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21	Effect of Dietary Sodium on Fluid/Electrolyte Regulation During Bed Rest Williams, W. Jon, Schneider, Suzanne M., Gretebeck, Randall J., Lane, Helen W., Stuart, Charles A., Whitson, Peggy A. 01 January 2003 (has links) Background: A negative fluid balance during bed rest (BR) is accompanied by decreased plasma volume (PV) which contributes to cardiovascular deconditioning. Hypothesis: We hypothesized that increasing dietary sodium while controlling fluid intake would increase plasma osmolality (POSM), stimulate fluid conserving hormones, and reduce fluid/electrolyte (F/E) losses during BR; conversely, decreasing dietary sodium would decrease POSM, suppress fluid conserving hormones, and increase F/E losses. Methods: We controlled fluid intake (30 ml · kg-1 · d-1) in 17 men who consumed either a 4.0 ± 0.06 g · d-1 (174 mmol · d-1) (CONT; n = 6), 1.0 ± 0.02 g · d-1 (43 mmol · d-1) (LS; n = 6), or 10.0 ± 0.04 g · d-1 (430 mmol · d-1) (HS; n = 5) sodium diet before, during, and after 21 d of 6° head-down BR. PV, total body water, urine volume and osmolality, POSM, and F/E controlling hormone concentrations were measured. Results: In HS subjects, plasma renin activity (-92%), plasma/urinary aldosterone (-59%; -64%), and PV (-15.0%; 6.0 ml · kg-1; p < 0.05) decreased while plasma atrial natriuretic peptide (+34%) and urine antidiuretic hormone (+24%) increased during BR (p < 0.05) compared with CONT. In LS, plasma renin activity (+166%), plasma aldosterone (+167%), plasma antidiuretic hormone (+19%), and urinary aldosterone (+335%) increased with no change in PV compared with CONT (p < 0.05). Total body water did not change in any of the subjects. Conclusions: Contrary to our hypothesis, increasing dietary sodium while controlling fluid intake during BR resulted in a greater loss of PV compared with the CONT subjects. Reducing dietary sodium while controlling fluid intake did not alter the PV response during BR compared with CONT subjects. fluid and electrolyte hormones osmolality plasma volume total body water Internal Medicine
22	Quantifying Renal Swelling during Machine Perfusion using Digital Image Correlation Webster, Kelly Eileen 22 June 2017 (has links) While machine perfusion of explanted kidneys is theoretically superior to standard cold storage, it may damage potential transplants unless machine-associated swelling is controlled. This thesis presents the effects of perfusate tonicity on renal swelling during hypothermic machine perfusion. Phosphate buffered solution (PBS) and PBS supplemented with 5% w/v mannitol were used as isotonic (289 mOsm/kg) and hypertonic (568 mOsm/kg) perfusates, respectively. Porcine kidney pairs were procured then flushed and machine perfused; the right and left kidneys were assigned opposite perfusates. An experimental methodology was developed to image porcine kidneys undergoing hypothermic machine perfusion (5 deg C) for 15 minutes followed by 120 minutes without perfusion to quantify surface displacement (renal swelling) with digital image correlation (DIC). Surface displacement and size (thickness) were compared between the right and left kidneys of each pair. In addition, discharged renal fluids (i.e., filtrate and venous outflow) and biopsies were collected. On average, kidneys perfused with the mannitol solution were smaller in size than the kidneys perfused with PBS (p < 0.05) at the start and end of each experiment; however, there was no significant difference between the renal sizes at the end of the 15 minute perfusion interval (p > 0.05). Thus, hypertonic and isotonic perfusates yielded different renal swelling outcomes (i.e., physical size and surface displacement), which suggests that perfusate tonicity influences renal swelling. These experiments are the first time ex vivo renal surface displacement measurements have been collected during machine perfusion. / Master of Science Transplant Kidney Edema Machine Perfusion Digital Image Correlation Perfusate Composition Osmolality Tonicity
