We used gas chromatography/mass spectrometry to measure brain 12-HETE (12-Hydroxy-5,8,10,14-eicosatetraenoic acid) formation from endogenous arachidonic acid in different species and different brain regions and in isolated brain microvessels. When blood-free brain slices were incubated for 20 minutes we found that the rabbit and cat brain incubates contained little 12-HETE when compared to rat and mouse brain incubates. Further in vitro studies of various rat brain regions showed a generally even distribution of 12-HETE. When isolated rat or rabbit microvessels were incubated and analyzed, we found 1 and 0.25 micrograms, respectively, of 12-HETE/mg of microvessel protein. Also, rabbit brain had limited or no capacity to actively metabolize tritiated 12-HETE. In summary, these studies show substantial species variation with respect to brain formation of 12-HETE and indicate that the vasculature is a potentially significant contributor to the 12-HETE found in whole brain tissue.
Previous investigations have shown that brain prostaglandin levels are transiently elevated following experimental fluid percussion brain injury. Associated with these increased prostaglandin levels there is free radical production and abnormalities in cerebral arteriolar function. The purpose of this study was to determine whether experimental fluid percussion brain injury in cats is associated with increased systemic levels of prostaglandins and the lipoxygenase product, 12-HETE. Blood samples were collected before and at various periods of time after 2.7 atm of fluid percussion brain injury was produced in adult cats. Prostaglandin and 12-HETE analysis was performed by radioimmunoassay after extraction of the plasma samples. The control levels for 6-keto-PGF1 alpha, PGE2, and 12-HETE were 477 +/- 42, 2,372 +/- 431, and 13,328 +/- 1,769 pg/ml, respectively. Following injury all three eicosanoids reached peak plasma levels by 1-5 min after injury. The percentile increases for all eicosanoids were similar and increased from 70 to 110%. The increases were sustained at up to 30 min postinjury and by 1 h after injury were at control levels. As in previous studies, hypertension following injury was maximal by 1 min postinjury and blood pressure had returned to near normal levels by 5 min postinjury. These studies demonstrate prolonged systemic increases in eicosanoids following injury. Since free radical production and vascular damage occur concomitantly with eicosanoid production, the prolonged increases in these products suggest that there is an attainable therapeutic window following injury during which administration of free radical scavengers may decrease radical damage and reduce the consequences of injury.
We have previously shown that topical brain application of kallikrein, an enzyme which converts kininogen to bradykinin, induces rabbit pial arteriole dilation. The purpose of the present investigation was to utilize a newly developed competitive kinin receptor antagonist to test the hypothesis that kallikrein-induced dilation was due to the conversion of brain kininogen to vasoactive kinins. As in our previous study, we measured rabbit pial arteriole diameter with a microscope using the closed cranial window technique. The kinin antagonist (6 /xM) reduced the dose-dependent dilation produced by bradykinin and blocked the dilation induced by kallikrein. In addition, the kinin antagonist was specific since it did not alter the cerebral arteriole dilation produced by adenosine, acetylcholine, or vasoactive intestinal polypeptide. These experiments provide further evidence for a possible role of the endogenous brain kallikrein-kinin system in the modulation of the cerebral circulation and provide the necessary pharmacologic foundation for future use of this antagonist in testing the role of kinins in the normal or altered cerebral circulation. (Stroke 1987; 18:792-795) W e and others have reported that bradykinin (BK) induces in vivo cerebral arteriole dilation. 1 " 4 We have recently shown that when kallikrein, the enzyme that converts kininogen to BK, is applied to the cerebral cortex, pial arteriole dilation is induced.1 Proof that kallikrein indeed formed BK and that the BK induced dilation was derived from the following results. First, BK-or kallikrein-induced dilation were both prevented by topical coapplication of the cyclooxygenase inhibitors indomethacin or meclofenamic acid, implying that both substances induced dilation by a cyclooxygenasedependent mechanism. This cyclooxygenase dependency is in agreement with previous literature since it is well known that BK stimulates prostaglandin formation. 5 -6 Secondly, the dilation induced by kallikrein was prevented by cotreatment with the kallikrein enzyme inhibitor aprotinin, implying that kallikreininduced dilation is due to its enzyme activity and not to a nonspecific effect. However, in spite of this evidence that kallikrein-induced dilation is due to BK formation it might still be argued that kallikrein-induced dilation is due to the formation of some cyclooxygenase-stimulating agonist other than a kinin.Recently, Vavrek and Stewart 7 have synthesized and tested a competitive BK antagonist that blocks the action of exogenous BK, kallidin, and met-lys-brady- Supported in part by National Institutes of Health Grants NS 12587, NS 23432, and a grant-in-aid from the American Heart Association. E.F.E. is an Established Investigator of the American Heart Association, and G.S.H. is supported by a postdoctoral fellowship from the American Heart Association. Virginia Affiliate.Address for reprints: Dr. Earl Ellis, Box 613, MCV Station, Richmond, VA 23298.Received October 31, 1986; accepted February 9, 1987. kinin in the guinea pig ileum, rat uterus, and rat blood...
