Incorporation of intravenously administered urea-15N into sheep plasma proteins and their amide groups.

Two sheep with a low and high nitrogen intake (7.6 and 24 g N/day respectively) were given a single intravenous dose of 15N-labelled urea (15.3 mg 15N/kg b.w.) The findings were as follows. The greater part of non-retained 15N from the administered dose was excreted during the first day after the intravenous administration of 15N-urea. Daily excretion in the faeces amounted to 1.35-2.37% of the 15N in the given dose. With a low N intake, more 15N from the given dose (59.4%) was retained in the N pool than with a high N intake (50.5%). The net passage of 15N into the rumen and 15N incorporation into the amide-N of the plasma proteins was likewise greater. 15N incorporation into the amide-N of the plasma proteins rose steadily for 3 days. The porportion of amidic 15N in the plasma proteins rose steadily for 3 days. The proportion of amidic 15N in the plasma protein total 15N changed on the second and third day after administering 15N-urea from 8% to 16%, with the maximum at the beginning of the second day. The amount of 15N incorporated into the proteins in 1 litre plasma attained up to 3% of the given dose. It is concluded from the results that the synthesis of amino acids and their amide groups is both a quantitatively and a qualitatively important metabolic route for the reutilization of blood urea nitrogen for protein synthesis in ruminants.     

Absorption,metabolism and excretion of 3-acetyl don in pigs

The absorption, metabolism and excretion of 3-acetyldeoxynivalenol (3-aDON) in pigs were studied. Pigs with a faecal microflora known to be able to de-epoxidate trichothecenes were used in the experiment. The pigs were fed a commercial diet with 3-aDON added in a concentration of 2.5 mg/kg feed for 2.5 days. No traces of 3-aDON or its de-epoxide metabolite were found in plasma, urine or faeces. Deoxynivalenol (DON) was detected in plasma as soon as 20 min after start of the feeding. The maximum concentration of DON in plasma was reached after 3 h and decreased rapidly thereafter. Only low concentrations close to the detection limit were found in plasma 8 h after start of the feeding. A significant part of the DON in plasma was in a glucuronide-conjugated form (42 ± 7%). No accumulation of DON occurred in plasma during the 60 h of exposure. The excretion of DON was mainly in urine (45 ± 26% of the toxin ingested by the pigs) and only low amounts of metabolites of 3-aDON (2 ± 0.4%) were recovered in faeces. De-epoxide DON constituted 52 ± 15% of the total amount of 3-aDON-metabolites detected in faeces. The remaining part in faeces was DON. DON was still present in the urine and faeces at the end of the sampling period 48 h after the last exposure. The results show that no de-epoxides are found in plasma or urine in pigs after trichothecene exposure, even in pigs having a faecal microflora with a de-epoxidation activity. The acetylated form of the toxin is deacetylated in vivo. Furthermore, the experiment shows that the main part of DON is rapidly excreted and does not accumulate in plasma, but a minor part of the toxin is retained and slowly excreted from the pigs.     

Metabolic disposition of [14C] metanil yellow in rats

The absorption, metabolism and excretion of [14C] metanil yellow was studied in rats. Following administration of a single oral dose of 5 mg dye (7.6 microCi)/kg body weight, 80.5% of the dose was excreted in the urine and faeces within 96 hr, with the majority being accounted for in the faeces. Liver, kidney, spleen and testis retained no count whereas 13.6% of the radioactivity was retained by gastrointestinal tract. Analysis of urine and faeces detected two azo-reduction metabolites of metanil yellow which were characterized by TLC and IR, NMR and mass spectroscopic studies as metanilic acid and p-aminodiphenylamine.     

