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Detection and Grading of Soft Tissue Sarcomas of the Extremities with ¹⁸F-3'-Fluoro-3'-Deoxy-L-Thymidine

¹ Positron Emission Tomography-center,
² Departments of Surgical Oncology and
³ Pathology and Laboratory Medicine, Groningen University Hospital, Groningen, the Netherlands

	ABSTRACT

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Purpose: The aim of the study was to investigate the feasibility of ¹⁸F-3'-fluoro-3'-deoxy-L-thymidine positron emission tomography (FLT-PET) for the detection and grading of soft tissue sarcoma (STS).

Experimental Design: Nineteen patients with 20 STSs of the extremities were scanned, using attenuation corrected whole-body FLT-PET. Standardized uptake values (SUVs) and tumor:nontumor ratios (TNTs) were compared with histopathological parameters using French and Japanese grading systems.

Results: Mean SUV, maximal SUV, and TNT could differentiate between low-grade (grade 1; n = 6) STS and high-grade (grade 2 and 3; n = 14) STS according to the French grading system (P = 0.001). Mean SUV, max SUV, and TNT correlated with mitotic score, MIB-1 score, the French and Japanese grading system (• = 0.550–0.747).

Conclusions: FLT-PET is able to visualize STS and differentiate between low-grade and high-grade STS. The uptake of FLT correlates with the proliferation of STS.

	INTRODUCTION

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Soft-tissue sarcomas (STS) form a heterogeneous group of rare malignancies, which arise from mesenchymal soft tissues and account for 1% of all cancers. In the United States, 8300 new cases are diagnosed each year and in the Netherlands, about 400 (1 , 2) . At first presentation, 13% of the patients with STS have metastases. The lung is the most common metastatic site, followed by bone, liver, and brain. Less common sites are regional lymph nodes, retroperitoneum, and soft tissues (3 , 4) . After treatment of the primary tumor, 40% of the patients will develop recurrences either locally or distantly.

The presence or absence of metastases and the malignancy grade of the tumor will dictate the treatment. Grading is frequently performed according to the French grading system (5) . In this grading system, points are scored for histological grade, tumor differentiation and amount of necrosis, and number of mitotic figures. Recently, a Japanese grading system, using the MIB-1 score instead of the mitotic score, has been introduced and correlates stronger with the prognosis than the French grading system (6 , 7) .

Optimal management of STS depends on the anatomical site, local growth pattern, tumor size and grade, and accurate staging of the disease, when first diagnosed. The site, growth pattern, and size of the primary tumor are best determined by magnetic resonance imaging or spiral computed tomography (CT). However, the clinical and radiological differentiation between benign soft tissue masses and STSs is difficult (8) . Information regarding distant metastases is obtained primarily by chest radiography or a CT scan of the lungs, whereas bone-scintigraphy is of limited value (8 , 9) . Distant metastases to the lungs are ruled out by CT. Physical examination, CT, magnetic resonance imaging, or ultrasonography are best used for the detection of local recurrences. However, after surgery and radiation therapy, physical examination and interpretation of the diagnostic images remains difficult (8) .

Therefore, the need for noninvasive detection, staging, and grading of a soft tissue tumor mass has increased. During the last decade, the value of positron emission tomography (PET) in STS with several tracers, especially [¹⁸F]fluoro-2'-deoxy-D-glucose (FDG), has been investigated (10, 11, 12, 13, 14, 15, 16) . However, the current potential of FDG-PET in the detection and/or grading is still unknown (10 , 11 , 15 , 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32) .

Several years ago ¹⁸F-3'-fluoro-3'-deoxy-L-thymidine (FLT) was introduced as PET tracer (33) . This tracer has theoretical advantages over the currently used FDG, because no uptake in inflammatory cells is anticipated. The aim of this study was to investigate the feasibility of FLT-PET for the detection and grading of STS.

	PATIENTS AND METHODS

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This prospective study, approved by Medical Ethics Committee of the Groningen University Hospital, consisted of 19 consecutive patients with a STS of the extremity. All of the patients were treated at the Groningen University Hospital and gave written informed consent. For inclusion, the liver and kidney functions and hematological parameters (hemaglobin, hematocrit, erythrocytes, thrombocytes, leukocytes, and WBC count) should be within normal limits. Pregnant patients or patients with psychiatric disorders were excluded from the study.

