Cloning and characterization of additional members of the G protein-coupled receptor family.

A search of the expressed sequence tag (EST) database retrieved a human cDNA sequence which partially encoded a novel G protein-coupled receptor (GPCR) GPR26. A human genomic DNA fragment encoding a partial open reading frame (ORF) and a rat cDNA encoding the full length ORF of GPR26 were obtained by library screening. The rat GPR26 cDNA encoded a protein of 317 amino acids, most similar (albeit distantly related) to the serotonin 5-HT(5A) and gastrin releasing hormone BB2 receptors. GPR26 mRNA expression analysis revealed signals in the striatum, pons, cerebellum and cortex. HEK293 and Rh7777 cells transfected with GPR26 cDNA displayed high basal cAMP levels, slow growth rate of clonal populations and derangements of normal cell shape. We also used a sequence reported only in the patent literature encoding GPR57 (a.k.a. HNHCI32) to PCR amplify a DNA fragment which was used to screen a human genomic library. This resulted in the cloning of a genomic fragment containing a pseudogene, psiGPR57, with a 99.6% nucleotide identity to GPR57. Based on shared sequence identities, the receptor encoded by GPR57 was predicted to belong to a novel subfamily of GPCRs together with GPR58 (a.k.a. phBL5, reported only in the patent literature), putative neurotransmitter receptor (PNR) and a 5-HT(4) pseudogene. Analysis of this subfamily revealed greatest identities (approximately 56%) between the receptors encoded by GPR57 and GPR58, each with shared identities of approximately 40% with PNR. Furthermore, psiGPR57, GPR58, PNR and the 5-HT(4) pseudogene were mapped in a cluster localized to chromosome 6q22-24. PNR and GPR58 were expressed in COS cells, however no specific binding was observed for various serotonin receptor-specific ligands.

Circulating neutrophils and liver injury in rat models of experimental alcoholic liver disease.

The present study examined the relationship between circulating neutrophils and liver injury in two widely used rat models of chronic ethanol administration. Hematological alterations, liver histopathology, and biochemical indices of liver injury were assessed in rats receiving chronic ethanol by oral liquid diet feeding (Lieber-DeCarli method) or by continuous intragastric infusion (Tsukamoto-French method). Oral administration of ethanol did not affect circulating neutrophil counts, but resulted in minimal liver injury characterized by elevated serum alanine aminotransferase (79%), increased liver mass (15%), and moderate steatosis. In contrast, rats receiving ethanol by continuous intragastric infusion showed an approximately 2-fold increase in circulating neutrophils, and a moderate degree of liver injury, indicated by a 169% elevation of serum alanine aminotransferase and a 2-fold increase in liver mass. Liver biopsies from these rats showed severe steatosis and scattered necrotic hepatocytes, and some neutrophil infiltrates. To determine whether an increase in the number of circulating neutrophils could potentiate liver injury induced by oral ethanol feeding, rats were treated with human recombinant granulocyte colony-stimulating factor at a dose of 100 microg/kg/day (s.c.) for 4 days. Treatment with granulocyte colony-stimulating factor resulted in a 6- to 9-fold increase in circulating neutrophil counts. Nevertheless, this change did not enhance the minor degree of ethanol-induced liver injury in this model. Our results indicate that, whereas neutrophil leukocytosis accompanies more severe manifestations of ethanol hepatotoxicity in rats, this condition per se does not directly induce or exacerbate ethanol-induced liver injury.

Cloning and chromosomal mapping of three novel genes, GPR9, GPR10, and GPR14, encoding receptors related to interleukin 8, neuropeptide Y, and somatostatin receptors.

