OECD validation of the Hershberger assay in Japan: phase 2 dose response of methyltestosterone, vinclozolin, and p,p'-DDE.The Organisation for Economic Co-operation and Development The Organisation for Economic Co-operation and Development (OECD), (in French: Organisation de coopération et de développement économiques; OCDE) is an international organisation of thirty countries that accept the principles of representative democracy and a free market has initiated the development of new guidelines guidelines, n.pl a set of standards, criteria, or specifications to be used or followed in the performance of certain tasks. for the screening and testing of potential endocrine disruptors Endocrine disruptors are exogenous substances that act like hormones in the endocrine system and disrupt the physiologic function of endogenous hormones. Studies have linked endocrine disruptors to adverse biological effects in animals, giving rise to concerns that low-level . The Hershberger assay is one of the assays selected for validation See validate. validation - The stage in the software life-cycle at the end of the development process where software is evaluated to ensure that it complies with the requirements. based on the need for in vivo in vivo /in vi·vo/ (ve´vo) [L.] within the living body. in vi·vo adj. Within a living organism. in vivo adv. screening to detect androgen androgen (ăn`drəjən): see testosterone. androgen Any of a group of hormones that mainly influence the development of the male reproductive system. agonists or antagonists antagonists, n muscles that counterbalance agonists during specific movements. opioid Neurology A pain-attenuating peptide that occurs naturally in the brain, which induces analgesia by mimicking endogenous opioids at opioid by measuring the response of five sex accessory organs Accessory organ A lump of tissue adjacent to an organ that is similar to it, but which serves no important purpose, if functional at all. While not necessarily harmful, such organs can cause problems if they grow too large or become cancerous. and tissues of castrated cas·trate tr.v. cas·trat·ed, cas·trat·ing, cas·trates 1. To remove the testicles of (a male); geld or emasculate. 2. To remove the ovaries of (a female); spay. 3. juvenile male rats: the ventral ventral /ven·tral/ (ven´tral) 1. pertaining to the abdomen or to any venter. 2. directed toward or situated on the belly surface; opposite of dorsal. ven·tral adj. prostate prostate /pros·tate/ (pros´tat) a gland surrounding the bladder neck and urethra in the male; it contributes a secretion to the semen.prostat´ic pros·tate n. The prostate gland. adj. , the seminal vesicles seminal vesicle n. Either of a pair of pouchlike glands situated on each side of the male urinary bladder that secrete seminal fluid and nourish and promote the movement of spermatozoa through the urethra. with coagulating glands, the levator ani The Levator ani is a broad, thin muscle, situated on the side of the pelvis. It is attached to the inner surface of the side of the lesser pelvis, and unites with its fellow of the opposite side to form the greater part of the floor of the pelvic cavity. and bulbocavernosus bulbocavernosus /bul·bo·cav·er·no·sus/ (bul?bo-kav?er-no´sus) bulbocavernous muscle. bul·bo·cav·er·no·sus n. See bulbospongiosus. muscle complex, the Cowper's glands Cowper's glands see bulbourethral glands. , and the glans penis glans penis n. The conical expansion of the corpus spongiosum that forms the head of the penis. Glans penis The bulbous tip of the penis. Mentioned in: Neurogenic Bladder . The phase 1 feasibility demonstration stage of the Hershberger validation program has been successfully completed with a single androgen agonist agonist /ag·o·nist/ (ag´ah-nist) 1. one involved in a struggle or competition. 2. agonistic muscle. 3. and a single antagonist antagonist /an·tag·o·nist/ (an-tag´o-nist) 1. a substance that tends to nullify the action of another, as a drug that binds to a cell receptor without eliciting a biological response, blocking binding of substances that could as reference substances. The phase 2 validation program employs a range of additional androgen agonists and antagonists as well as 5[alpha]-reductase inhibitors. Seven Japanese laboratories have contributed phase 2 validation studies of the Hershberger assay using methyltestosterone, vinclozolin, and 2,2-bis (4-chlorophenyl)-1,1-dichloroethylene (p,p'-DDE). The methyltestosterone doses were 0, 0.05, 0.5, 5, and 50 mg/kg/day, and the vinclozolin and p,p'-DDE doses were 0, 3, 10, 30, and 100 mg/kg/day. All chemicals were orally administered by gavage gavage /ga·vage/ (gah-vahzh´) [Fr.] 1. forced feeding, especially through a tube passed into the stomach. 2. superalimentation. ga·vage n. 1. for 10 consecutive days. In the antagonist version of the assay using vinclozolin and p,p'-DDE, 0.2 mg/kg/day of testosterone testosterone (tĕstŏs`tərōn), principal androgen, or male sex hormone. One of the group of compounds known as anabolic steroids, testosterone is secreted by the testes (see testis) but is also synthesized in small quantities in the propionate propionate /pro·pi·o·nate/ (pro´pe-o-nat) any salt of propionic acid. pro·pi·o·nate n. A salt or ester of propionic acid. propionate any salt of propionic acid. was coadministered by subcutaneous injection Noun 1. subcutaneous injection - an injection under the skin injection, shot - the act of putting a liquid into the body by means of a syringe; "the nurse gave him a flu shot" . All five accessory accessory, in criminal law, a person who, though not present at the commission of a crime, becomes a participator in the crime either before or after the fact of commission. sex preproductive organs and tissues consistently responded with statistically significant changes in weight within a narrow window. Therefore, the Japanese studies support the Hershberger assay as a reliable and reproducible re·pro·duce v. re·pro·duced, re·pro·duc·ing, re·pro·duc·es v.tr. 1. To produce a counterpart, image, or copy of. 2. Biology To generate (offspring) by sexual or asexual means. screening assay for the detection of androgen agonistic agonistic /ag·o·nis·tic/ (ag?o-nis´tik) pertaining to a struggle or competition; as an agonistic muscle, counteracted by an antagonistic muscle. and antagonistic effects antagonistic effect The negative effect that one chemical or family of chemicals has on other chemicals . Key words: Hershberger assay, methyltestosterone, OECD OECD: see Organization for Economic Cooperation and Development. validation, p,p'-DDE, vinclozolin. Environ en·vi·ron tr.v. en·vi·roned, en·vi·ron·ing, en·vi·rons To encircle; surround. See Synonyms at surround. [Middle English envirounen, from Old French environner Health Perspect 111:1912-1919 (2003). doi:10.1289/ehp.6357 available via http://dx.doi.org/ [Online 10 September 2003] ********** Certain reproductive re·pro·duc·tive adj. 1. Of or relating to reproduction. 2. Tending to reproduce. reproductive subserving or pertaining to reproduction. and developmental toxicants may have the potential to interfere with normal sexual differentiation sexual differentiation See Hermaphroditism, hirsutism, Müllerian ducts, Precocious puberty, Pseudoprecocious puberty, Tanner staging, Testis-determining factor, Virilization, Wolffian ducts, XXX, XXY, XXXY, XYY syndromes, Y Chromosome. and development in animals and humans by modulating or interfering with the endocrine system endocrine system (ĕn`dəkrĭn), body control system composed of a group of glands that maintain a stable internal environment by producing chemical regulatory substances called hormones. (McLachlan 1993; McLachlan and Korach 1995). The Organisation for Economic Cooperation and Development (OECD) has initiated an activity, to revise existing guidelines and develop new screening and testing guidelines to aid in the identification and assessment of such toxicants (OECD 1998, 2000, 2001, 2003). One proposed assay, referred to as the Hershberger assay,, uses the androgen sensitivity of several accessory sex organs and tissues of the male reproductive tract. The assay was originally developed in the 1930s by Korenchevsky. and co-workers, and a number of accessory sex organs and tissues were shown to be useful by these and other investigators, including the ventral prostate (Deanesly and Parkes 1936; Dingemanse et al. 1935; Korenchevsky 1932; Korenchevsky et al. 1932, 1933a, 1933b), the seminal vesicles and coagulating glands (Deanesly and Parkes 1936; Dingemanse et al. 1935; Korenchevsky 1932; Korenchevsky et al. 1932, 1933a, 1933b), the preputial glands preputial gland n. Any of the small sebaceous glands of the corona of the penis and the inner surface of the prepuce that secrete smegma. (Bulbring and Burn 1935; Korenchevsky 1932; Korenchevsky et al. 1932, 1933a, 1933b), the Cowper's glands (Wainman and Shipounoff 1941), and the glans penis (Bulbring and Burn 1935; Dingemanse et al. 1935; Korenchevsky 1932; Korenchevsky et al. 1932, 1933a, 1933b). In the 1940s, it was discovered that the levator ani and bulbocavernosus muscles also responded to androgens Androgens Male sex hormones produced by the adrenal glands and testes, the male sex glands. Mentioned in: Acne, Congenital Adrenal Hyperplasia, Finasteride, Homocysteine, Polycystic Ovary Syndrome, Salpingo-Oophorectomy , but in a different way from the other tissues (Eisenberg and Gordan 1950; Eisenberg et al. 1949; Wainman and Shipounoff 1941). The basis for this differential sensitivity is the presence of 5[alpha]-reductase in most accessory tissues of the male reproductive tract but its absence in the muscle complex (Di Salle et al. 1994). The capabilities of the assay were demonstrated in 1953 by Hershberger et al. when they analyzed an·a·lyze tr.v. an·a·lyzed, an·a·lyz·ing, an·a·lyz·es 1. To examine methodically by separating into parts and studying their interrelations. 2. Chemistry To make a chemical analysis of. 3. the response of the ventral prostate, seminal vesicles and coagulating glands, and the levator ani without the bulbocavernosus muscle to a number of active chemicals, including estrogens Estrogens Hormones produced by the ovaries, the female sex glands. Mentioned in: Acne, Polycystic Ovary Syndrome estrogens (es´trōjenz), n. and progesterones (Hershberger et al. 1953). In the 1970s and 1980s, with the discovery of the androgen receptor The androgen receptor (AR) is a type of nuclear receptor which is activated by binding of either of the androgenic hormones testosterone or dihydrotestosterone.[1] and the first compounds such as cyprotone acetate acetate (ăs`ĭtāt'), one of the most important forms of artificial cellulose-based fibers; the ester of acetic acid. The first patents for the production of fibers from cellulose acetate appeared at the beginning of the 20th cent. that were antagonists of the receptor receptor /re·cep·tor/ (-ter) 1. a molecule on the surface or within a cell that recognizes and binds with specific molecules, producing a specific effect in the cell; e.g. , the assay was modified to address antagonistic antagonistic adjective Referring to any combination of 2 or more drugs, which results in a therapeutic effect that is less than the sum of each drug's effect. Cf Additive, Synergism. activity. Briefly, a set dose of a reference agonist was coadministered to several groups of animals that were also administered a set of doses of the purported pur·port·ed adj. Assumed to be such; supposed: the purported author of the story. pur·port  ed·ly adv. antagonist. This modified system was successfully used
by several investigators for assaying androgen antagonists (Peers et al.