The kinetics of papillotoxic doses of 3H-N-phenylanthranilic acid in rats

N-phenylanthranilic acid (N-PAA; 4 mmol/kg/day p.o.) causes a diffuse renal papillary necrosis and a polyuria in 7 days. A single dose of 3H-N-PAA was widely distributed with second-order elimination kinetics, t1/2 +/- 50 h for stomach, heart, kidney, and bladder and t1/2 greater than or equal to 90 h for liver, spleen, muscle and lung. The estimated plasma t1/2 = 10.2 h, and over 75% was excreted via urine in 36 h and 13% via faeces in 72 h. In chronically cannulated animals 29% of N-PAA-derived material was in bile and 24% in urine at 36 h, which suggests enterohepatic circulation. Bile and urine contained several metabolites but no parent compound. Multiple doses for 8 and 16 days increased urinary N-PAA excretion to 90% in 36 h, but faecal contents decreased to 6-8% in 72 h and plasma t1/2 to less than or equal to 7.5 h.     

Benzoic acid conjugation in tuatara

The excretion and metabolism of orally administered [¹⁴C]-labelled benzoic acid (100 mg/kg) was examined in the reptile Sphenedon punctatus (tuatara). The major excreted metabolite was chromatographically and electrophoretically identical with ornithuric acid. Conjugation with glycine or glucuronic acid was not detected. 7–21 percent of the dose was recovered from the urine and faeces, the bulk of the excreted radioactivity being eliminated in the first seven days. Free benzoic acid and conjugates were excreted in the first week but only conjugates could be detected in fauces collected at later intervals. These results are discussed in relation to the taxonomic position of tuatara.     

The effects of dietary nitrogen to water-soluble carbohydrate ratio on isotopic fractionation and partitioning of nitrogen in non-lactating sheep

The main objective of this study was to investigate the relationship between partitioning and isotopic fractionation of nitrogen (N) in sheep consuming diets with varying ratios of N to water-soluble carbohydrate (WSC). Six non-lactating sheep were offered a constant dry matter (DM) allowance with one of three ratios of dietary N/WSC, achieved by adding sucrose and urea to lucerne pellets. A replicated 3 dietary treatments (Low, Medium and High N/WSC) × 3 (collection periods) and a Latin square design was used, with two sheep assigned to each treatment in each period. Feed, faeces, urine, plasma, wool, muscle and liver samples were collected and analysed for ¹⁵N concentration. Nitrogen intake and outputs in faeces and urine were measured for each sheep using 6-day total collections. Blood urea N (BUN) and urinary excretion of purine derivative were also measured. Treatment effects were tested using general ANOVA; the relationships between measured variables were analysed by linear regression. BUN and N intake increased by 46% and 35%, respectively, when N/WSC increased 2.5-fold. However, no indication of change in microbial protein synthesis was detected. Results indicated effects of dietary treatments on urinary N/faecal N, faecal N/N intake and retained N/N intake. In addition, the linear relationships between plasma δ¹⁵N and urinary N/N intake and muscle δ¹⁵N and retained N/N intake based on individual measurements showed the potential of using N isotopic fractionation as an easy-to-use indicator of N partitioning when N supply exceeds that required to match energy supply in the diet.     

Effect of niacin supplementation on digestibility,nitrogen utilisation and milk and blood variables in lactating dairy cows fed a diet with a negative rumen nitrogen balance

The aim of the present experiment was to determine if a niacin supplementation of 6 g/d to lactating dairy cow diets can compensate negative effects of a rumen nitrogen balance (RNB) deficit. A total of nine ruminally and duodenally fistulated lactating multiparous German Holstein cows were successively assigned to one of three diets consisting of 10 kg maize silage (dry matter [DM] basis) and7 kg DM concentrate: Diet RNB– (n = 6) with energy and utilisable crude protein at the duodenum (uCP) according to the average requirement of the animals but with a negative RNB (–0.41 g N/MJ metabolisable energy [ME]); Diet RNB0 (n = 7) with energy, uCP and a RNB (0.08 g N/MJ ME) according to the average requirement of the animals and, finally, Diet NA (n = 5), which was the same diet as RNB–, but supplemented with 6 g niacin/d. Samples of milk were taken on two consecutive days, blood samples were taken on one day pre- and post-feeding and faeces and urine were collected completely over five consecutive days. The negative RNB reduced milk and blood urea content and apparent total tract digestibility of DM, organic matter (OM) and neutral detergent fibre (NDF). Also N excretion with urine, the total N excreted with urine and faeces and the N balance were reduced when the RNB was negative. Supplementation of niacin elevated plasma glucose concentration after feeding and the N balance increased. Supplementing the diet with a negative RNB with niacin led to a more efficient use of dietary N thereby avoiding the negative effects of the negative RNB on the digestibility of DM, OM and NDF.     

