Exchangeable zinc pool masses and turnover are maintained in healthy men with low zinc intakes.

Previous studies suggest that rapidly exchanging zinc pools (EZP), thought to supply the zinc required by tissues, are smaller and turn over more rapidly in individuals with lower zinc intakes. We studied the effects of low dietary zinc (4.6 mg/d) on EZP mass and turnover in seven healthy men confined during a 20-wk clinical study. Supplements of 9.1 mg zinc were given during the 5-wk baseline and repletion periods, and placebos were given during a 10-wk zinc-restriction period. Stable 70Zn tracers were administered intravenously at the end of baseline, 3 and 10 wk after the start of zinc restriction and at the end of repletion. Multiple plasma samples were collected over an 8-d period after tracer administration. 70Zn:66Zn ratios were measured using inductively coupled plasma mass spectrometry, and tracer-tracee data were analyzed by compartmental modeling. Activities of the zinc-dependent enzymes, alkaline phosphatase and 5'nucleotidase, were unchanged during the study. There were no significant changes in EZP masses or kinetic parameters. A three-compartment model indicated that the masses of plasma zinc and total EZP averaged 3.25 +/- 0.58 and 147.8 +/- 33.2 mg, respectively, at the four time points studied. Plasma zinc mass turned over at an average of 5.3 times per hour. There was an 11% reduction (P = 0.06) in plasma zinc flux 3 wk after the start of the low zinc diet period, but it returned to baseline values after 10 wk of zinc restriction. The results suggest that total EZP mass is maintained when dietary zinc is reduced to 4.6 mg/d over a 10-wk period.

MRI assessment of microvascular characteristics in experimental breast tumors using a new blood pool contrast agent (MS-325) with correlations to histopathology.

A new contrast medium, MS-325, was compared to albumin-(Gd-DTPA)(30) in 18 chemically induced rat breast tumors based on quantitative estimates of microvascular permeability (K(PS)) and fractional plasma volume (fPV) using a two-compartment bidirectional model. No significant correlation was found between MS-325-enhanced microvascular assays with either tumor grade or with microvascular counts (MVCs). In comparison, the correlation coefficient between K(PS) and histologic tumor grade using albumin-(Gd-DTPA)(30) (r =.58) was statistically significant (P <.01). Also, using albumin-(Gd-DTPA)(30), a significant correlation (r =.55, P <.05) was observed between the K(PS) and MVC, a biomarker of angiogenesis. Correlations between fPV and MVC were not statistically significant for either contrast medium. In conclusion, using MS-325, no significant correlations between the MR-estimated permeability values or plasma volumes were observed in experimental breast tumors with either the histologic tumor grade or MVC. This analysis confirms our previous determination that capillary permeability estimates, using a prototype large molecular contrast medium, albumin-(Gd-DTPA)(30), correlate significantly with both histologic tumor grade and MVC.

Effect of acute zinc depletion on zinc homeostasis and plasma zinc kinetics in men.

BACKGROUND: Zinc homeostasis and normal plasma zinc concentrations are maintained over a wide range of intakes. OBJECTIVE: The objective was to identify the homeostatic response to severe zinc depletion by using compartmental analysis. DESIGN: Stable zinc isotope tracers were administered intravenously to 5 men at baseline (12.2 mg dietary Zn/d) and after 5 wk of acute zinc depletion (0.23 mg/d). Compartmental modeling of zinc metabolism was performed by using tracer and mass data in plasma, urine, and feces collected over 6-14 d. RESULTS: The plasma zinc concentration fell 65% on average after 5 wk of zinc depletion. The model predicted that fractional zinc absorption increased from 26% to essentially 100%. The rate constants for zinc excretion in the urine and gastrointestinal tract decreased 96% and 74%, respectively. The rate constants describing the distribution kinetics of plasma zinc did not change significantly. When zinc depletion was simulated by using an average mass model of zinc metabolism at baseline, the only change that accounted for the observed fall in plasma zinc concentration was a 60% reduction in the rate constant for zinc release from the most slowly turning over zinc pool. The large changes in zinc intake, excretion, and absorption-even when considered together-only explained modest reductions in plasma zinc mass. CONCLUSION: The kinetic analysis with a compartmental model suggests that the profound decrease in plasma zinc concentrations after 5 wk of severe zinc depletion was mainly due to a decrease in the rate of zinc release from the most slowly turning over body zinc pool.

