Gadolinium accumulation and fibrosis in the liver after administration of gadoxetate disodium in a rat model of active hepatic fibrosis.

PURPOSE: To evaluate the effect of gadoxetate disodium on fibrosis in a rat model of active hepatic fibrosis. MATERIALS AND METHODS: The local committee for animal research approved this study. Hepatic fibrosis was induced during 12 weeks of intraperitoneal injection of carbon tetrachloride (CCl(4)). Gadoxetate disodium was administered at 10 mmol/kg for 5 consecutive days starting after the final dose of CCl(4) (clinical dose of gadoxetate disodium is 0.25 mmol/kg). Three groups of Sprague-Dawley rats were studied. Group 1 consisted of six rats treated only with gadoxetate disodium, group 2 consisted of nine rats treated only with CCl(4), and group 3 consisted of nine rats treated with both gadoxetate disodium and CCl(4). Seven days after the final injection of gadoxetate disodium, the rats were sacrificed, and histologic findings and gadolinium deposition in the liver were examined. Fibrosis stage and gadolinium deposition were compared by using the Mann-Whitney test and Student t test. RESULTS: Fibrosis grading in groups 2 and 3 did not differ significantly (mean Batts-Ludwig fibrosis stage in group 2 was 2.67 and in group 3 was 2.78, P = .70; mean Ishak fibrosis stage in group 2 was 3.89 and in group 3 was 4.11, P = .71). Gadolinium deposition in the liver was slightly increased in group 3 in comparison to group 1 (3.2 ppm versus 4.0 ppm, P = .01), although this reversed when corrected as a percentage of total injected dose (0.022% versus 0.017%, P = .003). CONCLUSION: The high-dose administration of gadoxetate disodium in the setting of active hepatic fibrosis was not associated with increased fibrosis, suggesting that gadoxetate disodium does not incite a nephrogenic systemic fibrosis-like fibrotic change in the setting of active hepatic inflammation.

Nephrogenic systemic fibrosis in rats treated with erythropoietin and intravenous iron.

PURPOSE: To use a rat model for nephrogenic systemic fibrosis (NSF) that was administered high-dose gadodiamide to determine whether the co-administration of erythropoietin (Epo) and intravenous iron potentiated development of skin lesions that are thought to be a marker for the development of NSF. MATERIALS AND METHODS: The local committee for animal research approved this study. High-dose gadodiamide was administered, 2.5 mmol per kilogram of body weight for 20 days, or 500 times the U.S. Food and Drug Administration-approved dose, to four groups of Hannover-Wistar rats: group A, gadodiamide only; B, gadodiamide and Epo; C, gadodiamide and intravenous iron; and D, gadodiamide, Epo, and intravenous iron. The animals were sacrificed 7 days after final injection, and the authors examined dermal histologic findings from each animal and measured metal deposition by using inductively coupled plasma mass spectrometry. To compare the effect of metal deposition and cellularity, a linear mixed effects model was used to fit the data within PROC MIXED modeled with rat-specific random effects, and subsequently a Dunnett adjustment was performed. RESULTS: Rats treated with gadodiamide and both Epo and intravenous iron (group D) had significantly worse skin lesions at gross and histologic analysis (P = .004) compared with the rate treated with gadodiamide only (group A). Group D also had increased levels of deposited gadolinium as measured by means of mass spectrometry (P = .012). CONCLUSION: With a rat model similar to those already existing in the literature, skin changes were more marked in animals exposed to gadodiamide, Epo, and intravenous iron, as opposed to those animals exposed to gadodiamide alone; this experiment suggests that great caution may be warranted when prescribing gadolinium-based contrast agents to patients receiving Epo and intravenous iron.

Correlative dynamic contrast MRI and microscopic assessments of tumor vascularity in RIP-Tag2 transgenic mice.

