Effect of blood-brain barrier and blood-tumor barrier modification on central nervous system liposomal uptake.

In this study of 25 central nervous system (CNS) tumor-bearing rats, the CNS biodistribution of intravenously administered, indium-labeled liposomes was investigated. In 16 animals, the blood-brain barrier and blood-tumor barrier were modified using intracarotid administration of etoposide. In control animals, analysis by autoradiography and well-counting experiments demonstrated uptake of liposomes in the tumor-bearing hemisphere (% injected dose/g tissue = 0.135) with minimal uptake in the non-tumor-bearing hemisphere (% injected dose/g tissue = 0.007), p < 0.01. Unilateral intracarotid etoposide administration enhanced liposome uptake in both hemispheres-0.215 and 0.023 (tumor-bearing and nontumor-bearing), respectively. The presence of meningeal tumor involvement in nontumor-implanted hemispheres increased liposomal uptake 10-fold. These findings may have clinical applicability in designing therapeutic protocols for the treatment of CNS tumors.

Systemic biodistribution of radioiodinated interleukin-2 in the rat.

Interleukin-2 (IL-2) is a lymphokine capable of modulating a variety of immune functions. In vitro and in vivo studies have shown promising cytotoxic potential. Despite numerous ongoing clinical trials, however, little is known about the biodistribution of this lymphokine after in vivo administration. In this study using a rat model, the fate of radioiodinated human recombinant IL-2 (RIL-2) was analyzed by camera imaging, autoradiography, and well counting experiments. Camera imaging demonstrated the liver and kidney to be the organs of greatest radioactivity accumulation with peak liver uptake noted at approximately 10 min from onset of infusion, and peak kidney uptake at approximately 20 min. Autoradiographic assessment of selected organs (kidney, adrenal, liver, lung, and brain) revealed marked heterogeneity of uptake in the kidney and adrenal gland with preponderance of RIL-2 in the cortex of these organs. A more homogeneous distribution of RIL-2 uptake was noted in liver, lung, and brain parenchyma. Well counting confirmed the liver and kidney as the organs of greatest RIL-2 accumulation. Knowledge of the biodistribution of IL-2 may be of benefit both in studying mechanisms of toxicity and in designing novel therapeutic approaches.

Effects of etoposide-induced blood-brain barrier disruption on brain water, intracranial pressure, and cerebral vasomotor tone.

This study investigated the effects of hypertension and water loading on etoposide-induced, reversible blood-brain barrier disruption in a rat model. Twenty-nine animals were divided into four groups: group 1--intracarotid (i.c.) injection of saline followed in 1 h by 5 ml i.c. water; group 2--i.c. etoposide followed by i.c. water; group 3--i.c. saline followed by i.v. metaraminol to increase systemic blood pressure; group 4--i.c. etoposide followed by i.v. metaraminol. Systemic blood pressure and intracranial pressure were monitored continuously. Evans blue staining of the brain was used as a monitor of blood-brain barrier disruption. Animals were killed 1 h after either aramine or water infusion, and the brains removed and inspected for the degree of disruption. After dehydration, brain water was calculated for each hemisphere. Two-thirds of the animals infused with etoposide had evidence of barrier disruption, whereas none of the control animals infused with saline were disrupted. Neither control groups 1 or 3 showed significant change in intracranial pressure after water loading or augmentation of systemic blood pressure, respectively. Group 4 animals failed to demonstrate any significant change in intracranial pressure despite marked barrier disruption and acute hypertension (within the limits of normal autoregulation). A small but statistically significant increase in intracranial pressure was noted in group 2 animals with the greatest degree of barrier disruption. A significant increase in brain water was observed ipsilateral to etoposide infusion in only those animals with the most marked barrier disruption. These results indicate that etoposide-induced blood-brain barrier disruption caused significant increases in brain water without significant alteration of cerebral vasomotor tone or increases in intracranial pressure after water loading except in the most severe disruption. The classic untoward consequences of vasogenic edema were not encountered in the present model.

Physiological and electrophysiological consequences of etoposide-induced blood-brain barrier disruption.