Accuracy of simple techniques for estimating fractional zinc absorption in humans.

The theoretical basis of the accuracy of a number of simple techniques for estimating fractional zinc absorption (FZA) in humans using stable isotopic tracers has not been evaluated. These techniques include fecal monitoring (FM), deconvolution analysis (DA), double isotopic tracer ratio (DITR) and indicator dilution methods. Using a compartmental model, we investigated the accuracy and logic of each of these techniques. Time-dependent estimates of FZA based on the simple techniques were simulated using the compartmental model and compared with the known FZA derived from the model. The analysis elucidated logical errors in some of the FM techniques, and even when these problems were corrected, the FM technique was still prone to errors due to incomplete fecal tracer recovery and variable gastrointestinal (GI) transit time. Although logically correct, the indicator dilution techniques were also highly sensitive to incomplete fecal tracer recovery and variable GI transit time. The DA and DITR techniques were the most robust in that they were logically correct and were insensitive to incomplete fecal tracer recovery and variable GI transit time. Although all of the DA and DITR methods provided similarly good estimates of FZA relative to the compartmental model, the DITR technique performed on a spot urine specimen obtained several days after tracer administration was the preferred choice because of its simplicity and minimal requirements for patient compliance.

Tumor microvascular characterization using ultrasmall superparamagnetic iron oxide particles (USPIO) in an experimental breast cancer model.

The diagnostic potential of ultrasmall superparamagnetic iron oxide particles (USPIO) for quantitative tumor microvessel characterization was assessed by kinetic analysis of dynamic magnetic resonance imaging (MRI) in a rodent breast cancer model. Microvascular characteristics (transendothelial permeability (K(PS)) and fractional plasma volume (fPV)) were estimated in 32 female Sprague Dawley rats, bearing breast tumors of varying malignancy. These values were compared to a prototype macromolecular contrast medium standard, albumin-(GdDTPA)(30). Transendothelial permeability (K(PS)) correlated significantly (P < 0.05) with the tumor grade (Scarff-Bloom-Richardson (SBR) score) for the USPIO (r = 0.36), as well as for the reference macromolecule, albumin-(GdDTPA)(30) (r = 0.54). Estimates for the fPV did not show a statistically significant correlation with the tumor grade for either contrast medium. In conclusion, USPIO-enhanced MRI data were capable to characterize tumor microvessel properties in this breast cancer model: microvascular permeability (determined using USPIO) correlated significantly with tumor grade. Thus, quantitative estimation of microvascular characteristics in tumors could provide a surrogate of new vessel formation (angiogenesis) and thus a further important clinical indication for USPIO, in addition to MR angiography. J. Magn. Reson. Imaging 2001;13:882-888.

Assessment of a rapid clearance blood pool MR contrast medium (P792) for assays of microvascular characteristics in experimental breast tumors with correlations to histopathology.

The diagnostic potential of a new rapid clearance blood pool contrast medium (P792; MW = 6.47 kDa) for the MR assessment of microvessel characteristics was assessed in 42 chemically-induced breast tumors, with comparisons to albumin-(Gd-DTPA). Microvessel characteristics, including the transendothelial permeability (K(PS)) and the fractional blood volume (fPV), were estimated by using dynamic MR data fit to a bidirectional two-compartment model. The MR-derived estimates for K(PS) and fPV using each contrast agent were compared, and assays using each contrast agent were correlated to the histologic tumor grade (SBR score) and the microvascular density (MVD) counts. Using P792-enhanced data, neither K(PS) nor fPV showed a statistically significant correlation with the tumor grade or the MVD (P >.05). Conversely, using albumin-(GdDTPA)(30), K(PS) values correlated significantly with the histologic tumor grade (r =.55; P <.0005) and the MVD (r =.34, P <.05), whereas no correlation was established for fPV. In conclusion, based on P792 data no correlation between tumor microvascular characteristics and histologic markers (SBR score or MVD) was found in this breast tumor model. Our analysis suggests that contrast media of relatively large (on the order of 90 kDa) molecular size, such as albumin-(GdDTPA)(30), are more accurate for the characterization of tumor microvessels.

MR imaging characterization of microvessels in experimental breast tumors by using a particulate contrast agent with histopathologic correlation.