The purpose of these studies was to determine the effects of dietary n-3 fish oil on cerebrovascular reactivity and cerebrospinal fluid prostaglandin levels. Adult rabbits (n = 30) received fish oil (200 mg/kg eicosapentaenoic + 143 mg/kg docosahexaenoic acid), corn oil, or water by daily gavage for 6 wk and were then tested for their pial arteriolar diameter response to topical acetylcholine, bradykinin, or systemic asphyxia using the cranial window technique. Plasma and platelet fatty acids were measured by gas chromatography. Cerebrospinal fluid prostaglandin E and serum thromboxane B2 were measured by radioimmunoassay. n-3 Fatty acids were enriched in the plasma and platelets of the fish oil group (P less than 0.05). Serum thromboxane B2 was decreased by 31% in the fish oil group (P less than 0.05). The diameter response to acetylcholine and asphyxia was the same in all groups; however, the dilator response to bradykinin, which is known to be mediated by oxygen radicals, was significantly diminished in the fish oil group (P less than 0.05). Cerebrospinal fluid prostaglandin E concentration increased in response to acetylcholine, bradykinin, and asphyxia; however, the percent increase was less in the fish oil group. In summary, dietary n-3 fatty acids, which are purported to decrease heart disease, appear to selectively affect cerebral arteriolar reactivity, which is normally dependent on cyclooxygenase metabolism of arachidonic acid and formation of vasoactive oxygen radicals.
Previous studies have shown that after experimental neural trauma or acute hypertension the brain produces superoxide anion radicals, and brain arterioles display endothelial lesions, dilation, and loss of normal reactivity in response to a decrease in CO2 tension. Because these abnormalities are prevented by pretreatment with free radical scavengers or inhibitors of the cyclooxygenase component of prostaglandin (PG) H synthase, arachidonic acid metabolism by PGH synthase with concomitant formation of tissue injuring oxygen radicals causes the vascular damage. The purpose of the present experiments was to determine whether kinins, which are known to stimulate arachidonate metabolism and to induce cerebral arteriolar dilation via production of superoxide anion, may be involved in initiating the cerebrovascular abnormalities produced by neural trauma in cats. The diameter and reactivity of untreated in vivo pial arterioles on one cerebral cortex was compared with the diameter and reactivity of pial arterioles on the contralateral cortex, which were pretreated topically with a competitive receptor antagonist, which is specific for kinins. Before fluid percussion neural trauma was induced, arterioles on both cerebral hemispheres constricted normally to a decrease in CO2 tension. After injury, the arterioles on the untreated cortex dilated and did not constrict in response to a decrease in arterial CO2 tension, whereas the arterioles pretreated with the kinin antagonist dilated less and displayed normal reactivity to CO2. These experiments demonstrate that a specific kinin receptor stimulates PGH synthase-dependent, free radical-mediated cerebrovascular injury. Given the ubiquitous distribution of the kallikrein-kinin system, we propose that kinins may be an important common mediator of systemic vascular injury and abnormal vascular reactivity.
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