Effects of norepinephrine and glyceryl trinitrate on cerebral haemodynamics: transcranial Doppler study in healthy volunteers.

BACKGROUND: The effects of vasoactive substances on cerebral haemodynamics are not fully known. We studied the effects of norepinephrine and glyceryl trinitrate (GTN) on cerebral haemodynamics in healthy volunteers. METHODS: The effects of norepinephrine (n=10) and GTN (n=10) on the middle cerebral artery flow velocity (MCAFV), cerebral autoregulation, reactivity to carbon dioxide, and estimated cerebral perfusion pressure (eCPP) were studied using transcranial Doppler ultrasound. Established methods were used for calculating zero flow pressure (ZFP). Measurements were made at baseline, and after i.v. infusion of the study drug to the endpoints of 25% increase in mean arterial pressure (MAP) for norepinephrine (0.02-0.1 microg kg(-1) min(-1)), or 15% decrease in MAP for GTN (0.5-2.5 microg kg(-1) min(-1)). RESULTS: The MCAFV remained unchanged with norepinephrine, but decreased slightly with GTN {from [median (inter-quartile range)] 53 (38, 62) to 48 (33, 52) cm s(-1)}. Cerebrovascular reactivity did not change significantly with either drug. The eCPP did not change significantly with norepinephrine, but increased significantly with GTN [from 49 (32, 54) to 62 (47, 79) mm Hg]. ZFP increased with norepinephrine [from 39 (28, 48) to 56 (46, 62) mm Hg] and decreased with GTN [from 35 (30, 49) to 12 (-7, 20) mm Hg]. CONCLUSIONS: Norepinephrine, despite increasing arterial pressure, did not increase the eCPP. The eCPP increased significantly with GTN, despite decreased MAP. Cerebral vascular tone is an important determinant of CPP during pharmacologically induced changes in arterial pressure.

Effects of ephedrine, dobutamine and dopexamine on cerebral haemodynamics: transcranial Doppler studies in healthy volunteers.

BACKGROUND: Sympathomimetic drugs are assumed to have no direct effects on cerebral haemodynamics on the basis of animal experiments; there is little evidence of their direct effects in humans. This study aimed to address this issue. METHODS: The effects of ephedrine, dobutamine, and dopexamine on cerebral autoregulation, cerebral vascular reactivity to carbon dioxide, estimated cerebral perfusion pressure, and zero flow pressure (ZPF) were studied in 10 healthy volunteers using transcranial Doppler ultrasound. The strength of autoregulation was measured using the transient hyperaemic response test. The reactivity to carbon dioxide was measured as the change in middle cerebral artery flow velocity with a step change in end-tidal carbon dioxide. For the estimated cerebral perfusion pressure and the ZFP, established formulae were used which utilized instantaneous values of arterial pressure and middle cerebral artery flow velocity. Measurements were made at baseline and after i.v. infusion of the study drug to an endpoint of 25% increase in mean arterial pressure (MAP) (ephedrine, dobutamine) or cardiac index (dopexamine). RESULTS: There was no significant change in the strength of autoregulation (from (mean (SD)) 1.07 (0.16) to 1.07 (0.18); from 1.07 (0.16) to 1.03 (0.19); from 1.04 (0.12) to 1.04 (0.25)), reactivity to carbon dioxide (from 40% (8) to 36 (10); from 37 (12) to 37 (11); from 45 (12) to 43 (11)) with ephedrine, dobutamine, or dopexamine, respectively. Despite a clinically significant increase in MAP with ephedrine and dobutamine and a clinically significant increase in cardiac index with dopexamine, the estimated cerebral perfusion pressure did not change significantly (from 81 (38) to 60 (16) mm Hg with ephedrine; from 67 (22) to 63 (11) mm Hg with dobutamine; from 87 (27) to 79 (17) mm Hg with dopexamine). The ZFP increased significantly with ephedrine (from 29 (10) to 44 (11) mm Hg) and dobutamine (from 35 (14) to 43 (10) mm Hg) but not dopexamine (from 3 (23) to 11 (22) mm Hg). CONCLUSIONS: Sympathomimetic agents do not significantly change cerebrovascular homeostasis as assessed by the transient hyperaemic response test, reactivity to carbon dioxide and estimated cerebral perfusion pressure.

