Dr Christopher Rose's hepato-neuro laboratory

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• 2.2.1: Who are we?
• 2.2.2: Research projects
• 2.2.3: Dr Rose
• 2.2.4: Team
• 2.2.5: Publications
  • 2.2.5.1: Publications
  • 2.2.5.2: Bibliography
  • 2.2.5.3: Abstracts/Meetings
• 2.2.6: Technics
• 2.2.7: 24h de science

2012

1. Bosoi, C. R.; Tremblay, M. & Rose, C. F. Association francophone pour le savoir, May 7^th-11^th, Montréal, Canada. Oral presentation.
   

   [↓Abstract↓]

   L'encéphalopathie hépatique (EH), un syndrome métabolique neuropsychiatrique, est une complication majeure de la maladie hépatique. L’hyperammonémie est le facteur central dans l’EH. L’œdème cérébral est une importante caractéristique pathophysiologique de l’EH. Nous avons investigué le rôle du stress oxydatif dans deux modèles de maladie du foie/EH chez le rat; 1) dérivation portosystémique (PCA), et 2) ligature de la voie biliaire (BDL). L’ammoniaque et les espèces réactives d’oxygène (ROS) ont été mesurés dans le plasma (artériel) et au niveau cérébral. Le contenu cérébral en eau a été mesuré dans le cortex frontal. L’hyperammonémie s’est développée dans les deux groupes, PCA et BDL (p<0.001 vs contrôles). En conséquence, l’ammoniaque cérébrale était aussi élevée, sans différence significative entre les PCA et BDL. Seuls les rats BDL montraient une augmentation des ROS plasmatiques. Nous n’avons pas observé d’augmentation des ROS cérébraux chez les PCA et BDL. Le contenu en eau du cerveau était augmenté seulement chez les rats BDL (p<0.05 vs contrôles) ; il a été normalisé suite à un traitement avec un antioxydant (allopurinol). L’induction du stress oxydatif chez les rats PCA à l’aide du diméthyle maléate (inhibiteur de glutathion) a provoqué l’augmentation de l’eau cérébrale (p<0.05 vs contrôles). En conclusion, le stress oxydatif systémique est impliqué dans l’œdème cérébral et son effet synergique avec l’ammoniaque contribue à la progression de l’EH.
2. Bosoi, C. R.; Parent-Robitaille, C.; Tremblay, M. & Rose, C. F. 8^th Annual Canadian Association for Study of the Liver Meeting, February 24^th–27^th, Montreal, Canada in Can J Gastroenterol. 26:47A. Oral presentation.
   

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   [↓Abstract↓]

   Aims: The pathogenesis of hepatic encephalopathy (HE) is multifactorial. Even though ammonia is the central component in the pathogenesis of HE, oxidative stress is believed to play a role in exacerbating the neuropsychological effects of ammonia in patients with liver disease. With new, highly sensitive imaging techniques, brain edema is observed in HE patients. We previously demonstrated that portacaval shunted hyperammonemic rats do not develop oxidative stress or brain edema. In order to define a synergistic effect between hyperammonemia and systemic oxidative stress, the present study investigates the role of oxidative stress in the pathogenesis of brain edema in PCA rats following glutathione depletion by diethyl maleate (DEM).
   Methods: In the first set of experiments, we evaluated the effect of DEM in PCA and SHAM-operated control rats by injecting DEM at a dose of 0.4 and 1 mg/kg/day intraperitoneally for 10 days starting at day 18 after surgery. Rats were sacrificed at day 28 and oxidative stress was evaluated by arterial malon-dialdehyde (MDA, commercial kit). In the second set of experiments, 1 mg/kg/day DEM was used to induce oxidative stress. Ammonia (commercial kit) as well as other different oxidative stress markers: reactive oxygen species (DCFDA fluorescence technique), and 4-hydroxy-2-nonenal (HNE, Western blot) were assessed in arterial plasma and frontal cortex tissue. Brain water content was measured in the frontal cortex using a specific gravimetric technique.
   Results: DEM at 1 mg/kg/day (not 0.4 mg/kg/day) induced a significant increase in MDA levels in PCA rats. No increase in MDA was detected following either dose of DEM in SHAM-operated controls. Ammonia levels in both DEM-treated and non-treated PCA rats were significantly increased vs respective sham-operated controls (p<0.001) and remained unchanged between non-treated and DEM-treated PCA groups (p>0.05). An increase in brain water content was observed in DEM-treated PCA rats vs non-treated PCA rats (PCA+DEM: 78.45 ± 0.13% vs PCA: 77.38 ± 0.11, p< 0.001). Although no significant changes in reactive oxygen species were observed, there was an increase in plasma levels of HNE in DEM-treated PCA rats compared to non-treated PCA rats. No significant changes in any oxidative stress markers were observed in the frontal cortex.
   Conclusions: DEM treatment in PCA rats induced systemic oxidative stress but not central oxidative stress. This, imposed on hyperammonemia, was accompanied by the onset of brain edema in rats with PCA. Oxidative stress and brain edema were not detected in SHAM-operated rats, which were not hyperammonemic. Our findings suggest a synergistic effect between hyperammonemia and systemic oxidative stress is implicated in the pathogenesis of brain edema in hepatic encephalopathy.
3. Bosoi, C. R.; Parent-Robitaille, C.; Tremblay, M. & Rose, C. F. 8^th Annual Canadian Association for Study of the Liver Meeting, February 24^th–27^th, Montreal, Canada in Can J Gastroenterol. 26:46A. Oral presentation, Student Research Prize.
   

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   [↓Abstract↓]

   Aims: Liver disease leads to hyperammonemia, a central component in the pathogenesis of hepatic encephalopathy (HE). There is increasing evidence that systemic oxidative stress may exacerbate the neuropsychological effects of hyperammonemia in patients with liver disease. With new, highly sensitive imaging techniques, brain edema is commonly being observed in patients with cirrhosis and HE. Bile duct ligated rats, six-week after intervention, present with brain edema, hyperammonemia and also an increase in plasma reactive oxygen species (ROS) along with an increase in xanthine oxidase activity. In order to better understand the relationship between oxidative stress and ammonia and their role in the pathogenesis of brain edema, we evaluated the effect of xanthine oxidase inhibition in rats with cirrhosis.
   Methods: Cirrhosis was induced in rats by bile duct ligation (BDL) for 6 weeks. BDL and SHAM-operated rats received 100 mg/kg/day of allopurinol (xanthine oxidase inhibitor) during the last 10 days before sacrifice. As control groups, separate BDL and SHAM-operated rats received equivalent volume of saline. AST and ALT were measured at the end of the treatment period to assess liver function. Ammonia and ROS were assessed in arterial plasma using a commercially available kit and a DCFDA-fluorescent technique respectively. Brain water content was measured in the frontal cortex using the specific gravimetric technique.
   Results: Arterial ROS and ammonia levels were significantly increased in BDL vs SHAM-operated rats (p<0.001). BDL rats treated with allopurinol demonstrated a significant decrease in systemic ROS as well as ammonia levels vs non-treated BDL rats (1.70 ± 0.53RFU vs 4.97 ± 1.38RFU, p<0.05, 37.9 ± 13.8µM vs 101.1 ± 10.1µM, p<0.001, respectively), reaching values similar to those seen in SHAM-operated rats. Brain water content increased in BDL vs SHAM-operated rats and normalised in allopurinol treated BDL rats (77.20 ± 0.08% vs BDL: 78.46 ± 0.28%, p<0.05). Liver function markers, AST and ALT, increased in BDL rats compared to their respective SHAM-operated controls (p<0.001) and were not attenuated following allopurinol treatment.
   Conclusions: Allopurinol treatment decreased systemic ROS and attenuated brain edema as well as arterial ammonia levels. The effect of allopurinol demonstrates oxidative stress plays a role in ammonia metabolism and in the pathogenesis of brain edema. Our results suggest antioxidant treatment directed towards inhibiting ROS production could be beneficial in lowering ammonia and treating HE. Additional studies are warranted to evaluate the implication of oxidative stress in ammonia metabolism.

