Operant drinking in pigs following intracerebroventricular injections of hypertonic solutions and angiotensin II

The effect on operant drinking of intracerebroventricular injections of the following solutions has been investigated; hypertonic saline, hypertonic sugars, angiotensin II (Ang II) dissolved in water or dextrose, and Ang II dissolved in saline. Hypertonic (0.85 M) NaCl caused drinking in all pigs tested, but hypertonic (1.7 M) xylose, glucose or sucrose were less effective, indicating involvement of a cerebrospinal fluid sodium receptor mechanism as well as an osmoreceptor mechanism in the drinking responses. Angiotensin II in 0.15 M NaCl caused drinking in all pigs but when dissolved in water or dextrose it was ineffective. Injection of Ang II with hypertonic NaCl produced drinking similar in volume to the sum of the amount drunk in response to the individual stimuli. These results indicate that, in the pig, drinking in response to Ang II requires the presence of sodium ions.     

Efferent renal nerve activity during intracarotid and intracerebroventricular infusions of hypertonic sodium chloride solutions and isotonic volume expansion in the rat

The change in renal nerve activity under conditions known to increase renal sodium excretion was studied. In adult Sprague Dawley rats, anaesthetized with Inactin®, nor-motonic and hypertonic NaCl solutions were infused into 1) a vein, 2) a carotid artery and 3) the third ventricle. The left kidney was freed and placed in a plastic cup. A renal nerve was dissected free and placed on a stainless bipolar electrode. The nerve was cut distal to the electrode. The nerve signals were amplified and recorded on a tape recorder. Simultaneously integrated nerve signals and also arterial and venous pressures were recorded. Intracarotid infusion of a 1 M NaCl solution increased sodium output and temporarily decreased renal nerve activitv by some 35%. Corresponding intravenous (i.v.) infusion gave an increase in renal nerve activity and also in sodium output. The latter increase was delayed compared with that caused by the intracarotid infusion. No variations in blood pressure were noted. In control experiments with a slow i.v. infusion of physiological saline, renal nerve activity increased throughout the experiment, while sodium excretion remained constant. During infusion of a 1 M NaCl solution into the third ventricle, renal nerve activity decreased in about half of the cases. This reduction was often accompanied by an increased arterial blood pressure and an increased sodium output. Arterial blood pressure increases were especially pronounced at the highest infusion rate, i.e. 800 nl-min-¹. Isotonic volume expansion of 2% of the body weight resulted in a transient decrease in renal nerve activity by about 30%. Venous blood pressure rose and sodium output increased six-fold. The decrease in nerve activity was observed both when the vagal nerves were intact and when they were cut.     

Transient vasopressin release and thirst in response to prolonged intracerebroventricular infusions of hypertonic mannitol in saline

In the conscious goat infusions of 0.4 M mannitol in 0.15 M NaCl into the lateral cerebral ventricle (40 or 100 min, 0.02 ml/min) caused slight, transient vasopressin release and temporary thirst, whereas infusions or pure, hypertonic (0.7 M) mannitol did not elicit thirst and inhibited the basic vasopressin release in the nonhydrated animal. In contrast, infusions of equiosmolal (0.35 M) NaCl induced persistent thirst and pronounced elevation of the plasma vasopressin concentration throughout the infusion period. The cerebrospinal fluid (CSF) osmolality was raised by the same order of magnitude (= 13%) after the mannitol/NaCl and the hypertonic NaCl infusions. The CSF Na+ concentration was elevated by greater than 10% at 5 min after hypertonic NaCl infusions, but it was reduced by approximately 10% at 5 min after the mannitol/NaCl infusions. There was no appreciable difference in the CSF K+ concentration after the infusions. The results are discussed with regard to the possible importance of CSF Na+-concentration as opposed to strict osmotic factors for the excitation of receptors involved in the control of water balance.     

