Comparison of cytosine arabinoside delivery to rat brain by intravenous, intrathecal, intraventricular and intraparenchymal routes of administration.

We evaluated the delivery of 14C-cytosine arabinoside (AraC) to rat brain by: 1) intravenous (IV) bolus, by 2) intrathecal (IT) and 3) intraventricular (IVT) infusion, and by 4) convection-enhanced delivery (CED) into the caudate nucleus. Plasma and brain AraC metabolites were measured with HPLC, and distribution and concentration of 14C-AraC in brain sections were measured by quantitative autoradiography. After IV administration, the alpha and beta plasma half-lives were 1.9 and 46.5 min, respectively. The blood-to-brain transfer constant of AraC was 2.5+/-1.4 microliter g(-1) min(-1), compatible with high water solubility. After IT and IVT administration, tissue levels were high at the brain and ventricular surfaces, but declined exponentially into brain. After CED, maximum brain levels were up to 10,000 times higher than the IV group, and the distribution pattern was one of high 14C-AraC concentration in the convective component, with exponentially declining concentrations outside this region. The rate loss constant from brain was 0.002+/-0.0004 min(-1), suggesting that AraC was accumulating in brain cells. AraC was metabolized into uracil arabinoside within the brain. 14C-AraC was infused into 1 dog and distributed widely in the ipsilateral hemisphere. These studies suggest that delivery of AraC to brain parenchyma by the IV, IT or IVT routes will be subtherapeutic. Delivery by CED can achieve, and maintain, therapeutic levels of AraC in the brain, and should be further evaluated as a potential method of drug delivery.

The blood-brain and blood-tumor barriers: a review of strategies for increasing drug delivery.

Drug delivery to brain tumors has been a controversial subject. Some believe the blood-brain barrier is not important, while others believe it is the major obstacle in treatment and have devised innovative approaches to circumvent it. These approaches can be divided into two categories: those that attempt to increase drug delivery of intravascularly administered drugs by manipulating either the drugs or capillary permeability, and those that attempt to increase drug delivery by local administration. Several strategies have been developed to increase the fraction of intravascular drug reaching the tumor, including intra-arterial administration, barrier disruption, new ways of packaging drugs, and, most recently, inhibiting drug efflux from tumor. When given intravascularly, all drugs have a common drawback: the body acts as a sink, and, even in the best situations, only a small fraction of administered drug actually reaches the tumor. A consequence is that systemic toxicity is usually the dose-limiting factor. When given locally, such as into the cerebrospinal fluid or directly into the tumor, 100% of an administered dose is delivered to the target site. However, local delivery is associated with variable and unpredictable spatial distribution and variation in drug concentration. The major dose-limiting factor of most local delivery methods will be neurotoxicity. The relative advantages and disadvantages of the different methods of circumventing the blood-brain barrier are presented in this review, and special attention is given to convection-enhanced delivery, which has particular promise for the local delivery of large therapeutic agents such as monoclonal antibodies, antisense oligonucleotides, or viral vectors.

Microvessel organization and structure in experimental brain tumors: microvessel populations with distinctive structural and functional properties.

We studied microvessel organization in five brain tumor models (ENU, MSV, RG-2, S635cl15, and D-54MG) and normal brain, including microvessel diameter (LMVD), intermicrovessel distance (IMVD), microvessel density (MVD), surface area (S(v)), and orientation. LMVD and IMVD were larger and MVD was lower in tumors than normal brain. S(v) in tumors overlapped normal brain values and orientation was random in both tumors and brain. ENU and RG-2 tumors and brain were studied by electron microscopy. Tumor microvessel wall was thicker than that of brain. ENU and normal brain microvessels were continuous and nonfenestrated. RG-2 microvessels contained fenestrations and endothelial gaps; the latter had a maximum major axis of 3.0 microm. Based on anatomic measurements, the pore area of RG-2 tumors was estimated at 7.4 x 10(-6) cm(2) g(-1) from fenestrations and 3.5 x 10(-5) cm(2) g(-1) from endothelial gaps. Increased permeability of RG-2 microvessels to macromolecules is most likely attributable to endothelial gaps. Three microvessel populations may occur in brain tumors: (1) continuous nonfenestrated, (2) continuous fenestrated, and (3) discontinuous (with or without fenestrations). The first group may be unique to brain tumors; the latter two are similar to microvessels found in systemic tumors. Since structure-function properties of brain tumor microvessels will affect drug delivery, studies of microvessel function should be incorporated into clinical trials of brain tumor therapy, especially those using macromolecules.

