Thiamine-deficient Rats Research Articles

Electron‐microscopic examination of effects of yokukansan, a traditional Japanese medicine, on degeneration of cerebral cells in thiamine‐deficient rats

We previously demonstrated that yokukansan ameliorated not only learning disturbance but also behavioral and psychological symptoms of dementia-like behaviors (anxiety, aggressiveness) and neurological symptoms (opisthotonus) induced in rats by dietary thiamine deficiency (TD). In the present study, the effects of yokukansan on degeneration of cerebral cells were further examined electron-microscopically during pre-symptomatic and symptomatic stages in TD rats. In the pre-symptomatic TD stage, which appeared as increase in aggressive behaviors on the 21st and 28th days of TD diet-feeding, severe edematous degeneration of astrocytes was detected by electron microscopy, although the changes were not observed by light microscopy. In the symptomatic TD stage (the 34th day) characterized by development of neurological symptoms, severe sponge-like degeneration and multiple hemorrhages in the parenchyma were obvious by light microscopy. The electron-microscopic examination showed degeneration in neurons, oligodendroglias, and myelin sheaths in addition to astrocytes. TD rats, which exhibited multiple hemorrhages light microscopically, showed severe edematous changes and hypertrophy of the foot processes of astrocytes surrounding blood vessels. Administration of yokukansan ameliorated not only the TD-induced aggressive behavior and neurological symptoms but also degeneration of the cerebral cells. These results suggest that the inhibitory effect of yokukansan on degeneration in various brain cells might be closely related to the amelioration of aggression and neurological symptoms in TD rats.

Spatial memory deficits and thalamic serotonergic metabolite change in thiamine deficient rats

The purposes of the present study were to verify the effects of a severe thiamine deficiency episode on spatial cognitive aspects and thalamic serotonergic parameters. The animals were submitted to a severe thiamine deficiency treatment that was interrupted after the onset of the last neurological signs. The results obtained confirm previous findings about TD deficiency effects on cognitive function and, further show that this vitamin increases the thalamic serotonine metabolite, 5-hidroxyindolacetic acid (5-HIAA), level. In addition, the present data shed light on the importance of this metabolite in spatial cognitive function.

Impaired cellular contractile function in thiamine‐deficient rat cardiomyocytes

Background Thiamine (vitamin B1) is an essential cofactor of important metabolic enzymes. 1,2 Studies have demonstrated that thiamine deficiency (TD) leads to changes in cardiac morphological, electrophysiological and mechanical properties, as well as in cardiac metabolism. 3 - 9 Clinical studies have indicated that the use of loop diuretics can induce TD and eventually cause heart dysfunction. The most important reported clinical manifestation of TD involves high-output heart failure. In humans, TD damages the cardiovascular system causing heart failure. 10-12 The altered excitation-contraction coupling that characterizes cardiac failure occurs due to changes in Ca 2+ dynamics, action potential duration, global Ca 2+ transient, and contraction and relaxation rates. 13 Oliveira et al. 8 found that thiamine deprivation decreased the global Ca 2+ release from the sarcoplasmic reticulum (SR) due to the lower SR Ca 2+ load without changes in Ca 2+ current density. Aim According to data in the literature, TD may elicit deregulation of SR Ca 2+ handling in the heart, with implications on cellular cardiac contractility. However, it is unknown whether TD would cause contractile dysfunction at the cellular level. In this study, we sought to determine if TD affects cellular contractility. Methods Male Wistar rats (200-250 g) were randomly allocated to receive a diet containing thiamine (control, n = 6) or a TD diet (TD, n = 6) for 35 days as described previously by our group. 8,9 All experimental procedures were conducted in accordance with international guidelines (Declaration of Helsinki). Cell isolation Ventricular cardiomyocytes from age-matched control and TD rats were enzymatically isolated as described previously. 8,9 Briefly, the heart was mounted on a custom-designed Langendorff system, perfused for ∼3-5 min with calcium-free solution following perfusion with 1 mg/mL collagenase type II (Worthington, USA). After 10-15 min, single cells were isolated by mechanical dispersion and stored in Dulbecco's modified Eagle's medium. The average cell yield under these conditions is 60-70%. Measurement of cellular contractility Cellular contractility was measured as described previously. 14 Briefly, isolated cells were placed in an experimental chamber with a glass cover-slip base mounted on the stage of an inverted microscope. Cells were perfused with Tyrodes solution containing 1.8 mM CaCl 2 and field stimulated at frequencies of 1 and 3 Hz (20 V, 5 ms duration square pulses). Cells were imaged using a NTSC camera in a partial scanning mode. Cell shortening in response to electrical stimulation was measured with a video-edge detection system at 240 Hz frame rate (lonoptix). All parameters were evaluated using customized software developed in MatLab ® platform. 14 Experiments were performed at room temperature (∼25°C). Only calcium-tolerant, quiescent, rod-shaped myocytes showing clear cross striations were studied. Statistical analysis All results are expressed as mean ± standard error of the mean. For statistical analysis, we used Student's t-test and ANOVA for repeated measurements with Bonferroni post hoc testing. Values of P < 0.05 were considered significant. Results After 35 days of thiamine deprivation, cellular ATP availability decreases, leading to impairment of heart contraction as we reported in a previous study. 8 Thus, we hypothesized that a reduction in circulating thiamine levels would affect cardiomyocyte.