Effects of intracerebroventricular infusions of arginine vasopressin in sheep

In sheep, neither the in vivo effect of vasopressin administered by a method other than systemic infusion nor the central effects on behavior from the perspective of stress regulation has been fully elucidated in an intact animal. We examined changes in behavioral, adrenocorticotropic, and autonomic nervous functions after intracerebroventricular infusions of arginine vasopressin (AVP) to elucidate its central role. Intracerebroventricular infusions of AVP (0, 0.12, 1.2 and 12 microg/500 microl/30 min) evoked a dose-related increase in plasma cortisol concentration. There were significant treatment-related effects on the total duration of sham-chewing (Friedman's test, X2=12.75, p=.0052), on the total duration of bar-biting (Friedman's test, X2=15.0, p=.0018), and on the total duration of rubbing (Friedman's test, X2=12.0, p=.0074). AVP 12 microg treatment induced a greater degree of sham-chewing and bar-biting than the other three treatments did (Nemenyi multiple comparisons: p<0.1). These findings indicate, together with our previous findings, that AVP has the same corticotropic potential as corticotropin-releasing hormone infused intracerebroventricularly in equal molar concentrations. Although the degree to which central stress signaling pathways are involved in these responses remains speculative, the relationships between stereotypies and central AVP are of particular interest.     

The increase in the rate of heat production of frog's skeletal muscle caused by hypertonic solutions

1. The rate of heat production of resting muscle is increased by hypertonic solutions.2. The threshold osmolality required to produce the increased heat rate is less than 2 times normal; at 2.5-3 times normal the heat production rises to 20-50 mcal.g(-1).min(-1), which is 10-20 times the basal rate.3. In anaerobic conditions, the effect of hypertonic solutions on heat rate is only one tenth of that in aerobic conditions.4. A glycerol-treated muscle, with damaged tubular system, still gives a normal response to hypertonic solutions, though it does not respond to raised K(+) concentration.5. The metabolic response to hypertonic solutions is considerably suppressed by procaine.6. Ouabain, 10(-5)-10(-4)M, has no effect.7. The response remains substantial in a muscle which has been depolarized in isotonic K(2)SO(4).8. The membrane potential is slightly reduced by hypertonic solutions, but this cannot account for the increase of the resting metabolism.9. It is suggested that the effect may be due to the release of calcium ions, which produce an increase in myosin ATPase activity.     

Natriuresis obtained by intracerebroventricular infusion of hypertonic NaCI in rats with papillary necrosis.

Raising the sodium concentration in the third cerebral ventricle increases renal sodium, potassium and water excretion. The identification and characterization of the factor(s) mediating the centrally evoked natriuresis would be greatly facilitated if the exact intrarenal effector site were known. We have assessed the importance of inner medullary structures for the effects of CNS stimulation by examining its ability to alter renal excretion in rats with papillary necrosis, induced 2 d earlier with 2-bromoethylamine hydrobromide (BEA), 250 mg kg^-1 body wt i. v. Male Lewis x DA rats were divided into a BEA-treated group (n = 6) and a control group receiving vehicle alone (n = 6). In contrast to the white papillae normally seen, the papillae of BEA-treated animals were bright red and showed a clear line of demarcation at their base. The rats were anaesthetized i. p. with Inactin (120 mg kg^-l body wt). Artificial cerebrospinal fluid (CSF) was infused (520 nL min^-1) via a cannula into the left lateral ventricle. After 45 min CSF containing 1 M NaCl was used. Stimulation of the control rats with hypertonic CSF increased urine flow rate five-fold (5.4± 0.8 to 27.1±6.1 μL min^-1), Na excretion 23-fold (0.4±0.1 to 7.6±1.8 μmol min^-1) and K excretion fourfold (0.6±0.18 to 3.8±O.5 pmol min^-1). When the concentration mechanisms were damaged with BEA, the basal excretion rates of water and Na increased. The natriuretic response to ICV stimulation was severely impaired in these rats, but the kaliuretic effect was sustained. In conclusion, the natriuretic effect of ICV stimulation with hypertonic CSF is dependent on an intact renal inner medulla, which is not the case for the less pronounced kaliuretic response. Thus, either the juxtamedullary nephrons possess marked natriuretic responsiveness, not present in the cortical ones, or the responsiveness lies mainly in the papillary collecting ducts. However, it cannot be excluded that a disturbance of salt balance contributes to the observations.     