Absence of host-site influence on angiogenesis, blood flow, and permeability in transplanted RG-2 gliomas.

The host site is believed to regulate tumor angiogenesis, which could result in site-dependent drug delivery parameters, greatly affecting experimental tumor research. In RG-2 rat gliomas we measured cellular proliferation; cell cycle time was the same for RG-2 cells in brain and s.c. tumors (25 h), and was the same for endothelial cells in these tumors (46 h). We measured the transcapillary transfer constant (K) of alpha-aminoisobutyric acid and blood flow (F) with iodoantipyrine in RG-2 gliomas transplanted into brain, liver, kidney, muscle, s.c. tissue, and into the abdominal cavity. Data was evaluated by quantitative autoradiography and direct tissue sampling. The variation of F (12.6-84.0 ml/g/min) and K (26.1-49.2 microl/g/min) in RG-2 tumors in the different host sites was less than in surrounding tumor-free tissue (F = 20-1500 ml/g/min and K = 1.6-700 microl/g/min). In contrast to other models, RG-2 does not result in tumors with host site-dependent behavior. The RG-2 tumor cells appear to participate in, if not dominate, the angiogenesis process regardless of the host site. Values of F and K were more dependent on tumor topography (center versus periphery) and local histological features (necrosis versus viable tumor) than host site. We believe that the methods used for data acquisition may introduce as much variability in Results as the tumors themselves and that to better understand how tumor angiogenesis affects the vascular phenotype, comparative studies are needed to validate the results obtained with newer methodologies.

Comparison of 14C-sucrose delivery to the brain by intravenous, intraventricular, and convection-enhanced intracerebral infusion.

OBJECT: The authors evaluated convection-enhanced delivery (CED) of 14C-sucrose to the rat brain as a method of enhancing cerebral drug delivery and compared it with intravenous (i.v.) and intraventricular (i.v.t.) routes of administration. METHODS: Groups of rats received 14C-sucrose by bolus i.v. infusion, i.v.t. infusion for 1, 2, or 7 days at 0.17 microl/minute, or CED at rates from 0.01 to 0.5 microl/minute for periods from 1 hour to 7 days. Radioisotope distribution and concentration in tissue were analyzed using quantitative autoradiography. Intravenously administered sucrose reached the entire brain, but levels in tissue were low. After i.v.t. administration, sucrose levels in tissue were high at, and declined exponentially away from, the ventricular surface. Chronic CED administration maintained high levels of sucrose in tissue that focally were up to 10,000 times higher than in the i.v. group. The isotope distribution pattern after chronic CED infusions indicated a central component that resulted from convention and a peripheral component in gray matter that was the result of diffusion. The brain influx (0.42 microl/g/min) and diffusion constants of sucrose (2.8 x 10(-6) cm2/second) were similar to reported values. The total brain efflux constant was 0.0044 minute, whereas the blood-brain barrier (BBB) efflux constant was 0.0016 minute. There were no pathological changes in the brains after CED except those associated with cannula insertion. Sucrose, which was thought to be inert, was found to interact with brain tissue; up to 25% was bound to an unidentified tissue component. CONCLUSIONS: Chronic CED appears to be a potentially useful method for significantly circumventing the BBB and increasing delivery of water-soluble drugs to the brain.

The blood-brain barrier in primary CNS lymphomas: ultrastructural evidence of endothelial cell death.