PURPOSE: To define the diagnostic potential of magnetic resonance (MR) imaging enhanced with ultrasmall superparamagnetic iron oxide (USPIO) particles for the quantitative characterization of tumor microvasculature. MATERIALS AND METHODS: NC100150 injection, a USPIO in clinical trials, and albumin-(Gd-DTPA)(30) were compared at MR imaging on sequential days in the same 19 rats with mammary tumors. Kinetic analysis of dynamic T1-weighted three-dimensional spoiled gradient-recalled imaging data with a two-compartment bidirectional model yielded MR imaging estimates of microvascular permeability (K(PS)) and fractional plasma volume (fPV) for each contrast medium. RESULTS: Strongly positive and significant correlations were observed between MR imaging-derived K(PS )estimates and histologic tumor grade with either the soluble albumin-(Gd-DTPA)(30) (r = 0.88; P <.001) or larger particulate USPIO (r = 0.82; P <.001). A significant correlation (P <.05) was observed with each contrast medium between K(PS) and the histologic microvascular density (MVD), an angiogenesis indicator. Despite the considerable difference in molecule and particle sizes, no significant difference was observed in the MR imaging-derived mean permeability values generated with the two contrast media. CONCLUSION: USPIO, a macromolecular particulate MR imaging contrast agent, can be applied successfully to characterize tumor microvessels in animals. USPIO-derived K(PS) correlated strongly with histopathologic tumor grade, MVD, and K(PS) values derived by using albumin-(Gd-DTPA)(30) in the same tumors.

Quantitative gadopentetate-enhanced MRI of breast tumors: testing of different analytic methods.

This study assessed several proposed imaging strategies and analytic methods based on gadopentetate-enhanced MRI to differentiate benign from malignant breast tumors in a blinded experimental animal study. Steady-state dynamic MRI and first-pass imaging, performed with either T(1)- or T*(2)- weighted sequences, were compared. Semiquantitative and quantitative analysis methods, based on empirical measures of the data or physiological models, were subsequently applied to the imaging datasets. Comparative measures provided pathologic distinction of benign from malignant tumors, tumor grading, and histologic determination of microvascular density. Of the eight tested methods, only one, an estimate of first-pass perfusion using T *(2)-weighted imaging, showed an almost significant (P = 0.05) difference between benign and malignant tumors and correlated almost significantly (r =.3, P = 0.06) with the tumor grade. All other tests, performed either with steady-state imaging or with T(1)-weighted first-pass imaging, failed to differentiate benign from malignant tumors. In addition, they yielded poor correlations with tumor grade and microvascular density.

Comparison of Gadomer-17 and gadopentetate dimeglumine for differentiation of benign from malignant breast tumors with MR imaging.

RATIONALE AND OBJECTIVES: This study compared gadopentetate dimeglumine (molecular weight, 0.5 kD), a standard contrast medium, and Gadomer-17 (apparent molecular weight, approximately 35 kD), a new, clinically applicable, large-molecular contrast medium, with respect to their microvascular characterizations of experimentally induced breast tumors at magnetic resonance (MR) imaging. MATERIALS AND METHODS: A spectrum of breast tumors, benign through highly malignant, was induced in Sprague-Dawley rats (n = 30) by intraperitoneal administration of N-ethyl-N-nitrosourea (ENU), a potent carcinogen. All animals underwent three-dimensional spoiled gradient-recalled MR imaging, with precontrast imaging and dynamic postcontrast imaging after injection of gadopentetate dimeglumine (0.1 mmol/kg) and Gadomer-17 (0.03 mmol/kg), administered in a random order at a 24-hour interval. Several microvascular parameters were compared: the endothelial transfer coefficient (K(PS)), a measure of microvascular permeability; the fractional plasma volume (fPV), and the plasma equivalent volume. Each MR imaging parameter was correlated with histopathologic findings. RESULTS: With Gadomer-17, the mean values for K(PS) and fPV were significantly greater in carcinomas than in fibroadenomas (P < .004 and .04, respectively). With gadopentetate dimeglumine, the mean values for fPV and PEV were significantly greater in carcinomas (P <. 004 and .02, respectively). Because of the high variability within both fibroadenoma and carcinoma groups, however, there were no significant correlations between K(PS), fPV, or PEV and histopathologic tumor grade as indicated by the Scarff-Bloom-Richardson score, for either agent. CONCLUSION: Although the K(PS) and fPV estimates obtained from dynamic MR imaging data with Gadomer-17 enhancement offer some potential for characterizing breast tumors, none of the quantitative microvascular parameters derived with either agent were significantly correlated with histopathologic tumor grade.