Increased resistance to haemorrhage induced by intracerebroventricular infusion of hypertonic NaCl in conscious sheep.

The effect of elevated cerebrospinal fluid Na+ concentration (CSF [Na+]) on the tolerance of blood loss, and concomitant cardiovascular and humoral responses were studied in conscious sheep. A slow (0.7 ml kg-1 min-1) venous haemorrhage was continued until the mean systemic arterial pressure suddenly decreased to less than 50 mmHg, or in the absence of hypotension, until a total blood loss of 25 ml kg-1. Significantly more blood had to be removed to induce hypotension in animals receiving an intracerebroventricular (i.c.v.) infusion (0.02 ml min-1) of 0.5 M NaCl (starting 30 min before haemorrhage and continued throughout the experiment) compared to control haemorrhages without concomitant i.c.v. infusion (22.7 +/- 1.2 ml vs 16.9 +/- 0.9 ml kg-1). In one animal, subjected to 0.5 M NaCl infusion, the blood pressure was still maintained at 25 ml kg-1 of haemorrhage. In spite of a larger blood loss, animals receiving i.c.v. infusion of hypertonic NaCl had an improved recovery of the blood pressure after haemorrhage, due to a better maintained cardiac output rather than to a reinforced increase of the vascular resistance. The improved cardiovascular responses to haemorrhage during elevated CSF [Na+] are not readily explained by the effects on the plasma concentrations of vasopressin, angiotensin II or noradrenaline, although the latter was augmented. The plasma protein concentration decreased already during the 30 min of hypertonic NaCl infusion preceding haemorrhage, and the haemodilution caused by the subsequent blood removal was aggravated, which indicates that this treatment also causes transfer of fluid to the plasma compartment. We conclude that elevated CSF [Na+] increases tolerance to haemorrhage and improves cardiovascular function after blood loss in sheep. Since the haemodynamic responses in many respects were similar to those reported in response to the systemic administration of a small volume of hypertonic NaCl solution in haemorrhagic shock, part of the effect of that treatment may be mediated via cerebral effects of increased Na+ concentration.     

Effect of hypertonic intracarotid infusions on plasma vasopressin concentration

The effect of short-term bilateral intracarotid infusions of hypertonic saline on plasma vasopressin concentration (pAVP) was evaluated in five dogs. Intracarotid infusion of saline at 90 mumol . kg-1 . min-1 . artery-1 significantly (P less than 0.05) increased jugular vein osmolality (pOsm) and sodium concentration (pNa+) within 2 min. Saphenous vein pOsm was not altered during the 6 min of infusion, whereas pNa+ was increased (P less than 0.05) from 0.8 +/- 0.1 to 2.3 +/- 0.3 pg/ml. Subsequent experiments using hypertonic saline infusions of 90 and 180 mumol . kg-1 . min-1 administered intracarotidly and intravenously for 6 min were performed. Intracarotid isotonic infusions and intravenous hypertonic infusions did not significantly alter pAVP. Hypertonic intracarotid saline increased jugular vein pOsm and pNa+ in a dose-related fashion, whereas saphenous vein pOsm and pNa+ were not significantly changed after 6 min of infusion. Plasma vasopressin, compared with the isotonic intracarotid infusion (1.5 +/- 0.3 pg/ml), was increased (P less than 0.05) after hypertonic saline to 3.2 +/- 0.6 and 4.8 +/- 0.2 pg/ml for the 90 and 180 mumol . kg-1 . min-1 infusions, respectively. The cerebral osmolality indicated by jugular vein pOsm was therefore increased in the absence of changes in systemic pOsm during intracarotid hypertonic infusions. The increase in pAVP in response to these changes in pOsm supports the presence of central osmoreceptors regulating vasopressin release in the area of distribution of the common carotid arteries.     