The vasculature of 24 primary CNS B-cell lymphomas that were not related to acquired immunodeficiency syndrome was systematically studied by electron microscopy. Seven low-grade astrocytic tumors were included for comparison. Classical electron microscopy features of apoptosis were found in lymphoma cells of 21 of 22 subjects. Capillaries of gliomas and lymphomas showed changes reported previously: variability of endothelial cell (EC)-thickness and number, basal lamina thickness and duplication, and fenestrations. Primary CNS B-cell lymphoma ECs showed two distinctive populations of electron-dense and electron-lucent cells. The electron-dense ECs occurred in 38% of all capillaries, with changes consisting of chromatin condensation in bizarre and contracted nuclei, cytoplasmic shrinkage with markedly increased electron density, and dilatation of the endoplasmic reticulum. We interpreted these changes as indicative of apoptosis. Cell death eventually resulted in complete disintegration of the endothelium with frank discontinuities of the EC component of the blood-tumor barrier in capillaries and postcapillary venules. Another population of ECs had increased cell volume, conspicuous cytoplasmic electron lucency, dispersed organelles, scattered vesicles, and apical stress fibers. We interpreted these changes as indicative of cellular regeneration. Individual apoptotic ECs often lay next to normal or regenerating ECs. Neither type of EC change was observed in gliomas, which also lacked perivascular neoplastic lymphocytic cuffing. We believe that these populations of ECs, which have not been described in other disorders affecting the blood-brain barrier, may be induced by cytokines released from necrotic and/or apoptotic tumor lymphocytes and may explain the unusual imaging characteristics of primary CNS B-cell lymphomas treated with corticosteroids.

Changes in blood-brain barrier permeability associated with insertion of brain cannulas and microdialysis probes.

Blood-brain barrier (BBB) transcapillary transport was studied after insertion of cannulas and microdialysis probes into the brains of three groups of rats. Quantitative autoradiography was used to measure changes in BBB permeability around the insertion site. In the first group, BBB function was measured with 14C-sucrose at times from immediately, and up to 28 days, after insertion of a microdialysis probe. BBB function was disrupted biphasically: a 19-fold increase in the influx constant (K1) of sucrose occurred immediately after insertion with a second 17-fold increase at 2 days, followed by a slow decline to 5 times normal values at 28 days. In the second group, 14C-dextran (70 kDa) was used to measure BBB transcapillary transport; K1 was increased 90-fold after probe insertion. In the 3rd group, 14C-AIB (alpha-aminoisobutyric acid) was used to evaluate BBB transport after insertion of a 27 gauge cannula, which was used to infuse 1 microliter of saline over 5 min. The K1 of AIB was increased 25 times control values. We conclude that BBB transcapillary transport function is disturbed in response to insertion of brain cannulas and/or microdialysis probes, that BBB dysfunction is maximal at the cannula or probe tip, varies with time after insertion, may persist for at least 28 days after insertion, and occurs over a wide molecular range of solutes. These results suggest caution when using microdialysis as a method to study normal BBB function, and suggest that microdialysis may overestimate the rate of transfer into and out of the brain.

Blood-brain barrier integrity in Alzheimer's disease patients and elderly control subjects.

A defective blood-brain barrier (BBB) has been postulated to be present in Alzheimer's disease (AD), which would allow circulating beta-amyloid peptide to enter the brain. The authors tested this hypothesis by studying BBB function in 14 individuals with probable AD and 9 elderly control subjects. A computed tomographic method was used to measure blood-to-brain transport (K1), tissue-to-blood efflux (k2), tissue plasma space (Vp), and tissue extracellular space (Ve) of meglumine iothalamate. Repeated-measures analysis of variance indicated no significant differences between the groups for any of the measures. The authors conclude that there is no generalized abnormality of the blood-brain barrier in AD.

The entry of antiviral and antiretroviral drugs into the central nervous system.

