Hepatic encephalopathy: An update of pathophysiologic mechanisms

Hepatic encephalopathy (HE) is a neuropsychiatric disorder that occurs in both acute and chronic liver failure. Although the precise pathophysiologic mechanisms responsible for HE are not completely understood, a deficit in neurotransmission rather than a primary deficit in cerebral energy metabolism appears to be involved. The neural cell most vulnerable to liver failure is the astrocyte. In acute liver failure, the astrocyte undergoes swelling resulting in increased intracranial pressure; in chronic liver failure, the astrocyte undergoes characteristic changes known as Alzheimer type II astrocytosis. In portal-systemic encephalopathy resulting from chronic liver failure, astrocytes manifest altered expression of several key proteins and enzymes including monoamine oxidase B, glutamine synthetase, and the so-called peripheral-type benzodiazepine receptors. In addition, expression of some neuronal proteins such as monoamine oxidase A and neuronal nitric oxide synthase are modified. In acute liver failure, expression of the astrocytic glutamate transporter GLT-1 is reduced, leading to increased extracellular concentrations of glutamate. Many of these changes have been attributed to a toxic effect of ammonia and/or manganese, two substances that are normally removed by the hepatobiliary route and that in liver failure accumulate in the brain. Manganese deposition in the globus pallidus in chronic liver failure results in signal hyperintensity on T1-weighted Magnetic Resonance Imaging and may be responsible for the extrapyramidal symptoms characteristic of portal-systemic encephalopathy. Other neurotransmitter systems implicated in the pathogenesis of hepatic encephalopathy include the serotonin system, where a synaptic deficit has been suggested, as well as the catecholaminergic and opioid systems. Further elucidation of the precise nature of these alterations could result in the design of novel pharmacotherapies for the prevention and treatment of hepatic encephalopathy.     

The "peripheral-type" benzodiazepine (omega 3) receptor in hyperammonemic disorders

Increased levels of brain ammonia occur in both congenital and acquired hyperammonemic syndromes including hepatic encephalopathy, fulminant hepatic failure, Reye's syndrome and congenital urea cycle disorders. In addition to its effect on neurotransmission and energy metabolism, ammonia modulates the expression of various genes including the astrocytic "peripheral-type" benzodiazepine (or omega 3) receptor (PTBR). Increased expression of the isoquinoline carboxamide binding protein (IBP), one of the components of the PTBR complex, is observed in brain and peripheral tissues following chronic liver failure as well as in cultured astrocytes exposed to ammonia. Increased densities of binding sites for the PTBR ligand [3H]-PK11195 are also observed in these conditions as well as in brains of animals with acute liver failure, congenital urea cycle disorders and in patients who died in hepatic coma. The precise role of PTBR in brain function has not yet fully elucidated, but among other functions, PTBR mediates the transport of cholesterol across the mitochondrial membrane and thus plays a key role in the biosynthesis of neurosteroids some of which modulate major neurotransmitter systems such as the gamma-aminobutyric acid (GABA(A)) and glutamate (N-methyl-D-aspartate (NMDA)) receptors. Activation of PTBR in chronic and acute hyperammonemia results in increased synthesis of neurosteroids which could lead to an imbalance between excitatory and inhibitory neurotransmission in the CNS. Preliminary reports suggest that positron emission tomography (PET) studies using [11C]-PK11195 may be useful for the assessment of the neurological consequences of chronic liver failure.     

Glutamine in the pathogenesis of acute hepatic encephalopathy

Hepatic encephalopathy (HE) is the major neurological disorder associated with liver disease. It presents in chronic and acute forms, and astrocytes are the major neural cells involved. While the principal etiological factor in the pathogenesis of HE is increased levels of blood and brain ammonia, glutamine, a byproduct of ammonia metabolism, has also been implicated in its pathogenesis. This article reviews the current status of glutamine in the pathogenesis of HE, particularly its involvement in some of the events triggered by ammonia, including mitochondrial dysfunction, generation of oxidative stress, and alterations in signaling mechanisms, including activation of mitogen-activated protein kinases (MAPKs) and nuclear factor-kappaB (NF-κB). Mechanisms by which glutamine contributes to astrocyte swelling/brain edema associated with acute liver failure (ALF) will also be described.     

