Circadian Rhythm in Gamma Glutamyltranspeptidase and Leucine Aminopeptidase Urinary Activity in Rats

Urinary gamma glutamyltranspeptidase (GGT) and leucine aminopeptidase (LAP), renal tubular brush border enzymes, have been shown to be sensitive indicators of renal tubular functions. This study documents circadian rhythms in the urinary activity of GGT and LAP, statistically validated and quantified by the cosinor method, in 15 male Wistar rats standardized to a LD 12:12 illumination schedule (light from 0800 hr to 2000 hr) and fed ad libitum. The acrophase of the circadian rhythms in urinary GGT and LAP activity occurred at the end of the rest span of the animals: between 1730 and 1915 for GGT (depending on the mode of expression of the activity) and between 1700 and 1910 for LAP. Of striking resemblance in their timing, both these rhythms were also of large amplitude (about 50% of the mesor for urinary GGT activity and about 45% for LAP one). The circadian acrophases of urinary GGT and LAP activity led in timing the circadian rhythms in urine volume and creatinine excretion by about 13hr. Such findings consistent with the circadian variations found by other investigators in GGT in kidney homogenates or in LAP in human urine thus reflect a periodicity in renal tubular function. The reasons for these circadian variations, still unknown at this time, are discussed. The influence recently demonstrated of the hormonal context on protein and enzyme synthesis at the tubule, and its phase relations to urinary enzyme excretion emphasize how much the circadian rhythm in urinary GGT and LAP activity is well included in the murine time structure. Therefore it should be of interest to consider the circadian rhythm in urinary GGT and LAP release as a marker rhythm of predictive value as to the side effects of nephrotoxic drugs.     

Circadian Rhythm in Gamma Glutamyltranspeptidase and Leucine Aminopeptidase Urinary Activity in Rats

Urinary gamma glutamyltranspeptidase (GGT) and leucine aminopeptidase (LAP), renal tubular brush border enzymes, have been shown to be sensitive indicators of renal tubular functions. This study documents circadian rhythms in the urinary activity of GGT and LAP, statistically validated and quantified by the cosinor method, in 15 male Wistar rats standardized to a LD 12:12 illumination schedule (light from 0800 hr to 2000 hr) and fed ad libitum. The acrophase of the circadian rhythms in urinary GGT and LAP activity occurred at the end of the rest span of the animals: between 1730 and 1915 for GGT (depending on the mode of expression of the activity) and between 1700 and 1910 for LAP. Of striking resemblance in their timing, both these rhythms were also of large amplitude (about 50% of the mesor for urinary GGT activity and about 45% for LAP one). The circadian acrophases of urinary GGT and LAP activity led in timing the circadian rhythms in urine volume and creatinine excretion by about 13hr. Such findings consistent with the circadian variations found by other investigators in GGT in kidney homogenates or in LAP in human urine thus reflect a periodicity in renal tubular function. The reasons for these circadian variations, still unknown at this time, are discussed. The influence recently demonstrated of the hormonal context on protein and enzyme synthesis at the tubule, and its phase relations to urinary enzyme excretion emphasize how much the circadian rhythm in urinary GGT and LAP activity is well included in the murine time structure. Therefore it should be of interest to consider the circadian rhythm in urinary GGT and LAP release as a marker rhythm of predictive value as to the side effects of nephrotoxic drugs.     

Circadian Rhythms of Plasma Concentrations of Na+ and K+ and Their Urinary Excretion in Normal and Diabetic Rats