Loss of astrocytic glutamate transporters in Wernicke encephalopathy.

Wernicke encephalopathy (WE), a neurological disorder caused by thiamine deficiency (TD), is characterized by structural damage in brain regions that include the thalamus and cerebral cortex. The basis for these lesions is unclear, but may involve a disturbance of glutamatergic neurotransmission. We have therefore investigated levels of the astrocytic glutamate transporters EAAT1 and EAAT2 in order to evaluate their role in the pathophysiology of this disorder. Histological assessment of the frontal cortex revealed a significant loss of neurons in neuropathologically confirmed cases of WE compared with age-matched controls, concomitant with decreases in alpha-internexin and synaptophysin protein content of 67 and 52% by immunoblotting. EAAT2 levels were diminished by 71% in WE, with levels of EAAT1 also reduced by 62%. Loss of both transporter sites was confirmed by immunohistochemical methods. Development of TD in rats caused a profound loss of EAAT1 and EAAT2 in the thalamus accompanied by decreases in other astrocyte-specific proteins. Treatment of TD rats with N-acetylcysteine prevented the downregulation of EAAT2 in the medial thalamus, and ameliorated the loss of several other astrocyte proteins, concomitant with increased neuronal survival. Our results suggest that (1) loss of EAAT1 and EAAT2 glutamate transporters is associated with structural damage to the frontal cortex in patients with WE, (2) oxidative stress plays an important role in this process, and (3) TD has a profound effect on the functional integrity of astrocytes. Based on these findings, we recommend that early treatment using a combination of thiamine AND antioxidant approaches should be an important consideration in cases of WE.

Early brain stem lesions in thiamine deficient rats.

Journal Article Early Brain Stem Lesions in Thiamine Deficient Rats Get access Nutrition Reviews, Volume 27, Issue 2, February 1969, Pages 54–56, https://doi.org/10.1111/j.1753-4887.1969.tb04957.x Published: 01 February 1969

Cardiac structural changes and electrical remodeling in a thiamine-deficiency model in rats