The present study investigates the effects of etoposide-induced blood-brain barrier (BBB) disruption on systemic blood pressure (SBP), intracranial pressure (ICP), and electroencephalographic (EEG) activity. A total of 29 rats were divided into two groups. In Group 1, 8 control animals received intracarotid normal saline; in Group 2, 21 animals received intracarotid etoposide. SBP, ICP, and EEG were monitored continuously under general anesthesia and controlled ventilation after tracheostomy. Intravenous Evans blue dye was used for determination of BBB disruption. Although none of the Group 1 animals showed BBB disruption, 57% of the animals in Group 2 showed marked BBB disruption (3+). A slight but statistically significant increase in ICP was noted in the Group 2 animals with 3+ BBB disruption, although lesser degrees of barrier disruption (1+ or 2+) resulted in no significant alteration in ICP. The amplitude and frequency of the EEG decreased significantly ipsilateral to the side of intracarotid infusion in all animals with 3+ barrier disruption with a tendency to return toward normal within 2 hours. The degree of transient EEG change observed correlates well with the degree of barrier disruption, potentially allowing clinical determination of BBB disruption by this method.

Isolated central nervous system metastasis from transitional cell carcinoma of the bladder: report of a case and review of the literature.

Although systemic metastases from transitional cell carcinoma of the bladder occur frequently, involvement of the central nervous system is uncommon. We describe a patient with an isolated cerebral metastasis who had previously undergone resection of a Grade III, Stage B2 carcinoma of the bladder. We have been able to find only one previous case report of a solitary intracerebral metastasis from transitional cell carcinoma of the bladder without evidence of primary recurrence or additional sites of spread. Central nervous system metastasis from bladder carcinoma must be considered in the differential diagnosis of solitary intracerebral lesions.

Etoposide induced blood-brain barrier disruption in rats: duration of opening and histological sequelae.

The intracarotid infusion of the antineoplastic compound etoposide enhances blood-brain barrier (BBB) permeability. In a rat model system, the functional reversibility and anatomic sequelae of etoposide induced BBB disruption were investigated. Etoposide, in a dose range from 3.0 to 22.5 mg/kg, was infused into the left internal carotid artery of Sprague-Dawley rats. BBB disruption was evaluated by the appearance in the infused hemisphere of systemically administered Evans blue dye and quantitatively by the ratio of counts of the technetium labeled chelate of diethylenetriaminepentaacetic acid in the infused to the noninfused hemisphere. Functional reversibility of altered BBB permeability was investigated at three dose levels of etoposide (3.0, 15.0, and 22.5 mg/kg) by the administration of Evans blue dye at the time of etoposide infusion and the administration of the technetium labeled chelate of diethylenetriamine-pentaacetic acid at varying time intervals after etoposide infusion. Fourteen groups of 12 rats each were studied to define the time course of altered BBB permeability at these three doses. The anatomic sequelae of etoposide induced BBB disruption were investigated at varying time intervals (up to 3 weeks) after intracarotid etoposide infusion. Nineteen rats were examined after sacrifice by intracardiac fixation perfusion with 10% formalin. Each brain was sectioned coronally and examined under light microscopy after hematoxylin and eosin staining. Evidence of BBB disruption was seen at all dose levels of etoposide. The degree of BBB disruption increased with increasing doses of etoposide. The duration of altered BBB permeability increased from less than 1 day at 3.0 mg/kg to between 3 and 4 days at 22.5 mg/kg. Histological studies revealed no evidence of parenchymal damage, although at 4 days postdisruption, a mild perivascular lymphocytic infiltration was noted in the infused hemisphere. Etoposide infusion and subsequent BBB disruption were well tolerated by all test animals. In a rat model system the intracarotid infusion of etoposide is capable of producing prolonged reversible BBB disruption.

The protective effect of experimental subarachnoid haemorrhage on sodium dehydrocholate-induced blood-brain barrier disruption.