1973; Raynaud et al. 1980, 1984; Wakeling et al. 1981).Therefore, based upon the recommendation of scientific workshops, both the U.S. Endocrine Disruptor Screening and Testing Advisory Committee (U.S. EPA EPA eicosapentaenoic acid. EPA abbr. eicosapentaenoic acid EPA, n.pr See acid, eicosapentaenoic. EPA, n. 1998) and the OECD Endocrine endocrine /en·do·crine/ (en´do-krin, en´do-krin) 1. secreting internally. 2. pertaining to internal secretions; hormonal. See also under system. en·do·crine adj. Disrupter Testing and Assessment Working Group (OECD 2000) have proposed this assay as a Tier 1 screen to identify possible reproductive and developmental toxicants acting through androgen agonist and antagonist mechanisms. The OECD phase 1 validation program for the Hershberger assay was completed in 2001. In this phase, a standardized standardized pertaining to data that have been submitted to standardization procedures. standardized morbidity rate see morbidity rate. standardized mortality rate see mortality rate. protocol using ventral prostate, seminal vesicles with coagulating glands, levator ani and bulbocavernosus muscle complex, Cowper's glands, and glans penis was successfully tested against a reference androgen compound, testosterone propionate (TP), and a reference antagonist, flutamide (OECD 2001). Therefore, the OECD proposed a phase 2 validation program using additional androgen agonists and antagonists as the next step to validate To prove something to be sound or logical. Also to certify conformance to a standard. Contrast with "verify," which means to prove something to be correct. For example, data entry validity checking determines whether the data make sense (numbers fall within a range, numeric data the assay. In phase 2, the selected androgens were methyltestosterone (MT) and trenbolone; the selected antagonists were vinclozolin (VCZ), procymidone, linurone, and 2,2-bis (4-chlorophenyl)- 1,1-dichloroethylene (p,p'-DDE); and the 5[alpha]-reductase inhibitor inhibitor /in·hib·i·tor/ (in-hib´i-tor) 1. any substance that interferes with a chemical reaction, growth, or other biologic activity. 2. was finasteride Finasteride Definition Finasteride is a drug that belongs to the class of androgen inhibitors, which means that it blocks the production of male sex hormones. It is sold in the United States and Canada under the brand names Proscar and Propecia. . These test substances will be used to investigate the reliability of the assay, including a demonstration of the protocol's transferability among laboratories and the reproducibility reproducibility Lab medicine The degree of agreement among repeated measurements of a particular parameter, presented in terms of a standard deviation or coefficient of variation of the results in a set of measurements of the protocol's results. Seven Japanese laboratories participated in the phase 2 validation study that used three of the selected compounds: MT, VCZ, and p,p'-DDE. The participation of the laboratories in the OECD phase 2 validation study was performed as part of a national validation program in Japan. Materials and Methods Laboratories. The seven participating Japanese laboratories were the Chemicals Evaluation and Research Institute (CERI CERI Centre for Educational Research and Innovation (France) CERI Canadian Energy Research Institute CERI Cognitive Enhancement Research Institute CERI Chemicals Evaluation and Research Institute (Japan) ); the Food Drug Safety Center; the Institute of Environmental Toxicology toxicology, study of poisons, or toxins, from the standpoint of detection, isolation, identification, and determination of their effects on the human body. Toxicology may be considered the branch of pharmacology devoted to the study of the poisonous effects of drugs. ; the Japan Bioassay Bioassay A method for the quantitation of the effects on a biological system by its exposure to a substance, as well as the quantitation of the concentration of a substance by some observable effect on a biological system. Research Center; Mitsubishi Chemical Safety Institute; Panapham Co., Ltd.; and Sumitomo Chemical Company Ltd. Each laboratory performed in compliance with principles of good laboratory practice. Test substances. The test substances were methyltestosterone (MT; CAS No. 58-18-4; 99.8% pure; Fluka Production GmbH, St. Louis, MO, USA), vinclozolin (VCZ; CAS No. 50471-44-8; 99% pure; Kanto Chemical Co., Tokyo, Japan), and p,p-DDE (CAS No. 72-55-9; 99.5% pure; Sigma-Aldrich Co., St. Louis, MO, USA). Testosterone propionate (TP; CAS No. 57-85-2; 97% pure; Fluka) was used as a reference positive chemical control and was coadministered with VCZ and p,p'-DDE to detect androgen antagonistic effects. MT, p,p'-DDE, and TP were obtained from a centralized cen·tral·ize v. cen·tral·ized, cen·tral·iz·ing, cen·tral·iz·es v.tr. 1. To draw into or toward a center; consolidate. 2. chemical repository (1) A database of information about applications software that includes author, data elements, inputs, processes, outputs and interrelationships. A repository is used in a CASE or application development system in order to identify objects and business rules for reuse. at TNO TNO Tamarindo, Costa Rica (Airport code) TNO Nederlandse Organisatie voor Toegepast Natuurwetenschappelijk Onderzoek TNO Trans-Neptunian Object TNO The New Order (paramilitary street gang) TNO Trust No One (Zeist, the Netherlands) and distributed through CERI to each laboratory; VCZ was obtained by CERI and distributed to each laboratory, in the study. All laboratories used corn oil corn oil n. A pale yellow liquid obtained from the embryos of corn grains, used especially as a cooking and salad oil and in the manufacture of margarines. Noun 1. as the vehicle. The test substances used in each laboratory, are shown in Table 1. Animals. Laboratory details regarding rat strain, age at castration castration, removal of the sex glands of an animal, i.e., testes in the male, or ovaries and often the uterus in the female. Castration of the female animal is commonly referred to as spaying. , number of postoperative post·op·er·a·tive adj. Happening or done after a surgical operation. postoperative after a surgical operation. postoperative care acclimation acclimation /ac·cli·ma·tion/ (ak?li-ma´shun) the process of becoming accustomed to a new environment. ac·cli·ma·tion n. 1. days, age at autopsy, animal diet, and the number of animals housed per cage are summarized in Table 1. Five laboratories used Crj:CD (SD) (Sprague-Dawley) castrated rats from Charles River Charles River River, eastern Massachusetts, U.S. The longest river wholly in the state, it flows into Boston Bay after a course of about 80 mi (130 km). Navigable for about 7 mi (11 km), its estuary separates the cities of Boston and Cambridge. Japan, Inc. (Kanagawa/Shiga, Japan) between the ages of 40 and 46 days, and the test substances were administered 7-11 days after castration. Two laboratories used Brl Han: WIST wist v. Past tense and past participle of wit2. Jcl (GALAS GALAS Gay And Lesbian Armenian Society ) castrated rats from Japan Clea, Inc. (Tokyo, Japan) between the ages of 40 and 43 days, and the test substances were administered 6 or 7 days after castration. In all of the laboratories, the rats were weighed, weight-ranked, and assigned as·sign tr.v. as·signed, as·sign·ing, as·signs 1. To set apart for a particular purpose; designate: assigned a day for the inspection. 