Brain edema in acute liver failure and chronic liver disease: Similarities and differences

Hepatic encephalopathy (HE) is a complex neuropsychiatric syndrome that typically develops as a result of acute liver failure or chronic liver disease. Brain edema is a common feature associated with HE. In acute liver failure, brain edema contributes to an increase in intracranial pressure, which can fatally lead to brain stem herniation. In chronic liver disease, intracranial hypertension is rarely observed, even though brain edema may be present. This discrepancy in the development of intracranial hypertension in acute liver failure versus chronic liver disease suggests that brain edema plays a different role in relation to the onset of HE. Furthermore, the pathophysiological mechanisms involved in the development of brain edema in acute liver failure and chronic liver disease are dissimilar. This review explores the types of brain edema, the cells, and pathogenic factors involved in its development, while emphasizing the differences in acute liver failure versus chronic liver disease. The implications of brain edema developing as a neuropathological consequence of HE, or as a cause of HE, are also discussed.     

Cell-selective effects of ammonia on glutamate transporter and receptor function in the mammalian brain

Increased brain ammonia concentrations are a hallmark feature of several neurological disorders including congenital urea cycle disorders, Reye's syndrome and hepatic encephalopathy (HE) associated with liver failure. Over the last decade, increasing evidence suggests that hyperammonemia leads to alterations in the glutamatergic neurotransmitter system. Studies utilizing in vivo and in vitro models of hyperammonemia reveal significant changes in brain glutamate levels, glutamate uptake and glutamate receptor function. Extracellular brain glutamate levels are consistently increased in rat models of acute liver failure. Furthermore, glutamate transport studies in both cultured neurons and astrocytes demonstrate a significant suppression in the high affinity uptake of glutamate following exposure to ammonia. Reductions in NMDA and non-NMDA glutamate receptor sites in animal models of acute liver failure suggest a compensatory decrease in receptor levels in the wake of rising extracellular levels of glutamate. Ammonia exposure also has significant effects on metabotropic glutamate receptor activation with implications, although less clear, that may relate to the brain edema and seizures associated with clinical hyperammonemic pathologies. Therapeutic measures aimed at these targets could result in effective measures for the prevention of CNS consequences in hyperammonemic syndromes.     

Comprehensive gene expression profiling of human astrocytes treated with a hepatic encephalopathy-inducible factor,alpha 1-antichymotripsin

Astrocytes are major glial cells that play a critical role in brain homeostasis. Abnormalities in astrocytic function, such as hepatic encephalopathy (HE) during acute liver failure, can result in brain death following brain edema and the associated astrocyte swelling. Recently, we have identified alpha 1-antichymotripsin (ACT) to be a biomarker candidate for HE. ACT induces astrocyte swelling by upregulating aquaporin 4 (AQP4); however, the causal connection between these proteins is not clear yet. In this study, we utilized a microarray profile to screen the differentially expressed genes (DEGs) in astrocytes treated with ACT. We then performed Gene Ontology, REACTOME, and the comprehensive resource of mammalian protein complexes (CORUM) enrichment analyses of the identified DEGs. The results of these analyses indicated that the DEGs were enriched in pathways activating adenylate cyclase (AC)-coupled G protein-coupled receptors (GPCRs) and therefore were involved in the cyclic adenosine monophosphate (cAMP) signaling. These results indicate that ACT may act as a ligand of Gs-GPCRs and subsequently upregulate cAMP. As cAMP is known to upregulate AQP4 in astrocytes, these results suggest that ACT may upregulate AQP4 by activating AC GPCRs and therefore serve as a therapeutic target for acute HE.     