Magnetic resonance imaging in an experimental model of human ovarian cancer demonstrating altered microvascular permeability after inhibition of vascular endothelial growth factor.

OBJECTIVE: Magnetic resonance imaging enhanced with macromolecular contrast medium was used to monitor effects of angiogenesis inhibition on tumor microvascular permeability and ascites volume in an athymic rat model of human ovarian cancer. STUDY DESIGN: Groups of 6 athymic rats implanted intraperitoneally with SKOV-3, a human ovarian cancer cell line, were treated through a 14-day course with antibody to vascular endothelial growth factor or with saline solution for control animals. Dynamic magnetic resonance imaging was performed with a 92,000-d contrast agent, albumin-(gadolinium-diethylenetriaminepentaacetic acid)(30). Vascular permeability was estimated from dynamic enhancement data that were analyzed with a unidirectional 2-compartment kinetic model. RESULTS: Animals treated with vascular endothelial growth factor antibody accumulated significantly smaller volumes of peritoneal ascites (P <.05) and showed significantly lower magnetic resonance imaging-assayed tumor microvascular permeabilities (P <.05) than did control animals. CONCLUSION: Magnetic resonance imaging enhanced with a macromolecular contrast agent in an athymic rat model of human ovarian cancer treated with anti-vascular endothelial growth factor antibody can be used to measure a reduction in tumor microvascular permeability, corresponding to a reduction in ascites production.

A new polysaccharide macromolecular contrast agent for MR imaging: biodistribution and imaging characteristics.

The aims of this study were to characterize certain physicochemical, pharmacokinetic, and enhancement properties of a new macromolecular contrast agent, carboxymethyl hydroxyethyl starch-(Gd-DO3A)(35) [CMHES-(Gd-DO3A)(35)], consisting of a polysaccharide backbone covalently derivatized with multiple macrocyclic chelating groups for gadolinium. CMHES-(Gd-DO3A)(35) has an average molecular weight of 72 kD and a plasma half-time of 8.4 hours. T1 and T2 relaxivities are 14.1 +/- 0.1 L mmol(-1) * sec(-1) and 17.8 +/- 0.9 L mmol(-1) * sec(-1), respectively, for each gadolinium ion measured at 39 degrees C and 20 Mhz; this T1 relaxivity is more than 4 times that of gadopentetate. Seven days after intravenous administration only relatively small amounts of gadolinium could be detected in blood or other tissues of rats. The compound was well tolerated in diagnostic dosages by all experimental animals. Magnetic resonance angiography performed within 1 hour of CMHES-(Gd-DO3A)(35) administration showed a near-constant and strong enhancement of blood in arteries and veins. Analysis of dynamic enhancement patterns of experimental tumors (MAT-LyLu prostate cancer implanted in rats) following intravenous CMHES-(Gd-DO3A)(35) administration yielded quantitative estimates of tumor plasma volume and microvessel permeability; the demonstrated hyperpermeability of tumor microvessels was easily distinguished from the absence of measurable microvascular permeability in non-neoplastic soft tissues.

Zinc homeostasis in humans.

Maintaining a constant state of cellular zinc nutrition, or homeostasis, is essential for normal function. In animals and humans, adjustments in zinc absorption and endogenous intestinal excretion are the primary means of maintaining zinc homeostasis. The adjustments in gastrointestinal zinc absorption and endogenous excretion are synergistic. Shifts in endogenous excretion appear to occur quickly with changes in intake just above or below optimal intake. The absorption of zinc responds more slowly, but it has the capacity to cope with large fluctuations in intake. With extremely low zinc intakes or with prolonged marginal intakes, secondary homeostatic adjustments may augment the gastrointestinal changes. These secondary adjustments include changes in urinary zinc excretion, a shift in plasma zinc turnover rates and, possibly, an avid retention of zinc released from selected tissues, such as bone, in other tissues to maintain function.

Prostate cancer tumor grade differentiation with dynamic contrast-enhanced MR imaging in the rat: comparison of macromolecular and small-molecular contrast media--preliminary experience.