The potential interactive effects between subarachnoid hemorrhage (SAH) and blood brain barrier (BBB) disruption were studied in a rat model. Experimental subarachnoid hemorrhage was produced in twenty rats (experimental group) by the intracisternal injection of blood. In ten additional rats (control group), saline was administered in place of blood. Analysis of mean blood pressure (MBP), intracranial pressure (ICP) and cerebral perfusion pressure (CPP) demonstrated an increase in ICP and MBP and a drop in CPP in all animals following intracisternal injection. Subsequent infusion of the left internal carotid artery with sodium dehydrocholate resulted in blood-brain barrier (BBB) disruption in both groups as evidenced by Evans blue staining of the infused cortex. The extent of BBB disruption was significantly greater in the control group than the experimental group. Analysis of the experimental group demonstrated that animals with the lowest pre-SAH MBP and the lowest CPP during the maximum blood pressure response to SAH demonstrated the greatest resistance to experimental BBB disruption. The possibility of ischemia as a contributing factor in BBB protection subsequent to SAH is discussed.

Electroencephalographic consequences of sodium dehydrocholate-induced blood-brain barrier disruption: Part 1. Acute and chronic effects of intracarotid sodium dehydrocholate.

Prior work has shown that the intracarotid infusion of sodium dehydrocholate can produce prolonged reversible blood-brain barrier (BBB) disruption. Associated with barrier disruption is the occasional presence of behavioral seizure activity. Electroencephalographic changes were monitored in 32 rats after BBB disruption by the left internal carotid artery infusion of sodium dehydrocholate. The electroencephalogram (EEG) was monitored for 3 hours after disruption in 20 animals, and the remaining 12 animals were followed for 24 hours. The EEG was also monitored in 8 additional control animals: 4 had undergone carotid artery infusion with normal saline, and 4 had received sodium dehydrocholate intravenously. The 20 rats monitored for up to 3 hours postinfusion were found to have varying grades of BBB disruption as measured by the presence of Evans blue staining of the brain. EEG alterations in this group included decreased amplitude and slowing as well as the presence of spike activity over the disrupted and the nondisrupted hemispheres. The more extensive the disruption, the more severe the EEG changes. In animals with minimal to moderate disruption, the EEG usually returned to base line levels within 3 hours after infusion. Animals with marked disruption usually had bilaterally flat EEGs before the end of the observation period. The remaining 12 animals were followed for 24 hours postinfusion. Of 9 animals surviving 24 hours, 1 animal had a decrease in amplitude over the disrupted hemisphere; in the remaining 8 animals, the spontaneous EEG was unchanged from predisruption levels except for occasional spikes in 2 animals. Animals infused with intracarotid saline or intravenous sodium dehydrocholate demonstrated no EEG changes or Evans blue staining.(ABSTRACT TRUNCATED AT 250 WORDS)

Electroencephalographic consequences of sodium dehydrocholate-induced blood-brain barrier disruption: Part 2. Generation and propagation of spike activity after the topical application of sodium dehydrocholate.

Sodium dehydrocholate was applied topically to the right hemispheric cortex of eight rats and the electrocorticogram was monitored from both the treated cortex and the homotopic cortex of the contralateral hemisphere. All animals developed blood-brain barrier (BBB) disruption in the treated cortex as evidenced by cortical staining with systemically administered Evans blue dye. Spike activity developed in three of eight animals after the topical application of dehydrocholate. The subsequent intravenous injection of sodium dehydrocholate provoked spike activity in both hemispheres in all eight animals. Dependent and independent spike activity was recorded in the nondisrupted hemisphere. The intravenous administration of gamma-aminobutyric acid (GABA) resulted in alterations in spike activity in four of five animals because of penetration of the GABA through the altered BBB. These findings demonstrate that sodium dehydrocholate can result in increased BBB permeability when applied directly to the cortical surface. Spike activity subsequent to the topical application of dehydrocholate can be enhanced by systemic loading with dehydrocholate. Spike activity occurring over the nontreated cortex (secondary focus) represents interhemispheric propagation of spike activity from the disrupted hemisphere (primary focus). The lack of Evans blue staining in the actively discharging secondary focus suggests that spike activity does not account for the increases in BBB permeability observed with dehydrocholate treatment.

Fulminant disseminated carcinomatosis arising from squamous cell carcinoma of the tongue.