Synthesis of FLT was performed according to the method of Machulla et al. (34) FLT was produced by fluorination with [¹⁸F]fluoride of the 4,4'-dimethoxytrityl-protected anhydrothymidine, followed by a deprotection step and purification by high-performance liquid chromatography. FLT was produced with a radiochemical purity of >95% and specific activity of >10 TBq/mmol. The radiochemical yield was 5.6 ± 2.8% (decay corrected).

Nineteen patients were examined in the period of February 2002 until July 2003, using an ECAT EXACT HR+ (Siemens/CTI Inc., Knoxville, TN). Before PET imaging, patients were instructed to fast for at least 6 h to keep the study comparable with studies performed with FDG (35) . They were also instructed to drink one liter of water before imaging to stimulate FLT excretion from the renal calyces and to stimulate subsequent voiding. For injection of FLT, a venous cannula was inserted in the forearm of the patient.

Patients received a median of 400 (115–430) MBq FLT. Sixty min after injection, the region of the tumor was imaged in emission-transmission-transmission-emission mode. After scanning the tumor region, a non-attenuation-corrected whole-body scan was performed from crown to femur for 5 min per bed position. Data from multiple bed positions were iteratively reconstructed (ordered subset expectation maximization; 36 ).

Histological typing of the tumors of all patients was performed on H&E-stained sections according to the WHO classification (37) . Immunophenotype was determined in poorly differentiated tumors. Tumors were graded using both the French and Japanese grading system (5, 6, 7) .

The number of mitotic figures was counted per 2 mm² in H&E-stained slides, after selecting the most cellular areas with the highest mitotic rate. Proliferating cells were detected with immunohistochemistry, using monoclonal antibody MIB-1 and antigen retrieval, as described previously (12) . Monoclonal antibody MIB-1 recognizes the protein Ki-67 in all phases of the cell cycle with the exception of G₀.

The MIB-1 score was estimated by counting the percentage of MIB-1-positive cell nuclei per 1000 tumor cells in the region of the tumor with the greatest density of staining, which in most instances corresponds to areas with the highest mitotic activity.

Data Analysis
ROI.
Qualitative and quantitative evaluation of the PET scans was performed by analyzing the hypermetabolic zones on transaxial sections. The slice with the highest uptake was selected for region of interest (ROI) analysis.

SUV.
After selecting the plane with the maximum standardized uptake value (SUV), a ROI was drawn manually. ROIs were placed at the 70% contour of the maximal SUV in the tumor. The same ROI was applied in the contralateral leg or arm. The mean SUV of the tumor was divided by SUV of the background region to produce the tumor:nontumor ratio (TNT). In patients 3 and 13, it was not possible to let the ROI-tool calculate a mean SUV from 70% of the maximal SUV in the nontumor region, because the calculated ROI was below the background uptake of FLT (Table 1) . Therefore, the highest mean of the manually drawn ROI with the highest SUV was used. TNTs and SUVs were compared with histopathological parameters.

Whole Body Images.
Whole body images were scored for presence/absence of lesions outside the location of the primary tumor, blinded for other clinical information. Lesions were interpreted visually as malignant, if the FLT uptake in the lesion was higher than the surrounding tissue.

Statistical Analysis
Kruskall-Wallis nonparametric testing was used to see whether the groups, as defined by the French or Japanese grading system, differed. Dunnett’s T3 post hoc multiple comparisons test was performed for variance analysis between the different groups, as defined by the French or Japanese grading system, for mean SUV, maximal SUV, and TNT. Mann-Whitney testing was used to compare the mean SUV, maximal SUV, and TNT between the French or Japanese grading system. Spearman’s correlation coefficient was used to correlate mean SUV, maximal SUV, and TNT, with mitotic score, MIB-1 score, and the French or Japanese grading system. Two-tailed Ps <0.05 were considered significant.