Regulation of expression of the novel IL-1 receptor family members in the mouse brain

Members of the interleukin-1 (IL-1) family of cytokines are key mediators in the regulation of host defence responses and the development of inflammation in response to acute and chronic injury to the brain. Two major agonists, IL-1alpha and IL-1beta, bind to a membrane receptor complex composed of the type-1 IL-1 receptor (IL-1RI) and the accessory protein (IL-1RAcP). The discovery of new orphan members of the IL-1 receptor superfamily (including ST2/T1, IL-1Rrp2, TIGIRR1 and -2, SIGGIR, IL-18Ralpha and IL-18Rbeta) has increased speculation that alternative IL-1 ligands signalling pathways exist in the brain. We demonstrate here that all the IL-1R-like orphan receptors are expressed by many brain cell types including astrocytes, microglia, oligodendrocytic progenitor cells and neurons. IL-18Rbeta expression was significantly increased in response to treatment of mixed glia with bacterial lipopolysaccharide (LPS) in vitro, whereas expression of IL-1Rrp2 and TIGIRR1 was reduced. Furthermore, IL-18Rbeta, IL-1Rrp2, but not TIGIRR1 expression, was increased in the brain in vivo in response to peripheral administration of LPS or middle cerebral artery occlusion (MCA). These results suggest possible roles for newly identified members of the IL-1 receptor family in CNS diseases.     

The molecular pathogenesis of hepatic encephalopathy

Hepatic encephalopathy (HE) incorporates a spectrum of neuropsychiatric abnormalities seen in patients with liver dysfunction with a potential for full reversibility. Distinct syndromes are identified in acute liver failure and cirrhosis. Rapid deterioration in consciousness level and increased intracranial pressure that may result in brain herniation and death are a feature of acute liver failure whereas manifestations of HE in cirrhosis include psychomotor dysfunction, impaired memory, increased reaction time, sensory abnormalities, poor concentration and in severe forms, coma. For over a 100 years ammonia has been considered central to its pathogenesis. In the brain, the astrocyte is the main site for ammonia detoxification, during the conversion of glutamate to glutamine. An increased ammonia level raises the amount of glutamine within astrocytes, causing an osmotic imbalance resulting in cell swelling and ultimately brain oedema. The present review focuses upon the molecular mechanisms involved in the pathogenesis of HE. Therapy of HE is directed primarily at reducing ammonia generation and increasing its detoxification.     

Evidence for an Astrocytic Glutamate Transporter Deficit in Hepatic Encephalopathy

There is increasing evidence to suggest that hepatic encephalopathy in acute liver failure is the result of altered glutamatergic function. In particular, the high affinity uptake of glutamate is decreased in brain slices and synaptosomes from rats with acute liver failure as well as by exposure of cultured astrocytes to concentrations of ammonia equivalent to those reported in brain in acute liver failure. Both protein and gene expression of the recently cloned and sequenced astrocytic glutamate transporter GLT-1 are significantly reduced in the brains of rats with acute liver failure. Decreased expression of GLT-1 in brain in acute liver failure results in increased extracellular brain glutamate concentrations which correlates with arterial ammonia concentrations and with the appearance of severe encephalopathy and brain edema in these animals. Ammonia-induced reductions in expression of GLT-1 resulting in increased extracellular glutamate concentrations could explain some of the symptoms (hyperexcitability, cerebral edema) characteristic of hepatic encephalopathy in acute liver failure.     

Asymmetric Dimethylarginine and Hepatic Encephalopathy: Cause,Effect or Association?