Effect of niacin supplementation on digestibility, nitrogen utilisation and milk and blood variables in lactating dairy cows fed a diet with a negative rumen nitrogen balance

The aim of the present experiment was to determine if a niacin supplementation of 6 g/d to lactating dairy cow diets can compensate negative effects of a rumen nitrogen balance (RNB) deficit. A total of nine ruminally and duodenally fistulated lactating multiparous German Holstein cows were successively assigned to one of three diets consisting of 10 kg maize silage (dry matter [DM] basis) and 7 kg DM concentrate: Diet RNB- (n = 6) with energy and utilisable crude protein at the duodenum (uCP) according to the average requirement of the animals but with a negative RNB (-0.41 g N/MJ metabolisable energy [ME]); Diet RNB0 (n = 7) with energy, uCP and a RNB (0.08 g N/MJ ME) according to the average requirement of the animals and, finally, Diet NA (n = 5), which was the same diet as RNB-, but supplemented with 6 g niacin/d. Samples of milk were taken on two consecutive days, blood samples were taken on one day pre- and post-feeding and faeces and urine were collected completely over five consecutive days. The negative RNB reduced milk and blood urea content and apparent total tract digestibility of DM, organic matter (OM) and neutral detergent fibre (NDF). Also N excretion with urine, the total N excreted with urine and faeces and the N balance were reduced when the RNB was negative. Supplementation of niacin elevated plasma glucose concentration after feeding and the N balance increased. Supplementing the diet with a negative RNB with niacin led to a more efficient use of dietary N thereby avoiding the negative effects of the negative RNB on the digestibility of DM, OM and NDF.     

The metabolism of N-triphenylmethylmorpholine in the dog and rat

1. Rats were given N-triphenyl[(14)C]methylmorpholine, triphenyl[(14)C]carbinol, N-triphenylmethyl[G-(3)H]morpholine or [G-(3)H]morpholine as single oral doses; the routes of excretion were examined. 2. Dogs were given single oral doses of N-triphenyl[(14)C]methylmorpholine. 3. (14)C-labelled metabolites were excreted mainly in the faeces in both rats and dogs; no (14)CO(2) was expired and less than 3% remained in the carcass and skin after 96hr. 4. (3)H-labelled metabolites were excreted rapidly in urine; part of the label was found in the expired gases and over 10% remained in the carcass and skin after 96hr. 5. Differences in excretion pattern between the sexes were noticed in rats but not in dogs. 6. N-Triphenylmethylmorpholine was rapidly hydrolysed to form triphenylcarbinol and morpholine in the stomach; morpholine was absorbed rapidly and excreted largely unchanged, though some was degraded, since some of the (3)H was found in water. 7. Triphenylcarbinol was absorbed only slowly and was oxidized to p-hydroxyphenyldiphenylcarbinol. 8. Both triphenylcarbinol and its p-hydroxy derivative were found in urine, bile and faeces in the free form and conjugated with glucuronic acid. The proportion of conjugates was higher in rat bile than in faeces. 9. Traces of o-hydroxyphenyldiphenylcarbinol and m-hydroxyphenyldiphenylcarbinol were detected as metabolites both free and conjugated.     