	RESULTS

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Patients.
Nineteen patients with a median age of 58 (range, 27–75) years, 7 women and 12 men, were included in this study (Table 1) . Eighteen patients had one STS, and one patient had two STSs. Patient characteristics are presented in Table 1 . Eighteen patients had a biopsy before the FLT-PET, and one patient had a FLT-PET before the biopsy. A total of 17 incision biopsies and 2 true-cut biopsies were performed.

Primary Tumors.
Twenty tumors in a total of 19 patients were clearly visible with high contrast and were interpreted as malignant. Fig. 1 is an example of a FLT-PET whole body image (patient 16). The sensitivity for detecting malignant lesions was 100%. The Kruskal-Wallis variance analysis showed significant different variance in mean SUV, maximal SUV, and TNT between the groups, defined by the French or Japanese grading system.

View larger version (37K): [in this window] [in a new window]   Fig. 1. The whole body 18F-3'-fluoro-3'-deoxy-L-thymidine-positron emission tomography (FLT-PET) image of patient 16. Small arrows, physiological uptake of FLT can be seen in the bone marrow of the pelvis, ribs, and vertebrae; in the bones of the shoulder; in the liver; and in the bladder. Large arrows, the soft tissue sarcoma can be seen in the left upper leg and a lung metastasis in the mediastinum.

View larger version (50K): [in this window] [in a new window]   Fig. 2. A, the magnetic resonance imaging (MRI; A1) and 3'-[18F]fluoro-3'-deoxy-L-thymidine-positron emission tomography (FLT-PET; A2) images of a low-grade soft tissue sarcoma (STS; patient 6); B, the MRI (B1) and FLT-PET (B2) images of a high-grade STS (patient 13). The MRI images of both patients demonstrate a heterogeneous tumor. However, the FLT uptake in the high-grade STS is higher than in the low-grade STS.

View this table: [in this window] [in a new window]   Table 4 Spearman’s correlations () between grade, mean standardized uptake value (SUV), tumor:nontumor ratio (TNT), mitotic score and MIB-1 score

In three patients, the lesions seen on FLT-PET were not malignant according to pathological examination or follow-up. In patient 10, the lesions on FLT-PET in the groin and supraclavicular region were negative on physical examination and follow-up. In patient 13, the lesion on FLT-PET in the groin was histologically negative after lymph node dissection. In patient 14, the lesions on FLT-PET in the groin were indicated as lymph nodes with follicular hyperplasia after lymph node dissection.

In one patient, a metastatic lymph node was missed on FLT-PET. In patient 7, an axillary lymph node dissection was performed. In the lymph node dissection, one lymph node contained two metastases, both with a diameter of 5 mm, with 11 mitotic figures per 2 mm². This metastatic lymph node was not detected on whole-body FLT-PET.

	DISCUSSION

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The results of this study revealed that FLT-PET is able to visualize STS and recurrent STS and has the clinical potential to distinguish between low- (grade 1) and high-grade (grade 2 and 3) STS.

FLT uptake appeared to be related to proliferation and tumor grade. Mean SUV, maximal SUV, and TNT correlated with mitotic score, MIB-1 score, and the French and Japanese grading of STS. No difference between the French and Japanese grading systems was found, based on the correlations.

In the French grading system of STS, all three parameters (level of histological differentiation, amount of necrosis, and mitotic index) are independent predictors of metastasis (38) . It has been demonstrated that, when using the MIB-1 score instead of the mitotic score in the French grading system, the grading of STS improved. This modified Japanese grading system proved to be the most significant predictor of overall survival (6 , 7) . Therefore, a PET-tracer that would reflect proliferation, could have the potential to visualize the grading of STS. For this purpose, ¹⁸F-fluoro-3'-deoxy-3'-L-fluorothymidine (FLT) was developed (33 , 39) . This pyrimidine analog is phosphorylated by the enzyme thymidine kinase 1, which leads to intracellular trapping (33) . During DNA synthesis, thymidine kinase 1 concentration increases almost 10-fold and is, therefore, an accurate reflection of cellular proliferation (40) .