2011

4. Bosoi, C. R.; Parent-Robitaille, C.; Marin, H.; Tremblay, M. & Rose, C. F. 62^nd Annual Meeting of the American Association for the Study of Liver Diseases, November, San Francisco, USA in Hepatology. 54:1238A.
   

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   [↓Abstract↓]

   Background: Liver disease leads to hyperammonemia, a central component in the pathogenesis of hepatic encephalopathy (HE). There is increasing evidence systemic oxidative stress may exacerbate the neuropsychological effects of hyperammonemia in patients with liver disease. With new highly sensitive imaging techniques, brain edema is frequently being observed in patients cirrhosis and HE. Six-week cirrhotic rats develop brain edema, hyperammonemia and also an increase in plasma reactive oxygen species (ROS) along with an increase in xanthine oxidase activity. In order to better understand the relationship between oxidative stress and ammonia and their role in the pathogenesis of brain edema, we evaluated the effect of allopurinol, a xanthine oxidase inhibitor, in rats with cirrhosis. Methods: Secondary biliary cirrhosis was induced in rats by bile duct ligation (BDL) for 6 weeks. BDL and SHAM-operated rats received 100 mg/kg/day of allopurinol for 10 days. A group of BDL and SHAM-operated rats received saline. AST and ALT were measured at the end of the treatment period to assess liver function. Ammonia and ROS were assessed in arterial plasma using a commercially available kit and a DCFDA-fluorescent technique respectively. Brain water content was measured in the frontal cortex using the specific gravimetric technique. Results: Arterial ROS and ammonia levels were significantly increased in BDL vs SHAM-operated rats (p<0.001). BDL rats treated with allopurinol demonstrated a significant decrease in systemic ROS as well as ammonia levels vs non-treated BDL rats (1.70 ± 0.53RFU vs 4.97 ± 1.38RFU, p<0.05, 37.9 ± 13.8µM vs 101.1 ± 10.1µM, p<0.001, respectively), reaching values similar to those seen in SHAM-operated rats. Brain water content increased in BDL vs SHAM-operated rats and normalised in allopurinol treated BDL rats (77.20 ± 0.08% vs BDL: 78.46 ± 0.28%, p<0.05). Liver function markers, AST and ALT, increased in BDL rats compared to their respective SHAM-operated controls (p<0.001) and were not attenuated following allopurinol treatment. Conclusions: Allopurinol treatment decreased systemic ROS and attenuated brain edema as well as arterial ammonia levels. The effect of allopurinol demonstrates oxidative stress plays a role in ammonia metabolism and in the pathogenesis of brain edema. Our results suggest antioxidant treatment directed towards inhibiting ROS production could be beneficial in lowering ammonia and treating HE. Additional studies are warranted to evaluate the implication of oxidative stress in ammonia metabolism.
5. Bosoi, C. R.; Parent-Robitaille, C.; Marin, H.; Tremblay, M. & Rose, C. F. 62^nd Annual Meeting of the American Association for the Study of Liver Diseases, November, San Francisco, USA in Hepatology. 54:1245A.
   

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   [↓Abstract↓]

   Aims: Brain edema is a common occurrence in patients with hepatic encephalopathy (HE) due to chronic liver disease however the underlying pathophysiological mechanisms are weakly described. Hyperammonemia is considered the central component, but levels of plasma ammonia and severity of HE poorly correlate. Oxidative stress and impaired lactate metabolism are pathogenetic factors believed to be involved. This study investigates the temporal resolution of increases in ammonia, oxidative stress and lactate in relation to the development of brain edema in bile-duct ligated rats (BDL), a widely used rat model of chronic liver disease and HE. Methods: Cirrhosis was induced in rats through ligation of the bile duct. Ammonia and reactive oxygen species (ROS) were assessed in arterial plasma using a commercially available kit and a DCFDA-fluorescent technique respectively. Brain water content was measured in the frontal cortex using the specific gravimetric technique and lactate by Amplex Red fluorescence. Measurements were performed in BDL rats vs sham operated controls at 2, 4 and 6 weeks after surgical intervention in plasma and cerebrospinal fluid or brain tissue. Results: See table. Conclusions: Following 2 weeks of BDL, an increase in plasma ROS is observed with no increase in the other factors. Following 4 weeks of BDL, in addition to an increase in systemic ROS, an increase in plasma and brain ammonia and brain (not plasma) lactate is demonstrated however no evidence of brain edema. Brain edema appears at 6 weeks, along with an increase in all 3 factors. The further significant increase in brain lactate and ammonia at 6 weeks compared to 4 weeks, superimposed on systemic oxidative stress, may be responsible the of development of brain edema in BDL rats. Our results support the multifactorial pathogenesis of brain edema in HE and suggests systemic oxidative stress might be an important “first hit”, followed by increases in ammonia and lactate, in the pathogenesis of brain edema in chronic liver failure.

   SHAMⱡBDL
   2 weeksBDL
   4 weeksBDL
   6 weeks
   PLASMA
   AMMONIA(μM)37.24±12.5433.24±16.7371.32±12.03*118.50±10.78*$
   ROS(RFU)0.08±0.032.94±0.39***2.05±0.59***3.68±0.86***
   LACTATE(mM)1.40±0.191.22±0.181.21±0.131.75±0.35
   CEREBROSPINAL FLUID
   AMMONIA(μM)36.12±13.2335.94±9.6389.38±13.07*128.4±36.66***$
   ROS(RFU)26.11±9.9423.95±12.2613.61±1.6325.97±8.21
   BRAIN TISSUE
   LACTATE(μM/ 100 g proteins)88.51±5.2698.06±7.78190.26±26.14*254.60±10.12***$
   BRAIN EDEMA (%)78.05±0.1477.73 ±0.0777.69±0.0779.03±0.31*$
   ⱡ mean value of SHAM-operated rats 2, 4 and 6 weeks
   *p<0.05 vs SHAM
   ***p<0.01 vs SHAM
   $p<0.05 vs BDL 4 weeks

6. Bosoi, C. R.; Zwingmann, C.; Huynh, J.; Marin, H.; Tremblay, M. & Rose, C. F. 7^th Annual Canadian Association for Study of the Liver Meeting, February 26^th-March 2^nd, Vancouver, Canada in Can J Gastroenterol. 25:33A. Oral presentation. Student Research Prize.
   

