Comparison of integrin alphaVbeta3 expression and glucose metabolism in primary and metastatic lesions in cancer patients: a PET study using 18F-galacto-RGD and 18F-FDG.

The expression of alpha(v)beta(3) and glucose metabolism are upregulated in many malignant lesions, and both are known to correlate with an aggressive phenotype. We evaluated whether assessment of alpha(v)beta(3) expression and of glucose metabolism with PET using (18)F-galacto-RGD and (18)F-FDG provides complementary information in cancer patients. METHODS: Eighteen patients with primary or metastatic cancer (non-small cell lung cancer [NSCLC], n = 10; renal cell carcinoma, n = 2; rectal cancer, n = 2; others, n = 4) were examined with PET using (18)F-galacto-RGD and (18)F-FDG. Standardized uptake values (SUVs) were derived by volume-of-interest analysis. (18)F-Galacto-RGD and (18)F-FDG PET results were compared using linear regression analysis for all lesions (n = 59; NSCLC, n = 39) and for primaries (n = 14) and metastases to bone (n = 11), liver (n = 10), and other organs (n = 24) separately. RESULTS: The sensitivity of (18)F-galacto-RGD PET compared with clinical staging was 76%. SUVs for (18)F-FDG ranged from 1.3 to 23.2 (mean +/- SD, 7.6 +/- 4.9) and were significantly higher than SUVs for (18)F-galacto-RGD (range, 0.3-6.8; mean +/- SD, 2.7 +/- 1.5; P < 0.001). There was no significant correlation between the SUVs for (18)F-FDG and (18)F-galacto-RGD for all lesions (r = 0.157; P = 0.235) or for primaries, osseous or soft-tissue metastases separately (P > 0.05). For the subgroup of lesions in NSCLC, there was a weak correlation between (18)F-FDG and (18)F-galacto-RGD uptake (r = 0.353; P = 0.028). CONCLUSION: Tracer uptake of (18)F-galacto-RGD and (18)F-FDG does not correlate closely in malignant lesions. Whereas (18)F-FDG PET is more sensitive for tumor staging, (18)F-galacto-RGD PET warrants further evaluation for planning and response evaluation of targeted molecular therapies with antiangiogenic or alpha(v)beta(3)-targeted drugs.     

Imaging of delayed-type hypersensitivity reaction by PET and 18F-galacto-RGD.

Radiolabeled cyclic peptides containing the amino acid sequence arginine-glycine-aspartate (RGD peptides) have successfully been used to image the expression of the alpha(v)beta(3) integrin in malignant tumors. However, the alpha(v)beta(3) integrin also plays an important role in angiogenesis induced by chronic inflammatory processes. Therefore, the aim of this study was to evaluate whether radiolabeled RGD peptides may also be used to assess alpha(v)beta(3) expression in inflammatory diseases. We studied a hapten-induced delayed-type hypersensitivity reaction (DTHR) as a model for inflammatory processes, since DTHRs are involved in many human autoimmune disorders. METHODS: The abdominal skin of mice was sensitized by application of 2,4,6-trinitrochlorobenzene (TNCB). One week later, a DTHR was elicited by challenging the right ear with TNCB. Application of TNCB was then repeated every 48 h to induce chronic skin inflammation. Small-animal PET and autoradiography with the alpha(v)beta(3) ligands (18)F-galacto-RGD and (125)I-gluco-RGD were performed at various times after TNCB application. The time course of tracer uptake by the treated ears was compared with histologic skin changes. RESULTS: The first challenge with TNCB caused, within 12 h, an acute inflammatory response with dense dermal infiltrates of polymorphonuclear leukocytes and lymphocytes. However, autoradiography revealed no significant increase in (125)I-gluco-RGD uptake at that time (mean uptake ratio for treated ear to untreated ear, 1.02 +/- 0.1 [SD]). Further challenges with TNCB resulted in chronic skin inflammation with markedly increased small-vessel density in the ear tissue. This was paralleled by a continuous increase in uptake of (125)I-gluco-RGD. After 13 challenges, the uptake ratio had increased to 2.30 +/- 0.27 (P < 0.005 compared with baseline). Enhanced uptake of radiolabeled RGD peptides in chronic inflammation was also demonstrated noninvasively by PET with (18)F-galacto-RGD. Pretreatment of the mice with nonradiolabeled cyclic peptide c(RGDfV) almost completely blocked uptake of (18)F-galacto-RGD by the challenged ear, thus confirming the specificity of tracer uptake. CONCLUSION: Radiolabeled RGD peptides allow a noninvasive assessment of alpha(v)beta(3) expression in inflammatory processes. PET with (18)F-galacto-RGD might become a powerful tool to distinguish between the acute and chronic phases of T cell-mediated immune responses and may represent a new biomarker for disease activity in autoimmune disorders.     

