T 1 components so that a short T 1 signal including a myelin water component dominates a resulting image of a region of interest when the RF pulses are applied to the region of interest, said RF pulse generator further generating an excitation RF pulse for application to the region of interest; and a data acquisition element adapted to acquire image data in the region of interest for display of a myelin water image generated in response to application of said RF pulses and RF excitation pulse to the region of interest. 8. The system of claim 7 , wherein said RF suppression pulses suppress T1 signals longer than 400 ms for 1.5 T or 3 T fields or longer than 500 ms for 7 T fields. 9. The system of claim 7 , wherein the RF suppression pulses comprise double or multiple inversion RF pulses sufficient to remove long T1 water signals unrelated to myelin water. 10. The system of claim 9 , wherein the RF pulse sequence applied to the region of interest by the RF pulse generator satisfies either the following equation for two inversion pulses: M xy =M 0 (1−(2−(2−ε −TD/T 1 )ε −T1 1 /T 1 )ε −T1 2 /T 1 )ε −TE/T 2 * where M 0 is a fully relaxed magnetization value, T1 1 is a time duration from a first inversion RF pulse to a second inversion RF pulse, T1 2 is a time duration from the second inversion RF pulse to the excitation RF pulse, and TD is a time duration from the excitation RF pulse to a first inversion RF pulse in a subsequent pulse sequence M xy , TE is an echo pulse duration, and M xy is a transverse magnetization after the excitation RF at TE; or the following equation for three inversion pulses: M xy =M 0 (1−(2−(2−(2−ε −TD/T 1 )ε −T1 1 /T 1 )ε −T1 2 /T 1 )ε −TI 3 /T 1 )ε −TE/T 2 * where M 0 is a fully relaxed magnetization value, T1 1 is a time duration from a first inversion RF pulse to a second inversion RF pulse, T1 2 is a time duration from the second inversion RF pulse to the third inversion RF pulse, TI 3 is a time duration from the third inversion RF pulse to the excitation RF pulse, and TD is a time duration from the excitation RF pulse to a first inversion RF pulse in a subsequent pulse sequence, TE is an echo pulse duration, and M xy is a transverse magnetization after the excitation RF at TE; or the following equation for four inversion pulses: M xy =M 0 (1−(2−(2−(2−(2−ε −TD/T 1 )ε −T1 1 /T 1 )ε −T1 2 /T 1 )ε −TI 3 /T 1 )ε −TI 4 /T 1 )ε −TE/T 2 * where M 0 is a fully relaxed magnetization value, T1 1 is a time duration from a first inversion RF pulse to a second inversion RF pulse, T1 2 is a time duration from the second inversion RF pulse to the third inversion RF pulse, TI 3 is a time duration from the third inversion RF pulse to the fourth inversion RF pulse, TI 4 is a time duration from the fourth inversion RF pulse to the excitation RF pulse, and TD is a time duration from the excitation RF pulse to a first inversion RF pulse in a subsequent pulse sequence, TE is an echo pulse duration, and M xy is a transverse magnetization after the excitation RF at TE. 11. The system of claim 7 , wherein the excitation RF pulse comprises a 90° excitation RF pulse. 12. The system of claim 7 , wherein the region of interest is a slice of or a part or whole brain of a subject.