The ability of antiviral and antiretroviral drugs to enter the brain is a critical issue in the treatment of many viral brain diseases, including HIV-related neurologic disease. Much of the literature concerning nucleoside analog entry into the nervous system focuses on drug levels in the cerebrospinal fluid (CSF), equating these with drug levels in the brain extracellular fluid (ECF) as though the two compartments intermix freely. We review the anatomic and physiologic aspects of drug entry into CSF and into brain ECF, as well as the exchange processes between these two compartments. In most instances drug concentrations in the CSF and ECF compartments bear little relationship to one another and using CSF concentrations to extrapolate brain ECF concentrations may significantly overestimate the latter. Accepted terminology and methodology for making measurements of blood-brain barrier function are discussed. Studies of brain uptake that express results as brain:plasma ratios, or that have used microdialysis, may overestimate the amount of drug reaching the brain. Using published data, we present an estimate of the time course of Zidovudine (AZT) concentrations in brain ECF and show that brain concentrations of AZT will likely be below that necessary to inhibit HIV-1 replication when AZT is administered systemically. Antiviral nucleosides and oligonucleotides appear to have limited entry into the brain when given systemically, which may hinder therapy of viral brain diseases, while some of the protease inhibitors may enter the brain more readily. Alternative methods for increasing antiviral and antiretroviral drug delivery to brain are discussed.

The effects of dexamethasone on experimental brain tumors: I. Transcapillary transport and blood flow in RG-2 rat gliomas.

Dexamethasone dramatically improves cerebral edema associated with malignant gliomas. Although the pathophysiology of this effect is not clearly understood, many investigators have postulated that tumor capillary permeability is reduced by dexamethasone. We studied blood-to-tissue transport and blood flow in 178 RG-2 transplanted gliomas in a control group and four groups given dexamethasone at doses of 3, 6, 9, and 12 mg/kg for four days. 14C-alpha aminoisobutyric acid (AIB) was used to study blood-to-tissue transport in 31 animals; in an additional 27 animals 14C-AIB and 131I-iodoantipyrine (IAP) were used in double label experiments to study blood-to-tissue transport and blood flow. Regional measurements of the transfer constant (K) of AIB and blood flow (F) were made with quantitative autoradiography. There were significant differences between the control and dexamethasone-treated groups with regard to weight loss and plasma glucose. However, there was no significant effect of dexamethasone on values of K or F, regardless of the tumor or brain region examined, and regardless of the dose of dexamethasone administered. Analysis of the profiles of the transfer constant of AIB in the brain around tumor showed that the K of AIB decreased within 0.5 mm of the tumor edge in direct relationship to the dexamethasone dose. These results do not support the hypothesis that dexamethasone reduces brain tumor capillary permeability, and suggest that dexamethasone may decrease tumor-associated cerebral edema by effects on bulk flow away from the tumor margin.

The effects of dexamethasone on transcapillary transport in experimental brain tumors: II. Canine brain tumors.

We studied the effect of dexamethasone on transcapillary transport in ten Avian Sarcoma Virus (ASV)-induced canine brain tumors, before and one week after administration of dexamethasone, 2.5 mg/kg/day. A computed tomographic (CT) method was used to measure regional values of K1 (blood-to-tissue transfer constant), k2 (tissue-to-blood efflux constant), and Vp (tissue plasma vascular space) of meglumine iothalamate (Conray-60); the values were reconstructed for each 0.8 x 0.8 x 5 mm volume element of the CT data. For all tumors considered together, there was a decrease in the whole tumor K1 value of meglumine iothalamate from 26 +/- 2.2 (SE) before dexamethasone to 24 +/- 2.9 microliters/g/min after dexamethasone. Vp decreased from 7.2 +/- 0.7 to 6.7 +/- 0.9 ml/100 g, and the size of the tumor extracellular space (Ve) decreased from 0.30 to 0.26 ml/g. These changes were not statistically significant. However, when each tumor was used as its own control, K1 significantly decreased after dexamethasone in four tumors, significantly increased in two and was unchanged in four. These results suggest that decreased blood-to-tissue transport may be one mechanism underlying resolution of tumor associated cerebral edema in some brain tumors and that the effects of dexamethasone on blood-to-tissue transport in brain tumors are variable from one tumor to the next. Decreased 'permeability' may not be the sole mechanism by which dexamethasone reduces tumor-associated cerebral edema.

The effect of L-amino acid oxidase on activity of melphalan against an intracranial xenograft.