Patterns of alphavbeta3 expression in primary and metastatic human breast cancer as shown by 18F-Galacto-RGD PET.

The integrin alpha(v)beta(3) is a key player in angiogenesis and metastasis. Our aim was to study the uptake patterns of the alpha(v)beta(3)-selective PET tracer (18)F-galacto-RGD in invasive ductal breast cancer. METHODS: Sixteen patients with primary (n = 12) or metastasized breast cancer (n = 4) were examined with (18)F-galacto-RGD PET. Standardized uptake values (SUVs) were derived by region-of-interest analysis, and immunohistochemistry of alpha(v)beta(3) expression was performed (n = 5). RESULTS: (18)F-Galacto-RGD PET identified all invasive carcinomas, with SUVs from 1.4 to 8.7 (mean +/- SD, 3.6 +/- 1.8; tumor-to-blood and tumor-to-muscle ratios, 2.7 +/- 1.6 and 6.2 +/- 2.2, respectively). Lymph-node metastases were detected in 3 of 8 patients (mean SUV, 3.3 +/- 0.8). SUVs in distant metastases were heterogeneous (2.9 +/- 1.4). Immunohistochemistry confirmed alpha(v)beta(3) expression predominantly on microvessels (5/5) and, to a lesser extent, on tumor cells (3/5). CONCLUSION: Our results suggest generally elevated and highly variable alpha(v)beta(3) expression in human breast cancer lesions. Consequently, further imaging studies with (18)F-galacto-RGD PET in breast cancer patients for assessment of angiogenesis or planning of alpha(v)beta(3)-targeted therapies are promising.     

Biodistribution and predictive value of 18F-fluorocyclophosphamide in mice bearing human breast cancer xenografts.

In mice bearing human breast cancer xenografts, we examined the biodistribution of (18)F-fluorocyclophosphamide ((18)F-F-CP) to evaluate its potential as a noninvasive prognostic tool for predicting the resistance of tumors to cyclophosphamide therapy. METHODS: (18)F-F-CP was synthesized as we recently described, and PET data were acquired after administration of (18)F-F-CP in mice bearing human breast cancer xenografts (MCF-7 cells). Tracer biodistribution in reconstructed images was quantified by region-of-interest analysis. Distribution was also assessed by harvesting dissected organs, tumors, and blood, determining (18)F content in each tissue with a gamma-well counter. The mice were subsequently treated with cyclophosphamide, and tumor size was monitored for at least 3 wk after chemotherapy administration. RESULTS: The distribution of harvested activity correlated strongly with distribution observed in PET images. Target organs were related to routes of metabolism and excretion. (18)F-F-CP uptake was highest in kidneys, lowest in brain, and intermediate in tumors, as determined by both image-based and tissue-based measurements. (18)F-F-CP uptake was not inhibited by coadministration of an approximately x700 concentration of unlabeled cyclophosphamide. PET measures of (18)F-F-CP uptake in tumor predicted the magnitude of the response to subsequent administration of cyclophosphamide. CONCLUSION: Noninvasive assessment of (18)F-F-CP uptake using PET may potentially be helpful for predicting the response of breast tumors to cyclophosphamide before therapy begins.     

Quantitative PET imaging of tumor integrin alphavbeta3 expression with 18F-FRGD2.