The effects of streptozotocin induced diabetes (50 mg/Kg) on the circadian rhythms in the excretion of sodium and potassium as well as their plasma concentration rhythms were investigated. Control (C) and diabetic (D) rats were studied during a light-dark (12h:12h) cycle and fed ad libitum. Statistically significant circadian rhythms were found for sodium and potassium excretion in C rats. The orthophases of both rhythms occurred in the dark phase, the potassium one occurring before that of sodium. In D rats there is increased excretion of both sodium and potassium with the rhythmicity maintained for sodium excretion only, which has an earlier orthophase than in the C rats. Plasma sodium and potassium concentrations showed a statistically significant circadian pattern in C rats, with orthophase in the light phase. This rhythmicity only appears in plasma potassium concentration for D rats, with orthophase at the end of the dark phase. The results in diabetic rats may suggest that the glomerular filtration rate (GFR) and/or tubular reabsorption rhythms are still contributing to the sodium excretory rhythm, and that the loss of the circadian rhythm in sodium plasma concentration has no influence on the sodium excretion rhythm. Nevertheless, the loss of the potassium excretion rhythm may suggest a disruption of the variations in the secretory process, as this excretion seems to be independent of the plasma potassium concentration rhythm, which is not lost in D rats.     

Circadian Rhythms of Plasma Concentrations of Na+ and K+ and Their Urinary Excretion in Normal and Diabetic Rats

The effects of streptozotocin induced diabetes (50 mg/Kg) on the circadian rhythms in the excretion of sodium and potassium as well as their plasma concentration rhythms were investigated. Control (C) and diabetic (D) rats were studied during a light-dark (12h:12h) cycle and fed ad libitum. Statistically significant circadian rhythms were found for sodium and potassium excretion in C rats. The orthophases of both rhythms occurred in the dark phase, the potassium one occurring before that of sodium. In D rats there is increased excretion of both sodium and potassium with the rhythmicity maintained for sodium excretion only, which has an earlier orthophase than in the C rats. Plasma sodium and potassium concentrations showed a statistically significant circadian pattern in C rats, with orthophase in the light phase. This rhythmicity only appears in plasma potassium concentration for D rats, with orthophase at the end of the dark phase. The results in diabetic rats may suggest that the glomerular filtration rate (GFR) and/or tubular reabsorption rhythms are still contributing to the sodium excretory rhythm, and that the loss of the circadian rhythm in sodium plasma concentration has no influence on the sodium excretion rhythm. Nevertheless, the loss of the potassium excretion rhythm may suggest a disruption of the variations in the secretory process, as this excretion seems to be independent of the plasma potassium concentration rhythm, which is not lost in D rats.     

The effect of sleep upon human circadian rhythms

Subjects who slept for 4 h from 0000, and for a second 4 h variously distributed over the day, have provided values for rectal temperature and for urinary excretion of water, potassium, sodium, chloride, phosphate, creatinine, calcium and urate in the sleeping subject at all hours of the 24. These are compared with similar values in the wakeful subject. Temperature was lower during sleep at all hours except 1000 and 1200, and the difference was maximal shortly before 0000. At all hours potassium excretion was lower and phosphate excretion higher during sleep. Cosinor analysis of the different variables in the sleeping subject is compared with that in subjects following nycthemeral habits, and the interaction between endogenous rhythms and external influences such as sleep is discussed. The phasing of the temperature and urinary rhythms was essentially normal by the end of the observations. By contrast in a subject who slept at irregular hours mimicking the habits of an air pilot a free-running rhythm unrelated to the habits of sleep emerged. When he was finally living again on normal time his temperature and urinary acrophases had moved to the middle of the night. Phosphate excretion was largely exogenous, falling consistently when subjects rose after 8 h, but not after 4 h of sleep.     

Circadian rhythms of electrolyte and 17-hydroxycorticosteroid excretion in hyperthyroidism and hypothyroidism.