23	Hyaluronan and Renal Fluid Handling : Studies during Normal and Pathological Conditions of Renal Function Göransson, Viktoria January 2001 (has links) <p>The kidney is the major organ responsible for the regulation of the composition and volume of the body fluids, which is essential for homeostasis. The glycosaminoglycan hyaluronan (HA), with extreme water-binding capacity, is present in the interstitium of the kidney with a heterogenous distribution. The importance of HA in renal water-handling is unknown and was the focus of the present investigation.</p><p>Acute water-loading in rats caused the amount of papillary HA to increase and during water deprivation, the amount was reduced. Gerbils, with extreme urine concentrating capacity, have less HA in the renal papilla in normal conditions and responded diametrically different to water-loading (reduction in HA). Renomedullary interstitial cells (RMICs), which are probably the main producers of HA in the renal medulla, were cultured at different media osmolalities to mimic the milieu of the medulla during variations in the water balance. The amount of HA found in the media was decreased at high osmolalities and increased at low osmolalities, thereby strengthening the <i>in vivo</i> results. CD44, an HA-receptor involved in the uptake and degradation of HA, was expressed on RMICs in an osmolality dependent manner. During high media osmolality, the CD44 expression increased and at lower osmolalities, the opposite occurred, probably due to the need for uptake and degradation of HA.</p><p>Renal ischemia-reperfusion injury causes a cortical accumulation of HA, up-regulation of CD44, and a depression of functional parameters. The time periods of ischemia correlated with the accumulation of HA which, in turn, was inversely correlated to GFR. Hyaluronidase injections in this setting failed to reduce HA levels and significantly improve renal function.</p><p>In conclusion, the results from the present study suggest an important role for HA and RMICs in renal water-handling and that the intrarenal distribution of HA is altered after ischemia-reperfusion injury, which correlates with renal dysfunction.</p> Cell biology CD44 gerbils hyaluronan ischemia-reperfusion kidney osmolality oxygen tension rat renomedullary interstitial cells water Cellbiologi Cell biology Cellbiologi
24	Hyaluronan and Renal Fluid Handling : Studies during Normal and Pathological Conditions of Renal Function Göransson, Viktoria January 2001 (has links) The kidney is the major organ responsible for the regulation of the composition and volume of the body fluids, which is essential for homeostasis. The glycosaminoglycan hyaluronan (HA), with extreme water-binding capacity, is present in the interstitium of the kidney with a heterogenous distribution. The importance of HA in renal water-handling is unknown and was the focus of the present investigation. Acute water-loading in rats caused the amount of papillary HA to increase and during water deprivation, the amount was reduced. Gerbils, with extreme urine concentrating capacity, have less HA in the renal papilla in normal conditions and responded diametrically different to water-loading (reduction in HA). Renomedullary interstitial cells (RMICs), which are probably the main producers of HA in the renal medulla, were cultured at different media osmolalities to mimic the milieu of the medulla during variations in the water balance. The amount of HA found in the media was decreased at high osmolalities and increased at low osmolalities, thereby strengthening the in vivo results. CD44, an HA-receptor involved in the uptake and degradation of HA, was expressed on RMICs in an osmolality dependent manner. During high media osmolality, the CD44 expression increased and at lower osmolalities, the opposite occurred, probably due to the need for uptake and degradation of HA. Renal ischemia-reperfusion injury causes a cortical accumulation of HA, up-regulation of CD44, and a depression of functional parameters. The time periods of ischemia correlated with the accumulation of HA which, in turn, was inversely correlated to GFR. Hyaluronidase injections in this setting failed to reduce HA levels and significantly improve renal function. In conclusion, the results from the present study suggest an important role for HA and RMICs in renal water-handling and that the intrarenal distribution of HA is altered after ischemia-reperfusion injury, which correlates with renal dysfunction. Cell biology CD44 gerbils hyaluronan ischemia-reperfusion kidney osmolality oxygen tension rat renomedullary interstitial cells water Cellbiologi Cell biology Cellbiologi