The methylated derivative of l-arginine, asymmetric dimethylarginine (ADMA) is synthesized in different mammalian tissues including the brain. ADMA acts as an endogenous, nonselective, competitive inhibitor of all three isoforms of nitric oxide synthase (NOS) and may limit l-arginine supply from the plasma to the enzyme via reducing its transport by cationic amino acid transporters. Hepatic encephalopathy (HE) is a relatively frequently diagnosed complex neuropsychiatric syndrome associated with acute or chronic liver failure, characterized by symptoms linked with impaired brain function leading to neurological disabilities. The l-arginine—nitric oxide (NO) pathway is crucially involved in the pathomechanism of HE via modulating important cerebral processes that are thought to contribute to the major HE symptoms. Specifically, activation of this pathway in acute HE leads to an increase in NO production and free radical formation, thus, contributing to astrocytic swelling and cerebral edema. Moreover, the NO-cGMP pathway seems to be involved in cerebral blood flow (CBF) regulation, altered in HE. For this reason, depressed NO-cGMP signaling accompanying chronic HE and ensuing cGMP deficit contributes to the cognitive and motor failure. However, it should be remembered that ADMA, a relatively little known element limiting NO synthesis in HE, may also influence the NO-cGMP pathway regulation. In this review, we will discuss the contribution of ADMA to the regulation of the NO-cGMP pathway in the brain, correlation of ADMA level with CBF and cognitive alterations observed during HE progression in patients and/or animal models of HE.     

Upregulation of the low density lipoprotein receptor at the blood-brain barrier: intercommunications between brain capillary endothelial cells and astrocytes

In contrast to the endothelial cells in large vessels where LDL receptors are downregulated, brain capillary endothelial cells in vivo express an LDL receptor. Using a cell culture model of the blood-brain barrier consisting of a coculture of brain capillary endothelial cells and astrocytes, we observed that the capacity of endothelial cells to bind LDL is enhanced threefold when cocultured with astrocytes. We next investigated the ability of astrocytes to modulate endothelial cell LDL receptor expression. We have shown that the lipid requirement of astrocytes increases the expression of endothelial cell LDL receptors. Experiments with dialysis membranes of different pore size showed that this effect is mediated by a soluble factor(s) with relative molecular mass somewhere between 3,500 and 14,000. Substituting astrocytes with smooth muscle cells or brain endothelium with endothelium from the aorta or the adrenal cortex did not enhance the luminal LDL receptor expression on endothelial cells, demonstrating the specificity of the interactions. This factor(s) is exclusively secreted by astrocytes cocultured with brain capillary endothelial cells, but it also upregulates the LDL receptor on other cell types. This study confirms the notion that the final fine tuning of cell differentiation is under local control.     

An update on the role of brain glutamine synthesis and its relation to cell-specific energy metabolism in the hyperammonemic brain: further studies using NMR spectroscopy

Ammonia is a neurotoxin that is implicated in the pathogenesis of hepatic encephalopathy due to acute and chronic liver failure. However, its relation to neurological damage and brain edema is poorly understood. During the last decades, it has been the prevailing hypothesis that an osmotic disturbance induced by the astrocytic accumulation of glutamine leads to brain edema. However, various findings are at variance with this hypothesis. The present review will discuss: (a) correlation of ammonia with encephalopathy and brain edema in HE; (b) glutamine synthesis and astrocyte swelling; (c) glutamine synthesis and the glutamine-cycle: relation to brain energy metabolism; (d) glutamine synthesis and the glutamate-glutamine cycle and its relation to anaplerotic activity; (e) evidence favouring the "glutamine hypothesis"; (f) evidence contradicting the "glutamine hypothesis"; (g) glutamine synthesis and osmoregulation; (h) glutamine synthesis in chronic liver failure; (i) impaired brain energy metabolism in acute liver failure (ALF) and its relation to astrocytic glutamine synthesis. Taken together, the precise role of glutamine in the development of brain edema in ALF remains unclear. Astrocytic changes due to glutamine accumulation may lead secondarily to effects on brain energy metabolism. However, the relation between impaired energy metabolism and glutamine accumulation has not been well established. It is noteworthy that no single biochemical factor appears to be responsible for the many symptoms of HE. For example, brain glutamine accumulation and low-grade brain edema occur in chronic liver failure (CLF) suggesting common mechanisms are responsible for the neurological dysfunction in CLF and ALF. Recent NMR spectroscopic studies have provided considerably new information in this area. Future NMR studies using the stable isotope 13C may be useful in the study of the dynamics of brain metabolism in patients with ALF so as to better elucidate the precise role of glutamine accumulation and of glutamine-independent components to brain edema in ALF.     

