Active pharmaceutical ingredients detected in herbal food supplements for weight loss sampled on the Dutch market.

Herbal food supplements claiming to reduce weight may contain active pharmacological ingredients (APIs) that can be used for the treatment of overweight and obesity. The aim of this study was to determine whether herbal food supplements for weight loss on the Dutch market contain APIs with weight loss properties. Herbal food supplements intended for weight loss (n = 50) were sampled from August 2004 to May 2013. An HPLC-DAD-MS/MS method was used to screen for the presence of the APIs in herbal supplements. In 24 samples the APIs sibutramine, desmethylsibutramine (DMS), didesmethylsibutramine (DDMS), rimonabant, sildenafil and/or the laxative phenolphthalein were identified 41 times. The presence of these APIs was, however, not stated on the label. The potential pharmacological effects of the detected APIs were estimated using data from reported effective doses of approved drugs. Use of 20 of the 24 herbal food supplements may result in potential pharmacological effects. Furthermore, risk assessment of phenolphthalein, a suspected carcinogen and found to be present in 10 supplements, based on the margin of exposure (MOE) approach, resulted in MOE values of 96-30,000. MOE values lower than 10,000 (96-220) were calculated for the daily intake levels of four out of these 10 supplements in which phenolphthalein was found. However, taking into account that weight loss preparations may be used for only a few weeks or months rather than during a lifetime, MOE values may be two to three orders of magnitude higher. The current study shows that the use of food supplements with sibutramine, DMS, DDMS and/or phenolphthalein could result in pharmacological effects.

Evaluation of phenolphthalein, diazepam and quinacrine dihydrochloride in the in vitro mammalian cell micronucleus test in Chinese hamster ovary (CHO) and TK6 cells.

The in vitro micronucleus assay has been extensively used as an in vitro screening tool to identify test articles that might have aneugenic or clastogenic potential. Currently, the Organization for Economic Co-operation and Development (OECD) is working towards a final version of the guideline for the conduct of the in vitro mammalian cell micronucleus Test (MNvit). A few questions regarding appropriate cytotoxicity measurements and cytotoxicity limits to use remain to be answered. In order to resolve the remaining questions, we compared the induction of micronuclei at the top dose (50-60% cytotoxicity) determined by either Relative Cell Counts (RCC), Relative Increase in Cell Counts (RICC), Relative Population Doublings (RPD), or Cytokinesis-Blocked Proliferating Index (CBPI) using weak and strong inducers of micronuclei in both the presence and absence of cytochalasin B (CYB) in Chinese hamster ovary (CHO) and human lymphoblastoid TK6 cells. In order to assess extensive dose-response relationships, we selected expected weak (diazepam, phenolphthalein, quinacrine dihydrochloride dihydrate) and strong (cytosine arabinoside, mitomycin C, vinblastine sulphate) inducers of micronuclei with a variety of different mechanisms of action for testing. The results clearly demonstrated that all six compounds produced positive responses using either cytotoxicity measurement. The outcome from these studies further supports the cytotoxicity measurements and cytotoxicity limits proposed in the draft OECD guideline.

The toxicology and carcinogenesis study of phenolphthalein (CAS No. 77-09-8) in genetically modified haploinsufficient p16(Ink4a)/p19(Arf) mice (feed study).