We employed the polymerase chain reaction and genomic DNA library screening to clone novel human genes, GPR9 and GPR10, and a rat gene, GPR14. GPR9, GPR10, and GPR14 each encode G protein-coupled receptors. GPR10 and GPR14 are intronless within their coding regions, while GPR9 contains at least one intron. The receptor encoded by GPR9 shares the highest identity with human IL-8 receptor type B (38% overall and 53% in the transmembrane regions), followed by IL-8 receptor type A (36% overall and 51% in the transmembrane domains). GPR10 encodes a receptor that shares highest identity with the neuropeptide Y receptor (31% overall and 46% in the transmembrane domains). The receptor encoded by GPR14 shares highest identity with the somatostatin receptor SSTR 4 (27% overall and 41% in the transmembrane domains). Fluorescence in situ hybridization analysis localized GPR9 to chromosome 8p11.2-p12 and GPR10 to chromosome 10q25.3-q26.

[Hodgkin's disease: relapse after 16 years of continuous remission]. / Enfermedad de Hodgkin: recaída tras 16 años de remisión continuada.

We report a boy in whom and advanced Hodgkin's disease, nodular sclerosis variety, was diagnosed at 5 years of age and treated with exclusive chemotherapy. After 16 years of remission, he presented with a relapse of the disease, with a different histological pattern and was subjected to chemotherapy (C-MOPP/AVB) and unilateral axillary irradiation, obtaining a complete remission of the disease. Four months later, the patient is asymptomatic and without evidences of relapse.

The effect of adenosine-induced hypotension on systemic and splanchnic hemodynamics during halothane or sevoflurane anesthesia in the rat.

BACKGROUND: It has been suggested that the liver may be at risk for ischemic damage during adenosine-induced hypotension. This notion, however, is somewhat inconsistent with the understanding that adenosine is a powerful vasodilator of the splanchnic circulation. To help clarify the effect of adenosine-induced hypotension on splanchnic hemodynamics, we studied the systemic and splanchnic hemodynamic responses to adenosine, both alone and in the presence of halothane or sevoflurane. METHODS: Systemic and splanchnic hemodynamics were determined during the infusion of adenosine in 36 rats allocated randomly to one of three study groups: (1) awake, (2) halothane anesthesia (1.0 MAC), or (3) sevoflurane anesthesia (1.0 MAC). Adenosine was infused at a rate sufficient to decrease the mean arterial pressure by 35-38% from awake control values. Cardiac output and organ blood flows were measured using the radiolabeled microsphere technique. RESULTS: Adenosine infusion produced stable hypotension of rapid onset due to a reduction in systemic vascular resistance. Stroke volume increased, but cardiac output remained unchanged in the awake and sevoflurane groups because of a decrease in heart rate. Infusion of adenosine during halothane anesthesia increased cardiac output enough to compensate for the decrease in cardiac output due to halothane alone. In the splanchnic circulation, there was an increase in portal tributary (42%, P < 0.01) and hepatic arterial (38%, P < 0.05) blood flows during adenosine infusion in awake rats. This resulted in an overall increase in total liver blood flow (42%, P < 0.01). Halothane anesthesia was associated with a decrease in portal tributary blood flow (28%, P < 0.05). In contrast, sevoflurane anesthesia was associated with an increase in hepatic arterial flow (35%, P < 0.05) but with no change in portal tributary blood flow. During halothane anesthesia, adenosine infusion increased portal tributary (90%, P < 0.01) and hepatic arterial (37%, P < 0.05) blood flows, thereby increasing total liver blood flow to values similar to those in awake adenosine-infused rats. During sevoflurane anesthesia, adenosine infusion increased portal tributary blood flow (48%, P < 0.01), but hepatic arterial blood flow did not increase beyond the values observed during sevoflurane anesthesia alone. CONCLUSIONS: These findings demonstrate that adenosine is a potent vasodilator of portal tributary and hepatic arterial vasculature in the rat and that the splanchnic hemodynamic effects of adenosine predominate over those of halothane and sevoflurane.

Effect of propofol infusion on splanchnic hemodynamics and liver oxygen consumption in the rat. A dose-response study.