Aims Thiamine is an important cofactor present in many biochemical reactions, and its deprivation can lead to heart dysfunction. Little is known about the influence of thiamine deprivation on the electrophysiological behavior of the isolated heart cells and information about thiamine deficiency in heart morphology is controversial. Thus, we decided to investigate the major repolarizing conductances and their influence in the action potential (AP) waveform as well as the changes in the heart structure in a set of thiamine deficiency in rats. Main methods Using the patch-clamp technique, we investigated inward ( I K1) and outward K + currents ( I to), T-type and L-type Ca 2+ currents and APs. To evaluate heart morphology we used hematoxylin and eosin in transversal heart sections. Key findings Thiamine deficiency caused a marked decrease in left ventricle thickness, cardiomyocyte number, cell length and width, and membrane capacitance. When evaluating I to we did not find difference in current amplitude; however an acceleration of I to inactivation was observed. I K1 showed a reduction in the amplitude and slope conductance, which implicated a less negative resting membrane potential in cardiac myocytes isolated from thiamine-deficient rats. We did not find any difference in L-type Ca 2+ current density. T-type Ca 2+ current was not observed. In addition, we did not observe significant changes in AP repolarization. Significance Based on our study we can conclude that thiamine deficiency causes heart hypotrophy and not heart hypertrophy. Moreover, we provided evidence that there is no major electrical remodeling during thiamine deficiency, a feature of heart failure models.

Effects of Yokukansan, a Traditional Japanese Medicine, on Memory Disturbance and Behavioral and Psychological Symptoms of Dementia in Thiamine-Deficient Rats

Effects of yokukansan (TJ-54) on memory disturbance and behavioral and psychological symptoms of dementia (BPSD) were investigated in thiamine-deficient (TD) rats which were produced by feeding a TD diet for 37 d. Daily oral administration of TJ-54 (0.5, 1.0 g/kg) ameliorated the memory disturbance, anxiety-like behavior, the increase in aggressive behaviors, the decrease in social behaviors, and several neurological symptoms including opisthotonus observed in TD rats, in a dose-dependent manner. In addition, histopathological examinations showed that TJ-54 inhibited the degeneration of neuronal and astroglial cells in the brain stem, hippocampus and cortex in TD rats. Microdialysis experiments showed that TJ-54 inhibited extracellular glutamate rise in the ventral posterior medial thalamus in TD rats. These results suggest that TJ-54 possesses the preventive or progress inhibitive effect against the development of memory disturbance and BPSD-like behaviors induced by the degeneration of neuronal and astroglial cells resulting from TD. TJ-54 may inhibit glutamate-mediated excitotoxicity as one of mechanisms.

Neuroprotection by rasagiline in thiamine deficient rats

Thiamine deficiency (TD) in rats is a model of chronic impairment of oxidative metabolism leading to neuronal loss. TD rats exhibit neuropathological, behavioral and cognitive abnormalities. The aim of this study was to use this syndrome to assess the neuroprotective potential of drugs in a whole animal model. TD was produced in rats using the following protocol: thiamine deficient diet, daily injections of the central thiamine antagonist, pyrithiamine (0.5 mg/kg), and the test drugs, the selective monoamine oxidase (MAO) B inhibitors, rasagiline (1 or 3 mg/kg/day) and selegiline (2.4 or 8 mg/kg/day). Normal rats and untreated TD rats served as controls. Upon the appearance of neurological symptoms, the TD protocol was suspended, rats were transferred to a regular diet, pyrithiamine and test drug injections were terminated and rats were injected with 3 daily doses of thiamine (100 mg/kg). Neuroprotective potential was assessed by: general behavioral observations, cognitive testing using the Morris water maze and histopathological examination of the brains. Rasagiline but not selegiline significantly delayed the onset and severity of the neurological symptoms of TD. In the Morris water maze, TD-untreated rats displayed severe cognitive impairment while rasagiline-treated rats were similar to control rats and significantly different from TD-untreated rats. The effects were dose related. Selegiline treatment had no significant protective effect. TD-untreated brains displayed extensive gliotic and necrotic lesions mainly in the thalamus and posterior collicular nucleus, which were significantly reduced in the rasagiline-treated TD rats. These findings demonstrate significant neuroprotection by rasagiline with possible implications for clinical neurodegenerative disorders.

