Amide Proton Transfer (APT) Contrast for Imaging of Brain Tumors

Jinyuan Zhou; Bachchu Lal; David A. Wilson; John Laterra; Peter C.M. Van Zijl

doi:10.1002/mrm.10651

Amide Proton Transfer (APT) Contrast for Imaging of Brain Tumors

Jinyuan Zhou, Bachchu Lal, David A. Wilson, John Laterra, Peter C.M. Van Zijl

Research output: Contribution to journal › Article › peer-review

396 Scopus citations

Abstract

In this work we demonstrate that specific MR image contrast can be produced in the water signal that reflects endogenous cellular protein and peptide content in intracranial rat 9L gliosarcomas. Although the concentration of these mobile proteins and peptides is only in the millimolar range, a detection sensitivity of several percent on the water signal (molar concentration) was achieved. This was accomplished with detection sensitivity enhancement by selective radiofrequency (RF) labeling of the amide protons, and by utilizing the effective transfer of this label to water via hydrogen exchange. Brain tumors were also assessed by conventional T ₁-weighted, T₂-weighted, and diffusion-weighted imaging. Whereas these commonly-used approaches yielded heterogeneous images, the new amide proton transfer (APT) technique showed a single well-defined region of hyperintensity that was assigned to brain tumor tissue.

Original language	English (US)
Pages (from-to)	1120-1126
Number of pages	7
Journal	Magnetic resonance in medicine
Volume	50
Issue number	6
DOIs	https://doi.org/10.1002/mrm.10651
State	Published - Dec 2003

Keywords

9L gliosarcoma
Amide proton exchange
Magnetization transfer
Mobile protein
Peptide

ASJC Scopus subject areas

Radiology Nuclear Medicine and imaging

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10.1002/mrm.10651

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title = "Amide Proton Transfer (APT) Contrast for Imaging of Brain Tumors",

abstract = "In this work we demonstrate that specific MR image contrast can be produced in the water signal that reflects endogenous cellular protein and peptide content in intracranial rat 9L gliosarcomas. Although the concentration of these mobile proteins and peptides is only in the millimolar range, a detection sensitivity of several percent on the water signal (molar concentration) was achieved. This was accomplished with detection sensitivity enhancement by selective radiofrequency (RF) labeling of the amide protons, and by utilizing the effective transfer of this label to water via hydrogen exchange. Brain tumors were also assessed by conventional T 1-weighted, T2-weighted, and diffusion-weighted imaging. Whereas these commonly-used approaches yielded heterogeneous images, the new amide proton transfer (APT) technique showed a single well-defined region of hyperintensity that was assigned to brain tumor tissue.",

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AU - Zhou, Jinyuan

AU - Lal, Bachchu

AU - Wilson, David A.

AU - Laterra, John

AU - Van Zijl, Peter C.M.

PY - 2003/12

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N2 - In this work we demonstrate that specific MR image contrast can be produced in the water signal that reflects endogenous cellular protein and peptide content in intracranial rat 9L gliosarcomas. Although the concentration of these mobile proteins and peptides is only in the millimolar range, a detection sensitivity of several percent on the water signal (molar concentration) was achieved. This was accomplished with detection sensitivity enhancement by selective radiofrequency (RF) labeling of the amide protons, and by utilizing the effective transfer of this label to water via hydrogen exchange. Brain tumors were also assessed by conventional T 1-weighted, T2-weighted, and diffusion-weighted imaging. Whereas these commonly-used approaches yielded heterogeneous images, the new amide proton transfer (APT) technique showed a single well-defined region of hyperintensity that was assigned to brain tumor tissue.

AB - In this work we demonstrate that specific MR image contrast can be produced in the water signal that reflects endogenous cellular protein and peptide content in intracranial rat 9L gliosarcomas. Although the concentration of these mobile proteins and peptides is only in the millimolar range, a detection sensitivity of several percent on the water signal (molar concentration) was achieved. This was accomplished with detection sensitivity enhancement by selective radiofrequency (RF) labeling of the amide protons, and by utilizing the effective transfer of this label to water via hydrogen exchange. Brain tumors were also assessed by conventional T 1-weighted, T2-weighted, and diffusion-weighted imaging. Whereas these commonly-used approaches yielded heterogeneous images, the new amide proton transfer (APT) technique showed a single well-defined region of hyperintensity that was assigned to brain tumor tissue.

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KW - Peptide

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Amide Proton Transfer (APT) Contrast for Imaging of Brain Tumors

Abstract

Keywords

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