Most previous studies for detecting sarcomas have been performed with ¹⁸F-fluoro-2'-deoxy-D-glucose-PET (FDG-PET) and have recently been critically reviewed in two meta-analyses (31 , 32) . The sensitivity of FDG-PET for detecting primary and recurrent sarcomas varies from 88 to 92%, and specificity varies form 73 to 87% (31 , 32) . FDG-PET can be useful in tumor grading but is, with the exception of a study of Eary et al., (17) not able to differentiate between benign lesions and low-grade sarcoma (16 , 17 , 31 , 32) . The accuracy for the differentiation is influenced by technical limitations, time between injection and scanning, and false negative and false positive findings (18 , 21 , 22 , 26 , 29) . The SUV for FDG-PET for low-grade (grade 1) STS varied between 1.6 and 2.6, as compared with 0.2 and 1.5 for FLT-PET; the SUV for FDG-PET for high-grade STS (grade 2 and 3) varied between 8.0 and 9.4 as compared with 0.8 and 4.9 for FLT-PET (23 , 29) . Despite the lower sensitivity of FDG-PET than FLT-PET, the uptake of FDG was higher than of FLT. In a comparative study with FLT-PET, the correlation between FDG SUV and the proliferation of the STS should be investigated.

In conclusion, FLT-PET is able to visualize and differentiate high-grade from low-grade STS. The uptake of FLT correlates with the proliferation of STSs.

	ACKNOWLEDGMENTS

 
The radiodiagnostic images were kindly provided by Alphons H. H. Bongaerts, radiologist at the Department of Radiology, Groningen University Hospital, Groningen, the Netherlands.

	FOOTNOTES

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Requests for reprints: David C. P. Cobben, Positron Emission Tomography-center, Groningen University Hospital, P. O. Box 30.001, Groningen, the Netherlands. Phone: 31-50-3614815; Fax: 31-50-3611687; E-mail: D.C.P.Cobben{at}pet.azg.nl

Received 8/14/03; revised 11/ 4/03; accepted 11/26/03.

	REFERENCES

Top ABSTRACT INTRODUCTION PATIENTS AND METHODS RESULTS DISCUSSION REFERENCES

 