BACKGROUND: Propofol has been used for the maintenance of anesthesia. The effects of propofol infusion on splanchnic hemodynamics and liver oxygen consumption, however, have not been reported. In the current investigation, the authors studied the effects of a continuous infusion of propofol on systemic and splanchnic hemodynamics using a new method to measure liver oxygen consumption in awake control and anesthetized rats. METHODS: Cannulas were inserted into the left ventricle, femoral artery, portal vein, and hepatic vein during ether anesthesia, and the rats were allowed to awaken and recover for 3-4 h before study. Animals were infused for 30 min with either saline (controls) or propofol at a rate of 300, 600, 900, or 1,200 micrograms.kg-1 x min-1. Cardiac output and organ blood flows were measured using radiolabelled microspheres, and blood samples from the femoral artery, portal vein, and hepatic vein were used to determine liver oxygen consumption. RESULTS: Mean arterial pressure decreased in a dose-dependent manner with a 25% reduction at the highest infusion rate. Systemic vascular resistance similarly decreased, whereas cardiac output remained unchanged at all the infusion rates. Hepatic arterial blood flow increased in a dose-dependent fashion over the dose range studied, to a maximum increase of 120%. Portal tributary blood flow increased by 30% at the highest infusion rate. Total liver blood flow increased in a dose-dependent manner to a maximum of 38%. Total oxygen delivery to the liver by the hepatic artery and portal vein increased in a dose-dependent fashion. Liver oxygen consumption increased in a dose-dependent fashion to a maximum increase of 51% at an infusion rate of 1,200 micrograms.kg-1 x min-1. The percent of oxygen extracted by the liver was not altered by propofol infusion, and hepatic venous oxygen saturation did not decrease at any dose studied. Coronary and renal blood flows were not altered. Arterial PaCO2, increased from 31 +/- 2 mmHg in awake control rats to 41 +/- 2 mmHg in spontaneously breathing rats infused with 1,200 micrograms.kg-1 x min-1 propofol. CONCLUSIONS: The maintenance of anesthesia using an infusion of propofol resulted in an increase in liver oxygen consumption that was fully compensated for by an increase in oxygen delivery to the liver. Splanchnic hemodynamics and liver oxygenation are not adversely affected during maintenance of anesthesia with propofol in the normal rat.

Effect of propylthiouracil on the ethanol-induced increase in liver oxygen consumption in awake rats.

It has been postulated that the beneficial effects of the antithyroid drug propylthiouracil in the treatment of alcoholic liver disease depend primarily on the action of propylthiouracil in suppressing the increase in hepatic oxygen consumption induced by ethanol. The evidence for this effect of propylthiouracil is derived from studies in which liver oxygen consumption has been determined in in vitro preparations. In our study the effects of ethanol and propylthiouracil on liver oxygen consumption were assessed in vivo in an unrestrained and unanesthetized rat model, where liver blood flow and hepatic vein and portal vein oxygen content can be measured. Data show that the liver oxygen consumption increased in rats treated with ethanol-containing liquid diets for 4 to 6 wk, both on withdrawal of alcohol (30%, p < 0.01), and after readministration of ethanol (50%, p < 0.01). Single-dose ethanol administration increased portal tributary blood flow without affecting hepatic arterial blood flow in both controls and rats withdrawn from long-term ethanol treatment. Long-term ethanol administration per se had no effect on portal tributary blood flow; however, hepatic arterial blood flow was increased by 38% (p < 0.01). Treatment with propylthiouracil for 5 days resulted in complete suppression of the increase in liver oxygen consumption induced by long-term ethanol administration. Propylthiouracil treatment also attenuated the increase in portal tributary blood flow after the administration of a single dose of ethanol. These determinations were made 24 hr after the last dose of propylthiouracil.(ABSTRACT TRUNCATED AT 250 WORDS)

Hemodynamic and organ blood flow responses to halothane and sevoflurane anesthesia during spontaneous ventilation.