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   [↓Abstract↓]

   Aims: Chronic liver failure leads to hyperammonemia, a central component in the pathogenesis of hepatic encephalopathy (HE). Neurotoxic effects of ammonia induce numerous metabolic alterations such as increased brain lactate (Lac) and glutamine (Gln) levels. Brain edema is present in patients with chronic liver failure however the pathophysiological mechanisms are not clearly understood. The present study investigates the role of brain ammonia, Lac and Gln in pathogenesis of brain edema in 2 different rat models of chronic liver failure/HE; 1) portacaval anastomosis (PCA), and 2) bile-duct ligation (BDL).
   Methods: Ammonia (commercial kit), brain edema (specific gravimetric technique) Lac (Amplex Red fluorescence) and Gln (1H nuclear magnetic spectroscopy) were measured in brain tissue of PCA and BDL rats vs sham operated controls. De novo synthesis of Lac and Gln was assessed in brain tissue by 13C nuclear magnetic resonance spectroscopy, after injecting PCA and BDL rats along with their respective sham operated controls with [U-13C] glucose (500 mg/kg, i.p) 30 minutes before sacrifice. Lac, Gln and brain edema were also investigated in BDL rats at 2, 4 and 6 weeks after surgery and after reducing ammonia levels with AST-120 (spherical carbon adsorbent), at 1g/kg/day for 6 weeks.
   Results: Hyperammonemia developed in both PCA (177.3±8.9μM vs sham: 52.1±11.3μM; p<0.0001) and BDL (155.0±8.9μM vs sham: 41.0±11.2μM; p<0.0001); with no significant difference between the groups. An increase in brain water content was observed in rats with BDL (81.88±0.12% vs sham: 81.13±0.15%, p<0.05), as well as total Lac levels; whereas no significant change in brain water and total Lac was found in PCA. Gln levels significantly increased in PCA rats and BDL rats vs respective sham-operated controls. A significant increase in de novo synthesis of 13C Lac and 13C Gln from 13C glucose was found in BDL rats, whereas in PCA rats only de novo synthesis of 13C Gln increased. In addition, total Lac levels were increased in BDL rats before the apparition of brain edema. Following AST-120 treatment, Lac levels and brain edema significantly decreased, while Gln levels remained unchanged.
   Conclusions: BDL and PCA rats both presented with similar levels of hyperammonemia and Gln, as well as increased de novo synthesis of Gln from glucose. However only BDL rats demonstrated an increase in brain water and Lac as well as increased de novo synthesis of Lac from glucose. Our findings suggest increased brain Lac, not increased brain Gln, is associated with brain edema. We conclude that impaired Lac metabolism may contribute to the pathogenesis of brain edema in HE.
7. Bosoi, C. R.; Parent-Robitaille, C.; Marin, H.; Tremblay, M. & Rose, C. F. 7^th Annual Canadian Association for Study of the Liver Meeting, February 26^th-March 2^nd, Vancouver, Canada in Can J Gastroenterol. 25:271A. Distinction poster.
   

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   [↓Abstract↓]

   Aims: Brain edema represents a constant finding in patients with hepatic encephalopathy (HE) due to chronic liver failure; however its pathogenetic mechanisms are poorly described. Hyperammonemia is considered the central component in the pathogenesis of HE, but ammonia levels are not correlated with severity of HE. Other factors such as oxidative stress and impaired lactate metabolism are believed to be involved. Temporal resolution of these factors involved in the progression of the disease and brain edema might elucidate the relationship between these pathogenetic factors. The present study investigates temporal resolution of ammonia, oxidative stress and lactate in relation to the development of brain edema in bile-duct ligated rats (BDL), a widely used rat model of chronic liver failure and HE. Methods: Ammonia (commercial kit), reactive oxygen species (ROS) (DCFDA fluorescence), lactate (Amplex Red fluorescence) and brain edema (specific gravimetric technique) were measured in BDL rats vs sham operated controls at 2, 4 and 6 weeks after surgical intervention in plasma and cerebrospinal fluid or brain tissue. Results: See table.Conclusions: Following 2 weeks of BDL, an increase in plasma oxidative stress is observed with no appearance of hyperammonemia, hyperlactataemia, increased brain lactate and ammonia or brain edema. Following 4 weeks of BDL, in addition to an increase in systemic oxidative stress, an increase in plasma and brain ammonia and brain (not plasma) lactate is demonstrated but still no evidence of brain edema. Brain edema appears at 6 weeks, along with an increase in all 3 pathogenetic factors. The further increase in brain lactate and ammonia compared to 4 weeks, superimposed on systemic oxidative stress, may be responsible the development of brain edema in BDL rats. Our results support the multifactorial pathogenesis of brain edema in HE and suggests systemic oxidative stress might be an important “first hit”, followed by increases in ammonia and lactate, in the pathogenesis of brain edema in chronic liver failure.
8. Huynh, J.; Bosoi, C. R.; Parent-Robitaille, C.; Tremblay, M. & Rose, C. F. 7^th Annual Canadian Association for Study of the Liver Meeting, February 26^th-March 2^nd, Vancouver, Canada in Can J Gastroenterol. 25:34A. Oral presentation.
   

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   [↓Abstract↓]

   Aims: Brain edema is a serious complication associated with hepatic encephalopathy (HE) due to chronic liver failure. It is unclear whether brain edema is of vasogenic (blood brain barrier (BBB) breakdown) or of cytotoxic (disturbance of neurocellular metabolism) origin. It has been demonstrated that the Na-K-Cl cotransporter (NKCC) located on the luminal side of the BBB is implicated in the pathogenesis of brain edema in different animal models of ischemia. Furthermore, following the administration of bumetanide, an inhibitor of NKCC, brain edema is attenuated. Therefore, our aim was to study the BBB integrity and the role of NKCC in the pathogenesis of brain edema in cirrhotic rats. Methods: Two distinct animal models of chronic liver failure and HE are used in the present study; 1) biliary cirrhosis model (6 weeks bile duct ligation (BDL)). 2) portacaval shunt model (4 weeks portacaval anastomosis (PCA)). Both models develop hyperammonemia however brain edema is only observed in BDL. BBB breakdown was assessed by measuring brain extravasation of BBB permeability tracers. Evans blue and sodium fluorescein were injected (i.v), brains were perfused and extravasation was determined by spectophotometry. Expression of BBB tight junction proteins (occludin, claudin-5, ZO-1 and ZO-2) were assessed by immunoblot. Bumetanide was administered (i.p) for 10 days in BDL and BDL SHAM. Brain water content was measured in the frontal cortex using the specific gravimetric method. Levels of brain NKCC mRNA were evaluated by RT-PCR in microvessels isolated using centrifugation methods. Results: Extravasation of Evans blue and sodium fluorescein was not detected and there was no significant change in all tight junction protein levels measured in both BDL and PCA (negative control) models. Brain water content was reduced in bumetanide-treated BDL rats compared to control (77.66±0.15% vs 78.12±0.21%). In brain microvessels, NKCC mRNA increased in BDL rats compared to BDL SHAM (0.78±0.09 vs. 1.92±0.42) whereas no change was found in PCA compared to PCA SHAM (1.72±0.52 vs. 1.53±0.23). Conclusions: BDL rats did not demonstrate a change in BBB integrity or a change in expression of BBB tight junction proteins. This suggests brain edema in BDL is not of vasogenic origin. Moreover, an increase of NKCC mRNA and an attenuation of brain edema following bumetanide treatment were demonstrated in BDL rats suggesting NKCC plays a role in the development of brain edema in chronic liver failure.
9. Huynh, J.; Bosoi, C. R.; Parent-Robitaille, C.; Tremblay, M. & Rose, C. F. 46^th Annual Meeting European Association for the Study of the Liver, March 30^th-April 3^rd, Berlin, Germany in J Hepatol. 54:S249-S250.
   