1. Jemal A., Murray T., Samuels A., Ghafoor A., Ward E., Thun M. J. Cancer statistics, 2003. CA Cancer J. Clin., 53: 5-26, 2003.[Abstract/Free Full Text]
2. Visser O., Coebergh J. W. W., van Dijck J. A. A. M., Siesling S. . Incidence of Cancer in the Netherlands 1998, Vereniging van Integrale Kankercentra Utrecht, the Netherlands 2002.
3. Gustafson P. Soft tissue sarcoma. Epidemiology and prognosis in 508 patients. Acta Orthop. Scand. Suppl., 259: 1-31, 1994.[Medline]
4. Nijhuis P. H., Schaapveld M., Otter R., Molenaar W. M., van der Graaf W. T., Hoekstra H. J. Epidemiological aspects of soft tissue sarcomas (STS)—consequences for the design of clinical STS trials. Eur. J. Cancer, 35: 1705-1710, 1999.
5. Guillou L., Coindre J. M., Bonichon F., Nguyen B. B., Terrier P., Collin F., Vilain M. O., Mandard A. M., Le Doussal V., Leroux A., Jacquemier J., Duplay H., Sastre-Garau X., Costa J. Comparative study of the National Cancer Institute and French Federation of Cancer Centers Sarcoma Group grading systems in a population of 410 adult patients with soft tissue sarcoma. J. Clin. Oncol., 15: 350-362, 1997.[Abstract/Free Full Text]
6. Hasegawa T., Yamamoto S., Nojima T., Hirose T., Nikaido T., Yamashiro K., Matsuno Y. Validity and reproducibility of histologic diagnosis and grading for adult soft-tissue sarcomas. Hum. Pathol., 33: 111-115, 2002.[CrossRef][Medline]
7. Hasegawa T., Yokoyama R., Lee Y. H., Shimoda T., Beppu Y., Hirohashi S. Prognostic relevance of a histological grading system using MIB-1 for adult soft-tissue sarcoma. Oncology, 58: 66-74, 2000.[CrossRef][Medline]
8. Ham S. J., van der Graaf W. T., Pras E., Molenaar W. M., van den B. E., Hoekstra H. J. Soft tissue sarcoma of the extremities. A multimodality diagnostic and therapeutic approach. Cancer Treat. Rev., 24: 373-391, 1998.[CrossRef][Medline]
9. Jager P. L., Hoekstra H. J., Leeuw J., Der Graaf W. T., de Vries E. G., Piers D. A. Routine bone scintigraphy in primary staging of soft tissue sarcoma; is it worthwhile?. Cancer (Phila.), 89: 1726-1731, 2000.[CrossRef]
10. van Ginkel R. J., Hoekstra H. J., Pruim J., Nieweg O. E., Molenaar W. M., Paans A. M., Willemsen A. T., Vaalburg W., Koops H. S. FDG-PET to evaluate response to hyperthermic isolated limb perfusion for locally advanced soft-tissue sarcoma. J. Nucl. Med., 37: 984-990, 1996.[Abstract/Free Full Text]
11. Kole A. C., Nieweg O. E., van Ginkel R. J., Pruim J., Hoekstra H. J., Paans A. M., Vaalburg W., Koops H. S. Detection of local recurrence of soft-tissue sarcoma with positron emission tomography using [¹⁸F]fluorodeoxyglucose. Ann. Surg. Oncol., 4: 57-63, 1997.[Abstract]
12. Plaat B., Kole A., Mastik M., Hoekstra H., Molenaar W., Vaalburg W. Protein synthesis rate measured with L-[1–11C]tyrosine positron emission tomography correlates with mitotic activity and MIB-1 antibody-detected proliferation in human soft tissue sarcomas. Eur. J. Nucl. Med., 26: 328-332, 1999.[CrossRef][Medline]
13. Kole A. C., Plaat B. E., Hoekstra H. J., Vaalburg W., Molenaar W. M. FDG and L-[1–11C]-tyrosine imaging of soft-tissue tumors before and after therapy. J. Nucl. Med., 40: 381-386, 1999.[Abstract/Free Full Text]
14. van Ginkel R. J., Kole A. C., Nieweg O. E., Molenaar W. M., Pruim J., Koops H. S., Vaalburg W., Hoekstra H. J. L-[1–11C]-tyrosine PET to evaluate response to hyperthermic isolated limb perfusion for locally advanced soft-tissue sarcoma and skin cancer. J. Nucl. Med., 40: 262-267, 1999.[Abstract/Free Full Text]
15. Schwarzbach M., Willeke F., Dimitrakopoulou-Strauss A., Strauss L. G., Zhang Y. M., Mechtersheimer G., Hinz U., Lehnert T., Herfarth C. Functional imaging and detection of local recurrence in soft tissue sarcomas by positron emission tomography. Anticancer Res., 19: 1343-1349, 1999.[Medline]
16. Reske S. N., Kotzerke J. FDG-PET for clinical use. Results of the 3rd German Interdisciplinary Consensus Conference, "Onko-PET III," 21 July and 19 September 2000. Eur. J. Nucl. Med., 28: 1707-1723, 2001.[CrossRef][Medline]
17. Eary J. F., Conrad E. U., Bruckner J. D., Folpe A., Hunt K. J., Mankoff D. A., Howlett A. T. Quantitative [F-18]fluorodeoxyglucose positron emission tomography in pretreatment and grading of sarcoma. Clin. Cancer Res., 4: 1215-1220, 1998.[Abstract]
18. Schulte M., Brecht-Krauss D., Heymer B., Guhlmann A., Hartwig E., Sarkar M. R., Diederichs C. G., Schultheiss M., Kotzerke J., Reske S. N. Fluorodeoxyglucose positron emission tomography of soft tissue tumours: is a non-invasive determination of biological activity possible?. Eur. J. Nucl. Med., 26: 599-605, 1999.[CrossRef][Medline]
19. Schwarzbach M. H., Dimitrakopoulou-Strauss A., Willeke F., Hinz U., Strauss L. G., Zhang Y. M., Mechtersheimer G., Attigah N., Lehnert T., Herfarth C. Clinical value of [18-F]] fluorodeoxyglucose positron emission tomography imaging in soft tissue sarcomas. Ann. Surg., 231: 380-386, 2000.[CrossRef][Medline]