This study compared systemic hemodynamic and organ blood flow responses to equipotent concentrations of halothane and sevoflurane during spontaneous ventilation in the rat. The MAC values for halothane and sevoflurane were determined. Cardiac output and organ blood flows were measured using radiolabeled microspheres. Measurements were obtained in awake rats (control values) and at 1.0 MAC halothane or sevoflurane. The MAC values (mean +/- SEM) for halothane and sevoflurane were 1.10% +/- 0.05% and 2.40% +/- 0.05%, respectively. The PaCO2 increased to a similar extent in both groups compared with control values. During halothane anesthesia, heart rate decreased by 12% (P < 0.01), cardiac index by 26% (P < 0.01), and mean arterial blood pressure by 18% (P < 0.01) compared with control values. Stroke volume index and systemic vascular resistance did not change. During sevoflurane anesthesia, hemodynamic variables remained unchanged compared with control values. Coronary blood flow decreased by 21% (P < 0.01) and renal blood flow by 18% (P < 0.01) at 1.0 MAC halothane, whereas both remained unchanged at 1.0 MAC sevoflurane. Cerebral blood flow increased to a greater extent with halothane (63%; P < 0.01) than with sevoflurane (35%; P < 0.05). During halothane anesthesia, hepatic arterial blood flow increased by 48% (P < 0.01), whereas portal tributary blood flow decreased by 28% (P < 0.01). During sevoflurane anesthesia, hepatic arterial blood flow increased by 70% (P < 0.01) without a concomitant reduction in portal tributary blood flow. Total liver blood flow decreased only with halothane (16%; P < 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)

Haemodynamic and organ blood flow responses to sevoflurane during spontaneous ventilation in the rat: a dose-response study.

To determine the systemic haemodynamic and organ blood flow responses to the administration of sevoflurane during spontaneous ventilation, heart rate, cardiac index, mean arterial pressure, arterial blood gases, and blood flows to the brain, spinal cord, heart, kidneys and splanchnic organs were measured awake (control values) and after 30 min of anaesthesia with 0.5, 1.0, 1.2 or 1.5 MAC sevoflurane in rats. Cardiac output and organ blood flows were measured using radiolabelled microspheres. The MAC (mean +/- SEM) of sevoflurane was found to be 2.30 +/- 0.05%. At each concentration, haemodynamic variables were similar to awake values with the exception of a 12% reduction in mean arterial pressure at 1.5 MAC (P less than 0.01). Arterial PCO2 increased in a dose-related fashion. Cerebral and spinal cord blood flows increased at 1.2 and 1.5 MAC whereas coronary and renal blood flows did not change significantly. Portal tributary blood flow and preportal vascular resistance were unaffected. Hepatic arterial flow increased by 63% at 1.5 MAC (P less than 0.05) but total liver blood flow remained unchanged compared with awake values. In conclusion, the administration of sevoflurane during spontaneous ventilation produces a high degree of cardiovascular stability and maintains blood flow to major organs in the rat.

Central nervous system effects of acetate: contribution to the central effects of ethanol.

Acetate, resulting from ethanol metabolism in the liver, is released into the circulation and is utilized in a number of tissues, including the brain. In its metabolism, acetate leads to the production of adenosine, a powerful physiological mediator. We have investigated the effect of acetate on central nervous system (CNS) function in rodents. Sodium acetate in doses resulting in blood concentrations comparable to those attained after the administration of 1 to 2 g/kg ethanol, had significant CNS effects. Both ethanol and acetate produced a dose-dependent impairment of motor coordination. This effect of acetate was fully blocked by the adenosine receptor blocker 8-phenyltheophylline (8PT), whereas the dose-response relationship for ethanol was shifted to the right by about 30%. The inspired concentration of sevoflurane to achieve anesthesia was significantly reduced by both these agents. General anesthesia was potentiated in a dose-dependent fashion by ethanol and by acetate. The effect of acetate on anesthetic requirements was fully blocked by 8PT. The effect of ethanol on sevoflurane anesthetic requirements was inhibited by 22 to 35% by 8PT. Locomotor activity in mice was reduced by acetate in a dose-dependent fashion, an effect that was also fully blocked by 8PT. On the other hand, ethanol at a dose of 1 to 2 g/kg increased locomotor activity. This likely results from a direct stimulatory effect of ethanol, opposed by an inhibitor effect of acetate. The administration of 8PT enhanced the stimulation of locomotor activity induced by ethanol. In conclusion, acetate, a product of ethanol metabolism has significant CNS effects that can either potentiate or antagonize the effects of the ethanol molecule per se.(ABSTRACT TRUNCATED AT 250 WORDS)

Relationship between portal venous and hepatic arterial blood flows: spectrum of response.

