Microvascular permeability to macromolecules in human melanoma xenografts assessed by contrast-enhanced MRI--intertumor and intratumor heterogeneity.

Several novel macromolecular anticancer agents have fallen short of expectations owing to inadequate and heterogeneous uptake in tumor tissue. In the present work, contrast-enhanced magnetic resonance imaging was used to measure the intertumor and intratumor heterogeneity in the effective microvascular permeability constant, P(eff), of an 82 kDa macromolecule in an attempt to identify possible causes of the inadequate and heterogeneous uptake. Tumors of two human melanoma xenograft lines (A-07 and R-18) were included in the study. Human serum albumin with 30 gadopentetate dimeglumine units per molecule was used as a model molecule of macromolecular therapeutic agents. P(eff) was measured in manually defined regions of interest, corresponding to a whole tumor (ROI(WHOLE)) or to subregions of a tumor (ROIs(SUB)). The P(eff) of the ROI(WHOLE) of individual tumors ranged from 1.4 x 10(-7) cm/s to 2.8 x 10(-7) cm/s (A-07) and from 7.7 x 10(-8) cm/s to 3.2 x 10(-7) cm/s (R-18). P(eff) decreased with increasing tumor volume in R-18, but was independent of tumor volume in A-07. The intratumor heterogeneity in P(eff) exceeded the intertumor heterogeneity in both tumor lines. Some ROIs(SUB) showed P(eff) values that were similar to or slightly higher than the P(eff) values of albumin in normal tissues. Our observations suggest that inadequate and heterogeneous uptake of macromolecular therapeutic agents in tumor tissue is partly a result of low and heterogeneous microvascular permeability. However, the microvascular wall is probably not the major transport barrier to macromolecules in A-07 and R-18 tumors, as most individual tumors and individual tumor subregions showed high P(eff) values, i.e. values that are up to 10-fold higher than those of normal tissues.

[1]  C S Patlak,et al.  Methods for Quantifying the transport of drugs across brain barrier systems. , 1981, Pharmacology & therapeutics.

[2]  H. Maeda,et al.  A new concept for macromolecular therapeutics in cancer chemotherapy: mechanism of tumoritropic accumulation of proteins and the antitumor agent smancs. , 1986, Cancer research.

[3]  R K Jain,et al.  Delivery of Molecular Medicine to Solid Tumors , 1996, Science.

[4]  M Recht,et al.  Method for the quantitative assessment of contrast agent uptake in dynamic contrast‐enhanced MRI , 1994, Magnetic resonance in medicine.

[5]  E. Rofstad,et al.  Vascular structure of five human malignant melanomas grown in athymic nude mice. , 1982, British Journal of Cancer.

[6]  F. Starr,et al.  Measurement of blood‐brain barrier permeability in a tumor model using magnetic resonance imaging with gadolinium‐dtpa , 1992, Magnetic resonance in medicine.

[7]  R K Jain,et al.  Vascular permeability and microcirculation of gliomas and mammary carcinomas transplanted in rat and mouse cranial windows. , 1994, Cancer research.

[8]  D M Shames,et al.  Comparison of albumin‐(Gd‐DTPA)30 and Gd‐DTPA‐24‐cascade‐polymer for measurements of normal and abnormal microvascular permeability , 1997, Journal of magnetic resonance imaging : JMRI.

[9]  G A Dahle,et al.  Intratumor heterogeneity in perfusion in human melanoma xenografts measured by contrast-enhanced magnetic resonance imaging. , 2000, Magnetic resonance imaging.

[10]  R. Jain,et al.  Regulation of transport pathways in tumor vessels: role of tumor type and microenvironment. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[11]  L. M. Cobb Intratumour factors influencing the access of antibody to tumour cells , 2004, Cancer Immunology, Immunotherapy.

[12]  C S Patlak,et al.  Graphical Evaluation of Blood-to-Brain Transfer Constants from Multiple-Time Uptake Data , 1983, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[13]  H Lyng,et al.  Magnetic resonance imaging of human melanoma xenografts in vivo: proton spin-lattice and spin-spin relaxation times versus fractional tumour water content and fraction of necrotic tumour tissue. , 1994, International journal of radiation biology.

[14]  H. Lyng,et al.  Measurement of perfusion rate in human melanoma xenografts by contrast‐enhanced magnetic resonance imaging , 1998, Magnetic resonance in medicine.

[15]  E. Rofstad,et al.  Interstitial fluid pressure and capillary diameter distribution in human melanoma xenografts. , 1999, Microvascular research.

[16]  W. Perl Convection and permeation and albumin between plasma and interstitium. , 1975, Microvascular research.

[17]  E. M. Renkin Multiple pathways of capillary permeability. , 1977, Circulation research.

[18]  R. Jain,et al.  Role of extracellular matrix assembly in interstitial transport in solid tumors. , 2000, Cancer research.

[19]  E. Rofstad,et al.  Macromolecule uptake in human melanoma xenografts. relationships to blood supply, vascular density, microvessel permeability and extracellular volume fraction. , 2000, European journal of cancer.

[20]  T. Danielsen,et al.  Hypoxia-induced angiogenesis and vascular endothelial growth factor secretion in human melanoma. , 1998, British Journal of Cancer.

[21]  H Lyng,et al.  Vascular density in human melanoma xenografts: relationship to angiogenesis, perfusion and necrosis. , 1998, Cancer letters.

[22]  D M Shames,et al.  A MRI spatial mapping technique for microvascular permeability and tissue blood volume based on macromolecular contrast agent distribution , 1997, Magnetic resonance in medicine.

[23]  E. Rofstad,et al.  Orthotopic human melanoma xenograft model systems for studies of tumour angiogenesis, pathophysiology, treatment sensitivity and metastatic pattern. , 1994, British Journal of Cancer.