The development of noninvasive methods to visualize and quantify integrin alpha(v)beta(3) expression in vivo appears to be crucial for the success of antiangiogenic therapy based on integrin antagonism. Precise documentation of integrin receptor levels will allow appropriate selection of patients who will most likely benefit from an antiintegrin treatment regimen. Imaging can also be used to provide an optimal dosage and time course for treatment based on receptor occupancy studies. In addition, imaging integrin expression will be important to evaluate antiintegrin treatment efficacy and to develop new therapeutic drugs with favorable tumor targeting and in vivo kinetics. We labeled the dimeric RGD peptide E[c(RGDyK)](2) with (18)F and evaluated its tumor-targeting efficacy and pharmacokinetics of (18)F-FB-E[c(RGDyK)](2) ((18)F-FRGD2). METHODS: E[c(RGDyK)](2) was labeled with (18)F by conjugation coupling with N-succinimidyl-4-(18)F-fluorobenzoate ((18)F-SFB) under a slightly basic condition. The in vivo metabolic stability of (18)F-FRGD2 was determined. The diagnostic value after injection of (18)F-FRGD2 was evaluated in various xenograft models by dynamic microPET followed by ex vivo quantification of tumor integrin level. RESULTS: Starting with (18)F(-) Kryptofix 2.2.2./K(2)CO(3) solution, the total reaction time for (18)F-FRGD2, including final high-performance liquid chromatography purification, is about 200 +/- 20 min. Typical decay-corrected radiochemical yield is 23% +/- 2% (n = 20). (18)F-FRGD2 is metabolically stable. The binding potential extrapolated from graphical analysis of PET data and Logan plot correlates well with the receptor density measured by sodium dodecyl sulfate polyacrylamide electrophoresis and autoradiography in various xenograft models. The tumor-to-background ratio at 1 h after injection of (18)F-FRGD2 also gives a good linear relationship with the tumor tissue integrin level. CONCLUSION: The dimeric RGD peptide tracer (18)F-FRGD2, with high integrin specificity and favorable excretion profile, may be translated into the clinic for imaging integrin alpha(v)beta(3) expression. The binding potential calculated from simplified tracer kinetic modeling such as the Logan plot appears to be an excellent indicator of tumor integrin density.     

PET-based human dosimetry of 18F-galacto-RGD, a new radiotracer for imaging alpha v beta3 expression.

(18)F-Galacto-RGD is a new tracer for PET imaging of alpha v beta3, a receptor involved in a variety of pathologic processes including angiogenesis and metastasis. Our aim was to study the dosimetry of (18)F-galacto-RGD in humans. METHODS: Eighteen patients with various tumors (musculoskeletal tumors [n = 10], melanoma [n = 5], breast cancer [n = 2], or head and neck cancer [n = 1]) were examined. After injection of 133-200 MBq of (18)F-galacto-RGD, 3 consecutive emission scans from the thorax to the pelvis were acquired at 6.7 +/- 2.9, 35.6 +/- 7.6, and 70.4 +/- 12.2 min after injection. Blood samples (n = 4) for metabolite analysis were taken 10, 30, and 120 min after injection. The OLINDA 1.0 program was used to estimate the absorbed radiation dose. RESULTS: Reversed-phase high-performance liquid chromatography of serum revealed that more than 95% of tracer was intact up to 120 min after injection. (18)F-Galacto-RGD showed rapid clearance from the blood pool and primarily renal excretion. Background activity in lung and muscle tissue was low (percentage injected dose per liter at 71 min after injection, 0.56 +/- 0.15 and 0.69 +/- 0.25, respectively). The calculated effective dose was 18.7 +/- 2.4 microSv/MBq, and the highest absorbed radiation dose was in the bladder wall (0.22 +/- 0.03 mGy/MBq). CONCLUSION: (18)F-Galacto-RGD demonstrates high metabolic stability, a favorable biodistribution, and a low radiation dose. Consequently, this tracer can safely be used for noninvasive imaging of molecular processes involving the alpha v beta3 integrin and for the planning and monitoring of therapeutic approaches targeting alpha v beta3.     

Biodistribution and radiation dosimetry of 18F-fluoro-A-85380 in healthy volunteers.

This study reports on the biodistribution and radiation dosimetry of 2-(18)F-Fluoro-3-[2(S)-2-azetidinylmethoxy]pyridine ((18)F-fluoro-A-85380), a promising radioligand for the imaging of central nicotinic acetylcholine receptors (nAChRs). METHODS: Whole-body scans were performed in 3 healthy male volunteers up to 2 h after intravenous injection of 137-238 MBq (18)F-fluoro-A-85380. Transmission scans (3 min per step, 8 or 9 steps according to the height of the subject) in 2-dimensional mode were used for subsequent correction of attenuation of emission scans. Emission scans (1 min per step) were acquired over 2 h. Venous blood samples were taken up to 2 h after injection of the radiotracer. Urine was freely collected up to 2 h after injection of the radiotracer. For each subject, the percentage of injected activity measured in regions of interest over brain, intestine, stomach, bladder, kidneys, and liver were fitted to a monoexponential model, as an uptake phase followed by a monoexponential washout, or to a biexponential model to generate time-activity curves. Using the MIRD method, ten source organs were considered in estimating radiation absorbed doses for organs of the body. RESULTS: Injection of (18)F-fluoro-A-85380 was clinically well tolerated and blood and urine pharmacologic parameters did not change significantly. The primary routes of clearance were renal and intestinal. Ten minutes after injection, high activities were observed in the bladder, kidneys, and liver. Slow uptake was seen in the brain. The liver received the highest absorbed dose. The average effective dose of (18)F-fluoro-A-85380 was estimated to be 0.0194 mSv/MBq. CONCLUSION: The amount of (18)F-fluoro-A-85380 required for adequate nAChR imaging results in an acceptable effective dose equivalent to the patient.     