UNLABELLED: Phenolphthalein was commonly used as a laxative for most of the 20th century. The use of phenolphthalein in laxatives has decreased since 1997 when the United States Food and Drug Administration (FDA) proposed to withdraw its classification as an over-the-counter drug (21 CFR, Part 310). Phenolphthalein has been previously evaluated in 2-year carcinogenicity studies by the National Toxicology Program (1996). The major route of human exposure to phenolphthalein is via ingestion, dermal contact, and inhalation of contaminated air originating from process units manufacturing the compound. In this study, the carcinogenic effects of phenolphthalein were studied in the haploinsufficient p16(Ink4a)/p19(Arf) mouse model as an ongoing goal of the NTP is to seek model systems for toxicology and carcinogenesis studies, especially those that can provide mechanistic information relative to understanding an agent's mode of action. Male and female haploinsufficient p16(Ink4a)/p19(Arf) mice were exposed to phenolphthalein (greater than 97% pure) in feed for 27 weeks. Genetic toxicology studies were conducted in mouse peripheral blood erythrocytes. 27-WEEK STUDY IN MICE: Groups of 15 male and 15 female mice were exposed to 0, 200, 375, 750, 3,000, or 12,000 ppm phenolphthalein (equivalent to average daily doses of approximately 35, 65, 135, 540, and 2,170 mg phenolphthalein/kg body weight to males and 50, 90, 170, 680, 2,770 mg/kg to females) in feed for 27 weeks. Survival of all exposed groups of male and female mice was similar to that of the control groups. Mean body weights of males in the 12,000 ppm group were less than those of the control group after week 11. No differences in feed consumption were noted between exposed and control groups. Atypical hyperplasia of the thymus, a premalignant change of chemically induced thymic lymphoma, occurred in exposed males and females, and the incidence was significantly increased in 12,000 ppm females. Atrophy of the seminiferous tubules in the testis, hyperplasia of the testicular interstitial (Leydig) cells, and epididymal hypospermia occurred in most 3,000 and 12,000 ppm males. Additionally, the left and right testis weights, the left epididymis weights, sperm motility, the numbers of spermatid heads per testis, and sperm heads per cauda and per gram cauda epididymis were generally significantly less in 3,000 and 12,000 ppm males than in the control group. The incidences of nephropathy were significantly increased in 3,000 and 12,000 ppm males; incidences of hypertrophy of renal tubules were significantly increased in males receiving 750 ppm or greater. Hematopoietic cell proliferation of the spleen occurred in all 12,000 ppm males, and the incidences of this lesion were significantly increased in 375, 750, and 12,000 ppm females. GENETIC TOXICOLOGY: The frequency of micronucleated erythrocytes was assessed at four time points during the 27-week study in male and female haploinsufficient p16(Ink4a)/p19(Arf) mice. Significant concentration-related increases in micronucleated cells were observed at all time points in male and female mice. CONCLUSIONS: Under the conditions of this 27-week feed study, there was no evidence of carcinogenic activity of phenolphthalein in male or female haploinsufficient p16(Ink4a)/p19(Arf) mice exposed to 200, 375, 750, 3,000, or 12,000 ppm. Because this is a new model, there is uncertainty whether the study possessed sufficient sensitivity to detect a carcinogenic effect. Phenolphthalein induced atypical hyperplasia, a preneoplastic lesion of the thymus, in male and female mice, hematopoietic cell proliferation of the spleen in male and female mice, and toxicity to the kidney and reproductive system in male mice.

Phenolphthalein and bisacodyl: assessment of genotoxic and carcinogenic responses in heterozygous p53 (+/-) mice and syrian hamster embryo (SHE) assay.

Phenolphthalein (800 and 2400 mg/kg/day by gavage and 2400 mg/kg/day by diet) and bisacodyl (800-500, 4000-2000, and 8000 mg/kg/day by gavage) were administered to 15 male and 15 female and 20 male and 20 female p53(+/-) mice respectively for 26 weeks to investigate the potential carcinogenicity of each compound. Toxicokinetic analyses confirmed systemic exposure. p-Cresidine was administered by gavage (400 mg/kg/day) and served as the positive control agent in each study. Dietary phenolphthalein reduced survival in both sexes and early deaths were attributed to thymic lymphoma. No bisacodyl-related neoplasms were observed. Regardless of route of administration to p53(+/-) mice, phenolphthalein but not bisacodyl was unequivocally genotoxic, causing increased micronuclei in polychromatic erythrocytes. In the Syrian hamster embryo (SHE) cell transformation assay, phenolphthalein caused increases in morphologically transformed colonies, thereby corroborating NTP's earlier reports, showing phenolophthalein has potential carcinogenic activity. Bisacodyl was negative in the SHE assay. Results of these experiments confirm an earlier demonstration that dietary phenolphthalein causes thymic lymphoma in p53(+/-) mice and show that (1) phenolphthalein causes qualitatively identical results in this transgenic model regardless of route of oral administration, (2) phenolphthalein shows evidence of micronucleus induction in p53(+/-) mice for up to 26 weeks, (3) phenolphthalein induced transformations in the in vitro SHE assay, and (4) bisacodyl in p53(+/-) mice induces neither drug-related neoplasm, nor micronuclei in polychromatic erythrocytes, and did not induce transformations in the in vitro SHE assay.