The purpose of this study was to define the feasibility of dynamic contrast-enhanced magnetic resonance imaging (MRI) to estimate the vascular density and leakiness of spontaneous islet cell tumors in RIP-Tag2 transgenic mice. Dynamic T(1)-weighted spoiled gradient echo (SPGR) imaging at 2.0 T was performed in 17 RIP-Tag2 mice using a prototype blood pool macromolecular contrast medium (MMCM), albumin-(Gd-DTPA)(35). Kinetic analysis of the dynamic enhancement responses based on a two-compartment model was used to estimate fractional plasma volume (fPV) and the coefficient of endothelial permeability (K(PS)) for each tumor. The MRI estimate of fPV was correlated on a tumor-by-tumor basis with corresponding microscopic measurements of vascular density. The fPV assays by MMCM-enhanced imaging ranged from 2.4%-14.1% of tissue volume. Individual tumor fPV values correlated significantly (r = 0.79, P < 0.001) with the corresponding microscopic estimates of vascularity consisting of the combined area densities of lectin-perfused microvessels plus erythrocyte-stained blood lakes. A biotinylated derivative of the albumin-based MMCM confirmed extravasation of the contrast agent from some tumor blood vessels and accumulation in 25% of blood lakes. The K(PS) values ranged from 0 (no detectable leak) to 0.356 mL/min/100 cm(3). Dynamic MMCM-enhanced MRI is feasible in RIP-Tag2 pancreatic tumors, yielding estimates of vascular permeability and microscopically validated measurements of vascular richness.

Magnetic resonance imaging for monitoring the effects of thalidomide on experimental human breast cancers.

Thalidomide, which inhibits angiogenesis in certain tumor types, reduced extravasation of a macromolecular contrast medium (MMCM) in a human breast cancer model as assayed by MMCM-enhanced dynamic magnetic resonance imaging (MRI) and fluorescence microscopy in the same tumors. After a 1-week, three-dose course of thalidomide, the mean MRI-assayed endothelial transfer coefficient, K(PS), decreased significantly (p < 0.05) from 19.4 +/- 9.1 to 6.3 +/- 9.1 microl/min.100 cm(3). Correspondingly, microscopic measurements of extravasated MMCM, expressed as fractional area of streptavidin staining, were significantly (p < 0.05) lower in thalidomide-treated tumors (18.6 +/- 11.9%) than in control saline-treated tumors (50.2 +/- 2.3%). On a tumor-by-tumor basis, post-treatment K(PS) values correlated significantly (r(2) = 0.55, p < 0.05) with microscopic measures of MMCM extravasation. However, no significant differences were observed between saline- and thalidomide-treated tumors with respect to rate of growth, vascular richness, or amount of VEGF-containing cells. Because of its sensitivity to the detection of changes in vascular leakage in tumors, this MMCM-enhanced MRI assay could prove useful for monitoring the effects of thalidomide on an individual patient basis. The significant correlation between MRI and fluorescence microscopic measures of MMCM extravasation supports the utility of the non-invasive MRI approach for assessing the action of thalidomide on tumor blood vessels.

Vascular permeability during antiangiogenesis treatment: MR imaging assay results as biomarker for subsequent tumor growth in rats.

PURPOSE: To prospectively evaluate in rats the acute change in tumor vascular leakiness (K(PS)) assayed at magnetic resonance (MR) imaging after a single dose of the angiogenesis inhibitor bevacizumab as a predictive biomarker of tumor growth response after a prolonged treatment course. MATERIALS AND METHODS: Institutional animal care and use committee approval was obtained. Seventeen female rats with implanted human breast cancers underwent dynamic albumin-(Gd-DTPA)(30)-enhanced MR imaging followed by an initial dose of bevacizumab or saline (as a control). Treatment was continued every 3rd day, for a total of four doses at five possible dose levels: 0 mg bevacizumab (n = 4 [control rats]), 0.1 mg bevacizumab (n = 3), 0.25 mg bevacizumab (n = 2), 0.5 mg bevacizumab (n = 5), and 1.0 mg bevacizumab (n = 3). A second MR imaging examination was performed 24 hours after the initial dose to enable calculation of the acute change in MR imaging-assayed leakiness, or Delta K(PS). This acute change in K(PS) at MR imaging was correlated with tumor growth response for each cancer at the completion of the 11-day treatment course. For statistical analyses, an unpaired two-tailed t test, analysis of variance, and linear regression analyses were used. RESULTS: The MR imaging-assayed change in tumor microvascular leakiness, tested as a potential biomarker, correlated strongly with tumor growth rate (R(2) = 0.74, P < .001). K(PS) and tumor growth decreased significantly in all bevacizumab-treated cancers compared with these values in control group cancers (P < .05). CONCLUSION: The MR imaging-assayed acute change in vascular leakiness after a single dose of bevacizumab was an early, measurable predictive biomarker of tumor angiogenesis treatment response.