Biodistribution and dosimetry of 18F-EF5 in cancer patients with preliminary comparison of 18F-EF5 uptake versus EF5 binding in human glioblastoma

Purpose

The primary purpose of this study was to assess the biodistribution and radiation dose resulting from administration of ¹⁸F-EF5, a lipophilic 2-nitroimidazole hypoxia marker in ten cancer patients. For three of these patients (with glioblastoma) unlabeled EF5 was additionally administered to allow the comparative assessment of ¹⁸F-EF5 tumor uptake with EF5 binding, the latter measured in tumor biopsies by fluorescent anti-EF5 monoclonal antibodies.

Methods

¹⁸F-EF5 was synthesized by electrophilic addition of ¹⁸F₂ gas, made by deuteron bombardment of a neon/fluorine mixture in a high-pressure gas target, to an allyl precursor in trifluoroacetic acid at 0° then purified and administered by intravenous bolus. Three whole-body images were collected for each of ten patients using an Allegro (Philips) scanner. Gamma counts were determined in blood, drawn during each image, and urine, pooled as a single sample. PET images were analyzed to determine radiotracer uptake in several tissues and the resulting radiation dose calculated using OLINDA software and standard phantom. For three patients, 21 mg/kg unlabeled EF5 was administered after the PET scans, and tissue samples obtained the next day at surgery to determine EF5 binding using immunohistochemistry techniques (IHC).

Results

EF5 distributes evenly throughout soft tissue within minutes of injection. Its concentration in blood over the typical time frame of the study (～3.5 h) was nearly constant, consistent with a previously determined EF5 plasma half-life of ～13 h. Elimination was primarily via urine and bile. Radiation exposure from labeled EF5 is similar to other ¹⁸F-labeled imaging agents (e.g., FDG and FMISO). In a de novo glioblastoma multiforme patient, focal uptake of ¹⁸F-EF5 was confirmed by IHC.

Conclusion

These results confirm predictions of biodistribution and safety based on EF5’s characteristics (high biological stability, high lipophilicity). EF5 is a novel hypoxia marker with unique pharmacological characteristics allowing both noninvasive and invasive measurements.     

Biodistribution and radiation dosimetry of 11C-labelled docetaxel in cancer patients

Purpose  

Docetaxel is an important chemotherapeutic agent used for the treatment of several cancer types. As radiolabelled anticancer agents provide a potential means for personalized treatment planning, docetaxel was labelled with the positron emitter ¹¹C. Non-invasive measurements of [¹¹C]docetaxel uptake in organs and tumours may provide additional information on pharmacokinetics and pharmacodynamics of the drug docetaxel. The purpose of the present study was to determine the biodistribution and radiation absorbed dose of [¹¹C]docetaxel in humans.     

Biodistribution, radiation dosimetry and pharmacokinetics of 111In-antimyosin in idiopathic inflammatory myopathies.

In view of the established role of 111In-antimyosin in the detection of heart muscle pathology, radiation dose estimates were made for this substance. Biodistribution and biokinetic data were obtained from our studies, which failed to show abnormal uptake of 111In-antimyosin in localized sites of skeletal muscle involvement in patients with idiopathic inflammatory myopathies. METHODS: After intravenous administration of 74 MBq (2 mCi) 111In-antimyosin, gamma camera scintigraphy was performed in 12 adult patients with inflammatory muscle disease and in 2 control patients. Six whole-body scans were performed over 72 h, and uptake of 111In-antimyosin in organs was quantified using an attenuation-corrected conjugate counting method. Residence times in source organs were used with MIRDOSE software to obtain radiation dose estimates. Pharmacokinetic parameters were derived from serial whole-blood and plasma 111In concentrations. RESULTS: The tracer cleared slowly from the circulation, and highest organ uptakes were found in the marrow and liver; kidneys showed the highest concentrations. Uptake was also evident in spleen, the facial image and male genitalia. CONCLUSION: For a typical administered activity of 74 MBq 111In-antimyosin, the kidneys receive the highest dose (58 mSv), and the effective dose is 11 mSv. Radioactivity was cleared from plasma at an average rate of 136 mL/h, and the mean steady-state distribution was approximately 5 L plasma.     