Lack of susceptibility of heterozygous p53-knockout CBA and CIEA mice to phenolphthalein in a 6-month carcinogenicity study.

Phenolphthalein has carcinogenic activity, causing malignant lymphomas in B6C3F1 mice at a dietary dose of 3000 ppm in a 2-year carcinogenicity study and in female heterozygous p53-knockout TSG mice (C57BL/6 background) at the same dose in a 6-month study. To examine whether carcinogenic potential of phenolphthalein can be detected in other p53-knockout mouse [p53 (+/-)] strains such as p53 (+/-) CBA mice or p53 (+/-) CIEA mice (C57BL/6 background) and their littermates, they were given a diet containing 0, 6000 or 12000 ppm for 6 months. Unequivocal induction of neoplastic lesions was not apparent, suggesting that p53 (+/-) CBA mice and p53 (+/-) CIEA mice are resistant to the induction of malignant lymphomas by the treatment of phenolphthalein.

Possible mechanism on enhanced carcinogenesis of genotoxic carcinogens and unsolved mechanisms on lesser carcinogenic susceptibility to some carcinogens in rasH2 mice.

The rasH2 mice are hemizygous transgenic mice carrying the human prototype c-Ha-ras gene with its own promoter region, and have been used in 6-month short-term carcinogenicity tests for pharmaceutical drugs in accordance with the recommendation of the International Conference on Harmonization of Technical Requirements of Pharmaceuticals for Human Use (ICH). Based on the validation studies, it has been recognized that they are very susceptible to genotoxic carcinogens. To elucidate the mechanism of the enhanced carcinogenesis, spontaneous and chemically induced tumors in rasH2 mice have been subjected to molecular analyses, but the results have thus far been equivocal. This article focuses on the possible molecular mechanism of enhanced carcinogenesis in rasH2 mice, based on the results of a search in the literature. In addition, there are several reports suggesting lesser carcinogenic susceptibility of rasH2 mice to some carcinogens: Malignant lymphomas were induced by treatment with phenolphthalein in heterozygous p53 knockout mice, but not in rasH2 mice, and ethinylestradiol, uterine tumor promoter, resulted in depression of uterine proliferative lesions in rasH2 mice. In this review, the possible mechanisms of why rasH2 mice were less sensitive for these carcinogens are also discussed.

Tumor promoting effect of phenolphthalein on development of lung tumors induced by N-ethyl-N-nitrosourea in transgenic mice carrying human prototype c-Ha-ras gene.

In order to examine tumor modifying effects of phenolphthalein (PhP), female transgenic mice carrying human prototype c-Ha-ras gene (rasH2 mice) were given a single intraperitoneal injection of 60 mg/kg body weight of N-ethyl-N-nitrosourea (ENU), followed by the diet containing 12,000 ppm PhP for 26-week. Histopathologically, alveolar hyperplasias, adenomas and adenocarcinomas were observed in the ENU + PhP group, but only hyperplasias and adenomas were observed in the ENU alone group. The incidence and multiplicity of adenocarcinomas in the ENU + PhP group was significantly increased as compared to that in the ENU alone group. The combined multiplicity of adenomas and adenocarcinomas in this group was also significantly higher than that of the ENU alone group. In addition, the ratio of area of adenomas in the ENU + PhP group was significantly higher than that in the ENU alone group. The result of our study suggests that PhP has a clear tumor promoting effect in the lung of rasH2 mice.

New models for assessing carcinogenesis: an ongoing process.