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   [↓Abstract↓]

   Background: Brain edema is a serious complication associated with hepatic encephalopathy (HE) due to chronic liver failure (CLF) and its pathogenesis remains undefined. NKCC1, a Na-K-Cl cotransporter, located on the blood-brain barrier (BBB) has been demonstrated to be implicated in the pathogenesis of brain edema in experimental models of ischemia. Therefore, our aim was to 1) investigate the relationship of hyperammonemia, 2) study the integrity of the BBB and 3) determine the role of NKCC1, in association with brain edema in rats with CLF. Methods: Two distinct animal models of CLF and HE were used; i) biliary cirrhosis model (6 weeks bile duct ligation (BDL)) ii) portacaval shunt model (4 weeks portacaval anastomosis (PCA)). Brain water content was measured using the specific gravimetric method. BBB breakdown was assessed by measuring brain extravasation of injected BBB permeability tracers (Evans blue and sodium fluorescein). Expression of BBB tight junction proteins (occludin, claudin-5, ZO-1 and ZO-2) were assessed by immunoblot. Levels of brain NKCC1 mRNA were evaluated by RT-PCR in isolated cerebral microvessels. Rats were treated with bumetanide (an NKCC inhibitor; administered (i.p) for 10 days). Results: Similar degree of hyperammonemia was measured in both BDL and PCA rats however brain edema was only found in BDL rats. In brains of both BDL and PCA rats, extravasation of Evans blue and sodium fluorescein was not detected and no significant change in the levels of all tight junction proteins was found. Brain water content was reduced in bumetanide-treated BDL vs BDL-non treated (77.35±0.18% vs 78.89±0.25%). A 2.4 fold increase in NKCC1 mRNA was detected in BDL vs BDL-sham rats whereas no change was found in PCA vs PCA-sham rats. Conclusions: Chronic hyperammonemia independently does not lead to an increase in brain water. Brain edema, present in BDL rats, is not associated with a change in either BBB integrity or expression of BBB tight junction proteins and is therefore not of vasogenic origin. Furthermore, an increase in NKCC1 mRNA and attenuation of brain edema following bumetanide treatment, suggests NKCC1, independent of hyperammonemia, plays a role in the development of brain edema in CLF.

2010

10. Bosoi, C. R.; Zwingmann, C.; Huynh, J.; Marin, H.; Tremblay, M. & Rose, C. F. 61^st Annual Meeting of the American Association for the Study of Liver Diseases, October 29^th-November 2^nd, Boston, USA in Hepatology. 52:900A.
    

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    [↓Abstract↓]

    Background: Chronic liver failure leads to hyperammonemia, a central component in the pathogenesis of hepatic encephalopathy. Neurotoxic effects of ammonia have been shown to induce numerous metabolic alterations such as increased brain lactate and glutamine levels. Newly developed imaging techniques have demonstrated brain edema is present in patients with chronic liver failure however the pathophysiological mechanisms are not clearly understood. The present study investigates the role of de novo synthesis of brain lactate and glutamine in pathogenesis of brain edema in 2 different rat models of chronic liver failure/hepatic encephalopathy; 1) portacaval anastomosis (PCA), and 2) bile-duct ligation (BDL). Methods: PCA and BDL rats along with their respective sham-operated controls were injected with [1-13C] glucose (500 mg/kg, i.p) and sacrificed 30 minutes later. Glutamine and lactate were assessed in brain tissue by 1H and 13C nuclear magnetic resonance spectroscopy. Ammonia levels were measured in arterial plasma and cerebrospinal fluid using a commercially available kit. Brain water content was measured in frontal cortex using a specific gravimetric technique. Results: Hyperammonemia developed in both PCA (177.3 ± 8.9μM vs sham: 52.1 ± 11.3μM; p< 0.0001) and BDL (155.0 ± 8.9μM vs sham: 41.0 ± 11.2μM; p< 0.0001); with no significant difference between the groups (p> 0.05). Similar results were found in cerebrospinal fluid (PCA: 179.5 ± 10.3μM vs sham: 34.9 ± 6.3μM; p< 0.0001 and BDL: 142.6 ± 28.3μM vs sham: 27.9 ± 4.9μM; p< 0.0001); with no significant difference between the groups (p> 0.05). An increase in brain water content was observed in rats with BDL (81.88 ± 0.12% vs sham: 81.13 ± 0.15%, p< 0.05) whereas no significant change in brain water content was found in PCA vs their respective sham-operated controls. Glutamine levels significantly increased 3 fold in PCA rats and 2 fold in BDL rats vs respective sham-operated controls. A significant increase in de novo synthesis of 13C lactate and 13C glutamine from 13C glucose was found in BDL rats (1.6 fold and 2 fold respectively vs sham), whereas in PCA rats only de novo synthesis of 13C glutamine increased. Conclusion: BDL and PCA rats both presented with similar levels of hyperammonemia and increased brain ammonia, increased de novo synthesis of glutamine from glucose however only BDL rats demonstrated an increase in brain water as well as an increase in de novo synthesis of lactate from glucose. Our findings suggest lactate is an important pathogenic factor implicated in the pathogenesis of brain edema in chronic liver failure.
11. Bosoi, C. R.; Parent-Robitaille, C.; Tremblay, M. & Rose, C. F. 6^th Annual Canadian Association for the Study of Liver Meeting, February 27^th-March 2^nd, Toronto, Canada in Can J Gastroenterol. 24:A27. Oral presentation.
    