Biodistribution and pharmacokinetics of S-35-labeled 5-thio-D-glucose in hamsters bearing pancreatic tumors.

5-thio-D-glucose (5-TDG) exerts profound effects on rapidly metabolizing tissues. We have used liquid scintillation counting to study the tissue distribution and pharmacokinetics of S-35-labeled 5-TDG in hamster models of pancreatic tumors. In the normal hamster, initial uptake of S-35 activity into kidney, liver, and blood was high, but rapidly decreased with time. The pancreatic uptake (% dose/g) never exceeded 0.75%. This level occurred only at the earliest times after administration. Uptake in all three tumor models exceeded that in pancreatic tissue within 15 min of injection. The highest tumor-to-pancreas ratio was seen in the duct-tumor model, which also exhibited the most favorable tumor-to-tissue ratio when compared with kidney, liver and muscle. Favorable ratios were most pronounced at 6 and 24 hr after injection. These studies provide impetus for the use of 5-TDG as a model compound for the synthesis of potentially useful agents for clinical detection of pancreatic tumors.     

Determination of tumour hypoxia with [18F]EF3 in patients with head and neck tumours: a phase I study to assess the tracer pharmacokinetics, biodistribution and metabolism

PURPOSE: The aim of this study was to assess the pharmacokinetics, biodistribution and metabolism of [(18)F]EF3, a labelled 2-nitroimidazole hypoxia marker, in ten patients with head and neck cancer. METHODS: [(18)F]EF3 was administered intravenously (group 1, n = 5, mean dose +/- SD: 324 +/- 108 MBq; group 2, n = 5, mean dose +/- SD: 1,134 +/- 138 MBq) to patients (nine male, one female). Blood and urine samples and whole-body PET scans were obtained from 20 s to 4-6 h. Radioactivity was determined in several regions of interest. RESULTS: No serious adverse event was reported. [(18)F]EF3 concentration in blood exhibited a bi-exponential decline. [(18)F]EF3 was mainly eliminated in the urine. By 7 h 40 min after injection, 53 +/- 14% of the injected dose was collected in the urine. There was no significant difference between the low- and high-dose groups. A progressive accumulation occurred also in the colon, indicating a hepatobiliary excretion. Except in organs involved in the elimination of [(18)F]EF3, the tumour-to-organ ratio remained close to or below unity in muscle, lungs, heart and brain at various times after injection. In one patient, tumour hypoxia was observed with a tumour-to-blood ratio ranging from 1.4 to 1.9. Last, [(18)F]EF3 remained very stable after injection, with percentage of native tracer above 87% in the serum and 84% in the urine. CONCLUSION: Administration of [(18)F]EF3 in head and neck cancer patients is feasible and safe. Uptake and retention in tumour was observed, indicating the presence of hypoxia.     

Biodistribution,pharmacokinetics and PET Imaging of [18F]FMISO, [18F]FDG and [18F]FAc in a sarcoma- and inflammation-bearing mouse model