Traditionally, the use of rodent models in assessing the carcinogenic potential of chemicals has been expensive and lengthy, and the relevance of the carcinogenic effect to humans is often not fully understood. Today, however, with the rapid advances in molecular biology, genetically altered mice containing genes relevant to humans (e.g. oncogenes, tumor suppressor genes) and reporter genes (e.g. lacI) provide powerful tools for examining specific chemical-gene interactions thereby allowing a better understanding of the mechanisms of carcinogenesis in a shorter period of time. This paper will cover an overview of ongoing validation efforts, followed by examples of studies using several genetically engineered models including the p53def mouse model and the Big Blue transgenic mouse model. Specifically, examples where transgenic models were integrated into the testing program based on specific hypotheses dealing with genetic alterations in cancer genes and reporter genes will be discussed. The examples will highlight possible ways genetically altered mice may be integrated into a comprehensive research and testing strategy and thereby provide an improved estimation of human health risks.

Chromosome 11 loss from thymic lymphomas induced in heterozygous Trp53 mice by phenolphthalein.

C57BL/6 p53 (+/-) N5 mice heterozygous for a null p53 allele were given phenolphthalein to learn more about mechanisms of carcinogenesis and to evaluate the p53-deficient mouse as a tool for identifying potential human carcinogens. DNA samples isolated from 10 phenolphthalein-induced thymic lymphomas were analyzed for loss of heterozygosity (LOH) at the Trp53 locus and simple sequence length polymorphic (SSLP) loci. The initial screening revealed remarkable results from only chromosome 11. Allelotyping at approximately five centiMorgan intervals, we found SSLP heterozygosity for C57BL/6 and 129Sv over much of chromosome 11. In the tumors, treatment-related LOH was apparent on chromosome 11 at each of the 28 informative loci examined. The strain-specific polymorphism lost from individual tumors allowed us to deduce the distribution of alleles along the length of the maternal and paternal chromosomes 11. The allelic patterns indicate that mitotic homologous recombination occurred during embryogenesis if breeding protocols were carried out as described. The mitotic recombination observed may be attributable to p53 haploinsufficiency for normal suppression of mitotic recombination.

Chromosome 11 allelotypes reflect a mechanism of chemical carcinogenesis in heterozygous p53-deficient mice.

Mice heterozygous for a null p53 allele were administered three well-characterized carcinogens to learn more about mechanisms of carcinogenesis and to evaluate the p53-deficient mouse as a tool for identifying potential human carcinogens. Benzene-induced sarcomas, p-cresidine-induced bladder carcinomas and phenolphthalein-induced thymic lymphomas were allelotyped at the Trp53 locus and chromosome 11 simple sequence length polymorphic (SSLP) loci. Loss of Trp53 and loss of one copy of chromosome 11 occurred in each of 10 lymphomas examined and each of the eight sarcomas examined. Loss of Trp53 and loss of heterozygosity (LOH) at SSLP loci were sporadic in the bladder carcinomas. However, LOH was detected at two or more SSLP loci in six of the eight bladder tumors examined. Loss of one complete copy of chromosome 11 was implicated in three of the bladder tumors where LOH occurred at seven or more widely dispersed SSLP loci. Loss of one copy of chromosome 11 likely occurred through a p53-mediated selection process since Trp53 is located on mouse chromosome 11 and only one copy harbored a functional gene. The data suggest that loss occurred through a mechanism common among the three tumor types. Allelotype patterns of the maternal chromosome 11 were inconsistent with those expected from a nullizygous C57BL/6-Trp53 (N4) x inbred C57BL/6 cross which was reported for production of the mice under investigation. However, comparison with individual control tissues still allowed deduction of maternal chromosome loss. If the breeding protocols were carried out as described, the unexpected allelotype patterns observed in histologically normal tissues might be due to mitotic homologous recombination during embryogenesis.

Loss of heterozygosity frequency at the Trp53 locus in p53-deficient (+/-) mouse tumors is carcinogen-and tissue-dependent.