Determination of the human cytochrome P450 isoforms involved in the metabolism of zolmitriptan.

1. Zolmitriptan was extensively metabolized by freshly isolated human hepatocytes to a number of components including the three main metabolites observed in vivo (N-desmethyl-zolmitriptan, zolmitriptan N-oxide and the indole acetic acid derivative). In contrast, metabolism of zolmitriptan by human hepatic microsomes was extremely limited with only small amounts of the N-desmethyl and indole ethyl alcohol metabolites being produced. 2. Furafylline, a selective inhibitor of CYP1A2, almost completely abolished the hepatocellular metabolism of zolmitriptan and markedly inhibited formation of the N-desmethyl metabolite in microsomes. Chemical inhibitors, selective against other major human cytochrome P450 (CYP2C9, 2C19, 2D6 and 3A4), had no obvious effects. In addition, expressed human CYP1A2 was the only cytochrome P450 to form the N-desmethyl metabolite. 3. N-desmethyl-zolmitriptan was extensively metabolized by both human hepatocytes and microsomes. The indole acetic acid and ethyl alcohol derivatives were the major metabolites formed by hepatocytes, whereas only the indole ethyl alcohol derivative was produced by microsomes. Metabolism of N-desmethyl-zolmitriptan was not inhibited by cytochrome P450-selective chemical inhibitors nor was it observed following incubation with expressed human cytochrome P450. Clorgyline, a selective inhibitor of monoamine oxidase A (MAO-A), markedly inhibited the microsomal formation of the indole ethyl alcohol derivative. 4. Primary metabolism of zolmitriptan is dependent mainly on CYP1A2, whereas MAO-A is responsible for further metabolism of N-desmethyl-zolmitriptan, the active metabolite. Since the in vivo clearance of zolmitriptan is primarily dependent on metabolism, interactions with drugs that induce or inhibit CYP1A2 or MAO-A may be anticipated.

Effects of propofol on human hepatic microsomal cytochrome P450 activities.

1. The potential of propofol to inhibit the activity of major human cytochrome P450 enzymes has been examined in vitro using human liver microsomes. Propofol produced inhibition of CYP1A2 (phenacetin O-deethylation), CYP2C9 (tolbutamide 4'-hydroxylation), CYP2D6 (dextromethorphan O-demethylation) and CYP3A4 (testosterone 6beta-hydroxylation) activities with IC50 = 40, 49, 213 and 32 microM respectively. Ki for propofol against all of these enzymes with the exception of CYP2D6, where propofol showed little inhibitory activity, was 30, 30 and 19 microM respectively for CYPs 1A2, 2C9 and 3A4. 2. Furafylline, sulphaphenazole, quinidine and ketoconazole, known selective inhibitors of CYPs 1A2, 2C9, 2D6 and 3A4 respectively, were much more potent than propofol having IC50 = 0.8, 0.5, 0.2 and 0.1 microM; furafylline and sulphaphenazole yielded Ki = 0.6 and 0.7 microM respectively. 3. The therapeutic blood concentration of propofol (20 microM; 3-4 microg/ml) together with the in vitro Ki estimates for each of the major human P450 enzymes have been used to estimate the extent of cytochrome P450 inhibition, which may be produced in vivo by propofol. This in vitro-in vivo extrapolation indicates that the degree of inhibition of CYP1A2, 2C9 and 3A4 activity which could theoretically be produced in vivo by propofol is relatively low (40-51%); this is considered unlikely to have any pronounced clinical significance. 4. Although propofol has now been used in > 190 million people since its launch in 1986, there are only single reports of possible drug interactions between propofol and either alfentanil or warfarin. Consequently, it is difficult to conclude from either the published literature or the ZENECA safety database whether there is any evidence to indicate that propofol produces clinically significant drug interactions through inhibition of cytochrome P450-related drug metabolism.