20. Garcia R., Kim E. E., Wong F. C., Korkmaz M., Wong W. H., Yang D. J., Podoloff D. A. Comparison of fluorine-18-FDG PET and technetium-99m-MIBI SPECT in evaluation of musculoskeletal sarcomas. J. Nucl. Med., 37: 1476-1479, 1996.[Abstract/Free Full Text]
21. Nieweg O. E., Pruim J., van Ginkel R. J., Hoekstra H. J., Paans A. M., Molenaar W. M., Schraffordt Koops H. S., Vaalburg W. Fluorine-18-fluorodeoxyglucose PET imaging of soft-tissue sarcoma. J. Nucl. Med., 37: 257-261, 1996.[Abstract/Free Full Text]
22. Dimitrakopoulou-Strauss A., Strauss L. G., Schwarzbach M., Burger C., Heichel T., Willeke F., Mechtersheimer G., Lehnert T. Dynamic PET 18F-FDG studies in patients with primary and recurrent soft-tissue sarcomas: impact on diagnosis and correlation with grading. J. Nucl. Med., 42: 713-720, 2001.[Abstract/Free Full Text]
23. Lodge M. A., Lucas J. D., Marsden P. K., Cronin B. F., O’Doherty M. J., Smith M. A. A PET study of 18FDG uptake in soft tissue masses. Eur. J. Nucl. Med., 26: 22-30, 1999.[CrossRef][Medline]
24. Schwarzbach M. H., Dimitrakopoulou-Strauss A., Mechtersheimer G., Hinz U., Willeke F., Cardona S., Attigah N., Strauss L. G., Herfarth C., Lehnert T. Assessment of soft tissue lesions suspicious for liposarcoma by F18-deoxyglucose (FDG) positron emission tomography (PET). Anticancer Res., 21: 3609-3614, 2001.[Medline]
25. Folpe A. L., Lyles R. H., Sprouse J. T., Conrad E. U., III, Eary J. F. (F-18) fluorodeoxyglucose positron emission tomography as a predictor of pathologic grade and other prognostic variables in bone and soft tissue sarcoma. Clin. Cancer Res., 6: 1279-1287, 2000.[Abstract/Free Full Text]
26. Lucas J. D., O’Doherty M. J., Wong J. C., Bingham J. B., McKee P. H., Fletcher C. D., Smith M. A. Evaluation of fluorodeoxyglucose positron emission tomography in the management of soft-tissue sarcomas. J. Bone Jt. Surg. Br., 80: 441-447, 1998.
27. Delbeke D., Martin W. H., Sandler M. P., Chapman W. C., Wright J. K., Jr., Pinson C. W. Evaluation of benign versus malignant hepatic lesions with positron emission tomography. Arch. Surg., 133: 510-515, 1998.[Abstract/Free Full Text]
28. Watanabe H., Shinozaki T., Yanagawa T., Aoki J., Tokunaga M., Inoue T., Endo K., Mohara S., Sano K., Takagishi K. Glucose metabolic analysis of musculoskeletal tumours using 18-fluorine-FDG PET as an aid to preoperative planning. J. Bone Jt. Surg. Br., 82: 760-767, 2000.
29. Lucas J. D., O’Doherty M. J., Cronin B. F., Marsden P. K., Lodge M. A., McKee P. H., Smith M. A. Prospective evaluation of soft tissue masses and sarcomas using fluorodeoxyglucose positron emission tomography. Br. J. Surg., 86: 550-556, 1999.[CrossRef][Medline]
30. Haberkorn U. The role of diagnostic PET in treatment planning before tumor surgery (German). Chirurg, 72: 1010-1019, 2001.[CrossRef][Medline]
31. Ioannidis J. P., Lau J. 18F-FDG PET for the diagnosis and grading of soft-tissue sarcoma: a meta-analysis. J. Nucl. Med., 44: 717-724, 2003.[Abstract/Free Full Text]
32. Bastiaannet E., Groen H., Jager P. L., Cobben D. C. P., van der Graaf W. T. A., Vaalburg W., Hoekstra H. J. The value of FDG-PET in the detection, grading and response to therapy of soft tissue and bone sarcomas; a systematic review and meta-analysis. Cancer Treat. Rev., 1: 83-101, 2004.
33. Shields A. F., Grierson J. R., Dohmen B. M., Machulla H. J., Stayanoff J. C., Lawhorn-Crews J. M., Obradovich J. E., Muzik O., Mangner T. J. Imaging proliferation in vivo with [F-18]FLT and positron emission tomography. Nat. Med., 4: 1334-1336, 1998.[CrossRef][Medline]
34. Machulla H. J., Blochter A., Kuntzsch M., Piert M., Wei R., Grierson J. R. Simplified labeling approach for synthesizing 3'-deoxy-3'-[¹⁸F]fluorothymidine ([¹⁸F]FLT). J. Radiochem. Nucl. Chemistry, 243: 843-846, 2000.[CrossRef]
35. Schelbert H. R., Hoh C. K., Royal H. D., Brown M., Dahlbom M. N., Dehdashti F., Wahl R. L. Procedure guideline for tumor imaging using fluorine-18-FDG. J. Nucl. Med., 39: 1302-1305, 1998.[Free Full Text]
36. Lonneux M., Borbath I., Bol A., Coppens A., Sibomana M., Bausart R., Defrise M., Pauwels S., Michel C. Attenuation correction in whole-body FDG oncological studies: the role of statistical reconstruction. Eur. J. Nucl. Med., 26: 591-598, 1999.[CrossRef][Medline]
37. Fletcher C. D. M., Unni K., Mertens F. . WHO Classification of Tumours. Pathology and Genetics of Tumours of Soft Tissue and Bone, IARC Press Lyon 2002.
38. Coindre J. M., Terrier P., Guillou L., Le Doussal V., Collin F., Ranchere D., Sastre X., Vilain M. O., Bonichon F., N'Guyen B. B. Predictive value of grade for metastasis development in the main histologic types of adult soft tissue sarcomas: a study of 1240 patients from the French Federation of Cancer Centers Sarcoma Group. Cancer (Phila.), 91: 1914-1926, 2001.
39. Mier W., Haberkorn U., Eisenhut M. [¹⁸F]FLT; portrait of a proliferation marker. Eur. J. Nucl. Med., 29: 165-169, 2002.
40. Sherley J. L., Kelly T. J. Regulation of human thymidine kinase during the cell cycle. J. Biol. Chem., 263: 8350-8358, 1988.[Abstract/Free Full Text]