Der metabolismus von 3H-α-ecdyson bei larven von Tenebrio molitor

The metabolism of ³H-α-ecdysone has been investigated in larvae of Tenebrio molitor within a moulting cycle. The metabolization occurs by hydroxylation, dehydration, and conjugation. A total of 8 metabolites including α- and β-ecdysone were found. Peak I was cleaved enzymatically up to 56%. The hydrolized part consists of esters of sulfuric- and glucuronic acid with compounds II and III, also with α-ecdysone and 3-dehydroecdysterone to a lesser degree.The hydroxylation of α-ecdysone to β-ecdysone is a very rapid one. Velocity and intensity depends on the physiological stage of the larvae. On days with a large endogenous hormone titer they are maximal and on days with a low endogenous titer they are lower. The rate of conversion of α- to β-ecdysone shows a correlation with the endogenous titer and vice versa.At a low endogenous titer the rate of excretion is very strong, in larvae aged to 2 to 5 days and also 7 to 8 days, 8 h after injection 50 to 80% of injected activity was recovered in the faeces. At the beginning of the moulting cycle 3% and at the 6th day 30% (hormone titer maximum) of activity is excreted. The unexpected high rate of excretion at the first day is compensated by increasing metabolism and storage.The faeces mainly consist of conjugates and α- and β-ecdysone. A correlation between the appearance of these compounds and the physiological stage of the larvae could be found. On those days with low endogenous titer the quota of ecdysone (α and β) is higher.     

The fate of nitrogen from 15N-labeled nitrate after single intravenous administration of Na15NO3 in sheep

The metabolic fate of nitrogen from 15N-labeled sodium nitrate has been investigated in four healthy Polish Merino ewes. 15N-labeled sodium nitrate was administered intravenously at the dosage of 400 micromol.kg(-1) body weight. Blood plasma and urine concentrations of nitrate, ammonia, and urea and 15N enrichment of ammonia and urea were estimated over a 50-h period following 15N-nitrate administration. Nitrate (NO3-) was slowly eliminated from the blood plasma, and the presence of NO3(-) in the blood plasma above the nitrate "background" was observed for 50 h. 15N enrichment of blood plasma urea already appeared at 15 min and reached the maximum 6 h after 15N-nitrate administration. The urinary excretion of nitrate occured during 50 h after 15N-nitrate injection; the total urine excretion of NO3(-) was 23.63+/-2.39% of the administered dose. The mean urinary recoveries of nitrogen as 15N-urea and 15N-ammonia were 14.76+/-1.32% and 0.096+/-0.015% of the administered 15N-nitrate dose, respectively. It should be pointed out that in total only 38.49% of the administered nitrate-N was excreted in urine (as nitrate, ammonia and urea nitrogen) during 50 h. The results obtained indicate that sheep are able to store nitrate nitrogen in their body. The fate of the remaining approximately 60% of the 15NO3(-) administered dose is unknown. The results obtained do not allow one to conclude what fraction of the unrecovered approximately 60% of the 15NO3(-) dose was utilized by gastrointestinal microorganisms, and (or) metabolized, or stored in sheep tissues.     

Metabolism of [14C]methamphetamine in man, the guinea pig and the rat

1. The metabolites of (+/-)-2-methylamino-1-phenyl[1-(14)C]propane ([(14)C]methamphetamine) in urine were examined in man, rat and guinea pig. 2. In two male human subjects receiving the drug orally (20mg per person) about 90% of the (14)C was excreted in the urine in 4 days. The urine of the first day was examined for metabolites, and the main metabolites were the unchanged drug (22% of the dose) and 4-hydroxymethamphetamine (15%). Minor metabolites were hippuric acid, norephedrine, 4-hydroxyamphetamine, 4-hydroxynorephedrine and an acid-labile precursor of benzyl methyl ketone. 3. In the rat some 82% of the dose of (14)C (45mg/kg) was excreted in the urine and 2-3% in the faeces in 3-4 days. In 2 days the main metabolites in the urine were 4-hydroxymethamphetamine (31% of dose), 4-hydroxynorephedrine (16%) and unchanged drug (11%). Minor metabolites were amphetamine, 4-hydroxyamphetamine and benzoic acid. 4. The guinea pig was injected intraperitoneally with the drug at two doses, 10 and 45mg/kg. In both cases nearly 90% of the (14)C was excreted, mainly in the urine after the lower dose, but in the urine (69%) and faeces (18%) after the higher dose. The main metabolites in the guinea pig were benzoic acid and its conjugates. Minor metabolites were unchanged drug, amphetamine, norephedrine, an acid-labile precursor of benzyl methyl ketone and an unknown weakly acidic metabolite. The output of norephedrine was dose-dependent, being about 19% on the higher dose and about 1% on the lower dose. 5. Marked species differences in the metabolism of methamphetamine were observed. The main reaction in the rat was aromatic hydroxylation, in the guinea pig demethylation and deamination, whereas in man much of the drug, possibly one-half, was excreted unchanged.     