Glutamate transporters in hyperammonemia

Evidence suggests that increases in brain ammonia due to congenital urea cycle disorders, Reye Syndrome or liver failure have deleterious effects on the glutamate neurotransmitter system. In particular, ammonia exposure of the brain in vivo or in vitro preparations leads to alterations of glutamate transport. Exposure of cultured astrocytes to ammonia results in reduced high affinity uptake sites for glutamate due to a reduction in expression of the astrocytic glutamate transporter GLAST. On the other hand, acute liver failure leads to decreased expression of a second astrocytic glutamate transporter GLT-1 and a consequent reduction in glutamate transport sites in brain. Effects of the chronic exposure of brain to ammonia on cellular glutamate transport are less clear. The loss of glutamate transporter activity in brain in acute liver failure and hyperammonemia is associated with increased extracellular brain glutamate concentrations which may be responsible for the hyperexcitability and cerebral edema observed in hyperammonemic disorders.     

The astrocytic ("peripheral-type") benzodiazepine receptor: role in the pathogenesis of portal-systemic encephalopathy

An increasing body of evidence supports the notion that activation of astrocytic (peripheral-type) benzodiazepine receptors contributes to the pathogenesis of the central nervous system symptoms which are characteristic of portal-systemic encephalopathy (PSE). Binding site densities for the PTBR ligand [3H-PK11195] are increased in autopsied brain tissue from PSE patients as well as in the brains of animals with experimental chronic liver failure. In the case of the animal studies, increased PTBR sites resulted from increased PTBR gene expression. Exposure of cultured astrocytes to ammonia or manganese (two neurotoxic agents which under normal circumstances are removed by the hepatobiliary system and which are found to accumulate in brain in PSE) results in increased densities of [3H-PK11195] binding sites. Activation of PTBR is known to result in increased cholesterol uptake and increased synthesis in brain of neurosteroids some of which have potent positive allosteric modulator properties on the GABA-A receptor system. Accumulation of such substances in the brain in chronic liver failure could explain the neural inhibition characteristics of PSE.     

Up-regulation of central mu-opioid receptors in a model of hepatic encephalopathy: a potential mechanism for increased sensitivity to morphine in liver failure

Increased GABA-mediated neurotransmission, reported to occur in hepatic encephalopathy (HE), is associated with a decrease in the release of Met-enkephalin and the expression of its coding gene in the brain. Furthermore, patients with cirrhosis and a history of HE exhibit increased sensitivity to the neuroinhibitory effects of morphine. Thus, there is a rationale to study the status of the endogenous opioid system in HE. The aim of this study was to determine whether mu-opioid receptors in the brain are up-regulated in a well characterized model of HE. Binding parameters of mu-opioid receptors were derived by assaying the binding of the opiate agonist [3H]-tyr-D-Ala-Gly-N-Methyl-Phe-Gly-ol (DAMGO) to brain membranes from rats with precisely defined stages of HE and control animals. The mean density of mu-opioid receptor sites (Bmax) in rats with stage II, III, and IV HE was 15, 29, and 33% higher, respectively, than the corresponding control value (p<0.01). In addition, the affinity of mu opioid receptors for the agonist (1/Kd) also increased with progression of HE (mean for stage IV HE vs. corresponding control mean, p<0.01). In conclusion, in liver failure, increased density and affinity of central mu-opioid receptors in the brain may: (i) be the basis for the documented increased sensitivity to opiate agonists; and (ii) occur as a consequence of increased GABAergic tone reducing neuronal synthesis and release of opioid agonist peptides.     