25	Hypertonicity Regulation of Cytochrome P450 CYP3A I-Chyang, Andrew Chuang 11 December 2012 (has links) Cytochrome P450 3A isozymes (CYP3A) metabolize approximately 50% of therapeutic drugs. It has recently been discovered that human CYP3A mRNA levels can be induced by hypertonicity; a physiological state not previously linked to its regulation. The osmosensitive transcription factor, Nuclear Factor of Activated T-Cells 5 (NFAT5), regulates multiple genes that restore osmolyte homeostasis and promote cell protection during osmotic stress. In silico examinations and in vitro experiments using reporters, knockdown and binding assays in the human intestinal cell line C2bbe1 have revealed an active tonicity-responsive enhancer (TonE) within CYP3A7 intron (+5417/+5427 from CYP3A7 transcriptional start site) that is responsible for NFAT5 binding and NFAT5-dependent regulation of CYP3A isoforms. In addition, hypertonicity-mediated CYP3A induction is also observed in both hepatic and intestinal cell lines. Effects of tonicity changes on in vivo CYP3A expression and function were examined in a humanized CYP3A transgenic mouse with similar tissue expression in humans. More specifically, intervention with prolonged dehydration involving alternating between 24-hour cycles of water-deprivation and water ad lib for 1 week (cyclic water-deprivation; four 24-hour water-deprivation and three 24-hour water ad lib periods), increased expression of NFAT5 target genes Slc6a12 in the liver and kidney (2.5 ± 0.6-fold over water ad lib, n = 14, p = 0.04; and 3.1 ± 0.6-fold, n = 10, p = 0.02, respectively), Akr1b3 in the liver, and Slc5a3 in the kidney. Immunofluorescent microscopy revealed an increase of nuclear-distributed mouse NFAT5 in cyclic water-deprived animals, consistent with NFAT5 activation. Most importantly, CYP3A4 mRNA levels were noted to be elevated in the liver and kidney (11.8 ± 4.8-fold over water ad lib, n = 14, p = 0.04 and 2.2 ± 0.4-fold, n = 9, p = 0.02, respectively), with concurrent CYP3A protein and activity increase. Localized hypertonic environment in the gut was simulated by providing animals with a week-long high-salt diet. The effects of high-salt diet in the gut were similar to those of cyclic water-deprivation in the liver and kidney; where NFAT5 showed nuclear distribution and NFAT5 target gene expression (Slc6a12; 20.5 ± 6.7-fold over a week-long low-salt diet, n = 8, p = 0.02 and Slc6a6; 3.2 ± 0.7-fold, n = 10, p < 0.01, in the duodenum). Furthermore, an increase of CYP3A4 mRNA was observed (2.6 ± 0.5-fold over a week-long low-salt diet, n = 14, p = 0.03), with a corresponding rise in protein expression and activity levels. In summary, increased expression of in vitro and in vivo human CYP3A was achieved using a hypertonic stimulus; concurrent NFAT5 activation and NFAT5 target gene expression were observed. These results suggested a possible binding of activated NFAT5 to CYP3A TonE situated within the intronic region of CYP3A7. It could be further concluded that NFAT5 may be responsible for the hypertonic induction of human CYP3A. Hypertonicity NFAT5 CYP3A Cytochrome P450 Osmolality TonEBP Dietary salt Dehydration Water deprivation NaCl OREBP Tonicity enhancer CYP3A4 CYP3A5 CYP3A7 0419
26	Hypertonicity Regulation of Cytochrome P450 CYP3A I-Chyang, Andrew Chuang 11 December 2012 (has links) Cytochrome P450 3A isozymes (CYP3A) metabolize approximately 50% of therapeutic drugs. It has recently been discovered that human CYP3A mRNA levels can be induced by hypertonicity; a physiological state not previously linked to its regulation. The osmosensitive transcription factor, Nuclear Factor of Activated T-Cells 5 (NFAT5), regulates multiple genes that restore osmolyte homeostasis and promote cell protection during osmotic stress. In silico examinations and in vitro experiments using reporters, knockdown and binding assays in the human intestinal cell line C2bbe1 have revealed an active tonicity-responsive enhancer (TonE) within CYP3A7 intron (+5417/+5427 from CYP3A7 transcriptional start site) that is responsible for NFAT5 binding and NFAT5-dependent regulation of CYP3A isoforms. In addition, hypertonicity-mediated CYP3A induction is also observed in both hepatic and intestinal cell lines. Effects of tonicity changes on in vivo CYP3A expression and function were examined in a humanized CYP3A transgenic mouse with similar tissue expression in humans. More specifically, intervention with prolonged dehydration involving alternating between 24-hour cycles of water-deprivation