The circadian rhythms of excretion of sodium, potassium, calcium, magnesium, phosphorus and 17-hydroxycorticosteroid (17-ohcs) were determined in five normal subjects, in six patients with hyperthyroidism and five with hypothyroidism. Constant diets with identical 3-hourly feedings were employed, and urine collections were made every 3 hrs during a 3-day study period. The circadian patterns of urinary excretion of sodium, potassium and 17-OHCS were similar in all three groups with distinct daytime peaks and nighttime nadirs. The total quantities of the ions and 17-OHCS excreted were greater in hyperthyroid than in hypothyroid patients with the greatest difference noted with the 17-OHCS. The rhythms for calcium, magnesium and phosphorus excretion were accentuated in hyperthyroid patients but similar to those in normal subjects with early morning calcium and magnesium peaks and a phosphorus peak approximately 12 hrs later. While a similar although blunted circadian pattern for calcium and perhaps magnesium excretion was noted in hypothyroid patients, their phosphorus rhythms were distorted and rather flat. These latter results confirm the observation of MINTZ et al. and are compatible with their interpretation that thyroid hormone is permissibly necessary for the expression of a normal phosphaturic rhythm and that the circulating level of thyroid hormone influences the amplitude of the phosphaturic rhythm.     

Sleep and Circadian Rhythms of Temperature and Urinary Excretion on a 22.8 hr “Day”

Two groups of subjects (total N = 6) were studied in an isolation chamber for a period of 3 weeks whilst living on a 22.8 hr “day”. Regular samples of urine were taken when the subjects were awake, deep body temperature was recorded continuously and polygraphic EEG recordings were made of alternate sleeps. The excretion in the urine of potassium, sodium, phosphate, calcium and a metabolite of melatonin were estimated.

Measurements of the quantity and quality of sleep were made together with assessments of the temperature profiles associated with sleep. In addition, cosinor analysis of circadian rhythmicity in urinary variables and temperature was performed.

The 22.8 hr “days” affected variables and subjects differently. These differences were interpreted as indicating that the endogenous component of half the subjects adjusted to the 22.8 hr “days” but that, for the other three, adjustment did not occur. When the behaviour of different variables was considered then some (including urinary potassium and melatonin, sleep length and REM sleep) appeared to possess a larger endogenous component than others (for example, urinary sodium, phosphate and calcium), with rectal temperature behaving in an intermediate manner. In addition, a comparison between different rhythms in any subject enabled inferences to be drawn regarding any links (or lack of them) that might exist between the rhythms. In this respect also, there was a considerable range in the results and no links between any of the rhythms appeared to exist in the group of subjects as a whole.

Two further groups (total N=8) were treated similarly except that the chamber clock ran at the correct rate. In these subjects, circadian rhythms of urinary excretion and deep body temperature (sleep stages and urinary melatonin were not measured) gave no evidence for deterioration. We conclude, therefore, that the results on the 22.8 hr “day” were directly due to the abnormal “day” length rather than to a prolonged stay in the isolation chamber.     

Phase-Shifts of Apparent Orcadian Rhythms Due to West and East Transmeridian Flights or to Corresponding Night-Shift Sleep Displacements

Phase movements of apparent circadian rhythms during 2 wk of forward or backward displacement of the sleep-wake cycle were investigated in four experimental series in a subject. The 7-hr delay or advance of sleep due to a westward or an eastward transmeridian flight was duplicated by corresponding sleep displacements during experimental night shifts. Sudden phase advances (or delays) by several hours were observed in the rhythms of continuously recorded rectal temperature and urinary excretion rates (4-hr collection intervals) of adrenaline, noradrenaline and aldosterone the first day after sleep-wake displacement. The desired 7-hr phase-shifts were reached more quickly and completely when the phase was delayed than when it was advanced. In addition, the best-fitting period of these rhythms became shorter than 24 hr when the phase was delayed, and longer than 24 hr when it was advanced. The apparent rhythms of urine flow and electrolyte excretions (potassium, sodium, zinc) were much weaker and their phase movements more irregular than those of hormonal excretion. It is concluded that the sudden phase-shifts resulted from the immediate adaptation of the exogenous components of the rhythms to the demands of the displaced sleep-wake patterns (masking effects) and that the true phase-shifts of the endogenous components followed more slowly and gradually.     