2. to each of the experimental and control groups after they had recovered from castration. Body weight and clinical signs were recorded daily throughout the study. Rats were provided with water and a commercial diet (MF or CRF-1, Oriental oriental having some connection with the Orient. oriental avian eye fluke see philophthalmusgralli. oriental blood fluke schistosomajaponicum. oriental cattle plague see rinderpest. Yeast yeast, name applied specifically to a certain group of microscopic fungi and to commercial products consisting of masses of dried yeast cells or of yeast mixed with a starchy material and pressed into yeast cakes. Co., Tokyo, Japan) ad libitum ad libitum without restraint. ad libitum feeding food available at all times with the quantity and frequency of consumption being the free choice of the animal. . The animals were kept under specific-pathogen-free conditions. The animal room was maintained at a temperature of 23 [+ or -] 2[degrees]C, a relative humidity relative humidity n. The ratio of the amount of water vapor in the air at a specific temperature to the maximum amount that the air could hold at that temperature, expressed as a percentage. of 55 [+ or -] 15%, and artificial illumination illumination, in art illumination, in art, decoration of manuscripts and books with colored, gilded pictures, often referred to as miniatures (see miniature painting); historiated and decorated initials; and ornamental border designs. with fluorescent fluorescent having the quality of fluorescence. fluorescent antibody see fluorescence microscopy. fluorescent antibody test see fluorescence microscopy. light on a 12-hr light/dark cycle. All animals were cared for according to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. the principles outlined in the guide for animal experimentation prepared by the Japanese Association for Laboratory Animal Science (1992). Chemical administration. Each rest chemical was orally administered via a stomach tube for 10 consecutive days at approximately the same time each day. A vehicle control group receiving only corn oil was used in all cases. For the androgen antagonists (VCZ and p,p'-DDE), 0.2 mg/kg/day of TP was coadministered each day by subcutaneous injection in the dorsal dorsal /dor·sal/ (dor´s'l) 1. pertaining to the back or to any dorsum. 2. denoting a position more toward the back surface than some other object of reference; a synonym of posterior region after the oral administration of each chemical. In these cases, a positive control group of animals received TP injections alone. We selected the dose of TP on the basis of OECD recommendations and published data (OECD 2001; Sunami et al. 2000). The group size in all cases was six rats. For the TP and corn oil solutions containing each of the test chemicals, the volume of corn oil was 5 mL/kg. The MT doses were 0.05, 0.5, 5, and 50 mg/kg/day, and the VCZ and p,p'-DDE doses were 3, 10, 30, and 100 mg/kg/day. All doses were selected based on the results of preliminary, range-finding studies. The animals were killed by bleeding from the abdominal abdominal /ab·dom·i·nal/ (ab-dom´i-n'l) pertaining to the abdomen. ab·dom·i·nal adj. Of or relating to the abdomen. n. An abdominal muscle. vein under deep ether ether, in chemistry ether, any of a number of organic compounds whose molecules contain two hydrocarbon groups joined by single bonds to an oxygen atom. anesthesia anesthesia (ănĭsthē`zhə) [Gr.,=insensibility], loss of sensation, especially that of pain, induced by drugs, especially as a means of facilitating safe surgical procedures. approximately 24 hr after receiving their final dose. The five mandatory tissues--the ventral prostate and fluid, seminal vesicle and fluid, bulbocavernosus/levator ani ani (ä`nē), bird: see cuckoo. (1) See animated cursor. (2) (Automatic Number Identification) A telephone service that transmits the billing number (BN) and the telephone number of the muscle (BC/LA), glans penis, and Cowper's gland--were carefully dissected dis·sect·ed adj. 1. Botany Divided into many deep, narrow segments: dissected leaves. 2. Geology Cut by irregular valleys and hills. Adj. 1. free of adhering ADHERING. Cleaving to, or joining; as, adhering to the enemies of the United States. 2. The constitution of the United States, art. 3, s 3, defines treason against the United States, to consist only in levying war against them or in adhering to their enemies, fat and weighed to the nearest 0.1 mg. Six of the laboratories weighed the wet organs. One laboratory (Lab 4) weighed the prostate, seminal vesicle, Cowper's glands, and adrenal glands Adrenal glands The two glands that are located on top of the kidneys. These glands secrete several hormones, including the glucocorticoids which, among other things, influence the way the immune system works, and the mineralocorticoids, which affect retention of after approximately 24 hr fixation fixation: see psychoanalysis. in 10% formalin formalin /for·ma·lin/ (for´mah-lin) formaldehyde solution. for·ma·lin n. An aqueous solution of formaldehyde that is 37 percent by weight. solution, following the procedure of Yamada et al. (2000). The liver, paired kidneys, and paired adrenal glands were weighed as optional organs in some laboratories in each assay described in Table 2. Statistical analysis. Body weight and organ weight data were tested using Bartlett's test Bartlett's test (Snedecor and Cochran, 1983) is used to test if k samples have equal variances. Equal variances across samples is called homoscedasticity or homogeneity of variances. for homogeneity Homogeneity The degree to which items are similar. of variance The discrepancy between what a party to a lawsuit alleges will be proved in pleadings and what the party actually proves at trial. In Zoning law, an official permit to use property in a manner that departs from the way in which other property in the same locality . When the variances were homogeneous The same. Contrast with heterogeneous. homogeneous - (Or "homogenous") Of uniform nature, similar in kind. 1. In the context of distributed systems, middleware makes heterogeneous systems appear as a homogeneous entity. For example see: interoperable network. at the 5% significance level, one-way analysis of variance (ANOVA anova see analysis of variance. ANOVA Analysis of variance, see there ) was performed. If it yielded significant differences, the differences between the vehicle control group and each of the MT groups or the positive control group and each of the VCZ and p,p'-DDE groups were analyzed by Dunnett's test. When the variances were nor homogeneous, the Kruskal-Wallis test was used. If it yielded significant differences, the differences between each group and the corresponding control group were analyzed by the nonparametric Dunnett's test. Log-transformed organ-weight data were also tested by the same method. The coefficient coefficient /co·ef·fi·cient/ (ko?ah-fish´int) 1. an expression of the change or effect produced by variation in certain factors, or of the ratio between two different quantities. 2. of variance (CV) and [R.sup.2] values for the different effects of each compound were also calculated by dividing the sums of the squares of the ANOVA scores for an effect by the total sum of the squares. This calculation provides an estimate of the strength of an effects association with an end point. Data for each end point were also analyzed using a two-way ANOVA, with dosage dosage /dos·age/ (do´saj) the determination and regulation of the size, frequency, and number of doses. dos·age n. 1. Administration of a therapeutic agent in prescribed amounts. and laboratory as the main effects, so that the magnitude of the overall dosage and laboratory effects could be determined. For graphic presentation, the sex accessory organ data were normalized to visually compare the shapes of the dose response curves dose response curve, n the relationship between the dose level to an external stimulus or a drug and the response of an organism, often depicted graphically. See also law, Arndt-Schulz; dose-dependent reverse effect; and hormesis. produced by each laboratory. For this normalization In relational database management, a process that breaks down data into record groups for efficient processing. There are six stages. By the third stage (third normal form), data are identified only by the key field in their record. , the control value was set to 100% in the MT assay, and 100% in the TP without VCZ or p,p'-DDE assays. ANOVA was performed on the data from each laboratory and for the pooled laboratory data; these normalized values were not analyzed statistically, Results Methyltestosterone. Body weights, clinical observations, and organ weights. The weight changes in optional organs and the body weights on the first day of dosing and at necropsy necropsy /nec·rop·sy/ (nek´rop-se) examination of a body after death; autopsy. nec·rop·sy n. See autopsy. necropsy examination of a body after death. See also autopsy. are shown in Tables 2 and 3. No significant differences in body weight were observed between the vehicle control group and the MT group in each laboratory. No abnormal clinical signs were observed in any of the rats that were treated with MT. The paired kidney weights increased significantly at 50 mg/kg/day MT in Lab 4, and adrenal adrenal /ad·re·nal/ (ah-dre´n'l) 1. paranephric. 2. adrenal gland. 