A masking effect of urine from male dogs

Male dogs were given five separate two-way olfactory preference tests in which control urine from males was compared with: estrous urine; 75% estrous urine + 25% male urine; 50% estrous urine + 50% male urine; 25% estrous urine + 75% male urine; and 25% estrous urine + 75% water. The stimulus value of estrous urine was progressively decreased by the addition of increasing quantities of male urine. However, estrous urine still maintained a high stimulus value when it was diluted with an equivalent amount of water.     

Identification of puberty-accelerating pheromones in male mouse urine

Gas chromatography-mass spectrometry was employed to identify the two volatile amines in male mouse urine. These amines were much less concentrated in urine of castrated males. The identified amines, isobutylamine and isoamylamine, were assayed for the potential of puberty acceleration in postweaning female mice. A total of 105 young female mice were exposed to one of the following five odors: distilled water (control), 0.1 M isobutylamine, 0.1 M isoamylamine, a mixture of 0.05 M isobutylamine and 0.05 M isoamylamine, or fresh male mouse urine. The mixture of these amines accelerated the vaginal opening of young females. Except for the control, all experimental odors accelerated the first vaginal estrus in ICR strain mice.     

Rapid analysis of phytoestrogens in human urine by time-resolved fluoroimmunoassay

A time-resolved fluoroimmunoassay (TR-FIA), with europium labeled phytoestrogens as tracers, was developed for the quantitative determination of enterolactone, genistein and daidzein in human urine. The aim was to create a method for the screening of large populations in order to assess the possible correlations between the urinary levels and the risk of Western diseases.

After the synthesis of the 5′-carboxymethoxy derivative of enterolactone and 4′-O-carboxymethyl derivatives of daidzein and genistein, the respective compound was coupled to bovine serum albumin and then used as an antigen in the immunization of rabbits. The same derivatives of the phytoestrogen were used in preparing the europium tracers. After the enzymatic hydrolysis, the TR-FIA was carried out using the Victor 1420 multilabel counter. The method has sufficient sensitivity to measure the phytoestrogens at concentrations even below 5 nmol/l. The intra- and inter-assay coefficients of variation, at three different concentrations, varied from 1.9 to 5.3 and from 2.4 to 9.7, respectively.

We measured urinary enterolactone, genistein and daidzein in 215 samples from Finnish healthy women and found that more than 50% of the values ranged between 1 and 7, <0.1 and 0.6 and below 0.6 μmol/24 h, respectively. The TR-FIA method including only a hydrolysis step gave higher values than those measured by gas chromatography–mass spectrometry (GC–MS). However, the assay results by the present method showed strong correlation with those obtained by GC–MS. It is concluded that the TR-FIA is suitable for population screening of urinary phytoestrogens.     

An isotope dilution gas chromatographic-mass spectrometric method for the simultaneous assay of estrogens and phytoestrogens in urine

The metabolism of endogenous estrogens is complicated and certain metabolic patterns may reflect an individual risk of estrogen-dependent diseases such as breast cancer. Since the 1960s we have been constantly involved in developing estrogen profiling methods, in the beginning using gas chromatography and later gas chromatography–mass spectrometry (GC–MS) in the selected ion monitoring mode (SIM) and finally utilizing isotope dilution (ID–GC–MS–SIM). The addition of the dietary phytoestrogens to the profile rendered the method even more complicated. The present work presents the final estrogen profile method for 15 endogenous estrogens, four lignans, seven isoflavonoids and coumestrol in one small urine sample (1/150th of a 24 h human urine sample, minimum 2.5–5 ml) with complete validation including investigations as to the precision, sensitivity, accuracy and specificity. The method does not include the minimal amounts of unconjugated estrogens in urine. It may also be used for animal (e.g. rat and mouse) urine using a minimum of 2 ml of usually pooled sample. Despite its complexity it was found to fulfill the reliability criteria, resulting in highly specific and accurate results.     

Identification and quantification of polyphenol phytoestrogens in foods and human biological fluids

We review the methods used to measure phytoestrogens (genistein, daidzein, lignans and their derivatives) in foods and biological fluids, and discuss advantages and disadvantages of each. The range of detection limits reported varies widely between individual laboratories, but generally the best reported sensitivity is as follows: immunoassay>HPLC-mass spectrometry=HPLC-multichannel electrochemical detection (coularray)>GC-single ion monitoring-mass spectrometry>HPLC-UV diode array>HPLC-single channel electrochemical detection. The best sensitivity reported so far is 0.002 pmol per assay for daidzein by radioimmunoassay. HPLC with UV diode array detection is the most commonly employed, but is the least sensitive and specific. GC and HPLC coupled with mass spectrometry or electrochemical detection are the most accurate and reproducible methods for a wide variety of analytes. Generally most methods, with the exception of immunoassay, have not been correlated with other methods. Recoveries from extraction methods, limits of detection, nature of compounds analysed and the internal standards used are summarised for more than 90 reports in the literature. From this data, it is clear that an inter-laboratory validation and correlation between a wide range of methods for phytoestrogen analysis is required. One underdeveloped area that requires particular attention is the analysis of plant lignans.     