Magnetic resonance imaging assays for dimethyl sulfoxide effect on cancer vasculature.

OBJECTIVES: To evaluate the potential of quantitative assays of vascular characteristics based on dynamic contrast-enhanced magnetic resonance imaging (MRI) using a macromolecular contrast medium (MMCM) to search for and measure effects of dimethyl sulfoxide (DMSO) on cancer vasculature with microscopic correlations. MATERIAL AND METHODS: Saline-treated control (n = 8) and DMSO-treated (n = 7) human breast cancer xenografts (MDA-MB-435) in rats were imaged dynamically by MMCM-enhanced MRI using albumin-(Gd-DTPA)27-(biotin)11 (molecular weight approximately 90 kDa), before and after a 1-week, 3-dose treatment course. After the posttreatment MRI examinations, tumors were perfused with lectin and fixative and subsequently stained with RECA-1 and streptavidin for quantitative fluorescent microscopy. Quantitative MRI estimates of cancer microvessel permeability (KPS; microL/min.100 cm3) and fractional plasma volume (fPV; %) were based on a 2-compartment kinetic model. Fluorescent microscopy yielded estimates of MMCM extravasation and vascular density that were compared to the MRI results. RESULTS: DMSO decreased cancer vascular endothelial permeability significantly (P < 0.05) from tumor KPSday0 = 19.3 +/- 8.8 microL/min.100 cm3 to KPSday7 = 0 microL/min.100 cm3). K values in the saline-treated tumors did not change significantly. The amount of extravasated albumin-Gd-(DTPA)27-(biotin)11, as assayed by a fluorescently labeled streptavidin stain that strongly binds to the biotin tag on the MMCM, was significantly (P < 0.05) lower in the DMSO-treated cancers than in the control cancers (57.7% +/- 5.5% vs. 34.2% +/- 4.9%). Tumor vascular richness as reflected by the MRI-assayed fPV and by the RECA-1 and lectin-stained microscopy did not change significantly with DMSO or saline treatment. CONCLUSION: Reductions in cancer microvascular leakiness induced by a 7-day course of DMSO could be detected and measured by dynamic MMCM-enhanced MRI and were confirmed by microscopic measurements of the leaked macromolecular agents in the same cancers. Results support the robustness of an MMCM-enhanced MRI approach to the characterization of cancers and providing first evidence for an in vivo effect of DMSO on cancer blood vessels.

AG-013736, a novel inhibitor of VEGF receptor tyrosine kinases, inhibits breast cancer growth and decreases vascular permeability as detected by dynamic contrast-enhanced magnetic resonance imaging.