Impaired oxidation of branched-chain amino acids in the medial thalamus of thiamine-deficient rats

Thiamine, in its diphosphate form, is a required cofactor for enzymes of glucose metabolism and branched-chain alpha-ketoacid dehydrogenase (BCKDH). Although metabolic impairments in glucose metabolism have been found to occur in selectively vulnerable brain regions of the thiamine-deficient (TD) brain, the effects of thiamine deficiency on BCKDH have not been studied. BCKDH activity was assayed radiochemically in brain extracts of vulnerable (medial thalamus; MT) versus non-vulnerable (frontal cortex; FC) brain regions of rats made TD by administration of the central thiamine antagonist, pyrithiamine. A significant regional variation in BCKDH within the TD rat brain was noted, with a higher capacity for branched-chain amino acid oxidation in FC compared to MT: BCKDH activity was significantly reduced in MT of TD rats, resulting in selective accumulation of BCAAs in this brain region. Leucine concentrations were elevated over fivefold in the MT of symptomatic TD rats, compared with pair-fed control (PFC) rats. Impaired branched-chain ketoacid metabolism in rats may contribute to the neuronal dysfunction and ultimate thalamic neuronal cell death observed in thiamine deficiency.

Region‐selective alterations of glucose oxidation and amino acid synthesis in the thiamine‐deficient rat brain: a re‐evaluation using 1H/13C nuclear magnetic resonance spectroscopy

Thiamine deficiency provides an effective model of selective neuronal cell death. (1)H and (13)C-NMR was used to investigate the effects of thiamine deficiency on the synthesis of amino acids derived from [1-(13)C]glucose in vulnerable (medial thalamus; MT) compared to non-vulnerable (frontal cortex; FC) brain regions. Following 11 days of thiamine deficiency, a time-point associated with the absence of significant neuronal cell death, regional concentrations of glutamate, glutamine and GABA remained unaffected in FC and MT; however, decreased levels of aspartate in MT at this time-point were a predictor of regional vulnerability. De novo synthesis of glutamate and GABA were unaffected at 11 days of thiamine deficiency, while synthesis of [2-(13)C]aspartate was significantly impaired. Glucose loading, which has been shown to exacerbate symptoms in patients with thiamine deficiency, resulted in further decreases of TCA cycle flux and reduced de novo synthesis of glutamate, aspartate and GABA in thiamine-deficient (TD) rats. Isotopomer analysis revealed that impaired TCA cycle flux and decreased aspartate synthesis due to thiamine deficiency occurred principally in neurons. Glucose loading deteriorated TD-related decreases in TCA cycle flux, and concomitantly reduced synthesis of aspartate and glutamate in MT.

Glucose loading precipitates focal lactic acidosis in the vulnerable medial thalamus of thiamine-deficient rats

Glucose loading in thiamine-deficient patients is known to precipitate Wernicke's Encephalopathy; however, the mechanisms responsible have not been fully elucidated. Lactate accumulation occurs in brains of thiamine-deficient rats. In order to determine whether glucose loading in thiamine-deficient rats causes selective lactic acidosis in vulnerable brain structures, cerebral pH was measured autoradiographically using 14-labeled 5,5-dimethyloxazolidine-2, 4-dione ([(14)C]DMO) in the medial thalamus, a vulnerable brain region, versus cerebral cortex, a brain region that is spared in thiamine deficiency. Following administration of a glucose load, regional lactate levels and de novo lactate synthesis measured by (1)H-(13)C-NMR spectroscopy, increased significantly to 21.86 +/- 3.04 mumol/g (wet weight) in the medial thalamus (p < 0.001) and pH in this brain region was decreased significantly from 7.08 +/- 0.04 to 6.87 +/- 0.05 (p < 0.001). No such changes were observed in cerebral cortex following a glucose load. These results demonstrate that the increased production and accumulation of brain lactate result in acidosis following glucose loading in thiamine deficiency. Alterations of brain pH could contribute to the pathogenesis of thalamic neuronal damage and consequent cerebral dysfunction in Wernicke's Encephalopathy.

