Local cerebral glucose metabolism after global ischemia: treatment by ventriculocisternal perfusion with a fluorocarbon emulsion.

The local cerebral metabolic rate for glucose (LCMRg) was measured in cats subjected to global cerebral ischemia (GCI). Control (nonperfused) cats showed decreased LCMRg (P less than 0.01) in the frontal, temporal, parietal, and occipital cortex 9.5 hours after a 10-minute exposure to GCI. Cats perfused ventriculocisternally with oxygenated nutrient solution (ONS) for 8 hours showed significant increases in the LCMRg (p less than 0.05) at 9.5 hours postischemia in the parietal and occipital areas over the levels found in untreated ischemic cats. Supplementing the ONS perfusion medium with fluorocarbon (OFNS) increased the LCMRg (P less than 0.05) in the frontal, as well as the parietal and occipital areas, over that seen in untreated ischemic brains. The increase of LCMRg in three (rather than only two) cortical areas may be a result of the ability of the fluorocarbon in OFNS to deliver greater quantities of oxygen to the brain than ONS without fluorocarbon. Perfusion with OFNS without glucose, or with low (50 mg%) glucose, was more effective than OFNS with high (200 mg%) glucose in restoring LCMRg to normal in all four cortical areas affected by GCI. In five brain areas not affected by GCI, perfusion with OFNS having no glucose significantly increased LCMRg as compared to normal animals. This study demonstrates that OFNS perfused by the ventriculocisternal route can restore toward normal the LCMRg following GCI and that different concentrations of glucose in the perfusing fluid will have variable effects on LCMRg in certain brain areas.

Enhancement of the Arthus reaction and suppression of delayed type hypersensitivity (DTH) by pluronic F-68, a detergent frequently used to prepare perfluorocarbon emulsions.

The effect of a 20% w/v RM101 (perfluorobutyltetrahydrofuran) emulsion containing 5% w/v of the detergent Pluronic F-68 or 5% w/v Pluronic F-68 given alone on the Arthus reaction and on delayed type hypersensitivity (DTH) were evaluated in female A/J mice. The test substances were administered i.v. at 1% body weight at 0,4,7,14 and 28 days prior to the i.p. immunization with 10(7) sheep red blood cells (SRBC). The increase in footpad swelling at 4 h (Arthus reaction) and at 24 h (DTH) after elicitation with the s.c. administration of 10(8) SRBC into the left footpad was used to assess immune competence. Pluronic F-68 given alone enhanced the Arthus reaction only when administered on day 0 of immunization. Pluronic F-68 given alone, as well as the perfluorocarbon emulsion containing Pluronic F-68, suppressed the 24 h DTH for as long as 4 days prior to immunization. Nonemulsified perfluorocarbon, on the other hand, had no effect on either the Arthus reaction or on DTH. The immunostimulatory agent, levamisole, administered (10 mg/kg i.p.) 1.5-2 h prior to immunization with SRBC counteracted both the Arthus reaction and the DTH response produced by Pluronic F-68. The present data clearly demonstrate that the changes in Arthus reaction and the DTH response are due to the Pluronic F-68 used to emulsify the RM101 perfluorocarbon; the changes induced by the detergent in these two immune parameters probably involve separate mechanisms.

Fluorocarbon emulsion as a potential contrast medium in the subarachnoid space and brain tissue. Experiments in cats.

Ventriculosubarachnoid perfusion with oxygenated fluorocarbon emulsion has been used in the treatment of severe cerebral ischemia in cats. The perfusion vehicle is prepared mimicking cerebrospinal fluid in terms of electrolyte content, osmolality, pH, glucose and amino acids. Fluorocarbon emulsion is prepared with the vehicle as the external phase and charged with high partial pressures of oxygen. This fluorocarbon emulsion has been well-tolerated by the central nervous system. In addition to delivering oxygen to the ischemic tissues via the ventriculosubarachnoid space, the fluorocarbon emulsion has an absorption coefficient higher than normal brain and cerebrospinal fluid. This property makes it easily detected on the CT scan. Determination of appearance, attenuation, distribution, and absorption of the fluorocarbon has been performed in cats after direct intraventricular injection of the substances and after perfusion of the emulsion. The results of these experiments stress the possibility of using a fluorocarbon emulsion as a potential contrast medium in the brain and subarachnoid space, particularly after brain anoxia.