3. pertaining to an adrenal gland. ad·re·nal adj. 1. weights decreased at the same dose in Lab 4. Accessory sex organ weights. Accessory sex organ weight changes and overall means are shown in Tables 3 and 4, and normalized organ weight changes are shown in Figure 1. [FIGURE 1 OMITTED] For the ventral prostate, the normalized dose-response curves dose-response curve A graphic representation of the effects that varous doses of an agent–eg, ionizing radiation or a chemotherapeutic agent, have on a given parameter–eg, cell viability, mutation frequency, DNA damage, tumor growth or metastasis or produced by the four laboratories were similar, and the weight change at 50 mg/kg/day MT relative to the vehicle control ranged from 641% to 1,022%. This was the largest weight change observed in any of the examined organs. The [R.sup.2] values for effects of treatments (TRT TRT Transportation Research Thesaurus TRT Tribunal Regional do Trabalho (Brazil) TRT Türkiye Radyo Televizyon Kurumu TRT Tinnitus Retraining Therapy TRT Testosterone Replacement Therapy TRT Thai Rak Thai Party ) in the ventral prostate was higher than the respective TRT values for other organs. The normalized dose response curves produced by the four laboratories were similar for the seminal vesicle; the weight change ranged from 465% to 707% at 50 mg/kg/day MT relative to the vehicle control. For BC/LA, the normalized dose-response curves produced by the four laboratories were almost the same, and the weight change at 50 mg/kg/day MT relative to the vehicle control ranged from 226% to 240%. The normalized dose-response curves produced by the four laboratories were similar for the glans penis, and the weight change at 50 mg/kg/day MT relative to the vehicle control ranged from 150% to 162%. Although the range between the low and high relative weight changes in animals receiving 50 mg/kg/day MT was narrow, the relative weight increase at this dose was the smallest of the weight changes in all of the accessory sex organs that were examined. The average CV for the glans penis was the lowest of all the average values obtained for the other organs. The [R.sup.2] values for effects among laboratories (LAB) for the glans penis was the highest value obtained among the accessory sex organs examined in this study. For the Cowper's glands, the normalized dose-response curves produced by the four laboratories were similar, and the weight change ranged from 273% to 417% at 50 mg/kg/day MT relative to the vehicle control. Vinclozolin. Body weights, clinical general observations, and organ weights. The weight changes in optional organs and the body weight changes for VCZ-treated rats are shown in Tables 2 and 5. No significant differences in body weight were observed between the positive control group that received TP injections alone and the VCZ group in any of the laboratories. No abnormal clinical signs were observed in any of the rats treated with VCZ plus TP. Weight of the paired adrenal glands increased significantly at 100 mg/kg/day, and no other significant changes were detected in the liver and paired kidneys. Accessory sex organ weights. Weight changes in accessory sex organs and overall means are shown in Tables 5 and 6, and normalized organ weight changes are shown in Figure 2. [FIGURE 2 OMITTED] For the ventral prostate, the normalized dose-response curves produced by the four laboratories were similar. The ventral prostate weight changes at 100 mg/kg/day VCZ relative to the positive control ranged from 27% to 37%. The normalized dose-response curves produced by the four laboratories were similar for seminal vesicles. The weight changes at 100 mg/kg/day VCZ relative to the positive control were similar, ranging from 15% to 23%. These values were the lowest of all the values for the accessory sex organs, and the decreasing dose-response curve for the seminal vesicle was sharper than the curves for the other organs. For the BC/LA, the normalized dose-response curves produced by the four laboratories were similar, and the weight change at 100 mg/kg/day VCZ relative to the positive control were similar, ranging from 48% to 52%. The normalized dose-response curves produced by the four laboratories were similar for the glans penis, and the weight change at 100 mg/kg/day VCZ relative to the positive control were similar, ranging from 69% to 73%. The overall CV value was the lowest among the values for the examined accessory sex organs. The normalized dose-response curves produced by the four laboratories were similar for Cowper's glands. The weight change ranged from 36% to 42% at a dose of 100 mg/kg/day VCZ relative to the positive control. p,p'-DDE. Body weights, clinical observations, and organ weights. The weight changes in optional organs and the body weight changes for p,p'-DDE-treated rats are shown in Tables 2 and 7. The body weight decreased significantly in the 100 mg/kg/day group of lab 5, and a similar (but not significant) tendency was also observed in the 100 mg/kg/day group of Lab 2. No abnormal clinical signs were detected in any of the rats treated with p,p'-DDE plus TP. The liver weights increased significantly at 30 and 100 mg/kg/day in Lab 4. No significant changes were observed in other organs. Accessory sex organ weights. Weight changes in accessory sex organs and overall means are shown in Tables 7 and 8, and normalized organ weight changes are shown in Figure 3. [FIGURE 3 OMITTED] For the ventral prostate, the normalized dose-response curves produced by the five laboratories were very similar, except for the curve produced by Lab 7 because of the value at 30 mg/kg/day p,p'-DDE. The weight change at a dose of 100 mg/kg/day relative to the positive control ranged from 37% to 62%. The normalized dose-response curves produced by the laboratories were similar at 10, 30, and 100 mg/kg/day p,p'-DDE for seminal vesicle. The weight change of the seminal vesicles at 100 mg/kg/day relative to the positive control ranged front 23% to 54%. The dose-response curve for the seminal vesicle was the sharpest of the various curves produced for the accessory sex organs for p,p'-DDE. The TRT in the seminal vesicle was the highest value among the accessory sex organs measured in this study. For BC/LA, the normalized dose-response curves produced by four laboratories were similar. The weight change ranged from 55% to 72% at 100 mg/kg/day p,p'-DDE relative to the positive control. The normalized dose-response curves were similar in glans penis above a dose of 30 mg/kg/day p,p'-DDE. The weight change at 100 mg/kg/day p,p'-DDE relative to the positive control ranged from 79% to 86%, and this percentage was the highest among the values for the accessory sex organs receiving p,p'-DDE. The CV of the glans penis and the BC/LA were smaller than the values for the other organs. The TRT for the glans penis was the smallest of the values observed among the accessory sex organs in p,p'-DDE-treated rats. For Cowper's glands, the normalized dose-response curves produced by the laboratories were similar above a dose of 30 mg/kg/day p,p'-DDE. The weight change at 100 mg/kg/day relative to the positive control ranged from 41% to 65%. Discussion Seven Japanese laboratories performed the Hershberger assay using MT, VCZ, and p,p'-DDE as part of a national validation program. The weights of all the accessory sex organs from the experimental animals in all the laboratories exhibited significant dose-related changes in the assays using agonistic MT or antagonistic VCZ and p,p'-DDE; the normalized dose-response curves showed that all five tissues reacted in a similar manner for each compound. Furthermore, the weights of all the tissues treated with middle and/or high doses in each assay fell within narrow ranges. Therefore, we consider the Hershberger assay, as proposed by the OECD, to be a good screening assay for detecting the androgen agonistic and antagonistic effects of chemicals. The OECD proposed TP doses of 0.2 mg/kg/day and 0.4 mg/kg/day to detect antagonistic effects of chemicals based on the data from the OECD phase 1 validation of the Hershberger assay (OECD 2001). In the previous study, we used the 0.2 mg/kg/day dose of TP in Hershberger assays of 30 chemicals based on the OECD draft protocol and found that the accessory sex organ weights of the castrated rats were lower than those of castrated rats given TP, and the weights of these organs in rats given 10 mg/kg/day flutamide plus TP were also lower than in castrated rats given TP (Yamasaki et al. 2003). In addition, the weights of the accessory sex organs of the castrated rats were lower than those of castrated rats given 0.4 mg/kg/day TP, and their weights were also lower in noncastrated rats than in castrated rats given TP (Yamasaki et al. 2002). We selected the 0.2 mg/kg/day dose in this study, however, a dose of 0.4 mg/kg/day