The relationship between portal tributary blood flow (PBF) and hepatic arterial blood flow (HAF) was studied in awake, unrestrained rats with the radiolabeled microsphere technique. Six distinct patterns of response emerged. In group A (PBF+, HAF 0), ethanol, acetate, glucagon, prostacyclin, and a mixed diet increased PBF without a change in HAF; in group B (PBF+, HAF+), adenosine and histamine increased both PBF and HAF; in group C (PBF 0, HAF+), isoflurane and triiodothyronine did not change PBF but increased HAF; and in group D (PBF-, HAF+), halothane and vasopressin decreased PBF and increased HAF. Acute partial portal vein ligation decreased PBF (56%) and increased HAF (436%). Hypoxia (7.5% O2) decreased PBF (28%) and increased HAF (110%). In group E (PBF+, HAF-), acute hepatic artery ligation increased PBF (35%) and reduced HAF (74%), while in group F (PBF-, HAF-), thyroidectomy reduced PBF and HAF (36 and 47%, respectively). All blood flow responses were accompanied by the expected changes in both portal tributary and hepatic arterial vascular resistances. The data suggest that the portal and hepatic arterial vascular territories have regulatory mechanisms that allow for independent changes.

Effect of ethanol on splanchnic hemodynamics in awake and unrestrained rats with portal hypertension.

Alcoholic liver disease is frequently accompanied by portal hypertension. We have previously shown that alcohol intake in awake, unrestrained rats is followed by an increase in portal tributary blood flow. In this study, the effect of ethanol on splanchnic hemodynamics in rats with portal hypertension was analyzed. Portal hypertension was induced by partial ligation of the portal vein. This procedure resulted in an increase in portal tributary and hepatic arterial blood flows compared to sham-operated animals. Ethanol (2 gm per kg, oral) increased portal tributary blood flow in both sham-operated and portal vein-ligated rats (sham + water = 37.6 +/- 1.4; sham + ethanol = 63.1 +/- 1.9; p less than 0.01; partial portal vein stenosis + water = 53.2 +/- 3.3; partial portal vein stenosis + ethanol = 69.5 +/- 2.2 ml.kg-1.min-1; p less than 0.01). In sham-operated rats, hepatic artery blood flow was unchanged following ethanol (sham + water = 6.6 +/- 0.7; sham + ethanol = 7.1 +/- 1.0 ml.kg-1.min-1), whereas in portal vein-ligated rats, flow was increased (partial portal vein stenosis + water = 13.7 +/- 1.4; partial portal vein stenosis + ethanol = 19.8 +/- 1.1 ml.kg-1.min-1; p less than 0.025). The adenosine receptor blocker 8-phenyltheophylline suppressed only the ethanol-induced increase in both portal tributary and hepatic artery blood flows in portal vein-ligated rats. The increases in hepatic artery and portal tributary blood flows observed in portal vein-ligated rats without ethanol were not influenced by 8-phenyltheophylline.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of propylthiouracil and methimazole on splanchnic hemodynamics in awake and unrestrained rats.

The treatment of alcoholic liver disease with propylthiouracil is based on its effect of suppressing the ethanol-induced increase in hepatic oxygen consumption. It has been postulated that liver necrosis ensues when the increase in oxygen demand by the liver exceeds oxygen delivery to this organ. Data are now presented which show that propylthiouracil also increases portal blood flow in awake, unrestrained rats. Liver blood flow was determined using the labeled microsphere technique in rats at various intervals (0.25, 0.5, 1.0, 3.0, 6.0 and 24 hr) after oral propylthiouracil (50 mg per kg). Administration of propylthiouracil (dose range: 6.25 to 100.0 mg per kg) produced a dose-dependent increase in portal blood flow when given either orally or intraarterially. Maximal flows were obtained with 50 mg per kg (controls = 37.8 +/- 1.5, oral propylthiouracil = 50.7 +/- 2.2 ml.kg-1.min-1). This increase in portal blood flow was accompanied by a decrease in preportal vascular resistance (controls = 2.61 +/- 0.16; propylthiouracil, 50 mg per kg = 1.79 +/- 0.09 mmHg per ml.kg-1.min-1). These effects were correlated with the plasma concentrations of propylthiouracil (r = 0.67, n = 68, p less than or equal to 0.001). The effect of oral propylthiouracil (50 mg per kg) on portal blood flow started at 0.5 hr and lasted for 6 hr after administration, whereas total liver blood flow was increased for 3 hr. Oral propylthiouracil (50 mg per kg) for 5 days resulted in a 53% increase in thyroid weight, an 85% reduction in 125I thyroid uptake and a 74% decrease in serum thyroxine concentration.(ABSTRACT TRUNCATED AT 250 WORDS)

