Effects of Anoxia on Cerebral Blood Flow in the Rat Brain: Evidence for a Role of Adenosine in Autoregulation

Phillis, John W.; Preston, Gregory M.; DeLong, Robert E.

doi:10.1038/jcbfm.1984.83

Cited by 77 publications

(21 citation statements)

References 24 publications

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“…The low adenosine levels in normal CSF are, there fore, likely to reflect low levels of adenosine in the interstitial fluid of brain, rather than a loss of aden osine subsequent to entry into the CSF. The con clusion that extracellular adenosine concentrations in the brain of normoxic anesthetized rats may be in the 10-100 nM range is consistent with earlier observations of a failure of adenosine antagonists to affect basal CBF or pial vessel diameter, in the anesthetized rat (Phillis et al, 1984;Morii et al, 1985). This lack of effect of methyl xanthine antago nists on basal CBF suggests that adenosine is not an important factor in the regulation of vessel tone in the normoxic brain of anesthetized animals, and provides an indication that extracellular levels of adenosine are likely to be < 10 -7 M (Morii et al, 1986) under these conditions.…”

Section: Discussionsupporting

confidence: 89%

Increases in Cerebral Cortical Perfusate Adenosine and Inosine Concentrations during Hypoxia and Ischemia

Phillis

Walter

O’Regan

et al. 1987

J Cereb Blood Flow Metab

144

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Summary:The cerebral cortical cup technique was used to monitor changes in adenosine and inosine levels in the rat cerebral cortex during periods of hypoxia, anoxia, or hemorrhagic hypotension. Basal levels of adenosine and inosine in cortical perfusates stabilized within 10 min at concentrations of 30-50 and 75-130 nM, respectively. Comparable levels were observed in normal CSF col lected from the cisterna magna. Reductions in the oxygen content of the inspired air (14, 12, 8, and 5% oxygen) re

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Section: Discussionsupporting

confidence: 89%

Increases in Cerebral Cortical Perfusate Adenosine and Inosine Concentrations during Hypoxia and Ischemia

Phillis

Walter

O’Regan

et al. 1987

J Cereb Blood Flow Metab

144

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“…as brain hypoxia, ischemia, hypoglycemia, and status epilepticus (Berne et al , 1983). Prevention of such removal by nucleoside transport inhibitors such as DPY will potentiate the effects of adeno sine at its receptors in neuronal, glial, and vessel membranes (Berne et al , 1983;Phillis et al, 1984).…”