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    [↓Abstract↓]

    AIMS: The pathogenesis of hepatic encephalopathy (HE) is multifactorial involving gut-derived toxins such as ammonia. Liver disease leads to hyperammonemia and neurotoxic levels of ammonia which have been demonstrated to induce oxidative stress. Therefore a primary treatment target for HE is to decrease ammonia production in the gastrointestinal tract. AST-120 (spherical carbon adsorbent), an oral adsorbent of engineered activated carbon microspheres with surface areas exceeding 1600m2/g acts as a sink for neuro- and hepato-toxins present in the gut. In this study, we evaluated the protective effect of AST-120 in lowering arterial ammonia and oxidative stress and in attenuating brain edema in rats with cirrhosis.
    METHODS: Secondary biliary cirrhosis was induced in rats by bile-duct ligation (BDL) for 6 weeks. BDL and SHAM-operated rats received AST120 (dispersed in methylcellulose (MC)) by gavage at a dose of 0.1, 1 or 4g/kg/day for 6 weeks. Control BDL and SHAM-operated groups received MC only. AST and ALT were measured to assess liver function. Ammonia and reactive oxygen species (ROS) were measured in arterial plasma using a commercially available kit and DCFDA-fluorescent technique respectively. Brain water content was measured in the frontal cortex using the specific gravimetric technique.
    RESULTS: AST-120 was well-tolerated with no deaths in either of the treatment groups. Brain water content increased in BDL vs SHAM-operated rats (79.2±0.2% vs 78.7±0.1%, p<0.05). All AST-120 treatments, 0.1, 1 and 4g/kg/day, normalised brain water content in BDL rats. Arterial ammonia levels increased in the BDL control group vs SHAM-operated controls (169.9±21.1uM vs 70.5±14.4uM, p<0.05) and decreased significantly to SHAM levels in 0.1g/kg/day (117.2±12.6uM, p<0.05), 1g/kg/day (78.9±22.3uM, p<0.05) and 4g/kg/day (48.7±19.5uM, p<0.05) AST-120 treated BDL rats. Circulating levels of ROS were significantly increased in BDL vs SHAM-operated rats (11 fold, p<0.001). AST-120 treatments did not attenuate arterial levels of ROS compared to respective SHAM-operated controls. Liver functions enzymes, AST and ALT, were increased in all BDL rats compared to their respective SHAM-operated controls (p<0.001) but were not attenuated following AST120 treatments.
    CONCLUSIONS: AST-120 treatment normalized brain water content and decreased arterial ammonia levels but did not demonstrate an effect on systemic ROS. Long-term treatment with AST-120 is a safe, non-antibiotic alternative with significant ammonia-lowering effect as well as a protective effect on the development of brain edema in rats with chronic liver failure. Additional studies are warranted to evaluate the effects of AST-120 on HE in patients with advanced liver disease.
12. Bosoi, C. R.; Parent-Robitaille, C.; Tremblay, M. & Rose, C. F. 45^th annual meeting of the European Association for the Study of the Liver, April 14^th-18^th, Vienna, Austria in J Hepatol. 52:S202. Selected 10% top poster.
    

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    [↓Abstract↓]

    Background: Ammonia is central in the pathogenesis of hepatic encephalopathy (HE) and clinical sequelae are exacerbated by systemic inflammation. Sequestration of ammonia in the gut represents a primary treatment target for HE. AST-120 (spherical carbon adsorbent), an oral adsorbent of engineered activated carbon microspheres with surface areas exceeding 1600m2/g works as a sink for neuro- and hepato–toxins present in the gut. In this study, we evaluated the capacity of AST-120 to lower arterial ammonia, brain edema and systemic inflammatory markers in cirrhotic rats. Methods: Cirrhosis was induced in rats by bile duct ligation (BDL). BDL and SHAM-operated rats received AST-120 dispersed in methylcellulose by gavage at a dose of 0.1, 1 or 4g/kg/day for 6 weeks. Ammonia and the pro-inflammatory cytokine TNF-α were measured in arterial plasma using a commercially available kit and ELISA technique respectively. Brain water content was measured in the frontal cortex, cerebellum and brain stem using the specific gravimetric technique. Results: Arterial ammonia increased in non-treated BDL vs SHAM-operated controls (166.9±21.1uM vs 70.5±14.4uM, p<0.01). All doses of AST-120 decreased ammonia in BDL to similar levels found in respective SHAM-operated controls; 0.1g/kg/day (117.2±12.6uM vs 100.4±7.3uM, p>0.05); 1g/kg/day (78.9±22.3uM vs 78.1±8.9uM, p>0.05) and 4g/kg/day (48.8±19.6uM vs 49.9±14.7uM, p>0.05). Ammonia levels significantly correlated with doses of AST-120 (r=-0.66, p<0.0001). Brain water content increased in frontal cortex, cerebellum and brain stem in BDL vs SHAM-operated and was normalized in all AST-120 treatment groups compared to respective controls. Circulating levels of TNF-α were significantly increased in BDL vs SHAM-operated rats (p<0.05). AST-120 treatment did not attenuate TNF-α levels compared to respective SHAM-operated controls. Conclusion: AST-120 treatment dose-dependently decreased arterial ammonia levels, which resulted in normalization of multi-foci brain edema. This response was not correlated with differences in levels of circulating TNF-α. AST-120 treatment is a safe, non-antibiotic alternative demonstrating a significant ammonia-lowering effects, as well as a protective effect on the development of brain edema in rats with chronic liver disease. AST-120 represents a useful tool to elucidate further the relationship between circulating ammonia and gut-derived or systemic inflammatory components of liver disease.
13. Bosoi, C. R.; Zwingmann, C.; Huynh, J.; Marin, H.; Tremblay, M. & Rose, C. F. 14^th International Society for Hepatic Encephalopathy and Nitrogen Metabolism, September 14^th-September 18^th, Val-David, Canada.
    
14. Rose, C. F. 14^th International Society for Hepatic Encephalopathy and Nitrogen Metabolism, September 14^th-18^th, Val-David, Canada.
    

2009

15. Bosoi, C.; Parent-Robitaille, C.; Tremblay, M. & Rose*, C. F. 60^th Annual Meeting of the American Association for the Study of Liver Diseases, October 30^th-November 3^rd, Boston, USA in Hepatology. 50:336A. Oral presentation.
    

    -

    [↓Abstract↓]