was used in the phase 2 validation studies except in Japan (OECD 2003). The sensitivity of this assay of antagonistic chemicals at the 0.2 mg/kg/day and 0.4 mg/kg/day doses needs to be compared. The OECD phase 1 validation of the Hershberger assay using antagonistic flutamide reported that the seminal vesicle exhibited the most sensitive end point and that the glans penis exhibited the least sensitive end point, based on benchmark dose estimates (OECD 2001). When the overall dose-response curves for agonistic TP were compared, the glans penis was the most sensitive and the seminal vesicle was the least sensitive (OECD 2001). In the present study, it was difficult to select a particularly sensitive organ from among the five tissues examined in the androgen agonistic MT and antagonistic VCZ and p,p'-DDE assays. In the Hershberger assay using MT, the CV for the glans penis was smaller than that of the other organs, but the TRT of the ventral prostate was the highest among the values measured in the study. On the other hand, the LAB values of the ventral prostate and Cowper's glands were smaller than the values of the other organs, and the percentage weight change relative to the control value at the highest dose was the greatest in the ventral prostate. These findings demonstrate that the ventral prostate was particularly sensitive based on the TRT, LAB, and increasing percentage of organ weight, whereas the glans penis was sensitive based on the CV values. Similarly, the seminal vesicle was sensitive based oil the TRT, LAB, and decreasing percentage of organ weight, whereas the glans penis was sensitive based on the CV values in the assays using antagonistic VCZ and p,p'-DDE. The CV values for the ventral prostate, seminal vesicle, and Cowper's gland Cowper's gland: see reproductive system. were higher than those for the glans penis and BC/LA in the assays for all three chemicals. These organs contain fluid, and the dissection dissection /dis·sec·tion/ (di-sek´shun) 1. the act of dissecting. 2. a part or whole of an organism prepared by dissecting. of these organs is technically difficult, compared with that of the glans penis and BC/LA. These technical issues may have influenced the varied CV values obtained for these organs. Furthermore, we did not confirm whether preputial pre·pu·tial adj. Of or relating to the prepuce. preputial emanating from or pertaining to the prepuce. preputial anastomosis separation had occurred in the rats before castration. Preputial separation has been reported to occur between days 39 and 44 in SD rats (Yamasaki et al 2001); in this study, the castration was performed between days 40 and 46. Thus, the rats used in this study were likely a mixture of animals with or without preputial separation. The castration times may also have influenced the variation in the CV values for each organ. In the assay using the androgen antagonistic chemicals, slight differences in the normalized response curves for low doses in the p,p'-DDE assay were observed among the laboratories, but the response curves for each organ in the VCZ assay were similar. The fact that the percentages of organ weight relative to the control at high doses in the p,p'-DDE assay were lower than those in the VCZ assay suggests that the androgen antagonistic affinity of p,p'-DDE is weaker than that of VCZ. On the other hand, the organ weights of the rats given only TP varied among the laboratories. The slight variation in responses among the laboratories for the low dose in the p,p'-DDE assay may have been affected by the relationship between the agonistic affinity of TP and the weak antagonistic affinity of p,p'-DDE. In the phase 1 validation study using TP, the OECD reported that no essential differences were observed when the weights of the fresh and fixed organs were compared (OECD 2001). Lab 4 weighed the prostate, seminal vesicle, and Cowper's glands after fixation, whereas the other laboratories measured the weights of fresh organs; the changes in organ weight among the laboratories were essentially similar. Therefore, the difference in the weighing method (fresh vs. fixed organs) did not appear to affect the results of the assay. Although the terminal body weights were different between SD and Wistar rats, the responsiveness of these rats to VCZ and p,p'-DDE did not differ in this study. This finding demonstrates that no significant differences exist regarding the use of SD and Wistar rats in the Hershberger assay for the detection of androgen antagonists. Among the optional organs measured in this study, the weight of the adrenal glands increased significantly in rats given 100 mg/kg/day of VCZ and decreased in rats given 50 mg/kg/day MT. The decrease in adrenal weight may be suppressed sup·press tr.v. sup·pressed, sup·press·ing, sup·press·es 1. To put an end to forcibly; subdue. 2. To curtail or prohibit the activities of. 3. by a high dose of androgen in the form of MT, and the adrenal glands may be hypertrophied hy·per·tro·phy n. pl. hy·per·tro·phies A nontumorous enlargement of an organ or a tissue as a result of an increase in the size rather than the number of constituent cells: muscle hypertrophy. in response to a high level of antagonist. Increased kidney weights in rats given 50 mg/kg/day of MT and increased liver weights in rats given 30 and 100 mg/kg/day of p,p'-DDE suggested toxic effects. On the other hand, a significant decrease or a tendency to decrease of the body weights in the p,p'-DDE assay was observed by two out of five laboratories; this response was also considered to be a toxic effect of p,p'-DDE.
Table 1. Laboratory details for test compounds and animals.
Laboratory Test compound(s) Rat strain
1 MT, VCZ Crj CD (SD) (a)
2 MT, VCZ, p-p'-DDE Crj CD (SD) (a)
3 MT Crj CD (SD) (b)
4 MT, p-p'-DDE Crj CD (SD) (b)
5 VCZ, p-p'-DDE Crj CD (SD) (b)
6 VCZ, p,p'-DDE Brl Han: WIST Jcl (GALAS)
7 p,p'-DDE Brl Han: WIST Jcl (GALAS)
Age at
castration Postoperative
Laboratory Test compound(s) (days) acclimation days
1 MT, VCZ 41-44 11
2 MT, VCZ, p-p'-DDE 40-44 8
3 MT 41-43 7
4 MT, p-p'-DDE 42-44 7
5 VCZ, p-p'-DDE 43-46 7
6 VCZ, p,p'-DDE 41-43 7
7 p,p'-DDE 40-42 6
Age at No.
Laboratory Test compound(s) autopsy (days) Diet per cage
1 MT, VCZ 62-65 CRF-1 1
2 MT, VCZ, p-p'-DDE 59-63 MF 1
3 MT 59-61 MF 3
4 MT, p-p'-DDE 59-61 CRF-1 2
5 VCZ, p-p'-DDE 61-64 MF 2
6 VCZ, p,p'-DDE 59-61 MF 3
7 p,p'-DDE 57-59 MF 3
(a) Facility in Kanagawa, Japan. (b) Facility in Shiga, Japan.
Table 2. Weights of optional organs from rats given MT, VCZ,
or p,p'-DDE.
Chemical Lab Animal/tissue Dose
MT
MT (mg/kg/day) 0 0.05
1 Terminal body wt (g) 309.2 318.5
Liver (g) 12.5 13.5
Adrenals (mg) 50.5 60.4
Kidneys (g) 2.2 2.4
3 Terminal body wt (g) 282.7 288.6
Liver (g) 12.0 12.0
4 Terminal body wt (g) 287.3 286.0
Liver (g) 12.3 12.4
Adrenals (mg) 52.8 46.7
Kidneys (g) 2.0 2.2
VCZ
TP (mg/kg/day) 0.2 0.2
VCZ (mg/kg/day) 0 3
1 Terminal body wt (g) 338.4 344.7
Liver (g) 14.5 14.3
Adrenals (mg) 54.9 56.0
Kidneys (g) 2.4 2.4
p,p'-DDE
TP(mg/kg/day) 0.2 0.2
p,p'-DDE 0 3
(mg/kg/day)
4 Terminal body wt (g) 292.7 291.0
Liver (g) 12.8 12.4
Adrenals (mg) 47.2 46.8
Kidneys (g) 2.2 2.1
7 Terminal body wt (g) 240.9 241.4
Kidneys (g) 2.1 21.0
Chemical Lab Animal/tissue Dose
MT
MT (mg/kg/day) 0.5 5
1 Terminal body wt (g) 313.4 315.6
Liver (g) 13.1 12.7
Adrenals (mg) 56.1 48.1
Kidneys (g) 2.3 2.3
3 Terminal body wt (g) 293.1 290.4
Liver (g) 11.7 11.3
4 Terminal body wt (g) 281.4 293.4
Liver (g) 11.7 13.0
Adrenals (mg) 49.0 49.0
Kidneys (g) 2.0 2.2
VCZ
TP (mg/kg/day) 0.2 0.2
VCZ (mg/kg/day) 10 30
1 Terminal body wt (g) 340.3 347.4
Liver (g) 14.5 15.2
Adrenals (mg) 60.8 66.9
Kidneys (g) 2.4 2.5
p,p'-DDE
TP(mg/kg/day) 0.2 0.2
p,p'-DDE 10 30
(mg/kg/day)
4 Terminal body wt (g) 290.4 293.2
Liver (g) 14.3 16.5 *
Adrenals (mg) 45.7 47.6
Kidneys (g) 2.2 2.3
7 Terminal body wt (g) 241.4 238.0
Kidneys (g) 2.2 2.1
Chemical Lab Animal/tissue Dose
MT
MT (mg/kg/day) 50
1 Terminal body wt (g) 317.0
Liver (g) 13.9
Adrenals (mg) 45.3
Kidneys (g) 2.5
3 Terminal body wt (g) 288.7
Liver (g) 12.3
4 Terminal body wt (g) 294.2
Liver (g) 13.8
Adrenals (mg) 41.1 *
Kidneys (g) 2.4 *
VCZ
TP (mg/kg/day) 0.2
VCZ (mg/kg/day) 100
1 Terminal body wt (g) 334.0
Liver (g) 15.5
Adrenals (mg) 72.9 *
Kidneys (g) 2.5
p,p'-DDE
TP(mg/kg/day) 0.2
p,p'-DDE 100
(mg/kg/day)
4 Terminal body wt (g) 289.4
Liver (g) 20.1 *
Adrenals (mg) 51.2
Kidneys (g) 2.3
7 Terminal body wt (g) 235.8
Kidneys (g) 2.1
* Significantly different from control at p < 0.05.
Table 3. Mean body weights and mean organ weights in
rats given MT: data and log-transformed data.