Reprint of: Neuroinflammation in acute liver failure: Mechanisms and novel therapeutic targets

It is increasingly evident that neuroinflammatory mechanisms are implicated in the pathogenesis of the central nervous system (CNS) complications (intracranial hypertension, brain herniation) of acute liver failure (ALF). Neuroinflammation in ALF is characterized by microglial activation and arterio-venous difference studies as well as studies of gene expression confirm local brain production and release of proinflammatory cytokines including TNF-α and the interleukins IL-1β and IL-6. Although the precise nature of the glial cell responsible for brain cytokine synthesis is not yet established, evidence to date supports a role for both astrocytes and microglia. The neuroinflammatory response in ALF progresses in parallel with the progression of hepatic encephalopathy (HE) and with the severity of brain edema (astrocyte swelling). Mechanisms responsible for the relaying of signals from the failing liver to the brain include transduction of systemic proinflammatory signals as well as the effects of increased brain lactate leading to increased release of cytokines from both astrocytes and microglia. There is evidence in support of a synergistic effect of proinflammatory cytokines and ammonia in the pathogenesis of HE and brain edema in ALF. Therapeutic implications of the findings of a neuroinflammatory response in ALF are multiple. Removal of both ammonia and proinflammatory cytokines is possible using antibiotics or albumen dialysis. Mild hypothermia reduces brain ammonia transfer, brain lactate production, microglial activation and proinflammatory cytokine production resulting in reduced brain edema and intracranial pressure in ALF. N-Acetylcysteine acts as both an antioxidant and anti-inflammatory agent at both peripheral and central sites of action independently resulting in slowing of HE progression and prevention of brain edema. Novel treatments that directly target the neuroinflammatory response in ALF include the use of etanercept, a TNF-α neutralizing molecule and minocycline, an agent with potent inhibitory actions on microglial activation that are independent of its antimicrobial properties; both agents have been shown to be effective in reducing neuroinflammation and in preventing the CNS complications of ALF. Translation of these findings to the clinic has the potential to provide rational targeted approaches to the prevention and treatment of these complications in the near future.     

Neuroinflammation in acute liver failure: Mechanisms and novel therapeutic targets

It is increasingly evident that neuroinflammatory mechanisms are implicated in the pathogenesis of the central nervous system (CNS) complications (intracranial hypertension, brain herniation) of acute liver failure (ALF). Neuroinflammation in ALF is characterized by microglial activation and arterio-venous difference studies as well as studies of gene expression confirm local brain production and release of proinflammatory cytokines including TNF-α and the interleukins IL-1β and IL-6. Although the precise nature of the glial cell responsible for brain cytokine synthesis is not yet established, evidence to date supports a role for both astrocytes and microglia. The neuroinflammatory response in ALF progresses in parallel with the progression of hepatic encephalopathy (HE) and with the severity of brain edema (astrocyte swelling). Mechanisms responsible for the relaying of signals from the failing liver to the brain include transduction of systemic proinflammatory signals as well as the effects of increased brain lactate leading to increased release of cytokines from both astrocytes and microglia. There is evidence in support of a synergistic effect of proinflammatory cytokines and ammonia in the pathogenesis of HE and brain edema in ALF. Therapeutic implications of the findings of a neuroinflammatory response in ALF are multiple. Removal of both ammonia and proinflammatory cytokines is possible using antibiotics or albumen dialysis. Mild hypothermia reduces brain ammonia transfer, brain lactate production, microglial activation and proinflammatory cytokine production resulting in reduced brain edema and intracranial pressure in ALF. N-Acetylcysteine acts as both an antioxidant and anti-inflammatory agent at both peripheral and central sites of action independently resulting in slowing of HE progression and prevention of brain edema. Novel treatments that directly target the neuroinflammatory response in ALF include the use of etanercept, a TNF-α neutralizing molecule and minocycline, an agent with potent inhibitory actions on microglial activation that are independent of its antimicrobial properties; both agents have been shown to be effective in reducing neuroinflammation and in preventing the CNS complications of ALF. Translation of these findings to the clinic has the potential to provide rational targeted approaches to the prevention and treatment of these complications in the near future.     