Noninvasive estimation of blood alcohol concentrations by eye vapor analysis using an electrochemical fuel cell detector.

A widely used breath analysis instrument was adapted for the noninvasive determination of blood alcohol in small animals. The instrument's response to ethanol in vapor above the lacrimal fluid was analyzed subsequent to taking vapor samples from a small eye cup for 15 sec. After ethanol administration (1.5 g/kg, orally) to rats, eye vapor measurements and venous blood samples were obtained over 5 hr. Eye vapor measurements were transposed into blood alcohol concentrations and compared with concentrations obtained by gas chromatographic analysis of blood. The correlation of concentrations obtained by the two methods yielded correlation coefficients of 0.93 and 0.95 depending on the calculation used. Eye vapor response and blood alcohol concentration were also found to be highly correlated (r = 0.96) after alcohol administration to mice and sampling for 2.5 hr after ethanol administration. Kinetic profiles obtained by eye vapor analysis and gas chromatography are virtually identical. The method described allows widespread use of a new, noninvasive approach to alcohol analysis in laboratory animals.

Ethanol-induced increase in portal blood flow: role of acetate and A1- and A2-adenosine receptors.

The increase in portal blood flow induced by ethanol appears to be adenosine mediated. Acetate, which is released by the liver during ethanol metabolism, is known to increase adenosine levels in tissues and in blood. The effects of acetate on portal blood flow were investigated in rats using the microsphere technique. The intravenous infusion of acetate (7-250 mumol.kg-1.min-1) resulted in vasodilation of the preportal vasculature and in a dose-dependent increase in portal blood flow [control, 39.1 +/- 2.6 ml.kg-1.min-1; acetate (250 mumol.kg-1. min-1), 68.7 +/- 4.0 ml.kg-1.min-1]. This acetate-induced increase in portal blood flow was suppressed by the adenosine receptor blocker, 8-phenyltheophylline. Using the A1-adenosine receptor agonist N-6-cyclohexyl adenosine and the A2-agonist 5'-N-ethylcarboxamido adenosine, we demonstrate that the effect of adenosine on the preportal vasculature is mediated by the A2-subtype of adenosine receptors. In conclusion, these data support the hypothesis that the increase in portal blood flow after ethanol administration results from a preportal vasodilatory effect of adenosine formed from acetate metabolism in extrahepatic tissues.

Ethanol-induced increase in portal blood flow: role of adenosine.