PURPOSE: To differentiate prostate cancers of different histopathologic grades with dynamic gadolinium-enhanced magnetic resonance (MR) imaging. Results with a conventional small-molecular contrast medium (CM) were compared to those with a prototypic macromolecular CM. MATERIALS AND METHODS: High- and low-grade tumors, sublines of the Dunning R3327 rat prostate cancer line, were subcutaneously implanted into the flanks of 12 male Copenhagen rats. Dynamic contrast material-enhanced MR imaging was performed with small-molecular CM and macromolecular CM at an interval of 1 day. Microvascular permeability, as estimated with the endothelial transfer coefficient, and fractional plasma volume were calculated for each tumor and each CM by means of a two-compartmental, bidirectional kinetic model. RESULTS: Mean endothelial transfer coefficient values for both macromolecular CM and small-molecular CM were significantly different between the two tumor sublines (P = .0004 and P = .01, respectively). For the high- and low-grade tumors, no overlap of values was seen with macromolecular CM, but a broad overlap was seen with small-molecular CM despite a significant difference in mean values. CONCLUSION: Dynamic contrast-enhanced MR imaging permits differentiation of histopathologic prostatic tumor types. Quantitative microvascular permeability characteristics estimated from macromolecular CM-enhanced data were significantly superior to those derived from small-molecular CM-enhanced data.

Role of slowed Ca(2+) transient decline in slowed relaxation during myocardial ischemia.

The goal of this study was to test the hypothesis that during myocardial ischemia, slowing of the Ca(2+) transient decline causes slowed relaxation. Our approach was to monitor pressure and Ca(2+) transients in isovolumic rat hearts during control and low flow ischemia conditions. In addition, we experimentally slowed the decline of the Ca(2+) transient using cyclopiazonic acid (CPA) to inhibit the sarcoplasmic reticulum Ca(2+)-ATPase (SERCA, the most important pump for rapidly transporting Ca(2+) out of the cytosol). Using 9 microm CPA during normoxia, we were able to reproduce the slowed Ca(2+) transient decline and slowed relaxation found during low flow ischemia. The time constants of cytosolic [Ca(2+)] decline and pressure decline (tau(Ca) and tau(P) respectively) with CPA (78+/-5 ms and 64+/-3 ms) were similar to those found with ischemia (89+/-12 ms and 72+/-10 ms, mean+/-SEM, n=7) and were considerably greater than for controls (41+/-3 and 25+/-2 ms, mean+/-SEM, n=14, P<0.01). Furthermore, the relationship of tau(P) v tau(Ca) with CPA was similar to that found with ischemia. These findings are consistent with the hypothesis that the slowed Ca(2+) transient decline with both CPA and ischemia causes slowed relaxation. Consistent with this conclusion, a simple mathematical model to relate cytosolic [Ca(2+)] and pressure also suggests that slowed pressure relaxation can be explained by slowing of the Ca(2+) transient decline. This study suggests that impaired Ca(2+) uptake is a major injury causing slowed relaxation during ischemia.

Tumor blood volume assays using contrast-enhanced magnetic resonance imaging: regional heterogeneity and postmortem artifacts.

Tumor blood volume (BV), subject to both morphologic and physiologic influences, can be measured using contrast-enhanced magnetic resonance imaging (MRI). The aims of this study were to determine whether MRI enhanced with a macromolecular contrast medium (MMCM) could resolve differences in BV between different tumor types, between different regions within tumors, and within the same tumor in life and after death. Tumor BV estimates were based on the MRI signal intensity responses in the tumors and in reference venous blood following enhancement with a blood pool MMCM using two mammary adenocarcinoma models. Estimates of BV were made before and immediately following death. An in vitro measurement of tumor gadolinium concentration following death was correlated with MRI enhancement. Statistically significant differences (P < 0.05) were observed in MRI-estimated tumor BV between tumor subtypes, between in vivo and postmortem measurements, and between the tumor periphery and tumor centers. MRI assays enhanced with a macromolecular contrast agent can resolve blood volume differences between tumor types, between regions within the same tumor, and between vital and postmortem states.

Quantification of the extraction fraction for gadopentetate across breast cancer capillaries.

