<p>The Dixon method is a chemical shift MRI technique that separates fat and water signals to generate four image sets— in-phase, out-of-phase, fat-only, and water-only— from a single acquisition. This approach enhances lesion characterization, improves fat suppression, and identifies materials that produce magnetic susceptibility artifacts, such as gas, iron, blood products, or metal. Despite its diagnostic potential, Dixon imaging is often underutilized due to limited understanding of its physics and clinical applications. This review outlines the fundamental principles and technical considerations of Dixon imaging with an emphasis on its usefulness in abdominal and pelvic MRI interpretation. We highlight the role of in-phase and out-of-phase images in detecting macroscopic and microscopic fat, differentiating lipid-rich from lipid-poor lesions, and identifying hemosiderin or iron deposition. Fat-only images provide a high-contrast survey for ectopic or abnormal fat, useful in the evaluation of hepatic steatosis, adrenal and renal lesions, adnexal masses, and bone marrow pathology. Water-only images offer reliable fat suppression, particularly in the presence of field inhomogeneity or metallic hardware, improving lesion conspicuity compared with traditional techniques. Additionally, Dixon sequences facilitate recognition of susceptibility artifacts from gas, hemorrhage, or surgical materials, further refining diagnostic interpretation. Awareness of clinical and technical parameters which can lead to artifacts that may degrade image quality or mimic pathology is essential to avoid misinterpretation. Integrating Dixon image sets into routine abdominal and pelvic MRI protocols strengthens diagnostic confidence and efficiency by narrowing differential diagnoses and, in many cases, suggesting a specific diagnosis. Understanding the physics behind fat–water separation and incorporating these sequences into the radiologist’s search pattern ensures that the full diagnostic potential of Dixon imaging is realized.</p>

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Shifting perspective: effectively incorporating the dixon method into abdominal and pelvic MRI interpretations

  • Elhamy Heba,
  • Joseph Owen,
  • Michael Nisiewicz,
  • Ronak Patel,
  • James Lee,
  • Andres Ayoob

摘要

The Dixon method is a chemical shift MRI technique that separates fat and water signals to generate four image sets— in-phase, out-of-phase, fat-only, and water-only— from a single acquisition. This approach enhances lesion characterization, improves fat suppression, and identifies materials that produce magnetic susceptibility artifacts, such as gas, iron, blood products, or metal. Despite its diagnostic potential, Dixon imaging is often underutilized due to limited understanding of its physics and clinical applications. This review outlines the fundamental principles and technical considerations of Dixon imaging with an emphasis on its usefulness in abdominal and pelvic MRI interpretation. We highlight the role of in-phase and out-of-phase images in detecting macroscopic and microscopic fat, differentiating lipid-rich from lipid-poor lesions, and identifying hemosiderin or iron deposition. Fat-only images provide a high-contrast survey for ectopic or abnormal fat, useful in the evaluation of hepatic steatosis, adrenal and renal lesions, adnexal masses, and bone marrow pathology. Water-only images offer reliable fat suppression, particularly in the presence of field inhomogeneity or metallic hardware, improving lesion conspicuity compared with traditional techniques. Additionally, Dixon sequences facilitate recognition of susceptibility artifacts from gas, hemorrhage, or surgical materials, further refining diagnostic interpretation. Awareness of clinical and technical parameters which can lead to artifacts that may degrade image quality or mimic pathology is essential to avoid misinterpretation. Integrating Dixon image sets into routine abdominal and pelvic MRI protocols strengthens diagnostic confidence and efficiency by narrowing differential diagnoses and, in many cases, suggesting a specific diagnosis. Understanding the physics behind fat–water separation and incorporating these sequences into the radiologist’s search pattern ensures that the full diagnostic potential of Dixon imaging is realized.