Phase-shifts of apparent circadian rhythms due to west and east transmeridian flights or to corresponding night-shift sleep displacements

Phase movements of apparent circadian rhythms during 2 wk of forward or backward displacement of the sleep-wake cycle were investigated in four experimental series in a subject. The 7-hr delay or advance of sleep due to a westward or an eastward transmeridian flight was duplicated by corresponding sleep displacements during experimental night shifts. Sudden phase advances (or delays) by several hours were observed in the rhythms of continuously recorded rectal temperature and urinary excretion rates (4-hr collection intervals) of adrenaline, noradrenaline and aldosterone the first day after sleep-wake displacement. The desired 7-hr phase-shifts were reached more quickly and completely when the phase was delayed than when it was advanced. In addition, the best-fitting period of these rhythms became shorter than 24 hr when the phase was delayed, and longer than 24 hr when it was advanced. The apparent rhythms of urine flow and electrolyte excretions (potassium, sodium, zinc) were much weaker and their phase movements more irregular than those of hormonal excretion. It is concluded that the sudden phase-shifts resulted from the immediate adaptation of the exogenous components of the rhythms to the demands of the displaced sleep-wake patterns (masking effects) and that the true phase-shifts of the endogenous components followed more slowly and gradually.     

Effects of a Mild and Prolonged Restriction in Sodium or Food Intake on the Circadian Rhythm of Aldosterone and Related Variables

The effect of a mild reduction in dietary sodium intake (-30 mEq/24 hr) and body weight (-2 kg/2 months) on circadian rhythms of urinary aldosterone (UA), sodium (UNa), potassium (UK), creatinine (UC) and volume (UV) have been investigated in nine clinically healthy subjects. The mild reduction in dietary sodium is associated with: (1) a decrease in the 24-hr excretion rate of UNa, UK and UV, and an increased mesor of UA and UC; (2) a lowered extent of the circadian variation for UNa, UK, UV and a greater amplitude for UA and UC (3) a later crest in the temporal phase for UK, UA, UC, an earlier phasic wave for UNa. The mild reduction in calorie intake resulting in a body weight loss is associated with a more pronounced decrease in the 24-hr excretion rate of UNa and UK, and in the extent of circadian fluctuation for UNa. Peculiar events are: (1) the decreased 24-hr excretion rate for UA, and the increased mesor for UV; (2) the extent variability increased for UV, decreased for UC. Such effect may have a practical resonance for heuristic physiology since the role of dietary sodium and food intake has been better clarified. Dietary sodium and food can be regarded as 'chronomodulatory agents' for the adrenal cortex since their adrenotropic influence is extended to the tonic as well as phasic secretion of aldosterone.     

Effects of a Mild and Prolonged Restriction in Sodium or Food Intake on the Circadian Rhythm of Aldosterone and Related Variables

The effect of a mild reduction in dietary sodium intake (?30 mEq/24 hr) and body weight (?2 kg/2 months) on circadian rhythms of urinary aldosterone (UA), sodium (UNa), potassium (UK), creatinine (UC) and volume (UV) have been investigated in nine clinically healthy subjects. The mild reduction in dietary sodium is associated with: (1) a decrease in the 24-hr excretion rate of UNa, UK and UV, and an increased mesor of UA and UC; (2) a lowered extent of the circadian variation for UNa, UK, UV and a greater amplitude for UA and UC (3) a later crest in the temporal phase for UK, UA, UC, an earlier phasic wave for UNa. The mild reduction in calorie intake resulting in a body weight loss is associated with a more pronounced decrease in the 24-hr excretion rate of UNa and UK, and in the extent of circadian fluctuation for UNa. Peculiar events are: (1) the decreased 24-hr excretion rate for UA, and the increased mesor for UV; (2) the extent variability increased for UV, decreased for UC. Such effect may have a practical resonance for heuristic physiology since the role of dietary sodium and food intake has been better clarified. Dietary sodium and food can be regarded as ‘chronomodulatory agents’ for the adrenal cortex since their adrenotropic influence is extended to the tonic as well as phasic secretion of aldosterone.     