2-Deoxy-2-[¹⁸F]fluoro-d-glucose ([¹⁸F]FDG), [¹⁸F]fluoroacetate ([¹⁸F]FAc) and [¹⁸F]fluoromisonidazole ([¹⁸F]FMISO) were all considered to be positron emission tomography (PET) probes for tumor diagnosis, though based on different rationale of tissue uptake. This study compared the biodistribution, pharmacokinetics and imaging of these three tracers in a sarcoma- and inflammation-bearing mouse model.MethodsC3H mice were inoculated with 2×10⁵ KHT sarcoma cells in the right thigh on Day 0. Turpentine oil (0.1 ml) was injected in the left thigh on Day 11 to induce inflammatory lesion. Biodistribution, pharmacokinetics and microPET imaging of [¹⁸F]FMISO, [¹⁸F]FDG and [¹⁸F]FAc were performed on Day 14 after tumor inoculation.ResultsThe inflammatory lesions were clearly visualized by [¹⁸F]FDG/microPET and autoradiography at 3 days after turpentine oil injection. The tumor-to-muscle and inflammatory lesion-to-muscle ratios derived from microPET imaging were 6.79 and 1.48 for [¹⁸F]FMISO, 8.12 and 4.69 for [¹⁸F]FDG and 3.72 and 3.19 for [¹⁸F]FAc at 4 h post injection, respectively. Among these, the tumor-to-inflammation ratio was the highest (4.57) for [¹⁸F]FMISO compared with that of [¹⁸F]FDG (1.73) and [¹⁸F]FAc (1.17), whereas [¹⁸F]FAc has the highest bioavailability (area under concentration of radiotracer vs. time curve, 116.2 h×percentage of injected dose per gram of tissue).ConclusionsMicroPET images and biodistribution studies showed that the accumulation of [¹⁸F]FMISO in the tumor is significantly higher than that in inflammatory lesion at 4 h post injection. [¹⁸F]FDG and [¹⁸F]FAc delineated both tumor and inflammatory lesions. Our results demonstrated the potential of [¹⁸F]FMISO/PET in distinguishing tumor from inflammatory lesion.     

microPET of tumor integrin alphavbeta3 expression using 18F-labeled PEGylated tetrameric RGD peptide (18F-FPRGD4).

In vivo imaging of alpha(v)beta(3) expression has important diagnostic and therapeutic applications. Multimeric cyclic RGD peptides are capable of improving the integrin alpha(v)beta(3)-binding affinity due to the polyvalency effect. Here we report an example of (18)F-labeled tetrameric RGD peptide for PET of alpha(v)beta(3) expression in both xenograft and spontaneous tumor models. METHODS: The tetrameric RGD peptide E{E[c(RGDyK)](2)}(2) was derived with amino-3,6,9-trioxaundecanoic acid (mini-PEG; PEG is poly(ethylene glycol)) linker through the glutamate alpha-amino group. NH(2)-mini-PEG-E{E[c(RGDyK)](2)}(2) (PRGD4) was labeled with (18)F via the N-succinimidyl-4-(18)F-fluorobenzoate ((18)F-SFB) prosthetic group. The receptor-binding characteristics of the tetrameric RGD peptide tracer (18)F-FPRGD4 were evaluated in vitro by a cell-binding assay and in vivo by quantitative microPET imaging studies. RESULTS: The decay-corrected radiochemical yield for (18)F-FPRGD4 was about 15%, with a total reaction time of 180 min starting from (18)F-F(-). The PEGylation had minimal effect on integrin-binding affinity of the RGD peptide. (18)F-FPRGD4 has significantly higher tumor uptake compared with monomeric and dimeric RGD peptide tracer analogs. The receptor specificity of (18)F-FPRGD4 in vivo was confirmed by effective blocking of the uptake in both tumors and normal organs or tissues with excess c(RGDyK). CONCLUSION: The tetrameric RGD peptide tracer (18)F-FPRGD4 possessing high integrin-binding affinity and favorable biokinetics is a promising tracer for PET of integrin alpha(v)beta(3) expression in cancer and other angiogenesis related diseases.     

Initial characterization of an 18F-labeled myocardial perfusion tracer.

PET allows for quantitative, regional myocardial perfusion imaging. The short half-lives of the perfusion tracers currently in use limit their clinical applicability. Here, the biodistribution and imaging quality of a new 18F-labeled myocardial perfusion agent (18F-BMS-747158-02) in an animal model are described. METHODS: The biodistribution of 18F-BMS-747158-02 was determined at 10 and 60 min after injection. The first-pass extraction fraction of the tracer was measured in isolated rat hearts perfused with the Langendorff method. Small-animal PET imaging was used to study tracer retention. RESULTS: The biodistribution at 10 min after injection demonstrated high myocardial uptake (3.1 percentage injected dose per gram [%ID/g]) accompanied by little activity in the lungs (0.3 %ID/g) and liver (1.0 %ID/g). The tracer showed a high and flow-independent myocardial first-pass extraction fraction, averaging 0.94 (SD = 0.04). PET imaging provided excellent delineation of myocardial structures. The heart-to-lung activity ratio increased from 4.7 to 10.2 between 1 and 15 min after tracer injection (at rest). Adenosine infusion (140 microg/kg/min) led to a significant increase in myocardial tracer retention (from 1.68 [SD = 0.23]) s(-1) to 3.21 [SD = 0.92] s(-1); P = 0.03). CONCLUSION: The observation of a high and flow-independent first-pass extraction fraction promises linearity between tracer uptake and myocardial blood flow. Sustained myocardial tracer uptake, combined with high image contrast, will allow for imaging protocols with tracer injection at peak exercise followed by delayed imaging. Thus, 18F-BMS-747158-02 is a promising new tracer for the quantitative imaging of myocardial perfusion and can be distributed to imaging laboratories without a cyclotron.     