The mechanism by which ethanol induces an increase in portal vein blood flow was studied in rats using radiolabeled microspheres. Ethanol (2 g/kg) by gavage resulted in an increase of 50-70% in portal vein blood flow. The ethanol-induced increase in portal blood flow was suppressed by the adenosine receptor blocker 8-phenyltheophylline [ethanol, 61.8 +/- 4.1 ml.kg-1.min-1; ethanol + 8-phenyltheophylline (0.2 mg.kg-1.min-1), 44.2 +/- 2.0 ml.kg-1.min-1; P less than 0.05]. By itself, 8-phenyltheophylline (0.2 mg.kg-1.min-1) was without effect on cardiac output or portal blood flow. Adenosine infusion resulted in a dose-dependent increase in portal blood flow with a maximal effect at a dose of 0.17 mg.kg-1.min-1 (control, 41.3 +/- 2.3; adenosine, 81.7 +/- 8.0 ml.kg-1.min-1; P less than 0.05). This adenosine-induced increase in portal blood flow was inhibited by 8-phenyltheophylline in a dose-dependent manner [adenosine, 81.7 +/- 8.0 ml.kg-1.min-1; adenosine + 8-phenyltheophylline (0.2 mg.kg-1.min-1), 49.8 +/- 6.6 ml.kg-1.min; P less than 0.05]. Both alcohol and adenosine significantly reduced preportal vascular resistance by 40% (P less than 0.02) and 60% (P less than 0.01), respectively. These effects were fully suppressed by 8-phenyltheophylline. It is concluded that adenosine is a likely candidate to mediate the ethanol-induced increase in portal vein blood flow. It is suggested that an increase in circulating acetate and liver hypoxia may mediate the effects of alcohol by increasing tissue and interstitial adenosine levels.

Noninvasive estimation of blood alcohol concentrations: ethanol vapor above the eye.

The present study describes, in animals, a novel approach to the in vivo, noninvasive determination of alcohol in the body. The concentration of ethanol in vapor above the lacrimal fluid in the eye was analyzed in situ by the use of a fast (1-min) gas sensor method developed previously for biological liquids. After an oral dose of 1 g/kg to 11 animals, eye vapor measurements and blood samples were obtained over 4 hr. The correlation of 61 blood ethanol concentrations obtained by the two methods yielded a correlation coefficient of 0.92 and a slope of 0.99. The metabolic rates of ethanol determined by gas chromatographic analysis of blood and by ethanol eye vapor analysis are virtually identical. The data suggest that ethanol eye vapor analysis may be an attractive, noninvasive method for the determination of ethanol in animals. The method is not subject to false high readings due to alcohol in the buccal cavity and thus might constitute an alternative to breath analysis in the human. In a separate series, ethanol was determined by head space gas chromatography in samples of blood and lacrimal fluid while the animals were under ketamine anesthesia. The correlation of ethanol concentrations in blood and lacrimal fluid (r = 0.99) shows that ethanol is distributed in lacrimal fluid which comprises part of total body water.

Blood acetaldehyde and the ethanol-induced increase in splanchnic circulation.

Acute oral administration of ethanol significantly increases (50-60%) portal blood flow to the liver. As earlier studies have indicated that this effect is maximal at concentrations of ethanol that saturate the alcohol dehydrogenase (ADH) system and is blocked by the ADH inhibitor 4-methylpyrazol, we investigated the possible role of acetaldehyde, a product in the ADH reaction, as a mediator of this effect. In the first series of experiments it was shown that, contrary to expectations, cyanamide administration prior to alcohol suppressed fully the effect of ethanol on portal blood flow without altering it in the absence of ethanol [ethanol = 69.5 +/- 5.6; ethanol + cyanamide 42.9 +/- 2.4; control = 43.0 +/- 3.0; cyanamide = 55.1 +/- 3.7 ml X min-1 X (kg body wt)-1]. Arterial blood concentrations of acetaldehyde were elevated from 3.6 +/- 0.3 microM in the presence of ethanol to 293 +/- 48 microM in the presence of ethanol + cyanamide. Infusion of acetaldehyde either into the left ventricle, resulting in arterial blood acetaldehyde levels of 227 +/- 77 microM, or into the portal circulation, resulting in arterial blood levels of 198 +/- 40 microM, did not modify portal blood flow or splanchnic hemodynamics, nor the effect of ethanol per se. The combination of cyanamide + ethanol significantly reduced total peripheral resistance (from 28 +/- 3 to 19 +/- 2 dyne X cm X sec-5), while neither ethanol or cyanamide per se, nor acetaldehyde affected total peripheral resistance. Data suggest that acetaldehyde is not involved in the ethanol-mediated increase in portal vein flow. Further studies indicate that the effects of cyanamide in suppressing the ethanol-induced increase in portal blood flow and increasing total peripheral resistance appear to be related to an ethanol-cyanamide interaction which is independent of the acetaldehyde levels in the circulation.