Cardiac Alterations in Furosemide-treated Thiamine-deprived Rats

Background Chronic administration of furosemide may induce thiamine deficiency and cause or aggravate myocardial dysfunction. Methods and Results Wistar rats were divided into four groups according to food and treatment: (1) thiamine standard chow with intraperitoneal furosemide administration; (2) thiamine standard chow with intraperitoneal saline administration; (3) thiamine-deficient chow with intraperitoneal furosemide administration; and (4) thiamine-deficient chow with intraperitoneal saline administration. Thiamine status was evaluated by high-performance liquid chromatography determination in plasma, erythrocytes, and myocardium, and by erythrocyte transketolase activity and the thiamine pyrophosphate effect to recover transketolase activity. Left ventricular mass index, intramyocardial arteries-to-cardiomyocyte ratio, cardiomyocyte cross-sectional area, and cardiomyocyte nuclei number were estimated. Myocardial structure was also studied by transmission electronic microscopy. Group 3 showed significantly lower blood and myocardial thiamine levels, which was not observed in group 1. Left ventricular mass index, cardiomyocyte cross-sectional area, and intramyocardial arteries-to-cardiomyocyte ratio were smaller in thiamine-deficient and furosemide-treated rats. However, no significant variation was found in the number of cardiomyocyte nuclei among the groups. Transmission electronic microscopy showed mitochondrial alterations in the thiamine-deficient groups. Conclusion The present results indicate that furosemide administration is not the primary cause of thiamine deficiency in rats with adequate thiamine intake. Furosemide aggravates thiamine deficiency only in situations associated with insufficient thiamine intake, causing cardiac structural alterations, such as myocardial fiber hypotrophy, poor microvascularization, and mitochondrial degeneration.

Abolition of reperfusion-induced arrhythmias in hearts from thiamine-deficient rats

Extensive work has been done regarding the impact of thiamine deprivation on the nervous system. In cardiac tissue, chronic thiamine deficiency is described to cause changes in the myocardium that can be associated with arrhythmias. However, compared with the brain, very little is known about the effects of thiamine deficiency on the heart. Thus this study was undertaken to explore whether thiamine deprivation has a role in cardiac arrhythmogenesis. We examined hearts isolated from thiamine-deprived and control rats. We measured heart rate, diastolic and systolic tension, and contraction and relaxation rates. Whole cell voltage clamp was performed in rat isolated cardiac myocytes to measure L-type Ca(2+) current. In addition, we investigated the global intracellular calcium transients by using confocal microscopy in the line-scan mode. The hearts from thiamine-deficient rats did not degenerate into ventricular fibrillation during 30 min of reperfusion after 15 min of coronary occlusion. The antiarrhythmogenic effects were characterized by the arrhythmia severity index. Our results suggest that hearts from thiamine-deficient rats did not experience irreversible arrhythmias. There was no change in L-type Ca(2+) current density. Inactivation kinetics of this current in Ca(2+)-buffered cells was retarded in thiamine-deficient cardiac myocytes. The global Ca(2+) release was significantly reduced in thiamine-deficient cardiac myocytes. The amplitude of caffeine-releasable Ca(2+) was lower in thiamine-deficient myocytes. In summary, we have found that thiamine deprivation attenuates the incidence and severity of postischemic arrhythmias, possibly through a mechanism involving a decrease in global Ca(2+) release.

Interaction of Thiamine Deficiency and Voluntary Alcohol Consumption Disrupts Rat Corpus Callosum Ultrastructure