The effect of dietary water soluble carbohydrate to nitrogen ratio on nitrogen partitioning and isotopic fractionation of lactating goats offered a high-nitrogen diet

The objective of this study was to investigate the relationship between nitrogen (N) partitioning and isotopic fractionation in lactating goats consuming diets with a constant high concentration of N and increasing levels of water soluble carbohydrate (WSC). Eight lactating goats were offered four different ratios of WSC : N in the diet. A two-period incomplete cross-over design was used, with two goats assigned to each treatment in each period. N balance measurements were conducted, with measurement of feed N intake and total output of N in milk, faeces and urine. Treatment, period and infusion effects were tested using general ANOVA; the relationships between variables were analysed by linear regression. Dietary treatment and period had significant effects on dry matter (DM) intake (g/day). DM digestibility (g/kg DM) and N digestibility (g/kg N) increased as the ratio of WSC : N increased in the diet. No treatment effect was observed on milk urea N concentration (g/l) or urinary excretion of purine derivatives (mM/day). Although dietary treatment and period had significant effects on N intake, the change of N intake was small; no effect was observed for N partitioning among faeces, milk and urine. Milk, plasma and faeces were enriched in ¹⁵N compared with feed, whilst urine was depleted in ¹⁵N relative to feed. No significant relationship was established between N partitioning and isotopic fractionation. This study failed to confirm the potential to use N isotopic fractionation as an indicator of N partitioning in dairy goats when diets provided N in excess to requirements, most likely because the range of milk N output/N intake and urinary N output/N intake were narrow.     

Peripartal Excretion of Eimeria Oocyst by Cows on Swedish Dairy Farms and the Age of Calves at First Excretion

Faecal samples were collected 3 times a week for 6 weeks from 22 peripartal cows and for up to 15 weeks after birth from 27 calves in 3 herds, to determine the numbers of Eimeria oocysts excreted and the age at which the calves first excreted oocysts. Only low numbers of oocysts were excreted by the cows and no oocysts were detected in 93% of the samples. However, half the cows excreted oocysts at least once. The age at which the calves first excreted oocysts ranged from 2.5 to at least 15 weeks, and there was a significant difference between the herds in their mean age at first excretion. Oocysts of Eimeria alabamensis, E. auburnensis, E. bovis and E. ellipsoidalis were found in numbers ranging from 7 to 8450 oocysts per gram faeces. About 50% of the calves excreted oocysts before they were transferred to group pens. The primary source of infection of the calves was probably their penmates or the previous occupants of the pens, and the cows probably played a subsidiary role.     

The metabolism of 2-chloro-1-(2′,4′-dichlorophenyl)vinyl diethyl phosphate (Chlorfenvinphos) in the dog and rat