    Background: The pathogenesis of hepatic encephalopathy (HE) is multifactorial involving gut-derived toxins such as ammonia. Liver disease leads to hyperammonemia and neurotoxic levels of ammonia which have been demonstrated to induce oxidative stress. Therefore a primary treatment target for HE is to decrease ammonia production in the gastrointestinal tract. AST-120 (spherical carbon adsorbent), an oral adsorbent of engineered activated carbon microspheres with surface areas exceeding 1600m2/g works as a sink for neuro- and hepato–toxins present in the gut. In this study, we evaluated the protective effect of AST-120 in attenuating brain edema and the capacity of AST-120 to lower arterial ammonia and oxidative stress in rats with cirrhosis. Methods: Secondary biliary cirrhosis was induced in rats by bile duct ligation (BDL) for 6 weeks. BDL and SHAM-operated rats received AST-120 by gavage in methylcellulose (MC) at a dose of 0.1 or 1g/kg/day for 6 weeks. Control BDL and SHAM-operated groups received MC only. AST and ALT were measured at the end of the treatment period to assess liver function. Ammonia and reactive oxygen species (ROS) were measured in arterial plasma using a commercially available kit and DCFDA-fluorescent technique respectively. Brain water content was measured in the frontal cortex using the specific gravimetric technique. Results: AST-120 was well-tolerated with no deaths in either of the treatment groups. Brain water content increased in BDL vs SHAM-operated rats (81.8 ± 0.1% vs 81.3 ± 0.2%, p<0.05). Both 0.1 and 1g/kg/day AST-120 treatments normalised brain water content in BDL rats. Arterial ammonia increased in the BDL control group vs SHAM-operated controls (175.5 ± 48.1uM vs 105.3 ± 27.3uM, p<0.05) and decreased significantly in BDL 0.1g/kg/day (118.0 ± 6.4uM, p<0.05) and BDL 1g/kg/day (75.4 ± 31.4uM, p<0.05). Circulating levels of ROS were significantly increased in BDL vs SHAM-operated rats (11 fold, p<0.001). AST-120 treatment did not attenuate arterial levels of ROS compared to respective SHAM-operated controls. Liver functions enzymes, AST and ALT, were increased in all BDL rats compared to their respective SHAM-operated controls (p<0.001). Conclusions: AST-120 treatment normalized brain water content and decreased arterial ammonia levels but did not demonstrate an effect on systemic ROS. Long-term treatment with AST-120 is a safe, non-antibiotic alternative demonstrating a significant ammonia-lowering effect, as well as a protective effect on the development of brain edema in rats with chronic liver failure. Additional studies are warranted to evaluate the effects of AST-120 on HE in patients with advanced liver disease.
16. Bosoi, C. R.; Yang, X.; Jiang, W.; Parent-Robitaille, C.; Tremblay, M. & Rose, C. F. 5^th Annual Canadian Association Study Liver Winter Meeting, February 27^th-March 2^nd, Banff, Canada in Can J Gastroenterol. 23:64A. Oral presentation, Student Research Prize.
    

    -

    [↓Abstract↓]

    Background: Liver failure/disease leads to hyperammonemia which is central in the pathogenesis of hepatic encephalopathy. However, it is believed systemic oxidative/nitrosative stress may play an important role in exacerbating the neuropsychological effects of hyperammonemia observed in patients with liver disease. The present study aims to investigate the role of oxidative/nitrosative stress in 2 rat models of liver disease/hepatic encephalopathy; 1) portacaval anastomosis (PCA), and 2) bile-duct ligation (BDL). Methods: Rats were sacrificed 4 weeks following PCA and 6 weeks following BDL. Arterial plasma and cerebrospinal fluid (CSF) were collected to measure ammonia, reactive oxygen species (ROS), hydrogen peroxide (H2O2) (only measured in plasma) and nitric oxide (NO) using a commercially available kit, the DCFDA and Amplex Red fluorescent techniques and the Griess reaction respectively. S-nitrosylation of cystein thiols was measured in the frontal cortex and plasma proteins by immunoblotting. Brain water content was measured in the frontal cortex using a specific gravimetric technique. Results: Hyperammonemia developed in both PCA (PCA: 181.0 ± 8.5uM vs sham: 60.5 ± 7.0uM; p<0.0001) and BDL (BDL: 101.1 ± 11.0uM vs sham: 41.7 ± 9.2uM; p<0.05) rats with PCA rats being significantly higher compared to BDL rats (p<0.001). Consequently, ammonia increased in CSF in both PCA (PCA: 159.5 ± 15.8uM vs sham: 32.5 ± 3.7uM; p<0.0001) and BDL (BDL: 123.5 ± 21.7uM vs sham: 23.3 ± 6.1uM; p<0.05), but no significant change was observed between PCA and BDL. Only rats with BDL demonstrated an increase in plasma levels of ROS (5.8-fold increase vs sham; p<0.001), H2O2 (3.2-fold increase vs sham; p<0.05) and NO (2.9-fold increase vs sham; p<0.05). This was accompanied by an increase in S-nitrosylation of plasma proteins. No significant changes in CSF ROS and NO, nor in S-nitrosylation of frontal cortex proteins were found in BDL or PCA compared to their respective control groups. In addition, an increase in brain water content was observed in rats with BDL (BDL: 81.91 ± 0.19% vs sham: 81.23 ± 0.20, p<0.05). No significant change in brain water content was found in PCA rats vs sham-operated controls. Conclusion: Systemic oxidative stress together with hyperammonemia results in an increase in brain water in rats with BDL which is not demonstrated in PCA rats where only hyperammonemia is observed. Our findings suggest systemic oxidative stress is implicated in the pathogenesis of brain edema and its synergistic effect with ammonia may lead to progression of hepatic encephalopathy.
17. Bosoi, C. R.; Yang, X.; Jiang, W.; Parent-Robitaille, C.; Tremblay, M. & Rose, C. F. 44^th Annual Meeting of the European Association for the Study of the Liver, April 22^nd-26^th, Copenhagen, Denmark in J Hepatol. 50:S270. Travel Award (Cristina)
    

    -

    [↓Abstract↓]

    Background: Liver failure/disease leads to hyperammonemia, a central component in the pathogenesis of hepatic encephalopathy. However, it is believed systemic oxidative/nitrosative stress may exacerbate the neuropsychological effects of hyperammonemia observed in patients with liver disease. The present study aims to investigate the role of oxidative/nitrosative stress in 2 rat models of liver disease/hepatic encephalopathy; 1) portacaval anastomosis (PCA), and 2) bile-duct ligation (BDL). Methods: Rats were sacrificed 4 weeks following PCA and 6 weeks following BDL. Arterial plasma and cerebrospinal fluid (CSF) were collected to measure ammonia, reactive oxygen species (ROS), hydrogen peroxide (H2O2) and nitric oxide (NO). S-nitrosylation of cystein thiols was measured in the frontal cortex and plasma proteins by immunoblotting. Brain water content was measured in the frontal cortex using a specific gravimetric technique. Results: Hyperammonemia developed in both PCA (PCA: 181.0 ± 8.5uM vs sham: 60.5 ± 7.0uM; p< 0.0001) and BDL (BDL: 101.1 ± 11.0uM vs sham: 41.7 ± 9.2uM; p< 0.05) rats with PCA rats being significantly higher compared to BDL rats (p< 0.001). Consequently, ammonia increased in CSF in both PCA (PCA: 159.5 ± 15.8uM vs sham: 32.5 ± 3.7uM; p< 0.0001) and BDL (BDL: 123.5 ± 21.7uM vs sham: 23.3 ± 6.1uM; p< 0.05), but no significant change was observed between PCA and BDL. Only rats with BDL demonstrated an increase in plasma levels of ROS (5.8-fold increase vs sham; p< 0.001), H2O2 (3.2-fold increase vs sham; p< 0.05) and NO (2.9-fold increase vs sham; p< 0.05). This was accompanied by an increase in S-nitrosylation of plasma proteins. An increase in brain water content was observed in rats with BDL (BDL: 81.91 ± 0.19% vs sham: 81.23 ± 0.20, p< 0.05) whereas no significant change in brain water content was found in PCA vs sham-operated control rats. Conclusion: Hyperammonemia together with systemic oxidative stress are associated with brain edema in rats with BDL which is not demonstrated in PCA rats where only hyperammonemia is observed. Our findings suggest systemic oxidative stress is implicated in the pathogenesis of brain edema and its synergistic effect with ammonia may lead to progression of hepatic encephalopathy.
18. Bosoi, C.; Parent-Robitaille, C.; Tremblay, M. & Rose*, C. F. International Symposium on Hepatic Encephalopathy, September 17^th-19^th, Valencia, Spain.
    