Circadian rhythmus of the excretion of electrolytes and urinary proteins in rats]

Circadian rhythms in urinary water, sodium, potassium and proteins excretion are studied in 45 rats living alone in metabolism cages. Urines are collected during 4 consecutive 6 hours long periods during 2 consecutive days. Large circadian variations of these parameters (especially water and proteins excretion and urinary protein concentration) are described. The influence of feeding rhythms on the circadian urinary excretion rhythms is discussed. It is proposed that nightly renal hemodynamic changes (during meal digestion or with high renin plasma levels) can induce modifications in glomerular filtration rate and electrolytes and macromolecules transglomerular flow.     

Ten-Year-Replicated Circadian Profiles for 36 Physiological,Serological and Urinary Variables in Healthy Men

At 3-hr intervals over a 24-hr span, 36 systemic, serologic and urinary variables were examined in 7 men in their mid 20's in the Spring of 1969, and again in the same 7 men in the Spring of 1979 under a similar chronobiologic protocol, using the same chemical and numerical analytical procedures. The variables examined for rhythms by cosinor were: vital signs—blood pressure (systoliC., diastoliC., pulse pressure and mean arterial pressure), heart rate, intraocular pressure (left and right), oral temperature; serum components—albumin, albumin/globulin ratio, total bilirubin, calcium, carbon dioxide, chlorides, bilirubin, cholesterol, globulin, glucose, potassium, sodium, sodium/potassium ratio, transaminase, triglycerides, total protein, urea nitrogen; and urine components—calcium, calcium/magnesium ratio, creatinine, magnesium, pH, potassium, sodium, sodium/potassium ratio, urea clearance, urea nitrogen, volume and zinc. Although all subjects appeared clinically healthy in 1969 and in 1979, certain inter-study differences were observed in a number of rhythm parameters of different variables. Statistically significant increases in mesor for the group as a whole were observed forserum Ca, cholesterol, Cl, CO₂, K, Na, and while statistically significant mesor decreases for a group as a whole were noted in serum glucose and transaminase. Statistically significant increases in amplitude for the group as a whole were observed in serum chloride and urinary Na/K ratio, while statistically signficiant decreases were observed in amplitude for blood pressure, heart rate, serum albumin, A/G ratio, globulin, glucose, protein, sodium and transaminase. For the group as a whole, a statistically significant advance in acrophase was observed in serum transaminase, while a statistically significant delay in acrophase was observed for serum A/G ratio, globulin, glucose, potassium, protein, sodium and for urinary magnesium. Statistically significant by sign test, but not by cosinor, was a numerical mesor increase for urinary urea clearance, a numerical decrease in mesor for urinary zinc; a numerical amplitude decrease for serum cholesterol; and a numerical delay in acrophase for oral temperature and serum cholesterol, CO², and globulin in all men examined. Only mesor changes in serum cholesterol and urinary Ca/Mg were positively correlated with the change in body size over the 10-year span between studies.

From a circadian chronobiologic perspective, the immense amount of data uniquely reviewed in this report across a 10-year span in seven healthy individuals serves a useful beginning to the study of the effects of normal aging upon commonly measured physiologic and biochemical variables and, more importantly, upon the circadian rhythm characteristics of these variables. A great deal of supposition about what happens to the mesor, amplitude and acrophase of an individual's circadian rhythms in a variety of endpoints has been based upon transverse studies of short duration and relatively few longterm studies. The further accumulation of data such as presented here and similar long-term longitudinal time series can have no adequate substitute for truly understanding whether reproducible age-related changes in circadian rhythms occur as individuals age.

With these qualifications and with the further qualification that the timing of our observations within the aging process (mid-20's and mid-30's) may be suboptimal for conclusions about aging, very interesting trends definitely appear worth comment. There is some evidence in these data that the flattening of circadian rhythms may really accompany advancing age. In grouped data, this fall in amplitude may be secondary to an isolated fall in predictable swing around the mesor or a combination of this and increased variability of the acrophase with or without amplitude changes. The data are not robust enough to be sure of the relative contribution of these two components. In any event, the circadian amplitude of each and every physiologic variable studied demonstrated a tendency to fall between the mid-20's and mid- 30's. This tendency toward a flattening of circadian variability is also a very prominent property of many of the serum chemistries which were measured. The circadian patterns of excretion of substances in the urine change much less between the mid-20's and mid-30's in our subjects. These findings may indicate a separate effect of aging especially upon metabolic hepatic variables and upon nephrologic circadian rhythms. Cardiovascular rhythms seem to change more in parallel with hepatic metabolic rhythms in contradistinction to the kidney-related serum and urinary rhythms.