and water ad lib for 1 week (cyclic water-deprivation; four 24-hour water-deprivation and three 24-hour water ad lib periods), increased expression of NFAT5 target genes Slc6a12 in the liver and kidney (2.5 ± 0.6-fold over water ad lib, n = 14, p = 0.04; and 3.1 ± 0.6-fold, n = 10, p = 0.02, respectively), Akr1b3 in the liver, and Slc5a3 in the kidney. Immunofluorescent microscopy revealed an increase of nuclear-distributed mouse NFAT5 in cyclic water-deprived animals, consistent with NFAT5 activation. Most importantly, CYP3A4 mRNA levels were noted to be elevated in the liver and kidney (11.8 ± 4.8-fold over water ad lib, n = 14, p = 0.04 and 2.2 ± 0.4-fold, n = 9, p = 0.02, respectively), with concurrent CYP3A protein and activity increase. Localized hypertonic environment in the gut was simulated by providing animals with a week-long high-salt diet. The effects of high-salt diet in the gut were similar to those of cyclic water-deprivation in the liver and kidney; where NFAT5 showed nuclear distribution and NFAT5 target gene expression (Slc6a12; 20.5 ± 6.7-fold over a week-long low-salt diet, n = 8, p = 0.02 and Slc6a6; 3.2 ± 0.7-fold, n = 10, p < 0.01, in the duodenum). Furthermore, an increase of CYP3A4 mRNA was observed (2.6 ± 0.5-fold over a week-long low-salt diet, n = 14, p = 0.03), with a corresponding rise in protein expression and activity levels. In summary, increased expression of in vitro and in vivo human CYP3A was achieved using a hypertonic stimulus; concurrent NFAT5 activation and NFAT5 target gene expression were observed. These results suggested a possible binding of activated NFAT5 to CYP3A TonE situated within the intronic region of CYP3A7. It could be further concluded that NFAT5 may be responsible for the hypertonic induction of human CYP3A. Hypertonicity NFAT5 CYP3A Cytochrome P450 Osmolality TonEBP Dietary salt Dehydration Water deprivation NaCl OREBP Tonicity enhancer CYP3A4 CYP3A5 CYP3A7 0419
27	Derangements of tonicity and implications for veterinary patients Reinhart, Jennifer M. January 1900 (has links) Master of Science / Department of Clinical Sciences / Thomas Schermerhorn / Tonicity is property of a solution that is defined as the total effective (impermeable) osmole concentration that drives fluid movement across a semipermeable membrane via osmosis. Tonicity is related to but distinct from solution osmolality, which is a summation of all solute concentrations, regardless of the solute membrane permeability. In the mammalian body, tonicity is tightly regulated at both a cellular and systemic level; tonic derangements cause rapid change in cell and tissue volume leading to significant dysfunction. Input from the central nervous, circulatory, endocrine, gastrointestinal, and urinary systems are integral to osmoregulation, so many diseases in veterinary medicine are associated with tonicity disorders. However, because the homeostatic mechanisms that control tonicity overlap with those regulating electrolyte and acid-base balance as well as hydration and vascular volume, tonic consequences of disease can be difficult to isolate. Understanding of disease-associated changes in tonicity is further complicated by the fact that the tonic contributions of many solutes that accumulate in disease are unknown. Additionally, direct assessment of tonicity is difficult because tonicity is not just a physiochemical property, but it implies a physiologic effect. Thus, simple summation of osmole concentrations is an inadequate measurement of tonicity. The following report includes three studies investigating various aspects of tonicity as it applies to veterinary patients. Chapter 2 reports a study that examines the tonic effects of ketoacids and lactate using two different in vitro red blood cell assays. Results demonstrated that the ketoacids, beta-hydroxybutyrate and acetoacetate, behave as ineffective osmoles while the tonic behavior of lactate is variable, implying a more complex cellular handling of this anion. Two additional studies examine whether the mean corpuscular volume difference (dMCV) is a novel clinical marker for hypertonicity in dogs. Results of separate retrospective (Chapter 3) and prospective (Chapter 4) studies provide evidence that dMCV is a useful clinical marker for hypertonicity in dogs. Osmolality Red blood cells Sodium Diabetes mellitus Dog Metabolism Health Education (0680) Health Sciences (0566) Physiology (0719) Veterinary Medicine (0778)