Dynamic contrast-enhanced MRI (DCE-MRI) was used to noninvasively evaluate the effects of AG-03736, a novel inhibitor of vascular endothelial growth factor (VEGF) receptor tyrosine kinases, on tumor microvasculature in a breast cancer model. First, a dose response study was undertaken to determine the responsiveness of the BT474 human breast cancer xenograft to AG-013736. Then, DCE-MRI was used to study the effects of a 7-day treatment regimen on tumor growth and microvasculature. Two DCE-MRI protocols were evaluated: (1) a high molecular weight (MW) contrast agent (albumin-(GdDTPA)(30)) with pharmacokinetic analysis of the contrast uptake curve and (2) a low MW contrast agent (GdDTPA) with a clinically utilized empirical parametric analysis of the contrast uptake curve, the signal enhancement ratio (SER). AG-013736 significantly inhibited growth of breast tumors in vivo at all doses studied (10-100 mg/kg) and disrupted tumor microvasculature as assessed by DCE-MRI. Tumor endothelial transfer constant (K(ps)) measured with albumin-(GdDTPA)(30) decreased from 0.034+/-0.005 to 0.003+/-0.001 ml min(-1) 100 ml(-1) tissue (P<.0022) posttreatment. No treatment-related change in tumor fractional plasma volume (fPV) was detected. Similarly, in the group of mice studied with GdDTPA DCE-MRI, AG-013736-induced decreases in tumor SER measures were observed. Additionally, our data suggest that 3D MRI-based volume measurements are more sensitive than caliper measurements for detecting small changes in tumor volume. Histological staining revealed decreases in tumor cellularity and microvessel density with treatment. These data demonstrate that both high and low MW DCE-MRI protocols can detect AG-013736-induced changes in tumor microvasculature. Furthermore, the correlative relationship between microvasculature changes and tumor growth inhibition supports DCE-MRI methods as a biomarker of VEGF receptor target inhibition with potential clinical utility.

Imaging of tumor angiogenesis: current approaches and future prospects.

Tumor angiogenesis imaging should provide non-invasive assays of tumor vascular characteristics to supplement the now conventional diagnostic imaging goals of depicting tumor location, size, and morphology. This article will review the current status of angiogenesis imaging approaches, considering ultrasound, CT, MR, SPECT, PET and optical techniques with attention to their respective capabilities and limitations. As a group, these imaging methods have some potential to depict and quantify tumor microvascular features, including those considered to be functionally associated with tumor angiogenesis. Additionally, new molecule-specific imaging techniques may serve to depict those biochemical pathways and regulatory events that control blood vessel growth and proliferation. Non-invasive monitoring of anti-angiogenic therapies has great appeal and should find wide application for defining tumor microvascular and metabolic changes, because treatment-related changes in tumor morphology tend to occur rather late and are non-specific. Future developments are likely to include "fusion" or "hybrid" imaging methods. Superimposed data from MR imaging with spectroscopy, PET with CT, and PET with MR should be able to integrate advantages of different modalities yielding comprehensive information about tumor structure, function and microenvironment.

In-vivo NIR autofluorescence imaging of rat mammary tumors.

We investigate in vivo detection of mammary tumors in a rat model using autofluorescence imaging in the red and far-red spectral regions. The objective was to explore this method for non-invasive detection of malignant tumors and correlation between autofluorescence properties of tumors and their pathologic status. Eighteen tumor-bearing rats, bearing eight benign and seventeen malignant tumors were imaged. Autofluorescence images were acquired using spectral windows centered at 700-nm, 750-nm and 800-nm under laser excitation at 632.8-nm and 670- nm. Intensity in the autofluorescence images of malignant tumors under 670-nm excitation was higher than that of the adjacent normal tissue. whereas intensity of benign tumors was lower compared to normal tissue.

Magnetic resonance macromolecular agents for monitoring tumor microvessels and angiogenesis inhibition.

Dynamic contrast-enhanced magnetic resonance imaging (DCE-MRI) using macromolecular contrast media enables assessments of the tumor vasculature based on the differential distribution of the contrast agent within normal and pathologic tissues. Quantitative assays of both morphologic and functional properties can provide useful diagnostic insight into tissue angiogenesis. The use of MRI enhanced with macromolecular agents for the characterization of tumor microvessels has been experimentally demonstrated in a range of malignant tumor types. Kinetic analysis of DCE-MRI data can be used to estimate microvascular permeability and tumor blood volume. By measuring these functional tumor properties, an accurate, noninvasive, and quantitative description of the microcirculation of individual tumors can be acquired, improving the specificity of imaging examinations for cancer diagnosis and for treatment and follow up. The noninvasive MRI assessment of tumor angiogenesis can be applied in the diagnostic differentiation between benign and malignant tumors and can also provide means for in vivo monitoring of antitumor therapy. In this review, the potential clinical applications and limitations of various macromolecular contrast agents applied for evaluations of tumor angiogenesis, with and without drug interventions, are discussed.