Section: Discussionmentioning

confidence: 99%

Adenosine Receptors and the Nucleoside Transporter in Human Brain Vasculature

Kalaria

Harik

1988

J Cereb Blood Flow Metab

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Summary: Evidence suggests that adenosine modulates neuronal and cerebral vascular functions by interacting with specific receptors on brain cells and blood vessels. Adenosine and other nucleosides are also transported across the blood-brain barrier via a saturable, carrier mediated mechanism. Using direct ligand binding methods, we studied the two adenosine receptor sub types, Al and A2 and the nucleoside transporter moiety in human brain ' microvessels, pial vessels, choroid plexus, and cerebral cortex membranes. The following specific tritiated ligands were used: cyclohexyladenosine (CHA) for Al receptors; 5'-N-ethylcarboxamide adeno sine (NECA) for A2 receptors; nitrobenzylthioinosine (NBMPR) and dipyridamole (DPY) for nucleoside trans porters. We find that cerebral microvessels, pial vessels, and choroid plexus have few, if any, Al receptors, in con tradistinction to cerebral membranes, which have a 1O-20-fold higher density of Al receptor sites. SpecificIt is generally accepted that adenosine modulates central nervous system functions via its interaction with adenosine I (AI) and adenosine2 (A2) receptors located on cell membranes (Phillis and Wu, 198 1; Daly et aI., 1983). Al receptor agonists inhibit cy clic adenosine monophosphate formation, whereas A2 receptor stimulation increases adenylate cyclase activity and cAMP synthesis (Daly et aI., 1981). Marked changes in extracellular adenosine concen trations were described in a variety of conditions 32high-affinity NECA binding to A2 receptors in cerebral microvessels, pial vessels, and choroid plexus was satu rable and was equivalent to that of cerebral cortical membranes. The Bmax and Kd of the high-affinity NECA binding to vessel preparations were � 1.3 pmol/mg pro tein and �250 nM, respectively, which is similar to our previous findings in the rat and pig. NBMPR and DPY binding were also saturable and were consistent with a single class of high-affinity binding sites. The density of nucleoside transporters was �four-fold higher in cerebral microvessels than in cerebral cortex, pial vessels, and choroid plexus. These results suggest that human cere bral microvessels have A2 but not Al receptors and are particularly enriched with the adenosine transporter moiety. Key Words: Adenosine receptors-Blood-brain barrier-capillary endothelium-Cerebral blood vessels -Nucleoside transporter.that perturb brain functions, such as ischemia, hyp oxia, hypoglycemia, and status epilepticus. Also, there is evidence suggesting that adenosine and its analogs dilate cerebral blood vessels and increase brain perfusion (Winn et aI., 1981;Berne et al., 1983). On the other hand, it is also known that adenosine and other nucleosides (guanosine, ino sine, and uridine) traverse cell membranes, in cluding the blood-brain barrier (BBB), by a car rier-mediated, saturable, nonconcentrative, and non-energy-requiring facilitated diffusion mecha nism (Cornford and Oldendorf, 1975;Young and Jarvis, 1983).We have previously demonstrated by specific li gand binding methods the existence o...

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“…By contrast, the large decrease in 'buffering capacity' with IBMX took place despite an increase in basal PV flow, thus implying a rather greater inhibitory effect of IBMX than previously concluded; the hypotensive effect of IBMX is probably not responsible (see discussion above). DPD did not enhance 'buffering capacity '. Adenosine has been shown to be an important regulator of blood flow in a number of organs (Berne et al, 1983), including the brain (Phillis et al, 1984;Winn et al, 1985), the coronary circulation (Berne, 1963;Leung et al, 1985;Randall & Jones, 1985), skeletal muscle (Berne et al, 1983), the kidney (Osswald, 1988) and the intestine (Granger & Norris, 1980;Lautt, 1986). It has also been shown to control post-occlusion reactive hyperaemia of the HA (Ezzat & Lautt, 1987).…”

Section: Discussionmentioning

confidence: 99%

The role of adenosine in the hyperaemic response of the hepatic artery to portal vein occlusion (the ‘buffer response’)

Mathie¹,

Berndt²

1990

British J Pharmacology

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Adenosine has been shown to be responsible for the hyperaemic response of the hepatic artery to portal vein occlusion (the hepatic arterial 'buffer response'). 2 The effect of adenosine receptor blockade and of adenosine uptake inhibition on the hepatic arterial response to portal vein occlusion was investigated in three groups of anaesthetized dogs. 3 Venous return and arterial blood pressure were maintained during periods of portal occlusion by establishing a side-to-side portacaval shunt. Hepatic artery and portal vein blood flows were measured with electromagnetic flowmeters.4 Hepatic arterial infusions of 8-phenyltheophylline (500pgkg-1 min-1) and 3-isobutyl-1-methylxanthine (75pgkg-min-1), doses sufficient to block the vasodilator response of the hepatic artery to exogenously applied adenosine, reduced the magnitude of the 'buffer response' by 50% and 75%, respectively.

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Effects of Anoxia on Cerebral Blood Flow in the Rat Brain: Evidence for a Role of Adenosine in Autoregulation

Cited by 77 publications

References 24 publications

Increases in Cerebral Cortical Perfusate Adenosine and Inosine Concentrations during Hypoxia and Ischemia

Increases in Cerebral Cortical Perfusate Adenosine and Inosine Concentrations during Hypoxia and Ischemia

Adenosine Receptors and the Nucleoside Transporter in Human Brain Vasculature

The role of adenosine in the hyperaemic response of the hepatic artery to portal vein occlusion (the ‘buffer response’)

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