28	Studium vlivu genu yxkO Bacillus subtilis na motilitu během odpovědi na osmotický stres. / Study of effect of Bacillus subtilis yxkO gene on motility during stress response to osmotic upshift. Streitová, Eliška January 2010 (has links) Bacillus subtilis is gram-positive soil bacteria. In its natural environment it is constantly exposed to changes of chemical and physical conditons, including changes of osmolality. It responds to high osmolality by transporting of potassium ions and afterthat transporting and/or synthetising of compatible solutes. In last years the mutant strain Bacillus subtilis L-42 was isolated with non-specific insertional mutagenesis (mini Tn10) in our laboratory. This strain displays limited growth and inability to cope with hyperosmotic shock in a defined medium with potassium concentration of < 1 mmol/l. Insertion of transposon was located in yxkO gene which encodes a protein of unknown biological function. Some other data also indicate a possible role of disruption of yxkO gene in regulation of expression of hag gene, which encodes flagelin - a pivotal protein of bacterial flagellum. The goal of this thesis was to clarify if the disruption of yxkO gene influences motility and whether is affected the transcription of hag gene. With integrative vector pMUTIN4 a mutant strain with specific mutation of yxkO gene was prepared. Vector was pasted into chromosome of Bacillus subtilis strain 1A839 - genotype of this strain allows to extrude the known transcriptional regulation of hag gene. Cell's motility was...
29	The Effects of Diet, Population, and Water Temperature on the Stress Response of Angled Largemouth Bass Micropterus Salmoides Dinken, Colin P 04 May 2018 (has links) Angling practices subject Largemouth Bass Micropterus salmoides to multiple stressors, causing homeostatic physiological disturbances. The combined effects of ambient and live well temperature on stress responses from exercise have not been thoroughly examined. Large numbers of fish required for stress experiments can be produced by intensive culture, but hatchery fish may differ physiologically from wild fish due to dietary carbohydrates. Therefore, the effects of diet, population, and temperature on stress response and health were examined. Stress responses were similar among fish fed formulated and live diets and liver health improved within 4-6 weeks. Although cortisol responses of hatchery and wild fish differed, secondary stress responses were similar. Fish subjected to simulated angling at temperatures of 17, 25, 33 °C with live well temperature differentials of -4, 0, +4 °C, had the lowest resilience to stress at the warmest temperatures, exhausting energy supplies, coincident with metabolic acidosis and poor ion regulation. stress cortisol glucose lactate osmolality ion regulation leukocytes temperature tournaments angling liver diet carbohydrate glycogen lipid Largemouth Bass
30	Factors causing feed intake depression in lambs infected by gastrointestinal parasites Dynes, Robyn A. January 1993 (has links) A reduction in voluntary feed intake is a major factor in the lost productivity of grazing lambs infected by gastrointestinal parasites yet the mechanisms involved are poorly understood. Potential pathways involved in parasite-induced feed intake depression were investigated in lambs with minimal previous exposure to parasites and artificially infected by the small intestinal parasite Trichostrongylus colubriformis. Six in vivo experiments were conducted on lambs housed in individual pens or metabolism crates with similar feeding and experimental procedures. In Experiment 1 (Chapter 4) the effect of T. colubriformis infection on short term feed intake in lambs and of some pharmacological agents on feed intake depression were investigated. Prior to and for the duration of infection, lambs were fed once per day and feed intake recorded at regular intervals over the day (8 h). Following the onset of feed intake depression in the infected group (9 weeks after commencing dosing), all animals were treated with an analgesic (codeine phosphate per os), an anti-inflammatory agent (indomethacin per os), a CCK antagonist (L364-718 by subcutaneous injection) or saline (control) in a replicated Latin square design (n = 8). Although the pattern of feed consumption was similar in infected and non-infected lambs, average daily