Magnetic resonance imaging enhancement of normal tissues and tumors using macromolecular Gd-based cascade polymer contrast agents: preclinical evaluations.

OBJECTIVES: We sought to compare magnetic resonance imaging (MRI) enhancement using 4 novel macromolecular polyethyleneglycol (PEG)-based cascade-polymer gadolinium contrast agents (macromolecular contrast media) in normal soft tissues and a breast cancer model. MATERIALS AND METHODS: Four candidate PEG cascade polymers with effective molecular weights of 74, 82, 106, and 132 kDa, respectively, and T1-relaxivities of 8.1, 9.1, 9.7, and 10.0, respectively (at 2 Tesla and 37 degrees C in HEPES buffer), initially were used to characterize liver and kidney MRI-enhancement patterns in normal Sprague-Dawley rats (n = 4-5 per contrast agent). Kinetic analysis of dynamic MRI enhancement was used in 8 nude rats bearing MDA-MB 435 breast cancers to estimate fractional plasma volume and apparent endothelial leakiness (K) in tumors and muscle. RESULTS: Soft-tissue enhancement patterns followed closely the blood enhancement over the course of 30-50 minutes with estimated blood half-lives between 23 and 73 minutes, which varied with effective molecular weights. The 2 smaller compounds yielded measurable leaks in normal muscle [K = 204 and 56 microL/(min.100 cm), respectively], whereas the 2 larger molecules did not leak in muscle [K = 0 microL/(min.100 cm)]; however, MRI-assayed leakiness of tumor vessels with respect to those 2 larger macromolecular contrast media was 68 +/- 27 and 16 +/- 8 microL/(min.100 cm), respectively. CONCLUSIONS: Two relatively large (effective molecular weight >82 kDa) PEG-based cascade polymer contrast agents were well-suited for MRI quantification of tissue plasma volume and for differentiating leaky cancer microvessels from nonleaky normal vessels.

The choice of region of interest measures in contrast-enhanced magnetic resonance image characterization of experimental breast tumors.

OBJECTIVES: The objectives of this study were to determine if magnetic resonance (MR) estimates of quantitative tissue microvascular characteristics from regions of interest (ROI) limited to the tumor periphery provided a better correlation with tumor histologic grade than ROI defined for the whole tumor in cross-section. METHODS: A metaanalysis was based on 98 quantitative MR image breast tumor characterizations acquired in 3 separate experimental studies using identical methods for tumor induction and contrast enhancement. RESULTS: The endothelial transfer coefficient (K) of albumin (Gd-DTPA)30 from the tumor periphery correlated (r = 0.784) significantly more strongly (P < 0.001) with the pathologic tumor grade than K derived from the whole tumor (r = 0.604). K estimates, either from the tumor periphery or from the whole tumor, correlated significantly more strongly with histologic grade (P < 0.01) than MR image estimates of fractional plasma volume (fPV) from either tumor periphery (r = 0.368) or whole tumor (r = 0.323). CONCLUSIONS: K estimates from the tumor periphery were the best of these measurable MR image microvascular characteristics for predicting the histologic grade.

Initial computed tomography imaging experience using a new macromolecular iodinated contrast medium in experimental breast cancer.