Reproductive patterns of stray male dogs in the tropics

Two studies were performed to determine annual reproductive patterns in stray male dogs in the tropics. In Study 1, four dogs housed individually outdoors were monitored once monthly for 12 months, including collection and assessment of semen, measurements of scrotal width, and determination of serum testosterone and prolactin concentrations. In Study 2 (conducted concurrently), a single blood sample (for serum testosterone concentration) was collected from 220 clinically healthy dogs, and after euthanasia, scrotal width and morphology of epididymal sperm were determined. The year was divided into three seasons: warm-dry (March to June); warm-humid (July to October) and fresh-humid (November to February). In Study 1, scrotal width, ejaculate volume, sperm count and motility were significantly lower during the fresh-humid season and sperm midpiece abnormalities were significantly more common during the warm-humid and fresh-humid seasons. Serum testosterone concentrations remained constant during the year. Prolactin concentrations did not differ significantly among seasons, but had a well-defined increase from the beginning of March to the end of August. In Study 2, sperm morphology was similar to in Study 1 and serum testosterone concentrations varied nonsignificantly during the year. Environmental factors, e.g. daylength may have influenced circannual changes in prolactin secretion. Seasonal variations in some reproductive tract and seminal traits were significant but of small magnitude and the percentage of morphologically normal sperm did not vary significantly among seasons. In conclusion, healthy male dogs constantly produced sperm and were apparently fertile throughout the year.     

Identification of some plasma metabolites of 6, 7-3-H-estrone glucosiduronate in male dogs.

Following the constant infusion of 6, 7-3-H-estrone glucosiduronate in male dogs for a period of 120 minutes, the radioactive metabolites present in the plasma were separated by solvent partition, DEAE-Sephapadex, Celite partition and thin layer chromatography. The identities of the individual estrogens and estrogen conjugates were confirmed by specific activity determinations after chromatography in several different solvent systems, enzyme hydrolysis and steroids and their derivatives. Most of the radioactivity in the plasma was identified as estrone glucosiduronate. The major metabolite present was estradiol-17-beta-3-glucosiduronate. Small amounts of estradiol-17-alpha-3-glucosiduronate and free estrone were also identified. Three other minor conjugates were separated, but positive identification could not be made.     

Liquid chromatographic-photodiode array mass spectrometric analysis of dietary phytoestrogens from human urine and blood

Dietary phytoestrogens have been implicated in the prevention of chronic diseases. However, it is uncertain whether the phytoestrogens or the foods associated with phytoestrogens account for the observed effects. We report here a new liquid chromatography photodiode array mass spectrometry (LC-PDA-MS) assay for the determination of nanomolar amounts of the most prominent dietary phytoestrogens (genistein, dihydrogenistein, daidzein, dihydrodaidzein, glycitein, O-desmethylangolensin, hesperetin, naringenin, quercetin, enterodiol, enterolactone) in human plasma or serum and urine. This assay was found to be suitable for the assessment of quercetin exposure in an onion intervention study by measuring urinary quercetin levels. Other successful applications of this assay in clinical and epidemiologic studies validated the developed method and confirmed previous results on the negative association between urinary isoflavone excretion and breast cancer risk.     

Identification of 2-guanidinoethanol in human urine

Guanidino compounds in normal human urine were analyzed by high-performance liquid chromatography; an unknown peak was observed in the chromatogram that was identical to the peak of synthetic 2-guanidinoethanol. In another experiment, the substance was purified from human urine by successive use of strongly acidic ion-exchanger, thin-layer chromatography and then weakly acidic ion-exchanger. After this it was reacted with acetylacetone to form dimethylpyrimidyl derivative. After further reaction of this derivative with trifluoroacetic anhydrate, it was analyzed by gas chromatography/mass spectrometry. The mass chromatogram and mass spectrum were identical to those of the trifluoroacetylated dimethylpyrimidyl derivative of synthetic 2-guanidinoethanol. This is the first report on the identification of 2-guanidinoethanol in human urine. The concentration of 2-guanidinoethanol in the urine of healthy humans was 5.7 +/- 1.8 (mean +/- SD) mumol/g creatinine.     