Mutagenic carcinogens rapidly induced tumors in the p53 haploinsufficient mouse. Heterozygous p53-deficient (+/-) mice were exposed to different mutagenic carcinogens to determine whether p53 loss of heterozygosity (LOH) was carcinogen-and tissue-dependent. For 26 weeks, C57BL/6 (N4) [corrected] p53-deficient (+/-) male or female mice were exposed to p-cresidine, benzene or phenolphthalein. Tumors were examined first for loss of the wild-type p53 allele. p-cresidine induced p53 LOH in three of 13 bladder tumors, whereas hepatocellular tumors showed p53 LOH in carcinomas (2/2), but not in adenomas (0/3). Benzene induced p53 LOH in 13 of 16 tumors examined. Finally, phenolphthalein induced p53 LOH in all tumors analyzed (21/21). Analysis of the p-cresidine-induced bladder tumors by cold single-strand conformation polymorphism (SSCP) analysis of exon 4-9 amplicons failed to demonstrate polymorphisms associated with mutations in tumors that retained the p53 wild-type allele. p-cresidine induced a dose-related increase in lacI mutations in bladder DNA. In summary, these data demonstrate that loss of the wild-type allele occurred frequently in thymic lymphomas and sarcomas, but less frequently in carcinomas of the urinary bladder. In the bladder carcinomas other mechanisms may be operational. These might include (i) other mechanisms of p53 inactivation, (ii) inactivating mutations occurring outside exons 4-9 or (iii) p53 haploinsufficiency creating a condition that favors other critical genetic events which drive bladder carcinogenesis, as evidenced by the significant decrease in tumor latency. Understanding the mechanisms of p53 LOH and chemical carcinogenesis in this genetically altered model could lead to better models for prospective identification and understanding of potential human carcinogens and the role of the p53 tumor suppressor gene in different pathways of chemical carcinogenesis.

Evaluation of the TOPKAT system for predicting the carcinogenicity of chemicals.

The TOPKAT computer-based system for predicting chemical carcinogens was evaluated by determining its ability to predict the carcinogenicity of chemicals tested by the National Toxicology Program. TOPKAT was not effective in identifying potential rodent carcinogens and noncarcinogens in the data set analyzed. The chemicals in the TOPKAT database of known carcinogens and noncarcinogens that the software identifies as most "similar" to unknown chemicals are illustrated using six examples. These "similar" chemicals generally bear no apparent relationship to the chemical of interest with regard to metabolism or potential mechanism of carcinogenicity. Environ. Mol. Mutagen. 37:55-69, 2001 Published 2001 Wiley-Liss, Inc.

Induction of chromosome aberrations in vitro by phenolphthalein: mechanistic studies.

Phenolphthalein induces tumors in rodents but because it is negative in assays for mutation in Salmonella and in mammalian cells, for DNA adducts and for DNA strand breaks, its primary mechanism does not seem to be DNA damage. Chromosome aberration (Ab) induction by phenolphthalein in vitro is associated with marked cytotoxicity. At very high doses, phenolphthalein induces weak increases in micronuclei (MN) in mouse bone marrow; a larger response is seen with chronic treatment. All this suggests genotoxicity is a secondary effect that may not occur at lower doses. In heterozygous TSG-p53((R)) mice, phenolphthalein induces lymphomas and also MN, many with kinetochores (K), implying chromosome loss. Induction of aneuploidy would be compatible with the loss of the normal p53 gene seen in the lymphomas. Here we address some of the postulated mechanisms of genotoxicity in vitro, including metabolic activation, inhibition of thymidylate synthetase, cytotoxicity, oxidative stress, DNA damage and aneuploidy. We show clearly that phenolphthalein does not require metabolic activation by S9 to induce Abs. Inhibition of thymidylate synthetase is an unlikely mechanism, since thymidine did not prevent Ab induction by phenolphthalein. Phenolphthalein dramatically inhibited DNA synthesis, in common with many non-DNA reactive chemicals that induce Abs at cytotoxic doses. Phenolphthalein strongly enhances levels of intracellular oxygen radicals (ROS). The radical scavenger DMSO suppresses phenolphthalein-induced toxicity and Abs whereas H(2)O(2) potentiates them, suggesting a role for peroxidative activation. Phenolphthalein did not produce DNA strand breaks in rat hepatocytes or DNA adducts in Chinese hamster ovary (CHO) cells. All the evidence points to an indirect mechanism for Abs that is unlikely to operate at low doses of phenolphthalein. We also found that phenolphthalein induces mitotic abnormalities and MN with kinetochores in vitro. These are also enhanced by H(2)O(2) and suppressed by DMSO. Our findings suggest that induction of Abs in vitro is a high-dose effect in oxidatively stressed cells and may thus have a threshold. There may be more than one mechanism operating in vitro and in vivo, possibly indirect genotoxicity at high doses and also chromosome loss, both of which would likely have a threshold.