1. A single oral dose of [(14)C]Chlorfenvinphos to rats is quantitatively eliminated in 4 days. Rats do not show a sex difference in the elimination pattern and show only a small degree of biological variation in the total excretion data. Of the label 87.2% is excreted in the urine (67.5% in the first day after dosage), 11.2% in the faeces and 1.4% in the expired gases; less than 0.9% of (14)C is present in the gut and contents after 4 days. 2. After oral administration of [(14)C]Chlorfenvinphos to dogs, 94.0% (91.8-97.6%) of the (14)C is excreted in the urine and faeces during 4 days. Dogs do not show a sex difference in the pattern of elimination, and excretion of radioactivity in the urine is very rapid: 86.0% of (14)C during 0-24hr. 3. Chlorfenvinphos is completely metabolized in rats and dogs: unchanged Chlorfenvinphos is absent from the urine and from the carcass, when elimination is complete. In rats, 2-chloro-1-(2',4'-dichlorophenyl)vinyl ethyl hydrogen phosphate accounts for 32.3% of a dose of Chlorfenvinphos, [1-(2',4'-dichlorophenyl)ethyl beta-d-glucopyranosid]uronic acid for 41.0%, 2,4-dichloromandelic acid for 7.0%, 2,4-dichlorophenylethanediol glucuronide for 2.6% and 2,4-dichlorohippuric acid for 4.3%; in dogs, 2-chloro-1-(2',4'-dichlorophenyl)vinyl ethyl hydrogen phosphate accounts for 69.6%, [1-(2',4'-dichlorophenyl)ethyl beta-d-glucopyranosid] uronic acid for 3.6%, 2,4-dichloromandelic acid for 13.4% and 2,4-dichlorophenylethanediol glucuronide for 2.7%. 4. Dogs and rats show a species difference in the rate of excretion of (14)C in the urine, and in the proportions of the metabolites, with the exception of 2,4-dichlorophenylethanediol glucuronide, that are excreted in the urine. Alternative explanations for the latter species difference are suggested. 5. 2-Chloro-1-(2',4'-dichlorophenyl)vinyl ethyl hydrogen phosphate and 2,4-dichlorophenacyl chloride probably lie on the main metabolic pathway of Chlorfenvinphos, since, in common with that insecticide, they give rise to [1-(2',4'-dichlorophenyl)ethyl beta-d-glucopyranosid]uronic acid and 2,4-dichloromandelic acid as major metabolites in the urine. 6. The proposed scheme for the metabolism of Chlorfenvinphos represents a detoxication mechanism.     

Molecular weight as a factor in the excretion of monoquaternary ammonium cations in the bile of the rat, rabbit and guinea pig

1. The excretion in the bile and urine of intraperitoneally injected (14)C-labelled monoquaternary ammonium or pyridinium cations was measured in bile-duct-cannulated rats (ten compounds) and in guinea pigs and rabbits (six compounds). 2. Seven of these, namely N-methylpyridinium, tetraethylammonium, trimethylphenylammonium, diethylmethylphenylammonium, methylphenyldipropylammonium, dibenzyldimethylammonium and tribenzylmethylammonium, were excreted largely unchanged in the bile and urine. 3. 3-Hydroxyphenyltrimethylammonium, 3-bromo-N-methylpyridinium and cetyltrimethylammonium were metabolized to an appreciable extent in the rat. 4. In intact rats intraperitoneally injected trimethylphenylammonium (mol.wt. 136) was excreted mainly in the urine, dibenzyldimethylammonium (mol.wt. 226) was excreted in roughly equal amounts in the urine and faeces, and tribenzylmethylammonium (mol.wt. 302) was excreted mainly in the faeces. The faecal excretion of these compounds corresponded to their biliary excretion in bile-duct-cannulated rats. About 3-4% of tribenzyl[(14)C]methylammonium was eliminated as (14)CO(2). 5. In rats the extent of biliary excretion of four cations with molecular weights in the range 94-164 was less than 10% of the dose, whereas that of five cations with molecular weights 173-302 was greater than 10%. These results and other data from the literature suggested that the molecular weight needed for the biliary excretion of such cations to an extent of 10% or more of the dose was about 200+/-50. Studies with six cations in guinea pigs and rabbits suggest that this value applies also to these species. 6. The results suggest that the threshold molecular weight for the appreciable (>10%) biliary excretion of monoquaternary cations is different from that for anions (Millburn et al., 1967a; Hirom et al., 1972b). With rats, guinea pigs and rabbits, no significant species difference was noted, whereas with anions there is a marked species difference.     

Kinetics of phenazepam-14C excretion from the body of white rats in the single and prolonged administration of the preparation]

During 5 days after intraperitoneal injection of 14C-phenazepam into albino rats, about 77% of the total radioactivity was excreted with urine and feces in both intact animals and in those premedicated with phenazepam for 15 days. The excretory processes are described by the first order equations. The rates of phenazepam total excretion are identical in single and repeated injections. At the same time, phenazepam injected into the animals at a single dose is predominantly excreted with urine, while in multiple administration it is excreted with feces. Excretion of phenazepam with urine acquires the biexponential features, provided it is injected in multiple doses.     