The relative roles of alcohol and thiamine deficiency in causing brain damage remain controversial in alcoholics without the Wernicke-Korsakoff syndrome. Experimental control over alcohol consumption and diet are impossible in humans but can be accomplished in animal models. This experiment was designed to differentiate the separate and combined effects on the macro- and ultrastructure of the corpus callosum of thiamine deficiency and voluntary alcohol consumption. Adult male alcohol-preferring (P) rats (9 chronically alcohol-exposed and 9 water controls) received a thiamine-deficient diet for 2 weeks. There were four groups: five rats previously exposed to alcohol were treated with pyrithiamine (a thiamine phosphorylation inhibitor); five rats never exposed to alcohol were treated with pyrithiamine; four alcohol-exposed rats were treated with thiamine; and four rats never exposed to alcohol were treated with thiamine. On day 14, thiamine was restored in all 18 rats; 2 weeks later the 10 pyrithiamine-treated rats received intraperitoneal thiamine. The rats were perfused 61 days post-pyrithiamine treatment at age 598 days. Brains were dissected and weight and volumes were calculated. Sagittal sections were stained to measure white matter structures. The corpus callosum was examined using transmission electron microscopy to determine density of myelinated fibers, fiber diameter, and myelin thickness. The corpus callosum in the alcohol/pyrithiamine group was significantly thinner, had greater fiber density, higher percentage of small fibers, and myelin thinning than in the alcohol/thiamine and water/thiamine groups. Several measures showed a graded effect, where the alcohol/pyrithiamine group had greater pathology than the water/pyrithiamine group, which had greater pathology than the two thiamine-replete groups. Across all 16 rats, thinner myelin sheaths correlated with higher percentage of small fibers. Myelin thickness and axon diameter together accounted for 71% of the variance associated with percentage of small fibers. Significant abnormalities in the alcohol/pyrithiamine group and lack of abnormality in the alcohol-exposed/thiamine-replete group indicate that thiamine deficiency caused white matter damage. The graded abnormalities across the dually to singly treated animals support a compounding effect of alcohol exposure and thiamine depletion, and indicate the potential for interaction between alcohol and thiamine deficiency in human alcohol-related brain damage.

Gene expression changes in thalamus and inferior colliculus associated with inflammation, cellular stress, metabolism and structural damage in thiamine deficiency

Identification of gene expression changes that promote focal neuronal death and neurological dysfunction can further our understanding of the pathophysiology of these disease states and could lead to new pharmacological and molecular therapies. Impairment of oxidative metabolism is a pathogenetic mechanism underlying neuronal death in many chronic neurodegenerative diseases as well as in Wernicke's encephalopathy (WE), a disorder induced by thiamine deficiency (TD). To identify functional pathways that lead to neuronal damage in this disorder, we have examined gene expression changes in the vulnerable thalamus and inferior colliculus of TD rats using Affymetrix Rat Genome GeneChip analysis in combination with gene ontology and functional categorization assessment utilizing the NetAffx GO Mining Tool. Of the 15 927 transcripts analysed, 125 in thalamus and 141 in inferior colliculus were more abundantly expressed in TD rats compared with control animals. In both regions, the major functional categories of transcripts that were increased in abundance after TD were those associated with inflammation (approximately 33%), stress (approximately 20%), cell death and repair ( approximately 26%), and metabolic perturbation (approximately 19%), together constituting approximately 98% of all transcripts up-regulated. These changes occurred against a background of neuronal cell loss and reactive astro- and microgliosis in both structures. Our results indicate that (i) TD produces changes in gene expression that are consistent with the observed dysfunction and pathology, and (ii) similar alterations in expression occur in thalamus and inferior colliculus, brain regions previously considered to differ in pathology. These findings provide important new insight into processes responsible for lesion development in TD, and possibly WE.

Anti-arrhythmogenic effects in a thiamine-deficiency rat model.

Anti-arrhythmogenic effects in a thiamine-deficiency rat model.

Depletion of brain histamine produces regionally selective protection against thiamine deficiency-induced lesions in the rat.

Breakdown of the blood brain barrier and the subsequent accumulation of free radicals, lactate, and glutamate appear to be the immediate causes of thiamine deficiency (TD)-induced damage to thalamus. The mechanisms triggering these events are unknown but recent evidence suggests an important role of histamine. We therefore studied the effects of histamine depletion on thalamic lesions in the pyrithiamine-induced thiamine deficient (PTD) rat. Chronic intracerebroventricular (i.c.v., 7 days) infusion of alpha-fluoromethylhistidine (FMH), combined with bilateral ibotenate destruction of the histamine-containing neurons in the tuberomammillary (TM) nucleus and bolus i.c.v. infusion of 48/80, a potent mast cell degranulating agent, was used to deplete brain histamine levels. PTD rats receiving combined FMH + 48/80 + TM lesions developed acute neurological symptoms, including spontaneous seizures, approximately 1 day earlier than PTD rats treated with i.c.v. infusion of vehicle and sham lesions of the TM. When examined 1 week after restoration of thiamine, the PTD vehicle + sham lesion animals contained severe neuronal loss and gliosis in midline, intralaminar, ventral, lateral, and posterior nuclei. PTD animals treated with FMH + 48/80 + TM lesions had little evidence of neuronal loss or microglial proliferation in thalamus except in the gelatinosus and anteroventral nuclei, in which there was complete neuronal loss. These data demonstrate a significant and regionally selective role of histamine in the development of thalamic lesions in a rat model of Wernicke's encephalopathy. Furthermore, these data suggest either a dissociation between seizures and thalamic lesions or a significant role of histamine in seizure-related damage to the thalamus.