Identification of delta-guanidinovaleric acid in human urine

delta-Guanidinovaleric acid (DGVA) was identified in human urine using thin layer chromatography (TLC), high performance liquid chromatography (HPLC) and gas chromatography/mass spectrometry (GC/MS). In the TLC, all Rfs of sample from urine developed by 6 solvent systems were identical to that of authentic DGVA. In the GC/MS, the mass spectrum of the sample was identical to the trifluoroacetylated dimethylpyrimidyl derivative of DGVA butylester (M+ = 375). In the HPLC analysis, the DGVA peak was observed just before 15 min in either chromatogram obtained by analysis of human urine or authentic DGVA, and the content of DGVA in pooled human urine was calculated at 2.4 nmol/ml.     

Identification of 19-nor-corticosterone in rat urine

19-Nor-corticosterone (19-nor-B) was isolated from a pool of urine collected from Wistar-Kyoto (WKY) rats. Identity was established by comparison of chromatographic mobilities with standard 19-nor-B both as the free compound and diacetate derivative. Comparison of the gas chromatographic-mass spectra of the urinary product and standard 19-nor-B as the diacetate following isolation by high pressure liquid chromatography (HPLC) confirmed the identity of the urinary product to be 19-nor-B. This demonstration that 19-nor-B is a naturally occurring product in addition to 19-nor-deoxycorticosterone supports the concept of the existence of a biosynthetic pathway for the formation of the 19-nor-corticosteroids.     

Identification of felodipine metabolites in rat urine

After intragastric administration of 100 mumol kg-1 [14C]felodipine to rats eight urinary metabolites were isolated. Batch extraction at pH 2.2 and semipreparative reversed-phase liquid chromatography were used for trace enrichment of the metabolites. Trimethylsilylation followed by transesterification with diazomethane blocked the carboxylic acid and alcohol groups selectively before gas chromatography/mass spectrometry (GC/MS) in the electron impact (EI) mode. Deuterated derivatives of the metabolites and chemical ionization measurements added complementary structural information. All metabolites reported in this study were formed from oxidized felodipine by ester hydrolysis. Hydroxylation of the pyridine methyl group represented an important metabolic pathway and metabolites oxidized to the corresponding carboxylic acids were detected as well. Lactone formation from hydroxy acid metabolites in urine as a possible analytical artefact is discussed.     

Identification of fendiline metabolites in human urine

After oral application of 14C labelled fendiline, 13 metabolites of this drug could be identified in human urine. Only traces of parent fendiline were excreted in the urine. The main pathway of metabolism is hydroxylation of phenyl groups with subsequent glucuronidation and sulphation. On the other hand, oxidative dealkylation occurs with the amino group remaining at the 3,3-diphenylpropyl moiety and p-hydroxyacetophenone being formed almost entirely from the 1-phenylethyl group.     

Urethral plugs and urine retention in male mice

Because MM male mice suffer from a high incidence of urinary tract infection, an assessment was made as to whether the urethral plugs, which occur in male rodents, might be involved in its aetiology. When killed, males more commonly retained urine in their bladders than females but there was no significant difference between strains or method of killing. Males also voided urine more often during stressful handling followed by abdominal pressure, but also retained some urine more often than females. The study of sexually immature mice demonstrated no sex differences and no urine was retained in any bladder. It was concluded that the high frequency of urine retention in mature males is attributable to the presence of urethral plugs but these could not be implicated in the cause of MM urinary tract infection because of comparable findings in the controls. However, the possibility was considered that the plugs might facilitate infection of the kidneys once a bladder infection had become established.     

Prolactin reference range and pulsatility in male dogs

Little is known about serum prolactin (PRL) concentrations and secretion patterns in male dogs. Blood samples (n = 65) were collected from crossbred dogs and from Beagles and German Shepherd dogs to describe the PRL reference range, and from five male Beagles at 15-min intervals for 6 h (n = 24 samples/dog) to describe the ultradian rhythm of this hormone. Serum PRL was measured by a homologous endpoint enzyme immunometric assay. The reference range was established from nondetectable to 6.0 ng/mL. There was an effect of breed; serum PRL concentrations in Beagles were higher (P < 0.05) than in crossbreeds and German Shepherds. However, there was no significant correlation between PRL concentration and age of the dog. During the ultradian study, PRL was characterized by a fluctuating baseline with occasional distinct elevations, indicating a pulsatile secretion. The mean basal PRL concentration was 1.4 +/- 0.6 ng/mL and the mean AUC was 9.9 +/- 2.7 ng/mL/6h. Prolactin pulse frequency ranged from one to two peaks/6h, pulse duration between 15 and 75 min, and amplitude from 1.7 to 2.4 ng/mL. In conclusion, this reference range, pulsatility and breed differences should be taken into account when interpreting serum PRL concentrations, for clinical or research purposes.