To quantify the extraction fraction, E, for gadopentetate across tumor capillaries, R3230 adenocarcinomas were implanted in the mammary fat pads of seven rats. The value of E was determined by using a two-compartment tissue model in which the endothelial transfer coefficient, K(PS) (ml x min(-1) x cc(-1) of tissue), was estimated from the model fitted to changes in R1 relaxation time (deltaR1; s(-1)) measured by dynamic three-dimensional spoiled gradient recalled magnetic resonance imaging after injection of 0.1 mmol x kg(-1) of gadopentetate dimeglumine. The plasma flow rate through the tumor capillaries, Fp, (ml x min(-1) x g(-1) of tissue), was independently measured with fluorescent microspheres. E could be calculated by the relationship, E = K(PS)/Fp. The mean E for gadopentetate in the R3230 tumor was 0.197 +/- 0.118 with a range of 0.123-0.454. The relatively small mean value of E for gadopentetate allows a fair approximation of the permeability surface area product by K(PS) in this R3230 tumor model.

Correlation of dynamic contrast-enhanced MR imaging with histologic tumor grade: comparison of macromolecular and small-molecular contrast media.

OBJECTIVE: The endothelial integrity of microvessels is disrupted in malignant tumors. Quantitative assays of tumor microvascular characteristics based on dynamic MR imaging were correlated with histopathologic grade in mammary soft-tissue tumors. MATERIALS AND METHODS: A spectrum of tumors, benign through highly malignant, was induced in 33 female rats by administration of N-ethyl-N-nitrosourea, a potent carcinogen. Dynamic contrast-enhanced MR imaging was performed using a small-molecular contrast medium (gadopentetate, molecular weight = 0.5 kDa) and a macromolecular contrast medium (albumin-(Gd-DTPA)30, molecular weight = 92 kDa) at an interval of 1-2 days. Permeability surface area product (PS), as estimated by the corresponding endothelial transfer coefficient (K(PS)), and fractional plasma volume (fPV) were calculated for each tumor and each contrast agent using a two-compartment bidirectional kinetic model. MR imaging microvascular characteristics were correlated with histopathologic tumor grade. RESULTS: Tumor permeability to macromolecular contrast medium, characterized by K(PS), showed a highly positive correlation with tumor grade (r2 = .76, p < 10(-10)). K(PS) values were zero for all benign and some low-grade carcinomas, greater than zero in all other carcinomas, and increased in magnitude with higher tumor grade. A considerably smaller but significantly positive correlation was found between fPV and tumor grade using macromolecular contrast medium (r2 = .25, p < .003). No correlation between K(PS) or fPV values and tumor grade was found using gadopentetate (r2 = .01, p > .95 and r2 = .03, p > .15, respectively). CONCLUSION: Quantitative tumor microvascular permeability assays generated with macromolecular MR imaging contrast medium correlate closely with histologic tumor grade. No significant correlation is found using small-molecular gadopentetate.

Correlation of dynamic contrast-enhanced magnetic resonance imaging with histologic tumor grade: comparison of macromolecular and small-molecular contrast media.

BACKGROUND: The endothelial integrity of microvessels is disrupted in malignant tumors. Quantitative assays of tumor microvascular characteristics based on dynamic magnetic resonance imaging (MRI) were correlated with histopathologic grade in mammary soft tissue tumors. MATERIALS AND METHODS: A spectrum of tumors, benign through highly malignant, was induced in 33 female rats by administration of N -ethyl-N -nitrosourea (ENU), a potent carcinogen. Dynamic contrast-enhanced MRI was performed using a small-molecular contrast medium [gadopentetate, MW = 0.5 kDa] and a macromolecular contrast medium [albumin-(Gd-DTPA)30, MW = 92 kDa] at an interval of 1-2 days. Permeability surface area product (PS), as estimated by the corresponding endothelial transfer coefficient (KPS), and fractional plasma volume (fPV) were calculated for each tumor and each contrast agent using a two-compartment bi-directional kinetic model. MRI microvascular characteristics were correlated with histopathologic tumor grade. RESULTS: Tumor permeability to macromolecular contrast medium, characterized by KPS, showed a highly positive correlation with tumor grade (r 2 = 0.76, P < 10(-10)). KPS values were zero for all benign and some low-grade carcinomas, greater than zero in all other carcinomas, and increased in magnitude with higher tumor grade. A considerably smaller but significantly positive correlation was found between fPV and tumor grade using macromolecular contrast medium (r 2 = 0.25, P < 0.003). No correlation between KPS or fPV values and tumor grade was found using gadopentetate (r 2 = 0.01, P > 0.95 and r2 = 0.03, P > 0.15, respectively). CONCLUSION: Quantitative tumor microvascular permeability assays generated with macromolecular MRI contrast medium correlate closely with histologic tumor grade. No significant correlation is found using small-molecular gadopentetate.