Further, ongoing statistical analyses may hopefully turn up interesting and relevant cross-correlations among the individual data themselves in each study year and between the 10-year span, as well as with rhythm (mesor, amplitude and acrophase) and other physiologic characteristics of each subject. Planned re-observation of what happens to the circadian time structure of these seven individuals in their mid-40's will prove invaluable to further sorting out of the effects of aging upon circadian time structure.     

Attenuation of hypotensive effect of propranolol and thiazide diuretics by indomethacin.

The effects of 100 mg indomethacin daily for three weeks on blood pressure and urinary excretion of prostaglandin F2 alpha were studied in a double-blind, placebo-controlled comparison of two groups of patients with essential hypertension, eight receiving propranolol and seven thiazide diuretics. Compared with placebo, adding indomethacin to the patients'' established antihypertensive treatment increased blood pressure by 14/5 Hg supine and 16/9 mm Hg erect in the patients receiving propranolol, and by 13/9 mm Hg supine and 16/9 mm Hg erect in the patients receiving thiazide diuretics (all p less than or equal to 0.05). The excretion of the major urinary metabolite of prostaglandin F2 alpha was reduced by 67% in the propranolol-treated patients and by 57% in those receiving a thiazide diuretic. Body weight increased by 0 . 8 kg (propranolol) and 1 . 1 kg (thiazide diuretic) when indomethacin was given, but there were no significant changes in creatinine clearance, urinary sodium excretion, or packed cell volume in either treatment group. These results suggest that products formed by the arachidonic acid cyclo-oxygenase contribute to the regulation of blood pressure during treatment with both propranolol and thiazide diuretics. Inhibition of the cyclo-oxygenase with indomethacin partially antagonises the hypotensive effect of these drugs.     

Relationship between disruption of rhythmicity and reentrainment in surgical patients

Urine samples for assay, temperature, heart rate, and blood pressure were collected daily at 2-h intervals from 11 consenting subjects undergoing abdominal surgery, as well as 10 age-and sex-matched control subjects. Alterations in level, and timing of circadian excretion of catecholamine metabolites, adrenal cortical hormones, sodium, potassium, creatinine, and vital signs following surgery were measured. Data were examined to determine if a relationship exists between the degree of circadian alteration and the subject's return to typical circadian profiles. The data suggest that certain circadian rhythms of hospitalized subjects were altered and uncoupled from external stimuli. In addition, subjects with less disruption in some variables following surgery regained rhythmicity more quickly than more disrupted subjects. These findings suggest that health professionals should individualize patient care to promote rhythmicity. In addition, patient assessment should consider individual circadian patterns and disruption following surgery.     

Aminoglutethimide effect on circadian rhythms in urinary variables in a patient with idiopathic hyperaldosteronism

Aminoglutethimide (AG: 750 mg/day) was administered to a patient with idiopathic hyperaldosteronism (IHA) and circadian rhythms in urinary excretion of sodium (UNaV), potassium (UKV), aldosterone (AER) and 17-OHCS were analyzed by the single cosinor method. Urine was collected every 4h for 24h on the day before and on the 1st, 3rd and 7th day of AG administration, and above variables in each sample were determined. Circadian rhythms of 14 patients with primary aldosteronism (PA) who served as controls were also analyzed. In the present case, circadian acrophases in UNaV and AER studied before AG administration occurred at 22(19) and 07(05), respectively. They were similar to those of preoperative PA-patients. Circadian acrophase in UNaV occurred earlier with AG administration and on the 7th day it was at 14(05), a value similar to that of postoperative PA-patients. Circadian mesor in AER decreased remarkably from 4.1 to 0.6 micrograms/4h with AG administration, as did circadian mesor in UKV, whereas circadian mesor and acrophase in 17-OHCS did not change. Thus, the circadian characteristics in urinary variables in the present IHA-case were pathophysiologically similar to those of PA.     