OBJECTIVE: The objective of this study was to evaluate computed tomography (CT) enhancement characteristics for a new iodinated macromolecular contrast medium (MMCM), PEG12000-Gen4-triiodo, for angiographic effect and for assessment of abnormal vascular permeability in cancer. MATERIALS AND METHODS: Time persistence of angiographic effect was evaluated on rat CT images acquired over 30 minutes using the iodinated polyethyleneglycol- (PEG) based macromolecule. Dynamic CT imaging after PEG12000-Gen4-triiodo-enhancement in tumor-bearing rats was used to quantitatively estimate plasma volume and microvascular transendothelial permeability for both tumor and normal soft tissue. Using identical doses of iodine, 300 mg iodine/kg, blood curves for this MMCM and iohexol were compared. RESULTS: Serial whole-body CT angiograms using PEG12000-Gen4-triiodo showed diagnostic vascular detail through 20 minutes, and the blood enhancement curve was higher and more persistent than with small-molecular iohexol. Permeability estimates were significantly (P<0.02; paired t test) higher in tumors (48.2+/-18.1 microL/min-1 100 mL) than in muscle (2.5+/-5.7 microL/min-1 100 mL). CONCLUSIONS: Use of PEG-based MMCM for experimental CT allowed for a persistent angiographic enhancement and for quantitative estimation of tumor microvascular characteristics.

Magnetic resonance imaging detects early changes in microvascular permeability in xenograft tumors after treatment with the matrix metalloprotease inhibitor Prinomastat.

Macromolecular contrast medium-enhanced magnetic resonance imaging was applied to monitor the effect of matrix metalloprotease (MMP) inhibition on microvascular characteristics of human breast cancers implanted in athymic rats. Twice-daily intraperitoneal administration of Prinomastat over 1.5 days induced significant declines in MRI-assayed microvascular permeabilities (p<0.05); but this leak suppression effect had extinguished by the 10(th) day of MMP treatment using the same dose and time schedule. Results demonstrate that Prinomastat produces a rapid but transient decrease in tumor vascular permeability. Contrast-enhanced MRI using macromolecular contrast medium may prove useful as a biomarker for the dynamic MMP biological effect in cancers.

Evaluation of imatinib mesylate as a possible treatment for nephrogenic systemic fibrosis in a rat model.

INTRODUCTION: The purpose of the study was to evaluate the efficacy of imatinib mesylate in the treatment of nephrogenic systemic fibrosis (NSF) in a rat model administered high-dose gadodiamide, erythropoietin (Epo) and intravenous iron (IV iron). MATERIALS AND METHODS: The local committee for animal research approved this study. Four groups of six Hannover-Wistar rats were studied. Group A received normal saline; Group B, IV iron and Epo; Group C, gadodiamide, IV iron and Epo; and Group D, gadodiamide, IV iron, Epo and imatinib. Gadodiamide was administered at 10 mmol/kg of body weight for 5 consecutive days. Imatinib was administered at 50 mg/kg starting 3 days before gadodiamide injections and was continued for 50 days afterwards. Biopsies were taken 3 and 7 weeks after gadodiamide injection, and dermal histology was analyzed as well as gadolinium deposition as measured by inductively coupled plasma mass spectrometry. Additionally, rats treated with gadodiamide were observed for a total of 16 weeks. For comparison of cellularity, a linear mixed-effects model was used, and for metal deposition, an analysis of variance was used, which was corrected with a Tamhane correction for unequal variances. RESULTS: Rats treated with gadodiamide in addition to IV iron and Epo (group C) had worse skin lesions on histology (P<.001) compared to control animals (groups A and B). Treatment with imatinib resulted in decreased cellularity (group D vs C, P<.001), although there was no difference in the amount of deposited gadolinium (P>.5). Histology at 16 weeks demonstrated increased fibrosis and dermal calcifications, consistent with the clinical presentation of NSF. CONCLUSIONS: The administration of imatinib to rats treated with high-dose gadodiamide resulted in decreased lesion severity.

Evaluation of a novel macromolecular cascade-polymer contrast medium for dynamic contrast-enhanced MRI monitoring of antiangiogenic bevacizumab therapy in a human melanoma model.