Insulin-like growth factor I in cultured rat astrocytes: expression of the gene, and receptor tyrosine kinase.

Gene expression, receptor binding and growth-promoting activity of insulin-like growth factor I (IGF I) was studied in cultured astrocytes from developing rat brain. Northern blot analysis of poly(A)+ RNAs from astrocytes revealed an IGF I mRNA of 1.9 kb. Competitive binding and receptor labelling techniques revealed two types of IGF receptor in astroglial cells. Type I IGF receptors consist of alpha-subunits (Mr 130,000) which bind IGF I with significantly higher affinity than IGF II, and beta-subunits (Mr 94,000) which show IGF I-sensitive tyrosine kinase activity. Type II IGF receptors are monomers (Mr 250,000) which bind IGF II with three times higher affinity than IGF I. Both types of IGF receptor recognize insulin weakly. DNA synthesis measured by cellular thymidine incorporation was stimulated 2-fold by IGF I and IGF II. IGF I was more potent than IGF II, and both were significantly more potent than insulin. Our findings suggest that IGF I is synthesized in fetal rat astrocytes and acts as a growth promoter for the same cells by activation of the type I IGF receptor tyrosine kinase. We propose that IGF I acts through autocrine or paracrine mechanisms to stimulate astroglial cell growth during normal brain development.     

GABAergic neurosteroids: the "endogenous benzodiazepines" of acute liver failure

Acute liver failure (ALF) or fulminant hepatic failure represents a serious life-threatening condition. ALF is characterized by a significant liver injury that leads to a rapid onset of hepatic encephalopathy (HE). In ALF, patients manifest rapid deterioration in consciousness leading to hepatic coma together with an onset of brain edema which induces high intracranial pressure that frequently leads to herniation and death. It is well accepted that hyperammonemia is a cardinal, but not the sole, mediator in the pathophysiology of ALF. There is increasing evidence that neurosteroids, including the parent neurosteroid pregnenolone, and the progesterone metabolites tetrahydroprogesterone (allopregnanolone) and tetrahydrodeoxycorticosterone (THDOC) accumulate in brain in experimental models of ALF. Neurosteroids in ALF represent good candidates to explain the phenomenon of "increased GABAergic tone" in chronic and ALF, and the beneficial effects of benzodiazepine drugs. The mechanisms that trigger brain neurosteroid changes in ALF are not yet well known, but could involve partially de novo neurosteroidogenesis following activation of the translocator protein (TSPO). The factors that contribute to TSPO changes in ALF may include ammonia and cytokines. It is possible that increases in brain levels of neurosteroids in ALF may result in auto-regulatory mechanisms where hypothermia may play a significant role. Possible mechanisms that may involve neurosteroids in the pathophysiology of HE, and more speculatively in brain edema, and inflammatory processes in ALF are suggested.     

Enhanced binding of 3H-arginine8-vasopressin in the Brattleboro rat

Specific binding sites for 3[H]-arginine8-vasopressin (AVP) were characterized using membrane preparations of liver, renal medulla and brain (septal) tissue of heterozygous (HE) and homozygous (HO) Brattleboro (BB) rats. Measurement of binding sites indicated that significantly greater numbers of AVP receptors are present in the liver and septum of HO-BB rats. Similar numbers of AVP receptors were present in renal medullary tissue from HO-BB and HE-BB rats. Higher equilibrium dissociation constants were measured in the HO-BB septal tissue indicating a lower affinity of the brain receptor for 3[H]-AVP than in heterozygotes. No significant differences in AVP receptor affinity were noted in liver or kidney tissue. It is concluded that "up-regulation" of AVP receptor number and, in the brain, alterations in AVP receptor affinity may occur in the absence of endogenous AVP.