Protective effects of trifluralin on benzo(a)pyrene-induced tumors in A/J mice.

Trifluralin, a widely used herbicide, added to the diet before the p.o. administration of benzo(a)pyrene (BP) and fed continuously, significantly inhibited the induction of lung and forestomach tumors in female A/J mice. Dietary intake of trifluralin before the administration of BP resulted in a significant increase in glutathione in lung and forestomach but not in liver and glandular stomach. Trifluralin treatment also inhibited the binding of [3H]BP to liver and lung DNA, as well as to protein in the liver. Under these conditions, the protection against BP-induced lung tumors and perhaps forestomach tumors may be due to an elevation of tissue glutathione, resulting in a decreased binding of reactive metabolites of BP to macromolecules at these sites. The results indicate that trifluralin has a "blocking" effect in its inhibition of BP-induced tumors. Our studies show that trifluralin also inhibits chemical carcinogenesis in lung and forestomach when started in the diet 1 day after the administration of BP and fed continuously thereafter. In the case of lung, although maximum inhibition of tumors occurred when trifluralin was started 1 day after BP, there was significant protection at all time intervals (0 to 7 days) against lung tumors. The finding that trifluralin protects against BP tumorigenesis when started in the diet after the administration of the carcinogen clearly demonstrates that trifluralin also has a "suppressive" effect against BP-induced tumors.

Oxygenated fluorocarbon nutrient solution in the treatment of experimental spinal cord injury.

We employed an extravascular perfusion system through the subarachnoid space of the traumatized spinal cord of the cat for the delivery of oxygen utilizing a fluorocarbon emulsion containing essential nutrients, termed the oxygenated fluorocarbon nutrient solution (OFNS). Animals perfused for 2 hours with saline after impact injury of the spinal cord had significantly less edema at 1 cm below this site of injury than injured, untreated animals. However, in injured animals perfused with OFNS there was significant protection from spinal cord edema at both 1 and 2 cm below the site of injury. OFNS perfusion reduced the magnitude of hemorrhagic necrosis in both the gray and the white matter and protected the anterior horn cells against lysis at the site of injury. Adenosine triphosphate (ATP) is decreased within 1 minute and remains suppressed for 1 hour in gray and white matter of unperfused, injured animals. The level of ATP in both gray and white matter was significantly higher in injured OFNS-perfused animals than in saline-treated animals at the site below the spinal cord injury. Our data show that OFNS perfusion of the injured spinal cord reduced necrosis and edema and tended to normalize the levels of high energy ATP and intact anterior horn cells. These results demonstrate the feasibility of treating ischemic hypoxia of the spinal cord after trauma through an extravascular perfusion route that utilizes a fluorocarbon emulsion as a vehicle for the delivery of oxygen and other cellular nutrients.

Severe cerebral ischemia treatment by ventriculosubarachnoid perfusion with an oxygenated fluorocarbon emulsion.