Squamous cell carcinoma of the tongue tends to be an indolent disease. Tumors that present as small, localized lesions of the anterior tongue have a median five-year survival greater than 70 percent whether treated by irradiation or surgery. Distant metastases occur in only 7.5 percent. This report describes a well-differentiated T1N0M0 squamous cell carcinoma of the anterior tongue that progressed from diagnosis to death of the patient in less than nine months. At autopsy, the tumor had disseminated widely, including simultaneous metastases to all layers of the heart. It is concluded that factors other than morphology and anatomic extent at presentation may modify prognosis in squamous cell carcinoma of the tongue.

Etoposide-induced blood-brain barrier disruption. Effect of drug compared with that of solvents.

The intracarotid infusion of the anti-neoplastic compound, etoposide, has been shown to exert a dose-dependent effect on blood-brain barrier (BBB) permeability. Etoposide, however, is formulated in a complex solvent solution containing alcohol, Tween 80, polyethylene glycol 300, and citric acid. To investigate the contribution of the solvent solution to BBB disruption, the authors studied Sprague-Dawley rats after the internal carotid artery infusion of the solvent solution with and without the addition of etoposide. Experiments were performed at four doses of drug and/or solvent. Disruption of the BBB was evaluated qualitatively by the appearance of the systemically administered dye, Evans blue, in the cerebral hemispheres and quantitatively by the ratio of gamma counts of the technetium-labeled chelate of diethylenetriaminepentaacetic acid (99mTc-DTPA) in the ipsilateral:contralateral hemisphere. Significant barrier opening was obtained in all four groups of animals infused with solvent plus etoposide. In the corresponding groups of rats infused with the solvent solution alone, BBB disruption was markedly lower. Only in the group infused with the largest dose of solvent was the hemispheric ratio of 99mTc-DTPA significantly different from saline-infused animals. Each of the groups with solvent plus etoposide had 99mTc-DTPA ratios significantly different from the control group. Intracarotid infusion and subsequent BBB disruption were well tolerated by the animals receiving either solvent alone or solvent and etoposide. Disruption of the BBB secondary to the intracarotid infusion of etoposide is primarily caused by the drug itself and not by the solvent solution.

Effect of intracarotid etoposide on opening the blood-brain barrier.

The effect of an intracarotid artery infusion of etoposide on blood-brain barrier (BBB) integrity was investigated in a rat model system. The external carotid arteries of Sprague-Dawley rats were catheterized in a retrograde manner. Etoposide in a dose range from 3.0 mg/kg to 22.5 mg/kg was infused into the internal carotid artery by this technique. BBB disruption was evaluated qualitatively by the appearance in the infused hemisphere of the systemically administered dye Evans blue and quantitatively by the ratio of counts of the technetium-labeled chelate of diethylenetriaminepentaacetic acid (99mTc-DTPA) in the infused to the noninfused hemisphere. Evidence of increased BBB permeability was seen at all doses of etoposide. Degree of BBB disruption increased with increasing doses of etoposide. The intracarotid infusion and subsequent BBB disruption were well tolerated. Further clinical trials employing the intracarotid administration of etoposide should be cognizant of the potential for BBB disruption.

Intracarotid dehydrocholate infusion: a new method for prolonged reversible blood-brain barrier disruption.

An animal model for prolonged reversible blood-brain barrier (BBB) disruption has been developed. The external carotid arteries of Osborn-Mendel rats were catheterized in a retrograde manner. Varying concentrations of sodium dehydrocholate were infused into the internal carotid artery by this technique. BBB disruption was evaluated qualitatively by the appearance in the infused hemisphere of the systemically administered dyes Evans blue and sodium fluorescein and quantitatively by the ratio of counts of the technetium-labeled chelate of diethylenetriaminepentaacetic acid (99mTc-DTPA) in the infused to the noninfused hemisphere. The ability of sodium dehydrocholate to disrupt the BBB was documented with all three markers. As the concentration of the infused dehydrocholate was increased, both the incidence and the degree of BBB disruption increased. Reversibility of BBB disruption was evaluated by the administration of sodium fluorescein and 99mTc-DTPA at varying times after BBB disruption. Depending on the concentration of the infused sodium dehydrocholate, altered BBB permeability can be maintained for over 3 days. This new model of prolonged reversible BBB disruption deserves further investigation both for basic studies of the BBB and for therapeutic studies of drug delivery into the central nervous system.