intake was reduced 32 % and short term intake (recorded at 10 minute intervals for the first hour of feeding, 15 minute intervals for the second hour and hourly for the next 6 hours of feeding) reduced 40 % by infection. This identified the key component by which intake was depressed and enabled the use of a short term intake model and short duration of action compounds to identify the pathways involved in intake depression in this sequence of experiments. None of the pharmacological treatments increased intake in the infected group. These results suggest a reduction in the rate of consumption due to reduced hunger signals, rather than change of meal eating patterns, is the major cause of feed intake depression. Specific conclusions about the pathways investigated using the pharmacological agents could not be obtained. Experiment 2 (Chapter 5) was designed to investigate the roles of pain and osmolality on feed intake depression. Digesta samples collected prior to and during parasite infection and before and after feeding had similar osmolalities (240-260 mosmol/l) which indicated that feeding or infection had no effect on osmolality of digesta. Following the onset of feed intake depression in infected animals, all animals were treated in a Latin square design (n = 4) with no treatment, saline, local anaesthetic (xylocaine) or analgesic (codeine phosphate) solution 15 minutes before feeding, by slow injection into the duodenum. There was no effect of these treatments on food intake. In the second part of the experiment, hyperosmotic solutions (mannitol and NaCI) markedly depressed short term intake in non-infected animals, suggesting a role for osmoreceptors in intake regulation. However these effects were not blocked by local anaesthetic so the depressed intake may have resulted from generalised malaise rather than from specific osmoreceptor effects. In Experiment 3 (Chapter 6) the role of peripheral CCK on intake depression was examined by a dose-response study utilising the CCK antagonist, loxiglumide. Intravenous injection of 5, 10 or 20 mg/kg LW of loxiglumide to infected lambs 10-15 minutes before feeding (n = 6) had no effect on feed intake at any of the dose levels. In experiment 4 (Chapter 7) loxiglumide was infused intravenously for 10 minutes (30 mg/kg/h) before feeding and for the first 2 h (10 mg/kg/h) after feed was offered to minimise any effect of the rate of clearance of loxiglumide on the lack of feed intake response. As well, the rate of marker disappearance from the abomasum was recorded in both infected and non-infected animals. Continuous infusion of loxiglumide did not attenuate parasite induced intake depression nor did it have any effect on abomasal emptying. Abomasal volume was reduced by infection (66.3 vs 162 ml) as was the fractional outflow rate (2.2 vs 2.8 ml/min) but these differences were accounted for by the lower level of feed intake in the infected animals. In Experiment 5 (Chapter 8) brotizolam, a benzodiazepine appetite stimulant, thought to act on the hypothalamus, was administered in a dose-response study to infected and non-infected animals (n = 4) immediately prior to feeding or following termination of the first meal (45 minutes after feeding) and the feed intake response recorded. Brotizolam elevated both the short term (0-0.75 h), daily (22 h) intake and all time intervals in the first 5 h after feeding in infected and non-infected animals when administered after the first meal but when administered prior to feeding elevated intake only over the first 6 h of feeding. In both cases the magnitude of the response was greater in infected animals than in non-infected animals. Brotizolam appeared to increase the rate of eating without having a major impact on meal eating patterns when administered before feeding. Where administration was after the first meal, the effect was due to an "extra" meal being consumed. These findings showed that infected animals can respond to central stimulators of intake although the mechanism of the response is not known. Opioids were implicated in intake depression as the rate of intake rather than meal patterns appeared to be the major parameter depressed under parasitism. This was examined in experiment 6 (Chapter 9) where animals (n = 6) were fasted for 26 h or not fasted, then treated with saline (control), brotizolam (intake stimulant) or naloxone (opioid antagonist) immediately