    -

    [↓Abstract↓]

    Background: The pathogenesis of hepatic encephalopathy (HE) is multifactorial involving gut-derived toxins such as ammonia. Liver disease leads to hyperammonemia and neurotoxic levels of ammonia which have been demonstrated to induce oxidative stress. Therefore a primary treatment target for HE is to decrease ammonia production in the gastrointestinal tract. AST-120 (spherical carbon adsorbent), an oral adsorbent of engineered activated carbon microspheres with surface areas exceeding 1600m2/g works as a sink for neuro- and hepato-toxins present in the gut. In this study, we evaluated the protective effect of AST-120 in attenuating brain edema and the capacity of AST-120 to lower arterial ammonia and oxidative stress in rats with cirrhosis. Methods: Secondary biliary cirrhosis was induced in rats by bile duct ligation (BDL) for 6 weeks. BDL and SHAM-operated rats received AST-120 by gavage in methylcellulose (MC) at a dose of 0.1 or 1g/kg/day for 6 weeks. Control BDL and SHAM-operated groups received MC only. AST and ALT were measured at the end of the treatment period to assess liver function. Ammonia and reactive oxygen species (ROS) were measured in arterial plasma using a commercially available kit and DCFDA-fluorescent technique respectively. Brain water content was measured in the frontal cortex using the specific gravimetric technique. Results: AST-120 was well-tolerated with no deaths in either of the treatment groups. Brain water content increased in BDL vs SHAM-operated rats (81.8 ± 0.1% vs 81.3 ± 0.2%, p<0.05). Both 0.1 and 1g/kg/day AST-120 treatments normalised brain water content in BDL rats. Arterial ammonia increased in the BDL control group vs SHAM-operated controls (175.5 ± 48.1uM vs 105.3 ± 27.3uM, p<0.05) and decreased significantly in BDL 0.1g/kg/day (118.0 ± 6.4uM, p<0.05) and BDL 1g/kg/day (75.4 ± 31.4uM, p<0.05). Circulating levels of ROS were significantly increased in BDL vs SHAM-operated rats (11 fold, p<0.001). AST-120 treatment did not attenuate arterial levels of ROS compared to respective SHAM-operated controls. Liver functions enzymes, AST and ALT, were increased in all BDL rats compared to their respective SHAM-operated controls (p<0.001). Conclusions: AST-120 treatment normalized brain water content and decreased arterial ammonia levels but did not demonstrate an effect on systemic ROS. Long-term treatment with AST-120 is a safe, non-antibiotic alternative demonstrating a significant ammonia-lowering effect, as well as a protective effect on the development of brain edema in rats with chronic liver failure. Additional studies are warranted to evaluate the effects of AST-120 on HE in patients with advanced liver disease.
19. Davies, N.; Ten Have, G.; Sharma, V.; Ytrebø, L.; Sen, S.; Rose, C.; Revhaug, A.; Mookerjee, R. P.; Jalan, R. & Deutz, N. European Association for the Study of the Liver, April 22^nd-26^th, Copenhagen, Denmark in J Hepatol. 50:154.
    

    -

20. Yang, X.; Bosoi, C.; Tremblay, M. & Rose, C. F. 60^th Annual Meeting of the American Association for the Study of Liver Diseases, October 30^th-November 3^rd, Boston, USA in Hepatology. 50:459A.
    

    -

    [↓Abstract↓]

    Background: Ammonia plays a major role in the pathogenesis of hepatic encephalopathy however oxidative stress is also believed to be involved. Two lines of evidence lead us to the following aim of our study: 1) neurotoxic levels of ammonia have demonstrated to induce oxidative stress in vitro and 2) systemic oxidative stress is believed to exacerbate the neuropsychological effects of hyperammonemia observed in patients with liver disease. Our aim was to measure oxidative stress markers systemically and centrally, in association with brain edema in rats with cirrhosis. Methods: Rats were sacrificed 6 weeks following bile-ligated induced cirrhosis. Arterial plasma and cerebrospinal fluid (CSF) were collected to measure ammonia (commercially available kit), reactive oxygen species (ROS) (DCFDA-fluorescent technique), nitric oxide (NO) (Griess method) and lipid peroxidation (malondialdehyde, MDA) (commercially available kit). Frontal cortex was dissected to measure antioxidant catalase activity (Amplex Red fluorescent technique), S-nitrosylation of cystein thiols (immunoblotting) and brain water content was determined using the specific gravimetric technique. Results: Brain water content increased in BDL rats vs SHAM-operated controls (81.91 ± 0.19% vs 81.23 ± 0.20%, p<0.05). BDL rats vs SHAM-operated controls developed an increase in plasma arterial levels of ammonia (91.8 ± 18.4uM vs 41.2 ± 13.2uM, p<0.05), ROS (4.9 fold increase), NO (2.9 fold increase), MDA (41.9 ± 7.4uM vs 9.9 ± 0.6uM, p<0.005), S-nitrosylated proteins and a decrease in catalase activity (1.3 ± 0.5U/ml vs 3.2 ± 1.4U/ml, p<0.05). Centrally, BDL rats vs SHAM-operated controls developed an increase in CSF ammonia (123.5 ± 21.7uM vs 23.3 ± 6.1uM, p<0.05) but did not develop an increase in CSF ROS and NO or in brain MDA and S-nitrosylation detection. Furthermore, catalase activity in the brain was unchanged in BDL vs SHAM-operated controls. Conclusions: Six weeks following BDL, rats developed brain edema. An increase in arterial ammonia was accompanied with an increase in lipid peroxidation, NO, ROS and S-nitrosylation with a decrease in catalase activity. However, a similar increase in ammonia levels in CSF lead to contrary results where no increase in oxidative stress markers was found in brain. Our findings suggest 1) ammonia does not induce oxidative stress in the brain, 2) systemic oxidative stress is related to a decrease in catalase activity and 3) brain edema in BDL rats is associated with systemic, and not central, oxidative stress.
21. Yang, X.; Bosoi, C.; Tremblay, M. & Rose, C. F. International Symposium on Hepatic Encephalopathy, September 17^th-19^th, Valencia, Spain.
    