Biodistribution and radiation dosimetry of the synthetic nonmetabolized amino acid analogue anti-18F-FACBC in humans.

The synthetic leucine amino acid analog anti-1-amino-3-(18)F-fluorocyclobutane-1-carboxylic acid (anti-(18)F-FACBC) is a recently developed ligand that permits the evaluation of the L-amino acid transport system. This study evaluated the whole-body radiation burden of anti-(18)F-FACBC in humans. METHODS: Serial whole-body PET/CT scans of 6 healthy volunteers (3 male and 3 female) were acquired for 2 h after a bolus injection of anti-(18)F-FACBC (366 +/- 51 MBq). Organ-specific time-activity curves were extracted from the reconstructed data and integrated to evaluate the individual organ residence times. A uniform activity distribution was assumed in the body organs with urine collection after the study. Estimates of radiation burden to the human body were calculated on the basis of the recommendations of the MIRD committee. The updated dynamic bladder model was used to calculate dose to the bladder wall. RESULTS: All volunteers showed initially high uptake in the pancreas and liver, followed by rapid clearance. Skeletal muscle and bone marrow showed lower and prolonged uptake, with clearance dominated by the tracer half-life. The liver was the critical organ, with a mean absorbed dose of 52.2 microGy/MBq. The estimated effective dose was 14.1 microSv/MBq, representing less than 20% of the dose limit recommended by the Radioactive Drug Research Committee for a 370-MBq injection. Bladder excretion was low and initially observed 6 min after injection, well after peak tracer uptake in the body organs. CONCLUSION: The PET whole-body dosimetry estimates indicate that an approximately 370-MBq injection of anti-(18)F-FACBC yields good imaging and acceptable dosimetry. The nonmetabolized nature of this tracer is favorable for extraction of relevant physiologic parameters from kinetic models.     

18F-FLT增殖显像机制及前期临床研究

18F-3'-脱氧-3 '-L氟代胸苷(18F-FLT)作为一种增殖示踪剂,利用PET可将细胞增殖活动可视化并进行量化评估,为临床提供了一种非侵入性监测抗肿瘤疗效的检查方法.该文讨论了18F-FLT作为增殖示踪剂的机制,并回顾了目前18F-FLT PET临床前期研究的状况.虽然18F-FLT是一种可以反映细胞增殖活动的示踪剂,但也有很多限制:在大部分病例中,其摄取率显著低于目前临床广泛应用的18F-FDG,而且受化疗方案和肿瘤类型的影响,18F-FLT摄取与细胞增殖活动并不总是一致.     

32P-磷酸铬间质给药在荷人胰腺癌裸鼠的体内生物学分布及形态学表现

目的 研究^32P-磷酸铬(^32P胶体)瘤体间质给药治疗BALB／c—nu／nu裸鼠荷人胰腺癌(Pc-3)移植瘤时在体内相应组织中的分布、药代动力学特点及全身毒性反应。方法 51只荷瘤裸鼠，经瘤体给予不同剂量^32P胶体或尾静脉给药，分批处死，动态观察^32P胶体在裸鼠体内放射性分布和组织器官形态学表现，观察体重变化和计数WBC和PLT，测量瘤体表面放射性计数率。结果 ^32P胶体瘤体间质注射后其放射性计数率明显高于其他器官组织，器官组织放射性计数率瘤体给药明显低于尾静脉给药。增体给药有效半减期为13d。形态学检查显示给药后大部分Pc-3细胞被破坏，并出现分化较好的瘤细胞；肝、脾、肺及淋巴结等重要器官组织的辐射损伤为可逆性．未见明显骨髓抑制现象。结论 ^32P胶体瘤体间质给药是治疗胰腺癌安全、简便、有效的核素介入疗法。