Global hemispheric ischemia was produced in cats by bilateral carotid ligation and bleeding to a mean arterial pressure of 30 +/- 2 (SE) mm Hg. Total electrocerebral silence, as determined by computer-based power analysis, was obtained and maintained for 15 minutes. After this severe cerebral ischemic episode, the heparinized blood was reinfused and the carotid clamps were removed. After the cerebral ischemia, the ventriculosubarachnoid space was perfused with an oxygenated fluorocarbon nutrient solution (OFNS) or modified Elliott's B solution (ES) (control perfusion). The OFNS perfusate contained 400 to 640 mm Hg pO2 (produced by means of a bubble oxygenator pump system) as well as electrolytes, glucose, and amino acids, all of which are known to be important in cerebral metabolism. Flow rates of the perfusion were maintained at either 3 or 6 ml/minute and intracranial pressures were never permitted to exceed 10 mm Hg. During passage through the ventriculosubarachnoid space, oxygen, carbon dioxide, and electrolytes were exchanged between the brain and the OFNS perfusate. In addition, the OFNS perfusate was capable of picking up pCO2, lactate, and pyruvate. This produced a significant return of electrocerebral activity (P less than 0.01) and oxidative metabolism (P less than 0.01), as evidenced by a decline in the lactate/pyruvate ratio in the OFNS-treated cats, but not in nonperfused animals or those perfused with ES. In this study the ventriculosubarachnoid system served as an alternate vascular tree and enabled the perfusate to accomplish many of the functions of blood. Substantial penetration of the perfusate products into the brain occurred, enabling oxidative metabolism, removal of waste products, and electrocerebral activity to be reestablished.

Effect of the insecticides toxaphene and carbaryl on induction of lung tumors by benzo[a]pyrene in the mouse.

The insecticides toxaphene and carbaryl, when fed in the diet alone for 20 wk, were not tumorigenic to female A/J mice. Dietary levels of these insecticides were investigated for their effects on the incidence of lung tumors induced by oral administration of benzo[a]pyrene (BP). A significant reduction in BP-induced lung tumors was found after feeding 100 ppm toxaphene for 12 wk or 200 ppm for 20 wk. In contrast, 1000 ppm carbaryl fed for 20 wk caused a significant enhancement of BP-induced lung tumors. Mice that received toxaphene in the diet alone, or toxaphene and BP, showed an increase in BP hydroxylase activity in the liver and a decrease in enzyme activity in the lung. Carbaryl and BP increased BP hydroxylase activity in the lung without altering enzyme activity in the liver. Inhibition of lung BP hydroxylase activity was paralleled by a reduction in BP-induced lung tumors in mice fed toxaphene. Conversely, increased lung BP hydroxylase activity was associated with an enhancement of BP-induced lung tumors in animals fed carbaryl. The metabolism of BP by organs susceptible to BP-induced tumors and possible mechanisms for interactions with the insecticides are discussed.

Induction of aryl hydrocarbon hydroxylase and forestomach tumors ben benzo(a)pyrene.

While papillomatous tumors developed in the forestomach of female Ha/ICR mice after a 12-week chronic feeding period of benzo(a)pyrene (BP), no tumors developed in the glandular portion of stomach or in the lung or liver. Among all tissues examined, the forestomach showed the greatest increase of aryl hydrocarbon hydroxylase (AHH) activity following acute or chronic administration of BP. Single acute doses of BP induced AHH activity in forestomach, glandular stomach, lung, and small intestine, but not in the kidney and liver of these animals. Similarly, after chronic administration of BP, AHH activity was inducible in the forestomach, glandular stomach, and lung, but again not in the liver. Although the formation of tumors is associated with greater inducibility of AHH activity in the forestomach after BP administration, the relationship between tissue inducibility of AHH activity and susceptibility to BP carcinogenesis is still not clear. Further studies regarding the formation of specific carcinogenic epoxides of BP in itssues both susceptible (e.g., forestomach) and resistant to BP carcinogenesis would more clearly define the relationship between AHH inducibility and BP carcinogenesis.

Nicotine inhibition of the metabolism of 3,4-benzopyrene, a carcinogen in tobacco smoke.

A decreased rate of biliary excretion of radioactive metabolites of 3,4-benzopyrene was observed in rats given a single dose of nicotine. Prior treatment of rats with nicotine decreased benzopyrene hydroxylase activity in homogenates of liver, lung, and small intestine. The addition of nicotine to incubated tissues also decreased benzopyrene hydroxylase activity. These findings show that nicotine inhibits the metabolism of 3,4-benzopyrene in vivo and in vitro.