MT (mg/kg/day)
Lab 0 0.05 0.5
1 Starting body wt (g) 260.0 259.8 259.3
Terminal body wt (g) 309.2 318.5 313.4
Ventral prostate (mg) 21.1 20.4 18.7
Seminal vesicles (mg) 45.2 43.7 43.3
BC/LA (mg) 192.3 198.0 198.1
Glans penis (mg) 51.4 55.6 53.4
Cowper's glands (mg) 6.5 7.8 7.6
2 Starting body wt (g) 227.5 227.3 226.9
Terminal body wt (g) 297.6 291.2 292.6
Ventral prostate (mg) 12.6 14.4 21.4
Seminal vesicles (mg) 52.5 50.2 48.1
BC/LA (mg) 236.3 218.9 228.7
Glans penis (mg) 48.9 50.8 49.9
Cowper's glands (mg) 6.5 6.8 7.6
3 Starting body wt (g) 218.4 218.8 219.3
Terminal body wt (g) 282.7 288.6 293.1
Ventral prostate (mg) 19.3 22.1 26.2
Seminal vesicles (mg) 44.2 52.9 66.2
BC/LA (mg) 201.5 203.6 212.6
Glans penis (mg) 62.6 60.8 61.9
Cowper's glands (mg) 8.1 7.5 9.5
4 Starting body wt (g) 227.4 227.4 227.8
Terminal body wt (g) 287.3 286.0 281.4
Ventral prostate (mg) 19.2 20.8 19.5
Seminal vesicles (mg) 39.7 37.3 34.8
BC/LA (mg) 206.3 199.8 203.6
Glans penis (mg) 52.8 53.1 53.7
Cowper's glands (mg) 6.5 7.4 5.8
Log transformed data
1 Ventral prostate (mg) 1.3 1.3 1.3
Seminal vesicles (mg) 1.7 1.6 1.6
BC/LA (mg) 2.3 2.3 2.3
Glans penis (mg) 1.7 1.7 1.7
Cowper's glands (mg) 0.8 0.9 0.9
2 Ventral prostate (mg) 1.1 1.1 1.3 *
Seminal vesicles (mg) 1.7 1.7 1.7
BC/LA (mg) 2.4 2.3 2.4
Glans penis (mg) 1.7 1.7 1.7
Cowper's glands (mg) 0.8 0.8 0.9
3 Ventral prostate (mg) 1.3 1.3 1.4
Seminal vesicles (mg) 1.6 1.7 1.8
BC/LA (mg) 2.3 2.3 2.3
Glans penis (mg) 1.8 1.8 1.8
Cowper's glands (mg) 0.9 0.9 1.0
4 Ventral prostate (mg) 1.3 1.3 1.3
Seminal vesicles (mg) 1.6 1.6 1.5
BC/LA (mg) 2.3 2.3 2.3
Glans penis (mg) 1.7 1.7 1.7
Cowper's glands (mg) 0.8 0.9 0.8
MT (mg/kg/day)
Lab 5 50
1 Starting body wt (g) 249.8 258.9
Terminal body wt (g) 315.6 317.0
Ventral prostate (mg) 40.6 135.0 *
Seminal vesicles (mg) 65.7 248.2 *
BC/LA (mg) 253.2 * 460.5 *
Glans penis (mg) 64.8 * 83.2 *
Cowper's glands (mg) 10.8 * 25.3 *
2 Starting body wt (g) 228.0 226.7
Terminal body wt (g) 294.6 299.1
Ventral prostate (mg) 45.3 128.3 *
Seminal vesicles (mg) 70.7 278.5 *
BC/LA (mg) 287.3 533.8 *
Glans penis (mg) 55.5 * 73.3 *
Cowper's glands (mg) 11.0 27.2 *
3 Starting body wt (g) 219.4 218.2
Terminal body wt (g) 290.4 288.7
Ventral prostate (mg) 51.1 * 158.2 *
Seminal vesicles (mg) 108.0 * 312.6 *
BC/LA (mg) 254.2 482.0 *
Glans penis (mg) 74.4 94.7 *
Cowper's glands (mg) 11.8 * 22.1 *
4 Starting body wt (g) 228.5 227.3
Terminal body wt (g) 293.4 294.2
Ventral prostate (mg) 32.3 * 150.9 *
Seminal vesicles (mg) 41.2 184.4 *
BC/LA (mg) 243.8 487.1 *
Glans penis (mg) 56.8 83.5 *
Cowper's glands (mg) 7.6 26.3 *
Log transformed data
1 Ventral prostate (mg) 1.6 * 2.1 *
Seminal vesicles (mg) 1.8 * 2.4 *
BC/LA (mg) 2.4 * 2.7 *
Glans penis (mg) 1.8 * 1.9 *
Cowper's glands (mg) 1.0 1.4 *
2 Ventral prostate (mg) 1.6 * 2.1 *
Seminal vesicles (mg) 1.8 2.4 *
BC/LA (mg) 2.5 * 2.7 *
Glans penis (mg) 1.7 1.9 *
Cowper's glands (mg) 1.0 * 1.4 *
3 Ventral prostate (mg) 1.7 * 2.2 *
Seminal vesicles (mg) 2.0 * 2.5 *
BC/LA (mg) 2.4 * 2.7 *
Glans penis (mg) 1.9 * 2.0 *
Cowper's glands (mg) 1.1 * 1.3 *
4 Ventral prostate (mg) 1.5 * 2.2 *
Seminal vesicles (mg) 1.6 2.3 *
BC/LA (mg) 2.4 2.7 *
Glans penis (mg) 1.8 1.9 *
Cowper's glands (mg) 0.9 1.4 *
* Significantly different from vehicle control at p < 0.05.
Table 4. Overall mean organ weights, [R.sup.2], and CV in rats given
MT: data and lag-transformed data.
[R.sup.2]
(%) MT (mg/kg/day)
0 0.05
Overall means TRT LAB CV (%) (n=22-24) (n=23-24)
Overall
Ventral prostate (mg) 90 1 25 18.0 19.4
Seminal vesicles (mg) 81 4 20 45.4 46.0
BC/LA (mg) 83 6 12 209.1 205.0
Glans penis (mg) 78 19 7 54.0 55.2
Cowper's glands (mg) 81 0 22 6.9 7.4
Overall log-transformed
Ventral prostate (mg) 87 2 7.7 1.2 1.3
Seminal vesicles (mg) 83 6 4.7 1.7 1.6
BC/LA (mg) 87 2 2.2 2.3 2.3
Glans penis (mg) 77 21 1.8 1.7 1.7
Cowper's glands (mg) 78 2 10.3 0.8 0.9
MT (mg/kg/day)
0.5 5 50
Overall means (n=22-24) (n=22-24) (n=24)
Overall
Ventral prostate (mg) 21.5 42.3 143.1
Seminal vesicles (mg) 48.1 71.4 255.9
BC/LA (mg) 210.7 259.6 490.9
Glans penis (mg) 54.8 63.3 83.7
Cowper's glands (mg) 7.6 10.3 25.2
Overall log-transformed
Ventral prostate (mg) 1.3 1.6 2.1
Seminal vesicles (mg) 1.7 1.8 2.4
BC/LA (mg) 2.3 2.4 2.7
Glans penis (mg) 1.7 1.8 1.9
Cowper's glands (mg) 0.9 1.0 1.4
Abbreviations: TRT, [R.sup.2] values for effects of treatments;
LAB, [R.sup.2] values for effects among laboratories.
Table 5. Mean body weights and mean organ weights in rats given
0.2 mg/kg/day TP and VCZ: data and log-transformed data.