In vivo and in vitro proton NMR spectroscopic studies of thiamine-deficient rat brains.

Thiamine deficiency (TD) in rats produces lesions similar to those found in humans with Wernicke's encephalopathy, an organic mental disorder associated with alcoholism. Male Sprague-Dawley rats (n = 24) were deprived of thiamine in a regimen of thiamine-deficient chow and daily intraperitoneal injections of the thiamine antagonist pyrithiamine hydrobromide for 12 days (0.5 mg/kg). In rats with TD, significant changes were observed in the choline peak (reduction and dose-dependent recovery after thiamine replenishment), which was confirmed by the extraction study. Changes were mainly due to the reduction in glycerophosphorylcholine (GPC), suggesting that a reduction in GPC may be relevant to the primary biochemical lesion in TD. These data are compatible with the hypothesis that a decrease in choline compounds is the cause of the biochemical abnormalities that precede neuroanatomic damage characteristic of Wernicke's encephalopathy.

Immunohistochemical estimation of brain choline acetyltransferase and somatostatin related to the impairment of avoidance learning induced by thiamine deficiency

We have found that thiamine-deficient (TD) rats show significant impairment of avoidance learning on the 25th day after the start of TD diet, as measured by passive- avoidance task. Administration of physostigmine (0.1 mg/kg, i.p.) from the 14th day after the start of TD diet improved the impairment of avoidance learning to the pair-fed (PF) control level by the 25th day. However, the recovery effect of physostigmine did not occur on the 25th day when the treatment was begun on the 21st day. To ascertain the correlation between the cholinergic neuronal function in rat brain and the avoidance learning impairment induced by TD, the immunohistochemical distribution of brain choline acetyltransferase (ChAT) was determined by fluorescence intensity using two-dimensional microphotometry. The intensity of the ChAT fluorescence started to decrease in the cortex and hippocampus on the 14th day and showed a marked decrease in the cortex, hippocampus and thalamus on the 25th day of TD feeding in comparison with PF controls. The intensity of the somatostatin (SST) fluorescence was unchanged on the 14th day of TD feeding, but on the 25th day, SST was significantly decreased in comparison with PF controls. Furthermore, physostigmine treatment from 14th day after the start of TD diet reversed SST fluorescence intensity to the control level by the 25th day. These results suggest that the impairment of avoidance learning induced by TD may involve not only cholinergic but also somatostatinergic systems.

Increased histamine release and granulocytes within the thalamus of a rat model of Wernicke's encephalopathy

The current study examined the possible role of increased histamine release and granulocyte activity in the vascular changes that precede the onset of necrotic lesions with the thalamus of the pyrithiamine-induced thiamine deficiency (PTD) rat model of Wernicke's encephalopathy (WE). An increase in histamine release and the number of granulocytes was observed in lateral thalamus on day 9 and in medial thalamus on day 10 of PTD treatment, a duration of thiamine deficiency associated with perivascular edema in this brain region. Within the hippocampus, histamine release was significantly increased on day 9, declined to control levels on days 10–12, and was significantly elevated on days 12–14. No granulocytes were observed in hippocampus of either PTD or control rats. These observations suggest that the release of histamine from nerve terminals and histamine and other vasoactive substances from granulocytes may be responsible for thiamine deficiency-induced vascular breakdown and perivascular edema within thalamus.