We have previously shown that diet restriction-induced depletion of large neutral amino acids (LNAAs) in murine plasma to 46% of control significantly enhances intracranial delivery of melphalan without enhancing delivery to other organs. Studies have now been conducted to determine whether more substantial LNAA depletion could further enhance intracranial delivery of melphalan. Treatment with L-amino acid oxidase (LOX) significantly depleted murine plasma LNAAs: phenylalanine, leucine, and tyrosine (> 95%); methionine (83%); isoleucine (70%); and valine (46%). Experiments evaluating the intracellular uptake of melphalan and high-pressure liquid chromatography quantitation of melphalan metabolites revealed, however, that melphalan is rapidly degraded in the presence of LOX, and that the timing of the administration of melphalan following the use of LOX to deplete LNAAs is crucial. Conditions were found under which LOX-mediated degradation of melphalan was minimized and LNAA depletion was maximized, resulting in a potentiation of the antitumor effect of melphalan on human glioma xenografts in nude mice. Such potentiation could not be obtained using diet restriction alone.

Noninvasive measurement of arterial blood plasma concentration of iodinated contrast agents from CT scans of human brain.

OBJECTIVE: Our goal was to assess the accuracy of estimating the time course of the arterial plasma concentration of meglumine iothalamate from cranial CT images of different vascular structures in the brain. MATERIALS AND METHODS: Dynamic CT studies of transcapillary transport in various brain lesions were analyzed. Vascular structures in the brain were identified and classified in three categories: arteries, veins, and venous sinuses. Systemic venous blood samples were taken prior to the infusion of meglumine iothalamate and 10 min after completion of the infusion and used as a calibration for the volume averaging fraction of the image of each vascular structure. A time course of plasma meglumine iothalamate concentration for each of the vascular categories in the CT images was obtained and compared with a variety of methods. RESULTS: Significant differences were found for measurement of plasma meglumine iothalamate concentration from different vascular categories. There was also a disparity between the volume averaging fraction that we calculated and what would be expected due to the measured systemic hematocrit for all vascular structures. CONCLUSION: The use of images of veins and venous sinuses consistently underestimated the arterial concentration around the peak values. Correcting the imaged venous sinus values with the measured systemic hematocrit was even less reliable. The most accurate method of determining arterial plasma concentration of meglumine iothalamate from CT images of brain was to correct the identified arterial vessels for volume averaging.

A new head holder for reducing axial movement and repositioning errors during physiological CT imaging.

OBJECTIVE: We designed a new head holder for immobilization and repositioning in dynamic CT studies of the brain. MATERIALS AND METHODS: A customized thermoplastic face mask and foam head rest were made to restrict movement of the head in all directions, but particularly out of the axial plane (z-movement). RESULTS: This design provided a rigid, detailed mold of the face and back of the head that minimized motion during lengthy CT studies and enabled accurate repositioning of the head for follow-up studies. Markers applied directly to the skin were used to quantify z-movement. CONCLUSION: When tested on 12 subjects, immobilization was limited to < 2.0 mm under worst-case conditions when the subject was asked to attempt forced movements. Repositioning was accurate to < 1.5 mm when the subject was removed from the head holder and then placed back into it.

Noninvasive CT determination of arterial blood concentration of meglumine iothalamate.

A quantity that often must be determined in physiological imaging studies is the blood concentration of the tracer over time. This is usually performed by direct arterial or venous blood sampling. We studied the relationship between the concentration of meglumine iothalamate in arterial blood and values determined from voxels containing large blood vessels in a series of CT images at the same location over time. After correction for volume averaging based on a single venous blood sample, there was an excellent correlation between the two blood curves. Differences between the curves were shown to be inconsequential by a simulation of transcapillary transport determinations. We thus conclude that determination of plasma concentration from CT images is a reliable technique for CT transcapillary transport studies.

The effect of an amino acid-lowering diet on the rate of melphalan entry into brain and xenotransplanted glioma.