Detection of Corynebacterium kutscheri in the faeces of subclinically infected mice

Mice were infected experimentally and subclinically with Corynebacterium kutscheri to recover the organism from mice faeces. The faeces were then cultured using selective furazolidone-nalidixic acid-colimycin agar. The number of C. kutscheri per gram of fresh faeces varied from mouse to mouse, but once established in the intestine, the organism was excreted in the faeces for at least five months. Viable bacteria were detected in most of the faecal samples, including those stored in the animal room for five days. The number of organisms in the stored faeces decreased gradually but did not differ significantly from those in the fresh faeces until they had been stored for more than three days. Many infected mice excreted between 10(4.77) and 10(5.37) colony forming units (CFU) of C. kutscheri per day in their faeces, and one mouse even excreted 10(3.74) CFU at eight weeks postinfection. These values showed little daily variation. Our present study showed that subclinically infected mice discharged the organism continuously and persistently in their faeces. Therefore, faecal samples would be useful for monitoring infection with C. kutscheri in living mice in a manner that is not stressful for the animals.     

Crop uptake and leaching of 15N applied in ruminant slurry with selectively labelled faeces and urine fractions

Two animal slurries either labelled with ¹⁵N in the urine or in the faeces fraction, were produced by feeding a sheep with unlabelled and ¹⁵N-labelled hay and collecting faeces and urine separately. The slurries were applied (12 g total N ^-2) to a coarse sand and a sandy loam soil confined in lysimeters and growing spring barley (Hordeum vulgare L). Reference lysimeters without slurry were supplied with¹⁵ NH₄ ¹⁵NO³ corresponding to the inorganic N applied with the slurries (6 g N m^-2). In the second year, all lysimeters received unlabelled mineral fertilizer (6 g N m^-2) and grew spring barley. N harvested in the two crops (grain + straw) and the loss of nitrate by leaching were determined. ¹⁵N in the urine fraction was less available for crop uptake than mineral fertilizer ¹⁵N. The first barley crop on the sandy loam removed 49% of the ¹⁵N applied in mineral fertilizer and 36% of that applied with urine. The availability of fertilizer ¹⁵N (36%) and urine¹⁵ N (32%) differed less on the coarse sand. Of the¹⁵ N added with the faeces fraction, 12–14% was taken up by the barley crop on the two soils. N mineralized from faeces compensated for the reduced availability of urine N providing a similar or higher crop N uptake in manured lysimeters compared with mineral fertilized ones.About half of the total N uptake in the first crop originated from the N applied either as slurry or mineral fertilizer. The remaining N was derived from the soil N pool. Substantially smaller but similar proportions of¹⁵ N from faeces, urine and fertilizer were found in the second crop. The similar recoveries indicated a slow mineralization rate of the residual faeces N since more faeces was left in the soil after the first crop.More N was lost by leaching from manured lysimeters but as a percentage of N applied, losses were similar to those from mineral fertilizer. During the first and second winter, 3–5% and 1–3%, respectively, of the ¹⁵N in slurry and mineral fertilizer was leached as nitrate. Thus slurry N applied in spring just before sowing did not appear to be more prone to loss by nitrate leaching than N given in mineral fertilizer. Slurry N accounted for a higher proportion of the N leached, however, because more N was added in this treatment.     

Excretion of corticosteroid metabolites in urine and faeces of rats.

Stress enhances the production of corticosteroids by the adrenal cortex, resulting in the increased excretion of their metabolites in urine and faeces. An intraperitoneal injection of radioactive corticosterone was applied to adult, male Sprague-Dawley rats to monitor the route and delay of excreted metabolites in urine and faeces. Peak concentrations appeared in urine after 3.2 +/- 1.9 h and in faeces after 16.7 +/- 4.3 h. Altogether about 20% of the recovered metabolites were found in urine and about 80% in faeces. Using high-performance liquid chromatography (HPLC), several peaks of radioactive metabolites were found. Some metabolites were detected by enzyme immunoassay (EIA) using two different antibodies (corticosterone, 11beta-OH-aetiocholanolone). There was a marked diurnal variation with low levels of faecal corticosterone metabolites in the evening and higher values in the morning. This diurnal variation was influenced neither by the intraperitoneal injection of isotonic saline nor by ACTH. However, the administration of dexamethasone eliminated the morning peak for 2 days.