Release of ATP induced by hypertonic solutions in Xenopus oocytes

ATP mediates intercellular communication. Mechanical stress and changes in cell volume induce ATP release from various cell types, both secretory and non-secretory. In the present study, we stressed Xenopus oocytes with a hypertonic solution enriched in mannitol (300 m m ). We measured simultaneously ATP release and ionic currents from a single oocyte. A decrease in cell volume, the activation of an inward current and ATP release were coincident. We found two components of ATP release: the first was associated with granule or vesicle exocytosis, because it was inhibited by tetanus neurotoxin, and the second was related to the inward current. A single exponential described the correlation between ATP release and the hypertonic-activated current. Gadolinium ions, which block mechanically activated ionic channels, inhibited the ATP release and the inward current but did not affect the decrease in volume. Oocytes expressing CFTR (cystic fibrosis transmembrane regulator) released ATP under hypertonic shock, but ATP release was significantly inhibited in the first component: that related to granule exocytosis. Since the ATP measured is the balance between ATP release and ATP degradation by ecto-enzymes, we measured the nucleoside triphosphate diphosphohydrolase (NTPDase) activity of the oocyte surface during osmotic stress, as the calcium-dependent hydrolysis of ATP, which was inhibited by more than 50 % in hypertonic conditions. The best-characterized membrane protein showing NTPDase activity is CD39. Oocytes injected with an antisense oligonucleotide complementary to CD39 mRNA released less ATP and showed a lower amplitude in the inward current than those oocytes injected with water.     

侧脑室灌注牛磺酸对家兔db—cAMP性发热的影响

将30只新西兰白兔随机均分成3组,第一组二丁酰腺苷环一磷酸 牛磺酸,第二组生理盐水 牛磺酸和第三组二丁酰腺苷环一磷酸 生理盐水。采用侧脑室埋管、侧脑室注射和灌注技术,把牛磺酸和二丁酰腺苷环一磷酸等被试物注入动物脑室。结果发现,在中枢注射二丁酰腺苷环一磷酸导致单相长热程的过程中,侧脑室注入牛磺酸能明显抑制二丁酰腺苷环一磷酸性发热。3组的6小时体温反应指数分别为7.10±2.44、0.21±1.58和12.47±4.60(P<0.01)。本文还讨论了牛磺酸抑热的可能机制。     

Effect of variation of the composition of CSF in the rat upon drinking of water and hypertonic NaCl solutions

Infusing conscious unrestrained rats with either 0.5 M NaCl-CSF or 0.7 M sucrose-CSF into the lateral cerebral ventricle (IVT) at 38 microliters/hr for 4 hr induced drinking. Although the infusates were nearly equiosmotic, water drinking during the 0.5 M NaCl-CSF was greater than during 0.7 M sucrose-CSF. However, IVT infusions of 0.7 M mannitol-CSF at rates of 9.4 microliters/hr or 38 microliters/hr for 4 hr or 10 microliters/hr for 4 days failed to induce water drinking. Also, IVT infusion of 0.27 M mannitol-CSF at 38 microliters/hr for 4 hr failed to significantly alter water drinking. CSF [Na] was reduced by IVT infusion of either 0.7 M sucrose-CSF or 0.7 M mannitol-CSF. In contrast, CSF [Na] was increased by 4-hr IVT infusion of 0.5 M NaCl in rats denied access to water during the infusion. Intake of 0.5 M NaCl was not altered significantly from control intakes by any of the above IVT infusions. It is concluded that water drinking in the rat may be initiated by stimulation of either a sodium sensitive sensor alone or with an osmoreceptor system and that species specific differences in the induction of both water drinking and hypertonic saline drinking are apparent.