Melphalan (L-phenylalanine mustard, L-PAM, alkeran; molecular weight, 305,000) is transported across tumor cell membranes and the blood-brain barrier by the large neutral amino acid (LNAA) transport system. Normally, plasma LNAA levels are high enough and the affinity low enough that this system does not transport much melphalan into the brain. However, plasma amino acids can be reduced by fasting and protein-free diet. We used this method to reduce competition and to increase melphalan transport into brain tumors. In nude mice fasted for 12 h and then fed a protein-free diet for 2 and 6 h, mean plasma LNAA levels were 46% and 42% of control values. Nude mice with xenotransplanted D-54MG human gliomas were used to study tissue distribution and uptake kinetics of [3H]melphalan in a control group and a diet group (after a 12-h fast and 2 h of a 0% protein diet). The K1 (blood-to-tissue transfer constant) of melphalan, determined by graphical analysis and by nonlinear fitting to a 2-compartment model, was higher in the diet group in all tumor regions except the necrotic center of subcutaneous tumors; the increase was significant in the tumor periphery of brain and s.c. tumors. The ratio of K1s (diet to control) varied from 1.2 to 1.3 in brain tumors, 1.9 to 2.1 in subcutaneous tumors, and 1.8 to 3.1 in tumor-free brain. The apparent [3H]melphalan distribution space was significantly higher in the tumor periphery of both brain and subcutaneous tumors of the 15- and 30-min diet group. We also measured blood-brain barrier transport of [alpha-14C]aminoisobutyric acid and blood flow (with [131I]iodoantipyrine): the K1 of [alpha-14C]aminoisobutyric acid was 28.1 +/- 6.6 (SE) in brain tumors and 24.3 +/- 8.9 microliters/g/min in subcutaneous tumors. Blood flow was 58.2 --> 3.9 in brain tumors and 5.2 +/- 0.4 ml/100 g/min in subcutaneous tumors. Fasting, when combined with a protein-free diet, reduces plasma amino acid levels and thereby reduces competition between melphalan and LNAAs. This may increase the amount of melphalan that can enter a brain tumor without increasing the administered drug dose and suggests a therapeutic manipulation that can be used to increase the delivery of melphalan.

Blood flow and blood-to-tissue transport in 9L gliosarcomas: the role of the brain tumor model in drug delivery research.

We used double-label quantitative autoradiography to measure blood flow (with 131I-iodoantipyrine) and blood-to-tissue transport of 14C-alpha aminoisobutyric acid, AIB) in thirteen 9L gliosarcomas transplanted intracerebrally into Fischer-344 rats. Microscopically, the typical pattern of 9L tumor growth was observed: a solid central tumor mass surrounded by extensive perivascular invasion. The averaged mean whole tumor transfer constant, K, of AIB in the 9L tumors was 33 +/- 15 (+/- SD) microliters/g/min. The averaged mean value of blood flow, F, was 72.2 +/- 27.3 ml/100 g/min. In brain around tumor (BAT), K (13 +/- 4 microliters/g/min) was lower than in the solid tumor, but was still 6-9 times that of tumor-free brain. F in BAT (115.9 +/- 64.6 ml/100 g/min) was comparable to values in tumor-free cortex in the same hemisphere. Values of K and F were used to calculate a net extraction fraction (En) for different regions of brain and tumor. The value of En of AIB in normal cortex was 0.003, in BAT En was 0.02, and in whole tumor the value was 0.09. The delivery of water-soluble compounds in 9L brain tumors is limited by the permeability/surface area characteristics of the tumor capillaries. The properties of blood-to-tissue transport and blood flow of 11 different brain tumor models are compared, and discussed with regard to the choice of brain tumor models for drug delivery research. The 9L brain tumor model is comparable to other transplanted rat brain tumor models, although the extent of tumor cell invasion into BAT makes this model distinctive. However, with regard to blood-to-tissue transport the 9L model differs from autochthonous models and transplanted human glioma models. We discuss guidelines for selecting brain tumor models with which to study the problem of drug delivery to brain tumors.

A method to quantitatively measure transcapillary transport of iodinated compounds in canine brain tumors with computed tomography.

