BACKGROUND: 5-Fluorouracil (5-FU) is the most widely used cytotoxic drug in oncology and the only one useful in the management of colorectal cancer - a leading cause of cancer death worldwide. Recent studies of 5-FU have focused on increasing efficacy and reducing toxicity by varying the delivery schedule and combining it with modulators. With the development of whole body magnetic resonance systems it is now possible to examine the metabolism of 5-FU in vivo by exploiting the magnetic properties of the fluorine atom which is an integral component of the drug. PATIENTS AND METHODS: Magnetic Resonance Spectroscopy (MRS) was used to non-invasively monitor the metabolism of 5-FU in the liver metastases of colorectal cancer patients. The patients were treated with a continuous low dose intravenous infusion of 5-FU until the point of refractory disease, at which time interferon-alpha was added with the objective of modulating 5-FU activity. MRS was performed at specific phases of the treatment. RESULTS: Twenty-six patients were treated with 5-FU, 11 (42%) achieving partial response. Of the 15 given interferon when disease became refractory to 5-FU, 4 showed signs of further response. In patients observed by MRS during the first 8 weeks of 5-FU treatment, those with a visible 5-FU signal were likely to respond to treatment (p = 0.017). At the time of interferon-alpha addition, MRS showed that 7 patients developed new or increased 5-FU signals, and 4 patients showed a signal from the active metabolites of 5-FU. The patients who exhibited a new or increased 5-FU signal were more likely to show further response to interferon-alpha (p = 0.007). CONCLUSIONS: MRS is a powerful technique for monitoring intratumoural metabolism and modulation of 5-FU enabling prediction of tumour outcome. Direct metabolic information may facilitate the rapid development of optimal clinical schedules for 5-FU and its modulators, thus maximising antitumour effect and minimising toxicity to the patient. This technique may be applied to other areas of clinical medicine where knowledge of the tissue metabolism of a fluorinated drug is of interest.
BACKGROUND:5-Fluorouracil (5-FU) is the most widely used cytotoxic drug in oncology and the only one useful in the management of colorectal cancer - a leading cause of cancer death worldwide. Recent studies of 5-FU have focused on increasing efficacy and reducing toxicity by varying the delivery schedule and combining it with modulators. With the development of whole body magnetic resonance systems it is now possible to examine the metabolism of 5-FU in vivo by exploiting the magnetic properties of the fluorine atom which is an integral component of the drug. PATIENTS AND METHODS: Magnetic Resonance Spectroscopy (MRS) was used to non-invasively monitor the metabolism of 5-FU in the liver metastases of colorectal cancerpatients. The patients were treated with a continuous low dose intravenous infusion of 5-FU until the point of refractory disease, at which time interferon-alpha was added with the objective of modulating 5-FU activity. MRS was performed at specific phases of the treatment. RESULTS: Twenty-six patients were treated with 5-FU, 11 (42%) achieving partial response. Of the 15 given interferon when disease became refractory to 5-FU, 4 showed signs of further response. In patients observed by MRS during the first 8 weeks of 5-FU treatment, those with a visible 5-FU signal were likely to respond to treatment (p = 0.017). At the time of interferon-alpha addition, MRS showed that 7 patients developed new or increased 5-FU signals, and 4 patients showed a signal from the active metabolites of 5-FU. The patients who exhibited a new or increased 5-FU signal were more likely to show further response to interferon-alpha (p = 0.007). CONCLUSIONS: MRS is a powerful technique for monitoring intratumoural metabolism and modulation of 5-FU enabling prediction of tumour outcome. Direct metabolic information may facilitate the rapid development of optimal clinical schedules for 5-FU and its modulators, thus maximising antitumour effect and minimising toxicity to the patient. This technique may be applied to other areas of clinical medicine where knowledge of the tissue metabolism of a fluorinated drug is of interest.
Authors: Geoffrey S Payne; David J Collins; Peter Loynds; Graham Mould; Philip S Murphy; Andrzej S K Dzik-Jurasz; Preminda Kessar; Nazneen Haque; Masayuki Yamaguchi; Shogo Atarashi; Martin O Leach Journal: Br J Clin Pharmacol Date: 2005-02 Impact factor: 4.335
Authors: L D Stegman; A Rehemtulla; B Beattie; E Kievit; T S Lawrence; R G Blasberg; J G Tjuvajev; B D Ross Journal: Proc Natl Acad Sci U S A Date: 1999-08-17 Impact factor: 11.205
Authors: Cary A Presant; Joth Jacobson; Walter Wolf; Victor Waluch; Ilene C Weitz; John S Macdonald Journal: Invest New Drugs Date: 2002-11 Impact factor: 3.850
Authors: A S Ojugo; P M McSheehy; M Stubbs; G Alder; C L Bashford; R J Maxwell; M O Leach; I R Judson; J R Griffiths Journal: Br J Cancer Date: 1998-03 Impact factor: 7.640
Authors: T Dresselaers; J Theys; S Nuyts; B Wouters; E de Bruijn; J Anné; P Lambin; P Van Hecke; W Landuyt Journal: Br J Cancer Date: 2003-11-03 Impact factor: 7.640