Methods and systems for Maxwell compensation for spin-echo train imaging

What is claimed is: 1. A method for turbo spin-echo (TSE) imaging of a subject, the method implemented by one or more computing devices and comprising: generating a radio frequency (RF) excitation pulse to produce transverse magnetization that generates a nuclear magnetic resonance (NMR) signal and a series of RF refocusing pulses to produce a corresponding series of NMR spin-echo signals; modifying an original encoding gradient waveform comprising a non-rectilinear encoding trajectory by: introducing at least one zero zeroth-moment waveform segment comprising two bipolar pairs at one or both ends of the original encoding gradient waveform; and reversing a polarity of one of the two bipolar pairs for one of a first gradient axis or a second gradient axis different from the first gradient axis; generating during an interval adjacent to each of the series of RF refocusing pulses a first gradient pulse and a second gradient pulse, wherein: at least one of the first or second gradient pulses is generated according to the modified gradient waveform; and the first and second gradient pulses encode the NMR spin-echo signals corresponding to the first gradient axis and the second gradient axis, respectively; and constructing an image from generated digitized samples of the NMR spin-echo signals obtained based on the encoding. 2. The method of claim 1 , wherein the non-rectilinear encoding trajectory comprises interleaved spiral or spiral rings or a spiral trajectory comprising a spiral-out, a spiral-in, or a spiral-in-out trajectory. 3. The method of claim 1 , further comprising adjusting at least a portion of the original encoding gradient waveform that comprises a trapezoidal gradient segment that is not concurrent with data sampling, wherein the trapezoidal gradient segment is at one of the opposing ends prior to the introduction of the at least one zero zeroth-moment waveform segments and the method further comprises increasing or decreasing the length of the trapezoidal gradient segment, while concurrently decreasing or increasing its amplitude, respectively, to increase or decrease a Maxwell integral of the original encoding gradient waveform. 4. The method of claim 1 , wherein a Maxwell integral is substantially zero at a spin-echo time associated with the modified encoding gradient waveform and a magnitude of the Maxwell integral is substantially equal at each of a beginning and an end of the modified encoding gradient waveform. 5. A computing device, comprising memory comprising programmed instructions stored thereon and one or more processors configured to execute the stored programmed instructions to: generate a radio frequency (RF) excitation pulse to produce transverse magnetization that generates a nuclear magnetic resonance (NMR) signal and a series of RF refocusing pulses to produce a corresponding series of NMR spin-echo signals; modify an original encoding gradient waveform comprising a non-rectilinear encoding trajectory by: introducing at least one zero zeroth-moment waveform segment at one or both ends of the original encoding gradient waveform, wherein the original encoding gradient waveform comprises a trapezoidal gradient segment that is not concurrent with data sampling and is at one of the ends prior to the introduction of the at least one zero zeroth-moment waveform segment; and increasing or decreasing the length of the trapezoidal gradient segment, while concurrently decreasing or increasing its amplitude, respectively, to increase or decrease a Maxwell integral of the original encoding gradient waveform; generate during an interval adjacent to each of the series of RF refocusing pulses a first gradient pulse, wherein at least one of the first gradient pulses is generated according to the modified gradient waveform and the first gradient pulses encode the NMR spin-echo signals; and construct an image from generated digitized samples of the NMR spin-echo signals obtained based on the encoding. 6. The computing device of claim 5 , wherein the first gradient pulses encode the NMR spin-echo signals corresponding to a first gradient axis. 7. The computing device of claim 6 , wherein the one or more processors are further configured to execute the stored programmed instructions to generate during the interval adjacent to each of the series of RF refocusing pulses a second gradient pulse, wherein at least one of the second gradient pulses is generated according to the modified encoding gradient waveform and the second gradient pulses encode the NMR spin-echo signals corresponding to a second gradient axis different from the first gradient axis. 8. The computing device of claim 7 , wherein the at least one zero zeroth-moment waveform segments comprise two bipolar pairs and the one or more processors are further configured to execute the stored programmed instructions to reverse the polarity of one of the two bipolar pairs for one of the first or second gradient axes. 9. The computing device of claim 5 , wherein the non-rectilinear encoding trajectory comprises interleaved spiral or spiral rings or a spiral trajectory comprising a spiral-out, a spiral-in, or a spiral-in-out trajectory. 10. The computing device of claim 5 , wherein a Maxwell integral is substantially zero at a spin-echo time associated with the modified encoding gradient waveform and a magnitude of the Maxwell integral is substantially equal at each of a beginning and an end of the modified encoding gradient waveform. 11. A magnetic resonance imaging (MRI) system, comprising: a control sequencer coupled to a gradient subsystem comprising gradient amplifiers and gradient coils and an MRI subsystem comprising a static z-axis magnet and one or more radio frequency (RF) coils; and a data acquisition and display (DADC) device comprising memory comprising programmed instructions stored thereon and one or more processors configured to execute the stored programmed instructions to: generate a RF excitation pulse to produce transverse magnetization that generates a nuclear magnetic resonance (NMR) signal and a series of RF refocusing pulses to produce a corresponding series of NMR spin-echo signals; modify an original encoding gradient waveform comprising a non-rectilinear encoding trajectory by one or more of: adjusting at least a portion of the original encoding gradient waveform while maintaining substantially the same zeroth moment for the at least a portion of the original encoding gradient waveform; or introducing at least one additional waveform segment, having a zeroth moment of substantially zero, at one or both ends of the original encoding gradient waveform; generate during an interval adjacent to each of the series of RF refocusing pulses a first gradient pulse, wherein at least one of the first gradient pulses is generated according to the modified gradient waveform, the first gradient pulses encode the NMR spin-echo signals, a Maxwell integral is substantially zero at a spin-echo time associated with the modified encoding gradient waveform, and a magnitude of the Maxwell integral is substantially equal at each of a beginning and an end of the modified encoding gradient waveform; and construct an image from generated digitized samples of the NMR spin-echo signals obtained based on the encoding. 12. The MRI system of claim 11 , wherein the first gradient pulses encode the NMR spin-echo signals corresponding to a first gradient axis. 13. The MRI system of claim 12 , wherein the one or more processors are further configured to execute the stored programmed instructions to generate during the interval adjacent to each of the series of RF refocusing pulses a sec