VCZ (mg/kg/day)
Lab 0 3 10
1 Starting body wt (g) 273.4 273.6 273.3
Terminal body wt (g) 338.4 344.7 340.3
Ventral prostate (mg) 136.5 118.8 91.3
Seminal vesicles (mg) 393.5 358.5 248.7 *
BC/LA (mg) 533.9 511.5 441.9 *
Glans penis (mg) 91.1 88.9 79.8 *
Cowper's glands (mg) 32.7 32.7 24.3 *
2 Starting body wt (g) 241.6 241.5 240.1
Terminal body wt (g) 326.8 327.7 320.8
Ventral prostate (mg) 97.2 111.6 105.1
Seminal vesicles (mg) 361.7 335.9 321.0
BC/LA (mg) 537.7 500.5 485.2
Glans penis (mg) 81.7 75.9 73.7
Cowper's glands (mg) 28.0 26.8 21.1 *
5 Starting body wt (g) 247.6 247.6 248.3
Terminal body wt (g) 340.6 337.0 338.8
Ventral prostate (mg) 183.6 149.7 * 136.7 *
Seminal vesicles (mg) 420.8 458.7 344.3
BC/LA(mg) 590.4 608.8 529.3
Glans penis (mg) 76.4 78.0 77.7
Cowper's glands (mg) 38.6 36.0 32.9
6 Starting body wt (g) 229.5 229.6 229.7
Terminal body wt (g) 291.1 289.9 286.2
Ventral prostate (mg) 106.4 98.9 84.1
Seminal vesicles (mg) 216.7 221.6 168.4 *
BC/LA (mg) 361.3 320.6 323.9
Glans penis (mg) 70.1 69.9 67.3
Cowper's glands (mg) 20.8 21.1 19.5
Log-transformed data
1 Ventral prostate (mg) 2.1 2.1 1.9 *
Seminal vesicles (mg) 2.6 2.6 2.4 *
BC/LA (mg) 2.7 2.7 2.6
Glans penis (mg) 2.0 1.9 1.9 *
Cowper's glands (mg) 1.5 1.5 1.4 *
2 Ventral prostate (mg) 1.9 2.0 2.0
Seminal vesicles (mg) 2.6 2.5 2.5
BC/LA (mg) 2.7 2.7 2.7
Glans penis (mg) 1.9 1.9 1.9
Cowper's glands (mg) 1.4 1.4 1.3
5 Ventral prostate (mg) 2.3 2.2 2.1 *
Seminal vesicles (mg) 2.6 2.7 2.5 *
BC/LA (mg) 2.8 2.8 2.7
Glans penis (mg) 1.9 1.9 1.9
Cowper's glands (mg) 1.6 1.5 1.5
6 Ventral prostate (mg) 2.0 2.0 1.9
Seminal vesicles (mg) 2.3 2.3 2.2
BC/LA (mg) 2.6 2.5 2.5
Glans penis (mg) 1.8 1.8 1.8
Cowper's glands (mg) 1.3 1.3 1.3
VCZ (mg/kg/day)
Lab 30 100
1 Starting body wt (g) 274.8 273.3
Terminal body wt (g) 347.4 334.0
Ventral prostate (mg) 60.7 * 36.4 *
Seminal vesicles (mg) 174.5 * 60.7 *
BC/LA (mg) 381.8 * 257.8 *
Glans penis (mg) 76.8 * 64.0 *
Cowper's glands (mg) 20.2 * 12.4 *
2 Starting body wt (g) 241.1 241.0
Terminal body wt (g) 319.6 319.1
Ventral prostate (mg) 79.4 34.1 *
Seminal vesicles (mg) 210.8 * 71.8 *
BC/LA (mg) 416.0 * 275.2 *
Glans penis (mg) 69.8 58.5 *
Cowper's glands (mg) 20.1 * 11.2 *
5 Starting body wt (g) 248.0 247.7
Terminal body wt (g) 333.5 335.3
Ventral prostate (mg) 98.2 * 51.0 *
Seminal vesicles (mg) 247.7 96.4 *
BC/LA(mg) 430.7 * 308.6 *
Glans penis (mg) 70.2 52.7 *
Cowper's glands (mg) 25.9 * 16.2 *
6 Starting body wt (g) 229.4 229.2
Terminal body wt (g) 286.3 289.2
Ventral prostate (mg) 75.3 38.9 *
Seminal vesicles (mg) 116.2 * 47.3 *
BC/LA (mg) 268.0 * 181.8 *
Glans penis (mg) 64.7 51.4 *
Cowper's glands (mg) 15.1 7.4 *
Log-transformed data
1 Ventral prostate (mg) 1.8 * 1.5 *
Seminal vesicles (mg) 2.2 * 1.8 *
BC/LA (mg) 2.6 * 2.4 *
Glans penis (mg) 1.9 * 1.8 *
Cowper's glands (mg) 1.3 * 1.1 *
2 Ventral prostate (mg) 1.9 1.5 *
Seminal vesicles (mg) 2.3 * 1.8 *
BC/LA (mg) 2.6 * 2.4 *
Glans penis (mg) 1.8 * 1.8 *
Cowper's glands (mg) 1.3 1.0 *
5 Ventral prostate (mg) 2.0 * 1.7 *
Seminal vesicles (mg) 2.4 * 2.0 *
BC/LA (mg) 2.6 * 2.5 *
Glans penis (mg) 1.8 1.7 *
Cowper's glands (mg) 1.4 * 1.2 *
6 Ventral prostate (mg) 1.9 1.6 *
Seminal vesicles (mg) 2.1 * 1.7 *
BC/LA (mg) 2.4 * 2.3 *
Glans penis (mg) 1.8 1.7 *
Cowper's glands (mg) 1.2 * 0.9 *
* Significantly different from vehicle control at p < 0.05.
Table 6. Overall mean organ weights, [R.sup.2], and CV in rats given
0.2 mg/kg/day TP and VCZ: data and log-transformed data.
[R.sup.2] VCZ
(%) (mg/kg/day)
0 3
Overall means TRT LAB CV (%) (n = 24) (n = 24)
Overall
Ventral prostate (mg) 60 16 19 130.9 119.8
Seminal vesicles (mg) 64 19 19 348.2 343.7
BC/LA (mg) 50 34 12 505.8 485.3
Glans penis (mg) 67 29 7 79.8 78.2
Cowper's glands (mg) 51 26 19 30.0 29.2
Overall log-transformed
Ventral prostate (mg) 69 11 4.8 2.1 2.1
Seminal vesicles (mg) 77 14 3.8 2.5 2.5
BC/LA (mg) 54 34 2.0 2.7 2.7
Glans penis {mg) 70 27 1.8 1.9 1.9
Cowper's glands (mg) 59 22 6.6 1.5 1.5
VCZ (mg/kg/day)
10 30 100
Overall means (n = 24) (n = 24) (n = 24)
Overall
Ventral prostate (mg) 104.3 78.4 40.1
Seminal vesicles (mg) 270.6 187.3 69.1
BC/LA (mg) 445.1 374.1 255.9
Glans penis (mg) 74.7 70.4 56.7
Cowper's glands (mg) 24.5 20.3 11.8
Overall log-transformed
Ventral prostate (mg) 2.0 1.9 1.6
Seminal vesicles (mg) 2.4 2.2 1.8
BC/LA (mg) 2.6 2.6 2.4
Glans penis {mg) 1.9 1.8 1.8
Cowper's glands (mg) 1.4 1.3 1.0
Abbreviations: TRT, [R.sup.2] values for effects of treatments;
LAB, [R.sup.2] values for effects among laboratories.
Table 7. Mean body weights and mean organ weights in rats given
0.2 mg/kg/day TP and p,p'-DDE: data and log-transformed data.
p,p'-DDE (mg/kg/day)
Lab 0 3 10
2 Starting body wt (g) 229.7 228.9 230.4
Terminal body wt (g) 313.4 313.4 313.0
Ventral prostate (mg) 137.8 125.7 128.9
Seminal vesicles (mg) 387.2 272.3 * 377.0
BC/LA (mg) 549.9 521.9 519.4
Glans penis (mg) 73.3 76.5 73.5
Cowper's glands (mg) 27.2 21.8 28.3
4 Starting body wt (g) 224.6 223.8 223.6
Terminal body wt (g) 292.7 291.0 290.4
Ventral prostate (mg) 115.0 101.3 103.3
Seminal vesicles (mg) 237.2 219.5 251.4
BC/LA (mg) 495.5 496.6 450.9
Glans penis (mg) 81.0 80.1 77.6
Cowper's glands (mg) 30.2 28.1 25.5
5 Starting body wt (g) 233.2 232.6 231.8
Terminal body wt (g) 319.4 326.9 322.9
Ventral prostate (mg) 153.3 158.4 165.9
Seminal vesicles (mg) 371.1 432.6 411.8
BC/LA (mg) 518.7 574.3 547.0
Glans penis (mg) 77.3 75.9 76.5
Cowper's glands (mg) 33.9 33.8 32.8
6 Starting body wt (g) 217.1 217.1 216.2
Terminal body wt (g) 276.6 270.2 272.6
Ventral prostate (mg) 106.2 89.8 100.0
Seminal vesicles (mg) 225.7 219.4 202.4
BC/LA (mg) 300.3 305.7 290.3
Glans penis (mg) 67.0 62.3 66.3
Cowper's glands (mg) 21.0 21.5 19.8
7 Starting body wt (g) 173.8 173.7 174.0
Terminal body wt (g) 240.9 241.4 241.4
Ventral prostate (mg) 906.0 79.1 88.1
Seminal vesicles (mg) 282.8 246.2 240.0
BC/LA (mg) 435.7 430.3 407.0
Glans penis (mg) 65.5 64.9 63.8
Cowper's glands (mg) 26.2 26.7 25.4
Log-transformed
2 Ventral prostate (mg) 2.1 2.1 2.1
Seminal vesicles (mg) 2.6 2.4 2.6
BC/LA (mg) 2.7 2.7 2.7
Glans penis (mg) 1.9 1.9 1.9
Cowper's glands (mg) 1.4 1.3 1.4
4 Ventral prostate (mg) 2.1 2.0 2.0
Seminal vesicles (mg) 2.4 2.3 2.4
BC/LA (mg) 2.7 2.7 2.7
Glans penis (mg) 1.9 1.9 1.9
Cowper's glands (mg) 1.5 1.4 1.4