prior to feeding. Fasting stimulated feed intake in the short term (100 % increase in 75 min) and over the day (12 % increase) in both infected and non-infected animals. Following fasting, infected animals ate a similar amount of feed to the non-infected, fasted animals and more than the non-infected, non-fasted animals. The signals resulting from a one day fast were sufficient in the short term to override parasite induced mechanisms causing feed intake depression. Naloxone suppressed the intake stimulatory effects of a 26 h fast in both infected and non-infected animals, which supports a role for endogenous opioids as hunger signals. Where animals were not fasted, naloxone reduced intake only in the non-infected animals which suggested endogenous opioid levels may be lower in infected animals than in non-infected animals. In the final experiment (Experiment 7, Chapter 10) the role of central hunger and satiety mechanism were investigated. Infected and non-infected animals (n = 6) were treated with naloxone or saline by intravenous injection, or saline and met-enkephalinamide (an opioid analogue) by intracerebral infusion, or naloxone and the opioid analogue simultaneously to investigate the role of central opioids in feed intake depression. To determine the role of CCK induced satiety signals on feed intake at a central level, loxiglumide and CCK were infused separately and in combination for 30 minutes prior to feeding and for the first 60 minutes of feed on offer, into a lateral cerebral ventricle of the brain of infected and control animals (n = 6). The opioid analogue tended to increase intake in infected animals but the effect was not significant probably because the dose used was too low to elicit a response in sheep. Naloxone depressed intake only in the infected animals, which conflicted with the results of Experiment 4. As a consequence these results were inconclusive because of the single low dose of opioid analogue used and the conflicting naloxone responses. CCK alone depressed intake by 39-52 % only in infected animals and this effect of the 90 minute infusion was evident over the 8 h short term recording period. Loxiglumide attenuated the feed intake depressive effects of CCK in the infected animals to the extent that intake was elevated above control levels. Loxiglumide alone was an intake stimulant in both infected and non-infected animals. Intake was increased over the entire 8 h but mostly in the second hour when intake was increased by 188 % in infected animals and by 16 % in the non-infected animals and resulted in almost continuous eating. These results showed loxiglumide will temporarily block the effect of parasite infection on feed intake in sheep when administered centrally and the fact that it blocked the effects of exogenous CCK on intake indicated that the effect is mediated via CCK receptors. In conclusion GIT parasite infection reduced both short term and daily feed intake apparently by a change in rate of intake rather than any alteration in meal patterns. It was further suggested that anyone of a number of potential peripheral pathways, including changes to osmolality, gut emptying, pain and inflammation of the gut, alone is not involved in anorexia in sofar as the compounds used could block these factors and the results support the idea that intake depression is mediated via a central mechanism. Intake in infected animals responded to a much greater extent when fasting, i.c.v. loxiglumide or brotizolam were employed. Feed intake thus appears to be regulated through the same mechanisms in infected and non-infected animals. The results from compounds affecting the central mechanism suggest central CCK receptors are important in parasite induced anorexia, possibly by changing the onset of satiety or by interacting with endogenous opioids to reduce the rate of feed intake. Secondly reduced endogenous opioids may be causing the reduction in the rate of feed consumption alone or as a result of other interactions. It was concluded that intake in parasitised animals could be increased to that of control animals by employing procedures and compounds thought to act on the hypothalamus. feed intake gastrointestinal parasites Trichostrongylus colubriformis CCK antagonists L364-718 loxiglumide fasting opioids naloxone pain osmolality inflammation 070204 - Animal Nutrition

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