Drug interactions with zidovudine phosphorylation in vitro.

We have investigated the effect of a range of drugs (some commonly coadministered with zidovudine [ZDV] to human immunodeficiency virus-positive patients) on intracellular phosphorylation of ZDV by stimulated peripheral blood mononuclear cells, Molt 4 cells, and U937 cells in vitro. Of the drugs tested (azoles, antiviral agents, antibiotics, and anticancer agents), only doxorubicin and ribavirin caused inhibition of anabolite formation as measured by high-performance liquid chromatography. This in vitro approach may provide important leads to potential interactions at the phosphorylation level in patients with human immunodeficiency virus disease. It is reassuring that so many commonly administered drugs do not alter ZDV phosphorylation.

Effects of dideoxyinosine and dideoxycytidine on the intracellular phosphorylation of zidovudine in human mononuclear cells.

1. Zidovudine (3'-azido-2',3'-dideoxythymidine; AZT; ZDV) is a dideoxynucleoside analogue active against human immunodeficiency virus (HIV). We are currently investigating the intracellular metabolism of ZDV to its putative active triphosphate form (ZDV triphosphate) in peripheral blood mononuclear cells and a lymphoblastoid cell line (h1A2v2). 2. Optimal conditions for intracellular phosphate formation in peripheral blood mononuclear cells occurred following a 72 h preincubation with the mitogen phytohaemagglutinin at a concentration of 10 micrograms ml-1. ZDV was metabolized predominantly to the monophosphate with smaller amounts of the di- and triphosphate anabolites. There was considerable inter- and intraindividual variability in phosphate formation in peripheral blood mononuclear cells. A similar pattern of phosphorylation was seen with the h1A2v2 lymphoblastoid cell line with ZDV monophosphate being the major metabolite. 3. With increasing interest in combination nucleoside analogue therapy in HIV-positive patients it is important to know if an interaction occurs at the level of phosphorylation. Neither dideoxyinosine (ddI) or dideoxycytidine (ddC) significantly reduced the intracellular phosphorylation of ZDV in either peripheral blood mononuclear cells or h1A2v2 cells. In contrast thymidine always gave marked inhibition (e.g. at 2.0 microM, 89% inhibition of total phosphate formation in peripheral blood mononuclear cells and 79% in h1A2v2 cells). It is, therefore, unlikely that in vivo either ddI or ddC will perturb ZDV phosphorylation.

Metabolism of the oral contraceptive steroids ethynylestradiol, norgestimate and 3-ketodesogestrel by a human endometrial cancer cell line (HEC-1A) and endometrial tissue in vitro.

Human endometrial cancer cells and human endometrial tissue have been extensively used to study steroid hormone action and metabolism. The natural estrogens estradial (E2) and estrone (E1) are known to be metabolized by both cells and tissue with the interconversion of the two steroids and the formation of sulphate conjugates. The aim of the present work was to see if the commonly used oral contraceptive steroids ethynylestradiol (EE2), norgestimate (Ngmate) and 3-ketodesogestrel (3-KDG) were metabolized by a human endometrial cancer cell line (HEC-1A) and human endometrial tissue in vitro. Metabolites were analysed by on-line radiometric HPLC. Endometrial tissue was obtained from women undergoing dilation and curettage or hysterectomy operations. In preliminary studies with endogenous estrogens, HEC-1A cells were able to interconvert E1 and E2; the equilibrium favouring the formation of E2. Normal endometrial tissue extensively converted E2 to E1, tumour tissue appeared to catalyse this reaction much less avidly. In addition sulphate conjugates were formed by normal tissue from some patients. Cell line and endometrial tissue was able to hydrolyse estrone 3-sulphate. With EE2 as substrate there was no evidence of phase I metabolism by cell line or tissue. However, conversion to the presumed 3-sulphate conjugate was observed following incubation with normal tissue from some women. Deacetylation of the progestogen Ngmate to norgestrel oxime (NgOx) was complete within 24 h. There was also some loss of the oxime moiety to give norgestrel (Ng) following incubation with HEC-1A cells. Metabolism of Ngmate was also complete within 24 h following incubation with endometrial tissue. There were both qualitative and quantitative differences in metabolite formation between tissue obtained from different women. In contrast, 3-KDG was relatively resistant to metabolism by cell line and tissue. The major metabolite formed by HEC-1A cells accounted for only 3.3 +/- 0.4% of total added radiolabelled steroid and co-chromatographed with 3 alpha-hydroxydesogestrel. Smaller amounts of other radiometabolites were formed. No phase I metabolites of 3-KDG were formed by normal endometrial tissue, however small amounts of radiometabolites appeared to be formed by malignant tissue. These studies have provided evidence to suggest that the oral contraceptives EE2, Ngmate and 3-KDG are metabolized in the human endometrium. Knowledge of the metabolism of these in target tissues such as the endometrium may be pertinent considering the possibility that metabolites may exert specific effects.