Reduced natriuresis after oral sodium load in cholestatic rats: role of compartment volumes and ANP

The purpose of this study was to assess the participation of the atrial natriuretic peptide (ANP)-cGMP system in electrolyte and volume handling of cholestatic rats submitted to an acute oral sodium load. Cholestasis was induced by ligation and section of the common bile duct (n = 51). Control rats were sham operated (n = 56). Three weeks after surgery, 24-hr urinary volume, sodium, potassium, cGMP and creatinine excretion were measured. Three days later, animals received 10 mmol/kg NaCl (1 M) by gavage, and urinary excretion was measured for 6 hr. In parallel groups of rats, plasma volume, electrolytes and ANP concentration, extracellular fluid volume (ECFV), and renal medullary ANP-induced cGMP production were determined in basal conditions or 1 hr after oral sodium overload. As compared with controls, cholestatic rats had a larger ECFV and higher plasma ANP (67.2 +/- 5.2 vs 39.7 +/- 3.5 pg/ml), but lower hematocrit and blood volume, and were hyponatremic. Cholestatic rats showed higher basal excretion of sodium, potassium, and volume than controls, but equal urinary cGMP. After the NaCl overload, cholestatic rats showed a reduced sodium excretion but equal urinary cGMP. One hr after sodium overload, both groups showed hypernatremia, but whereas in control rats ECFV and ANP increased (50.7 +/- 4.1 pg/ml), in cholestatic rats ECFV was unchanged, and plasma volume and ANP were reduced (37.5 +/- 5.8 pg/ml). ANP-induced cGMP production in renal medulla was similar in cholestatic and control nonloaded rats (14.2 +/- 5.2 vs 13.4 +/- 2.6 fmol/min/mg). One hr after the load, medullary cGMP production rose significantly in both groups, without difference between them (20.6 +/- 3.1 vs 22.7 +/- 1. 7 fmol/min/mg). We conclude that the blunted excretion of an acute oral sodium load in cholestatic rats is associated with lower plasma ANP due to differences in body fluid distribution and cannot be explained by renal refractoriness to ANP.     

Circadian rhythms of urinary excretions of water and electrolytes in patients receiving total parenteral nutrition (TPN)

In order to determine whether the usual feeding pattern actually modifies the circadian rhythms of urinary excretion of water and electrolytes, we compared the circadian rhythm characteristics in patients receiving total parenteral nutrition (TPN group) with those in patients on an ordinary hospital diet (control group). Statistically significant circadian rhythms were detected in all of the urinary variables investigated herein by using the population mean-cosinor method in both groups. In addition, there were no statistically significant differences of the mesor, the %-amplitude and the acrophase between the two groups. These results suggest that the usual feeding pattern is not a main determinant in forming the circadian rhythm characteristics of human urinary variables.     

Immobilization on the day 14th does not disrupts the basic diurnal rhythm of bone resorption

Weight bearing and physical activity are important mechanical stimuli to bone growth and metabolism, and microgravity, such a space flight and/or bed rest, induces bone resorption and bone loss. An increased excretion of urinary Ca, an increased bone resorption and a decreased bone mineral density (BMD) have been observed in bed rest experiment of healthy subjects. Bone resorption markers show the specific circadian rhythms in human. Cross-linked carboxyl-terminal telopeptide of type I collagen (ICTP) and the urinary excretion of deoxypyridinoline (Dpy) are the highest in the early morning and the lowest late at night. Bed rest immobilization might influence these rhythms, due to no mechanical loading with loss of daily life activity. Bone resorption markers in healthy subjects had been compared between before and during bed rest to determine disruption of diurnal rhythms of bone resorption.