5 Ventral prostate (mg) 2.2 2.2 2.2
Seminal vesicles (mg) 2.6 2.6 2.6
BC/LA (mg) 2.7 2.8 2.7
Glans penis (mg) 1.9 1.9 1.9
Cowper's glands (mg) 1.5 1.5 1.5
6 Ventral prostate (mg) 2.0 2.0 2.0
Seminal vesicles (mg) 2.3 2.3 2.3
BC/LA (mg) 2.5 2.5 2.5
Glans penis (mg) 1.8 1.8 1.8
Cowper's glands (mg) 1.3 1.3 1.3
7 Ventral prostate (mg) 2.0 1.9 1.9
Seminal vesicles (mg) 2.4 2.4 2.4
BC/LA (mg) 2.6 2.6 2.6
Glans penis (mg) 1.8 1.8 1.8
Cowper's glands (mg) 1.4 1.4 1.4
p,p'-DDE
(mg/kg/day)
Lab 30 100
2 Starting body wt (g) 230.7 228.4
Terminal body wt (g) 317.3 303.3
Ventral prostate (mg) 93.6 * 51.5 *
Seminal vesicles (mg) 256.0 * 88.3 *
BC/LA (mg) 458.5 * 300.4 *
Glans penis (mg) 73.6 63.0 *
Cowper's glands (mg) 23.7 17.4 *
4 Starting body wt (g) 222.5 224.0
Terminal body wt (g) 293.2 289.4
Ventral prostate (mg) 74.7 * 48.7 *
Seminal vesicles (mg) 156.8 * 82.7 *
BC/LA (mg) 395.1 * 301.5 *
Glans penis (mg) 76.2 66.7 *
Cowper's glands (mg) 24.2 12.3 *
5 Starting body wt (g) 233.0 232.8
Terminal body wt (g) 323.6 307.3 *
Ventral prostate (mg) 141.8 77.6 *
Seminal vesicles (mg) 326.1 148.1 *
BC/LA (mg) 490.9 291.3 *
Glans penis (mg) 74.0 60.8 *
Cowper's glands (mg) 32.6 20.2 *
6 Starting body wt (g) 217.0 218.2
Terminal body wt (g) 274.7 273.0
Ventral prostate (mg) 71.7 * 52.5 *
Seminal vesicles (mg) 164.5 75.1 *
BC/LA (mg) 309.0 209.9 *
Glans penis (mg) 65.0 56.6 *
Cowper's glands (mg) 15.4 * 11.0 *
7 Starting body wt (g) 174.2 173.8
Terminal body wt (g) 238.0 235.8
Ventral prostate (mg) 89.6 56.5 *
Seminal vesicles (mg) 231.6 152.0 *
BC/LA (mg) 408.2 311.9 *
Glans penis (mg) 66.9 52.0 *
Cowper's glands (mg) 25.9 17.0 *
Log-transformed
2 Ventral prostate (mg) 2.0 1.7 *
Seminal vesicles (mg) 2.4 1.9 *
BC/LA (mg) 2.7 * 2.5 *
Glans penis (mg) 1.9 1.8 *
Cowper's glands (mg) 1.4 1.2 *
4 Ventral prostate (mg) 1.9 * 1.7 *
Seminal vesicles (mg) 2.2 * 1.9 *
BC/LA (mg) 2.6 * 2.5 *
Glans penis (mg) 1.9 1.8 *
Cowper's glands (mg) 1.4 1.1 *
5 Ventral prostate (mg) 2.1 1.9 *
Seminal vesicles (mg) 2.5 2.2 *
BC/LA (mg) 2.7 2.5 *
Glans penis (mg) 1.9 1.8 *
Cowper's glands (mg) 1.5 1.3 *
6 Ventral prostate (mg) 1.8 * 1.7 *
Seminal vesicles (mg) 2.2 * 1.9 *
BC/LA (mg) 2.5 2.3 *
Glans penis (mg) 1.8 1.7 *
Cowper's glands (mg) 1.2 * 1.0 *
7 Ventral prostate (mg) 1.9 1.7 *
Seminal vesicles (mg) 2.4 2.2 *
BC/LA (mg) 2.6 2.5 *
Glans penis (mg) 1.8 1.7 *
Cowper's glands (mg) 1.4 * 0.2 *
* Significantly different from vehicle control at p < 0.05.
Table 8. Overall mean organ weights, [R.sup.2], and CV in rats given
0.2 mg/kg/day TP and p,p'-DDE: data and log-transformed data.
[R.sup.2] p,p'-DDE
(%) (mg/kg/day)
0 3
Overall means TRT LAB CV (%) (n = 30) (n = 30)
Overall
Ventral prostate (mg) 36 32 20 120.6 110.9
Seminal vesicles (mg) 45 31 19 300.8 278.0
BC/LA (mg) 37 42 10 460.0 465.8
Glans penis (mg) 30 37 7 72.8 71.9
Cowper's glands (mg) 33 29 19 27.7 26.4
Log-transformed
Ventral prostate (mg) 48 23 4.4 2.1 2.0
Seminal vesicles (mg) 59 20 3.7 2.5 2.4
BC/LA (mg) 40 43 1.7 2.7 2.7
Glans penis (mg) 31 35 1.8 1.9 1.9
Cowper's glands (mg) 40 25 6.3 1.4 1.4
p,p'-DDE (mg/kg/day)
10 30 100
Overall means (n = 30) (n = 30) (n = 30)
Overall
Ventral prostate (mg) 117.2 94.3 57.3
Seminal vesicles (mg) 296.5 227.0 109.2
BC/LA (mg) 442.9 412.3 283.0
Glans penis (mg) 71.5 71.1 59.8
Cowper's glands (mg) 26.4 24.4 15.6
Log-transformed
Ventral prostate (mg) 2.1 2.0 1.7
Seminal vesicles (mg) 2.5 2.3 2.0
BC/LA (mg) 2.6 2.6 2.4
Glans penis (mg) 1.9 1.9 1.8
Cowper's glands (mg) 1.4 1.4 1.2
Abbreviations: TRT [R.sup.2] values far effects of treatments;
LAB, [R.sup.2] values for effects among laboratories.
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A drug or other substance not containing a steroid. antiandrogens. J Steroid Biochem 15:355-359. Yamada T, Sunami O, Kunimatsu T, Kamita Y, Okuno Y, Seki T, et al. 2000. Dissection and weighing of accessory sex glands sex gland n. A testis or an ovary; a gonad. after formalin fixation, and a 5-day assay using young mature rats are reliable and feasible in the Hershberger assay. Toxicology 162:103-119. Yamasaki K, Sawaki M, Noda S, Muroi T, Takatsuki M. 2001. Preputial separation and glans penis changes in normal growing Crj:CD(SD) IGS IGS - Internet Go Server. rats. Reprod Toxicol 15:533-535. Yamasaki K, Sawaki M, Noda S, Takatsuki M. 2002. Uterotrophic and Hershberger assays for n-butylbenzene in rats. Arch Toxicol 75:703-706. Yamasaki K, Takeyoshi M, Yakabe Y, Sawaki M, Imatanaka M, Shinoda K, et al. 2003. Immature immature /im·ma·ture/ (im?ah-chldbomacr´) unripe or not fully developed. im·ma·ture adj. Not fully grown or developed. immature unripe or not fully developed. rat uterotrophic assay of 18 chemicals and Hershberger assay of 30 chemicals. Toxicology 183:95-115. Kanji (human language, character) kanji - /kahn'jee/ (From the Japanese "kan" - the Chinese Han dynasty, and "ji" - glyph or letter of the alphabet. Not capitalised. Plural "kanji") The Japanese word for a Han character used in Japanese. Yamasaki, (1) Masakuni Sawaki, (1) Ryo Ohta, (2) Hirokazu Okuda, (3) Seiichi Katayama, (4) Tomoya Yamada, (5) Takafumi Ohta, (6) Tadashi Kosaka, (7) and William Owens People named William Owens include:
(1) Chemicals Evaluation and Research Institute, Oita, Japan; (2) Food Drug Safety Center, Kanagawa, Japan; (3) Japan Bioassay Research Center, Kanagawa, Japan; (4) Mitsubishi Chemical Safety Institute, Ibaraki, Japan; (5) Sumitomo Chemical Company, Osaka, Japan; (6) Panapham Laboratories Co., Ltd., Kumamoto, Japan; (7) Institute of Environmental Toxicology, Ibaraki, Japan; (8) Environmental Health and Safety Division, Organisation for Economic Co-operation and Development, Paris, France Address correspondence to K. Yamasaki, Chemicals Assessment Center, Chemicals Evaluation and Research Institute, 3-822, Ishii, Hita, Oita 087-0061, Japan. Telephone: 81-973-24-7211. Fax: 81-97323-9800. E-mail: yamasaki-kanji@ceri.jp This study was supported by grants from the Ministry of Economy, Trade, and Industry; the Ministry of Health, Labour, and Welfare; and the Ministry, of the Environment in Japan. The authors declare they have no competing financial interests. Received 27 March 2003; accepted 10 September 2003. |
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