Kinetic analysis of 2-[11C]thymidine PET imaging studies of malignant brain tumors: Preliminary patient results

Joanne M. Wells, David A. Mankoff, Janet F. Eary, Alexander M. Spence, Mark Muzi, Finbarr O'Sullivan, Cheryl B. Vernon, Jeanne M. Link, Kenneth A. Krohn

Research output: Contribution to journalArticle

33 Scopus citations

Abstract

2-[11C]Thymidine (TdR), a PET tracer for cellular proliferation, may be advantageous for monitoring brain tumor progression and response to therapy. Kinetic analysis of dynamic TdR images was performed to estimate the rate of thymidine transport (K1t) and thymidine flux (K TdR) into brain tumors and normal brain. These estimates were compared to MRI and pathologic results. Methods: Twenty patients underwent sequential [11C]CO2 (major TdR metabolite) and TdR PET studies with arterial blood sampling and metabolite analysis. The data were fitted using the five-compartment model described in the companion article. Results: Comparison of model estimates with clinical and pathologic data shows that K1t is higher for MRI contrast enhancing tumors (p < .001), and KTdR increases with tumor grade (p < .02). On average, TdR retention was lower after treatment in high-grade tumors. The model was able to distinguish between increased thymidine transport due to blood-brain barrier breakdown and increased tracer retention associated with tumor cell proliferation. Conclusion: Initial analysis of model estimates of thymidine retention and transport show good agreement with the clinical and pathological features of a wide range of brain tumors. Ongoing studies will evaluate its role in measuring response to treatment and predicting outcome.

Original languageEnglish (US)
Pages (from-to)145-150
Number of pages6
JournalMolecular Imaging
Volume1
Issue number3
DOIs
StatePublished - Jul 2002

Keywords

  • Brain tumors
  • Kinetic modeling
  • PET
  • Proliferation
  • [C]Thymidine

ASJC Scopus subject areas

  • Biotechnology
  • Molecular Medicine
  • Biomedical Engineering
  • Radiology Nuclear Medicine and imaging
  • Condensed Matter Physics

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