    -

    [↓Abstract↓]

    Background: Ammonia plays a major role in the pathogenesis of hepatic encephalopathy however oxidative stress is also believed to be involved. Two lines of evidence lead us to the following aim of our study: 1) neurotoxic levels of ammonia have demonstrated to induce oxidative stress in vitro and 2) systemic oxidative stress is believed to exacerbate the neuropsychological effects of hyperammonemia observed in patients with liver disease. Our aim was to measure oxidative stress markers systemically and centrally, in association with brain edema in rats with cirrhosis. Methods: Rats were sacrificed 6 weeks following bile-ligated induced cirrhosis. Arterial plasma and cerebrospinal fluid (CSF) were collected to measure ammonia (commercially available kit), reactive oxygen species (ROS) (DCFDA-fluorescent technique), nitric oxide (NO) (Griess method) and lipid peroxidation (malondialdehyde, MDA) (commercially available kit). Frontal cortex was dissected to measure antioxidant catalase activity (Amplex Red fluorescent technique), S-nitrosylation of cystein thiols (immunoblotting) and brain water content was determined using the specific gravimetric technique. Results: Brain water content increased in BDL rats vs SHAM-operated controls (81.91 ± 0.19% vs 81.23 ± 0.20%, p<0.05). BDL rats vs SHAM-operated controls developed an increase in plasma arterial levels of ammonia (91.8 ± 18.4uM vs 41.2 ± 13.2uM, p<0.05), ROS (4.9 fold increase), NO (2.9 fold increase), MDA (41.9 ± 7.4uM vs 9.9 ± 0.6uM, p<0.005), S-nitrosylated proteins and a decrease in catalase activity (1.3 ± 0.5U/ml vs 3.2 ± 1.4U/ml, p<0.05). Centrally, BDL rats vs SHAM-operated controls developed an increase in CSF ammonia (123.5 ± 21.7uM vs 23.3 ± 6.1uM, p<0.05) but did not develop an increase in CSF ROS and NO or in brain MDA and S-nitrosylation detection. Furthermore, catalase activity in the brain was unchanged in BDL vs SHAM-operated controls. Conclusions: Six weeks following BDL, rats developed brain edema. An increase in arterial ammonia was accompanied with an increase in lipid peroxidation, NO, ROS and S-nitrosylation with a decrease in catalase activity. However, a similar increase in ammonia levels in CSF lead to contrary results where no increase in oxidative stress markers was found in brain. Our findings suggest 1) ammonia does not induce oxidative stress in the brain, 2) systemic oxidative stress is related to a decrease in catalase activity and 3) brain edema in BDL rats is associated with systemic, and not central, oxidative stress.

2008

22. Bosoi, C.; Tremblay, M. & Rose, C. F. 59^th Annual Meeting of the American Association for the Study of Liver Diseases, October 31^st-November 4^th, San Francisco, USA in Hepatology. 48:1079A.
    

    -

    [↓Abstract↓]

    Background: Ammonia is central in the pathogenesis of hepatic encephalopathy however it is believed systemic oxidative/nitrosative stress may play an important role in exacerbating the neuropsychological effects of hyperammonemia observed in patients with cirrhosis. Furthermore, it has recently been demonstrated in vitro that pathophysiological concentrations of ammonia induce oxidative/nitrosative stress in brain (cultured astrocytes), however this remains to be evaluated in vivo. The present study aims to investigate the role of oxidative/nitrosative stress in a well characterized hyperammonemic rat model of portacaval anastomosis (PCA). Methods: Rats were sacrificed 4 weeks following PCA or SHAM-operation. Ammonia, nitrate/nitrite, reactive oxygen species and total glutathione were measured in both plasma (arterial) and cerebrospinal fluid. Activities of antioxidant enzymes (catalase, superoxide dismutase and glutathione reductase/peroxidase) were measured in both plasma (arterial) and frontal cortex of the brain. Results: Ammonia concentrations were increased in both plasma (PCA: 173.7 ± 13.58uM vs SHAM: 77.8 ± 11.2uM; p<0.001) and cerebrospinal fluid (PCA: 146.6 ± 26.0uM vs SHAM: 31.5 ± 6.9uM; p<0.001) in PCA rats compared to SHAM operated controls. Furthermore, PCA rats showed a significant increase in catalase (PCA: 3.27 ± 0.03U/ml vs SHAM: 3.10 ± 0.05U/ml; p<0.05) and superoxide dismutase (PCA: 97.30 ± 0.47 vs SHAM: 95.57 ± 0.45 % inhibition; p<0.05) activities, but no significant differences were found in frontal cortex between the two groups. In addition, no significant changes in reactive oxygen species, nitrate/nitrite and total glutathione levels, nor in glutathione reductase and peroxidase activities were found in both plasma and brain tissue of PCA and SHAM rats. Conclusion: Rats with PCA develop hyperammonemia which leads to toxic levels of ammonia in the brain. This in turn does not induce oxidative/nitrosative stress systemically or centrally. Maintenance of systemic antioxidant activity in rats with PCA preserves a balanced redox status and prevents progression of encephalopathy.
23. Bosoi, C. R.; Parent-Robitaille, C.; Tremblay, M. & Rose*, C. F. Society Free Radical Biology and Medicine 15^th Annual Meeting, November 19^th-23^rd, Indianapolis, USA in Free Radic Biol Med. 45:S102.
    

    -

    [↓Abstract↓]

    Background: Liver failure/disease leads to hyperammonemia which is central in the pathogenesis of hepatic encephalopathy. However, it is believed systemic oxidative/nitrosative stress may play an important role in exacerbating the neuropsychological effects of hyperammonemia observed in patients with liver disease. The present study aims to investigate the role of oxidative/nitrosative stress in 2 rat models of liver disease/hepatic encephalopathy; 1) portacaval anastomosis (PCA), and 2) bile-duct ligation (BDL). Methods: Rats were sacrificed 4 weeks following PCA or 6 weeks following BDL. Ammonia, reactive oxygen species (ROS), H2O2 and nitric oxide (NO) were measured in plasma (arterial) and ammonia, ROS and NO were measured in cerebrospinal fluid (CSF) using respectively a commercially available kit, a fluorescent technique and the Griess reaction. Brain water was measured in the frontal cortex using a specific gravimetric technique. Results: Hyperammonemia developed in both PCA (PCA: 173.7 ± 13.6 uM vs sham: 77.8 ± 11.2 uM; p<0.001) and BDL (BDL: 114.1 ± 19.2 uM vs sham: 33.2 ± 4.7 uM; p<0.05) rats with PCA rats being significantly higher compared to BDL rats (p<0.05). Consequently, ammonia increased in CSF in both PCA (PCA: 146.6 ± 26.0 uM vs sham: 31.5 ± 6.9 uM; p<0.001) and BDL (BDL: 128.4 ± 36.7 uM vs sham: 23.3 ± 6.1 uM; p<0.05). No significant change was observed between PCA and BDL. Only rats with BDL demonstrated an increase in plasma levels of ROS (5.8-fold increase vs sham; p<0.001) and H2O2 (3.2-fold increase vs sham; p<0.05). No significant change in CSF ROS was found in BDL or PCA compared to their respective control groups. In addition, an increase in brain water content was only observed in rats with BDL (BDL: 81.52 ± 0.15% vs sham: 80.43 ± 0.21%, p<0.05). No significant change in plasma ROS, H2O2 or brain water was found in PCA rats vs sham-operated controls. Conclusion: Oxidative stress in addition to hyperammonemia results in an increase in brain water in rats with BDL which is not in PCA rats where only hyperammonemia is observed. Our findings suggest systemic oxidative stress is implicated in the pathogenesis of brain edema and its synergistic effect with ammonia may lead to progression of hepatic encephalopathy.

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