Toxicokinetics of phenolphthalein in male and female rats and mice.

Phenolphthalein (PTH), which has been used as the active ingredient in a number of prescription and over-the-counter laxative products, is a rodent chemical carcinogen in multiple organs in the NTP 2-year bioassay at doses of 291-2927 mg/kg. This paper describes the toxicokinetics and estimates the internal dose of PTH administered as a single iv or gavage dose, or ad libitum for 14 days in feed to F344 rats, B6C3F1 mice, p53 (+/-) mice, and C57BL mice at doses that bracketed those used in the bioassay. Plasma concentrations for free phenolphthalein (PTH-F) and phenolphthalein glucuronide (PTH-G) were obtained for each dose regimen. Total phenolphthalein (PTH-T) was calculated as the sum of the molar concentrations of PTH-F and PTH-G. Noncompartmental pharmacokinetic models were used to calculate the area under the curve (AUC) from 0 h to infinity (AUC(infinity)), clearance (Cl), and oral bioavailability (F) for PTH-F; and were used to calculate AUC(infinity), t((1/2)), and relative absorption (Q) for PTH-T. After iv administration, PTH-F rapidly declined in rats and mice; PTH-T rose rapidly to Cmax and slowly declined 6-8 h after dosing, with no sex-related differences for rats or mice. For feed studies, mean plasma concentration (f1.gif" BORDER="0">(infinity)) and 24-h area under the curve (AUC(24h)) values were calculated. Results from feed studies showed no dose response in rat plasma PTH-F above approximately 50 mg/kg. Rat PTH-T AUC(24h) and f1.gif" BORDER="0">(infinity) were linear with doses up to approximately 650 mg/kg. In B6C3F1 mice, PTH-F and PTH-T AUC(24h) increased nonlinearly with doses above approximately 165 mg/kg. PTH is well absorbed and readily converted to PTH-G when administered in feed to rats and mice, except at the highest bioassay doses, where PTH absorption may be saturated.

Phenolphthalein induces chromosome aberrations in human and Chinese hamster liver cells (CHEL) cultured in vitro.

Phenolphthalein is a nonprescription laxative agent that has been widely used during this century. Recent studies in animal models have shown that phenolphthalein has carcinogenic activity. In order to assess cytogenetic effects on human cells in vitro, we tested phenolphthalein in a chromosome aberration assay in human embryo cells derived from amniotic fluid. Our results show that phenolphthalein induces a significant increase in the frequency of chromosome aberrations in human cells. The lowest dose level at which the clastogenic effect is evident is 23.2 microg/ml. Similar positive results were obtained in a Chinese hamster liver cell line, which is metabolically competent to activate different classes of promutagens and procarcinogens into biologically active metabolites. Instead, parallel experiments in Chinese hamster ovary cells did not show any clastogenic effect due to phenolphthalein. These latter data suggested that phenolphthalein acts as a promutagen and must be metabolically activated to exert its clastogenic effect. Teratogenesis Carcinog. Mutagen. 20:209-217, 2000.

Lack of susceptibility of transgenic mice carrying the human c-Ha-ras proto-oncogene (rasH2 mice) to phenolphthalein in a 6-month carcinogenicity study.

Phenolphthalein has carcinogenic activity, causing malignant lymphomas in B6C3F1 mice at a dietary dose of 3000 ppm in a 2-year carcinogenicity study and in heterozygous p53-deficient female mice at the same dose in a 6-month study. To examine whether phenolphthalein carcinogenic potential can be detected in male and female transgenic (Tg) mice carrying the human c-Ha-ras gene (rasH2 mice) and their wild-type littermates (non-Tg mice), a diet containing 3000, 6000 or 12000 ppm was given for 6 months. Unequivocal induction of neoplastic lesions was not apparent, suggesting that rasH2 mice are resistant to the induction of malignant lymphomas by the treatment of phenolphthalein.