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				G. J. Kelloff, J. M. Hoffman, B. Johnson, H. I. Scher, B. A. Siegel, E. Y. Cheng, B. D. Cheson, J. O'Shaughnessy, K. Z. Guyton, D. A. Mankoff, et al. Progress and Promise of FDG-PET Imaging for Cancer Patient Management and Oncologic Drug Development Clin. Cancer Res., April 15, 2005; 11(8): 2785 - 2808. [Abstract] [Full Text] [PDF]

				H. L. van Westreenen, D. C.P. Cobben, P. L. Jager, H. M. van Dullemen, J. Wesseling, P. H. Elsinga, and J. Th. Plukker Comparison of 18F-FLT PET and 18F-FDG PET in Esophageal Cancer J. Nucl. Med., March 1, 2005; 46(3): 400 - 404. [Abstract] [Full Text] [PDF]

				C. Waldherr, I. K. Mellinghoff, C. Tran, B. S. Halpern, N. Rozengurt, A. Safaei, W. A. Weber, D. Stout, N. Satyamurthy, J. Barrio, et al. Monitoring Antiproliferative Responses to Kinase Inhibitor Therapy in Mice with 3'-Deoxy-3'-18F-Fluorothymidine PET J. Nucl. Med., January 1, 2005; 46(1): 114 - 120. [Abstract] [Full Text] [PDF]

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