RATIONALE AND OBJECTIVES: To assess the applicability of a novel macromolecular polyethylene glycol (PEG)-core gadolinium contrast agent for monitoring early antiangiogenic effects of bevacizumab using dynamic contrast-enhanced (DCE) magnetic resonance imaging (MRI). MATERIALS AND METHODS: Athymic rats (n = 26) implanted with subcutaneous human melanoma xenografts underwent DCE-MRI at 2.0 T using two different macromolecular contrast agents. The PEG core cascade polymer PEG12,000-Gen4-(Gd-DOTA)16, designed for clinical development, was compared to the prototype, animal-only, macromolecular contrast medium (MMCM) albumin-(Gd-DTPA)35. The treatment (n = 13) and control (n = 13) group was imaged at baseline and 24 hours after a single dose of bevacizumab (1 mg) or saline to quantitatively assess the endothelial-surface permeability constant (K(PS), µL⋅min⋅100 cm(3)) and the fractional plasma volume (fPV,%), using a two-compartment kinetic model. RESULTS: Mean K(PS) values, assessed with PEG12,000-Gen4-(Gd-DOTA)16, declined significantly (P < .05) from 29.5 ± 10 µL⋅min⋅100 cm(3) to 10.4 ± 7.8 µL⋅min⋅100 cm(3) by 24 hours after a single dose of bevacizumab. In parallel, K(PS) values quantified using the prototype MMCM albumin-(Gd-DTPA)35 showed an analogous, significant decline (P < .05) in the therapy group. No significant effects were detected on tumor vascularity or on microcirculatory parameters in the control group between the baseline and the follow-up scan at 24 hours. CONCLUSION: DCE-MRI enhanced with the novel MMCM PEG12,000-Gen4-(Gd-DOTA)16 was able to monitor the effects of bevacizumab on melanoma xenografts within 24 hours of a single application, validated by the prototype, animal-only albumin-(Gd-DTPA)35. PEG12,000-Gen4-(Gd-DOTA)16 may be a promising candidate for further clinical development as a macromolecular blood pool contrast MRI agent.

Permeability to macromolecular contrast media quantified by dynamic MRI correlates with tumor tissue assays of vascular endothelial growth factor (VEGF).

PURPOSE: To correlate dynamic MRI assays of macromolecular endothelial permeability with microscopic area-density measurements of vascular endothelial growth factor (VEGF) in tumors. METHODS AND MATERIAL: This study compared tumor xenografts from two different human cancer cell lines, MDA-MB-231 tumors (n=5), and MDA-MB-435 (n=8), reported to express respectively higher and lower levels of VEGF. Dynamic MRI was enhanced by a prototype macromolecular contrast medium (MMCM), albumin-(Gd-DTPA)35. Quantitative estimates of tumor microvascular permeability (K(PS); µl/min × 100 cm(3)), obtained using a two-compartment kinetic model, were correlated with immunohistochemical measurements of VEGF in each tumor. RESULTS: Mean K(PS) was 2.4 times greater in MDA-MB-231 tumors (K(PS)=58 ± 30.9 µl/min × 100 cm(3)) than in MDA-MB-435 tumors (K(PS)=24 ± 8.4 µl/min × 100 cm(3)) (p<0.05). Correspondingly, the area-density of VEGF in MDA-MB-231 tumors was 2.6 times greater (27.3 ± 2.2%, p<0.05) than in MDA-MB-435 cancers (10.5 ± 0.5%, p<0.05). Considering all tumors without regard to cell type, a significant positive correlation (r=0.67, p<0.05) was observed between MRI-estimated endothelial permeability and VEGF immunoreactivity. CONCLUSION: Correlation of MRI assays of endothelial permeability to a MMCM and VEGF immunoreactivity of tumors support the hypothesis that VEGF is a major contributor to increased macromolecular permeability in cancers. When applied clinically, the MMCM-enhanced MRI approach could help to optimize the appropriate application of VEGF-inhibiting therapy on an individual patient basis.