Z-spectroscopy with Alternating-Phase Irradiation

Johanna Närväinen; Penny L Hubbard; Risto A Kauppinen; Gareth A Morris

doi:10.1016/j.jmr.2010.09.004

Z-spectroscopy with Alternating-Phase Irradiation

Johanna Närväinen, Penny L Hubbard, Risto A Kauppinen, Gareth A Morris

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34 Citations (Scopus)

Abstract

Magnetization transfer (MT) MRI and Z-spectroscopy are tools to study both water-macromolecule interactions and pH-sensitive exchange dynamics between water and the protons of mobile chemical groups within these macromolecules. Both rely on saturation of frequencies offset from water and observation of the on-resonance water signal. In this work, an RF saturation method called Z-spectroscopy with Alternating-Phase Irradiation (ZAPI) is introduced. Based on the T(2)-selectivity of the irradiation pulse, ZAPI can be used to separate the different contributions to a Z-spectrum, as well as to study the T(2) distribution of the macromolecules contributing to the MT signal. ZAPI can be run at resonance for water and with low power, thus minimizing problems with specific absorption rate (SAR) limits in clinical applications. In this paper, physical and practical aspects of ZAPI are discussed and the sequence is applied in vitro to sample systems and in vivo to rat head to demonstrate the method.

Original language	English
Pages (from-to)	242-50
Number of pages	9
Journal	Journal of Magnetic Resonance
Volume	207
Issue number	2
DOIs	https://doi.org/10.1016/j.jmr.2010.09.004
Publication status	Published - 2010

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title = "Z-spectroscopy with Alternating-Phase Irradiation",

abstract = "Magnetization transfer (MT) MRI and Z-spectroscopy are tools to study both water-macromolecule interactions and pH-sensitive exchange dynamics between water and the protons of mobile chemical groups within these macromolecules. Both rely on saturation of frequencies offset from water and observation of the on-resonance water signal. In this work, an RF saturation method called Z-spectroscopy with Alternating-Phase Irradiation (ZAPI) is introduced. Based on the T(2)-selectivity of the irradiation pulse, ZAPI can be used to separate the different contributions to a Z-spectrum, as well as to study the T(2) distribution of the macromolecules contributing to the MT signal. ZAPI can be run at resonance for water and with low power, thus minimizing problems with specific absorption rate (SAR) limits in clinical applications. In this paper, physical and practical aspects of ZAPI are discussed and the sequence is applied in vitro to sample systems and in vivo to rat head to demonstrate the method.",

author = "Johanna N{\"a}rv{\"a}inen and Hubbard, {Penny L} and Kauppinen, {Risto A} and Morris, {Gareth A}",

year = "2010",

doi = "10.1016/j.jmr.2010.09.004",

language = "English",

volume = "207",

pages = "242--50",

journal = "Journal of Magnetic Resonance",

issn = "1096-0856",

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TY - JOUR

T1 - Z-spectroscopy with Alternating-Phase Irradiation

AU - Närväinen, Johanna

AU - Hubbard, Penny L

AU - Kauppinen, Risto A

AU - Morris, Gareth A

PY - 2010

Y1 - 2010

N2 - Magnetization transfer (MT) MRI and Z-spectroscopy are tools to study both water-macromolecule interactions and pH-sensitive exchange dynamics between water and the protons of mobile chemical groups within these macromolecules. Both rely on saturation of frequencies offset from water and observation of the on-resonance water signal. In this work, an RF saturation method called Z-spectroscopy with Alternating-Phase Irradiation (ZAPI) is introduced. Based on the T(2)-selectivity of the irradiation pulse, ZAPI can be used to separate the different contributions to a Z-spectrum, as well as to study the T(2) distribution of the macromolecules contributing to the MT signal. ZAPI can be run at resonance for water and with low power, thus minimizing problems with specific absorption rate (SAR) limits in clinical applications. In this paper, physical and practical aspects of ZAPI are discussed and the sequence is applied in vitro to sample systems and in vivo to rat head to demonstrate the method.

AB - Magnetization transfer (MT) MRI and Z-spectroscopy are tools to study both water-macromolecule interactions and pH-sensitive exchange dynamics between water and the protons of mobile chemical groups within these macromolecules. Both rely on saturation of frequencies offset from water and observation of the on-resonance water signal. In this work, an RF saturation method called Z-spectroscopy with Alternating-Phase Irradiation (ZAPI) is introduced. Based on the T(2)-selectivity of the irradiation pulse, ZAPI can be used to separate the different contributions to a Z-spectrum, as well as to study the T(2) distribution of the macromolecules contributing to the MT signal. ZAPI can be run at resonance for water and with low power, thus minimizing problems with specific absorption rate (SAR) limits in clinical applications. In this paper, physical and practical aspects of ZAPI are discussed and the sequence is applied in vitro to sample systems and in vivo to rat head to demonstrate the method.

U2 - 10.1016/j.jmr.2010.09.004

DO - 10.1016/j.jmr.2010.09.004

M3 - Article (Academic Journal)

C2 - 20920868

SN - 1096-0856

VL - 207

SP - 242

EP - 250

JO - Journal of Magnetic Resonance

JF - Journal of Magnetic Resonance

IS - 2

ER -

Z-spectroscopy with Alternating-Phase Irradiation

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