We present a quantitative method for determining a blood-to-tissue influx constant (K1), a tissue-to-blood efflux constant (k2), and tissue plasma vascular space (Vp) that uses a computed tomographic (CT) scanner to make tissue and plasma measurements of the concentration of an iodinated compound. Meglumine iothalamate was infused intravenously over time periods of 0.5-5 min, up to 49 CT scans were obtained at one brain level, and arterial plasma was sampled over a 30- to 40-min period. K1, k2, and Vp were calculated for each voxel of the 320 x 320 matrix, using a two-compartment pharmacokinetic model and nonlinear least-squares regression. The method was used in dogs with avian sarcoma virus-induced brain tumors. As many as four studies on different days were done in the same animal. In tumor-free cortex, K1 of meglumine iothalamate was 2.4 +/- 1.7 microliter g-1 min-1 (mean +/- SD) and Vp was 3.4 +/- 0.5 ml 100 g-1. Mean whole-brain tumor K1 values ranged from 3.3 to 97.9 microliters g-1 min-1; k2 ranged from 0.032 to 0.27 min-1; and Vp ranged from 1.1 to 11.4 ml 100 g-1. These values were reproducible in serial experiments in single animals. Independent verification of K1 values was obtained with quantitative autoradiographic measurements of alpha-aminoisobutyric acid, which has similar physicochemical properties to meglumine iothalamate. The CT methodology is capable of demonstrating regional variation of transcapillary transport in brain tumors and may be of value in the study of human brain tumors.

Quantitative measurements of capillary transport in human brain tumors by computed tomography.

The rate at which water-soluble chemotherapeutic drugs enter brain tumors can be extremely variable. The ability to measure or predict the rate of drug entry may have an important role in treatment. We have developed a method that uses information from contrast-enhanced computed tomographic scans to measure quantitatively the rate of transcapillary transport of iodinated compounds in brain tumors. In a group of 10 patients with brain tumors, we obtained serial measurements of tissue (Am) and arterial plasma (Cp) iodine concentration from timed computed tomographic scans done over 30 minutes, after intravenous infusion of meglumine iothalamate (Conray-60). These measurements were analyzed with a two-compartment pharmacokinetic model and nonlinear least-squares regression methods to obtain K1, a blood-to-tissue transfer constant; k2, a tissue-to-blood rate constant; and Vp, tissue plasma vascular volume. Images of K1, k2, and Vp were reconstructed after calculating these values for each 0.8 x 0.8 x 5-mm volume element of the original data. Mean whole tumor K1 values varied from 2.0 mu 1 gm-1 min-1 in a thalamic astrocytoma to 33.9 mu 1 gm-1 min-1 in a glioblastoma multiforme. The value of k2 varied from 0.034 to 0.108 min-1, and Vp varied from 2.4 to 7.9 ml 100 gm-1. In tumor-free brain, the K1 of meglumine iothalamate was 2.9 mu 1 gm-1 min-1; k2 was 0.058 min-1; and Vp was 2.1 ml 100 gm-1.(ABSTRACT TRUNCATED AT 250 WORDS)

Potential errors due to aliasing in digital video analysis of quantitative autoradiography.

Digital image analysis of quantitative autoradiographic (QAR) films is widely used in neuroscience applications. Unless proper precautions are taken when autoradiographic images are converted to digital form they can be inadvertently modified by improper application of the sampling process. This type of modification is termed aliasing error and can cause nonexistent structures to appear in the reconstructed digital image, changing the apparent optical density values of the data. The theoretical basis of aliasing error is presented, along with examples of aliasing from optical resolution test patterns and 2-deoxy[14C]glucose (2-DG) experimental QAR images. We show that aliasing can change the apparent shape of structures, as well as the derived values obtained from QAR experiments. In an example with experimental 2-DG images, aliasing in the cerebellar cortex consistently underestimates tissue radioactivity levels in gray matter (P less than 0.001) and overestimates levels in adjacent white matter (P less than 0.001). Additional data transformations, such as the equations used for blood flow or glucose utilization, can, somewhat unpredictably, accentuate the errors introduced by aliasing. We present a discussion of the autoradiographic image features and electronic design that play a role in introducing aliasing errors and means by which aliasing can be recognized and minimized.