Book contents
- Frontmatter
- Contents
- Preface
- Acknowledgements
- Section 1 Diaphragm and adjacent structures
- Section 2 Liver
- Section 3 Biliary system
- Section 4 Spleen
- Section 5 Pancreas
- Section 6 Adrenal glands
- Section 7 Kidneys
- Section 8 Retroperitoneum
- Section 9 Gastrointestinal tract
- Section 10 Peritoneal cavity
- Section 11 Ovaries
- Section 12 Uterus and vagina
- Section 13 Bladder
- Section 14 Pelvic soft tissues
- Section 15 Groin
- Section 16 Bone
- Case 97 Postradiation pelvic insufficiency fracture
- Case 98 Iliac pseudotumor due to bone harvesting
- Case 99 Pseudoprogression due to healing of bone metastases by sclerosis
- Case 100 Pseudometastases due to red marrow conversion
- Case 101 Iliac bone defect due to iliopsoas transfer
- Index
- References
Case 100 - Pseudometastases due to red marrow conversion
from Section 16 - Bone
Published online by Cambridge University Press: 05 November 2011
- Frontmatter
- Contents
- Preface
- Acknowledgements
- Section 1 Diaphragm and adjacent structures
- Section 2 Liver
- Section 3 Biliary system
- Section 4 Spleen
- Section 5 Pancreas
- Section 6 Adrenal glands
- Section 7 Kidneys
- Section 8 Retroperitoneum
- Section 9 Gastrointestinal tract
- Section 10 Peritoneal cavity
- Section 11 Ovaries
- Section 12 Uterus and vagina
- Section 13 Bladder
- Section 14 Pelvic soft tissues
- Section 15 Groin
- Section 16 Bone
- Case 97 Postradiation pelvic insufficiency fracture
- Case 98 Iliac pseudotumor due to bone harvesting
- Case 99 Pseudoprogression due to healing of bone metastases by sclerosis
- Case 100 Pseudometastases due to red marrow conversion
- Case 101 Iliac bone defect due to iliopsoas transfer
- Index
- References
Summary
Imaging description
Red bone marrow can become stimulated and metabolically active as a rebound phenomenon after chemotherapy, in response to severe or chronic hemorrhage, or by bone marrow stimulants used in oncology patients (e.g., granulocyte-colony stimulating factor, erythropoietin or interleukin-3) [1–5]. In such settings, bone marrow uptake of 18F-FDG at PET can be markedly increased and simulate diffuse metastatic disease (Figure 100.1).
Importance
An incorrect diagnosis of metastases due to increased FDG uptake at PET by red marrow conversion could lead to unnecessary additional treatment or inappropriate changes in management [4]. Conversely, it is also possible that this appearance could mask true bone metastases [5, 6].
Typical clinical scenario
Increased bone marrow activity at PET has been reported primarily in cancer patients treated with colony stimulating factors.
Differential diagnosis
The main differential consideration for widespread bone marrow uptake of FDG by converted red marrow is diffuse medullary metastases (Figure 100.2). In practice, medullary metastases are usually focal while red marrow conversion is usually diffuse, but this rule is not absolute – medullary metastases are occasionally diffuse [7] and red marrow conversion is occasionally focal [8, 9]. The evolution of these abnormalities over time may allow accurate differentiation. If critical to pending management decisions, biopsy may be required.
- Type
- Chapter
- Information
- Pearls and Pitfalls in Abdominal ImagingPseudotumors, Variants and Other Difficult Diagnoses, pp. 356 - 359Publisher: Cambridge University PressPrint publication year: 2010