PIP: In England, pharmacologists and a biochemist at the University of Liverpool used an established human endometrial cancer cell line (HEC-1A) and human endometrial tissue in vitro to confirm that HEC-1A and tissue metabolize oral contraceptive (OC) steroids. They used on-line radiometric high-performance liquid chromatography to analyze metabolic activity. Surgeons obtained the endometrial tissue from women undergoing dilatation and curettage or hysterectomy at the Royal Liverpool University Hospital. Earlier research showed that HEC-1A cells interconvert estrone (E1) and 17 beta-estradiol (E2), with E2 predominating in the equilibrium. In this in vitro study, healthy endometrial tissue extensively changed E2 to E1, while malignant tissue caused this conversion to a much lesser extent. The healthy endometrial tissue of some patients formed sulphate conjugates. Both HEC-1A and endometrial tissue hydrolyzed E1 3-sulphate. They did not bring about phase I metabolism when ethinyl estradiol (EE2) was the substrate. Yet, incubation with healthy tissue from some women did lead to conversion of the presumed 3-sulphate conjugate. Incubation with HEC-1A cells completely removed the acetyl group from norgestimate, resulting in mainly norgestrel oxime (55.1% of metabolites) within 24 hours. It also resulted in some norgestrel (16.3%). Incubation with endometrial tissue also brought about complete metabolism of norgestimate within 24 hours. The tissue from different women brought about qualitative and quantitative differences. HEC-1A and endometrial tissue did not metabolize much of 3-ketodesogestrel (3-KDG). In fact, the major metabolite formed by HEC-1A was 3 alpha-hydroxydesogestrel, which made up 3.3% of total added radiolabeled steroid. Healthy endometrial tissue did not produce any phase I metabolites of 3-ketodesogestrel, while tumor tissue may have produced a small amount of radiometabolites. These findings indicate that the endometrium does metabolize the OC EE2, 3-KDG, and norgestimate.

Metabolism of the oral contraceptive steroids ethynylestradiol and norgestimate by normal (Huma 7) and malignant (MCF-7 and ZR-75-1) human breast cells in culture.

Human breast cancer cells are used extensively for the study of steroid hormone action. It is known that in both receptor positive and receptor negative cell lines there is considerable metabolism of the natural estrogens, estradiol (E2) and estrone (E1) with interconversion of the two steroids and formation of sulphate and glucuronide conjugates. The aim of the present work was to see if the commonly used oral contraceptive steroids (OCS) ethynylestradiol (EE2) and norgestimate (Ngmate) were metabolized in human breast cancer cell lines (MCF-7 and ZR-75-1) and a normal breast cell line (Huma 7). MCF-7, ZR-75-1 and Huma 7 cells were maintained in Dulbeccos Modified Eagles Medium (DMEM) containing foetal calf serum (FCS) insulin and hydrocortisone. In addition, ZR-75-1 cells required epidermal growth factor (EGF) and E2 while MCF-7 cells required only EGF. On reaching confluence cells were transferred to DMEM containing charcoal-stripped FCS, insulin and hydrocortisone. 48 h later this medium was renewed, radiolabelled steroid ([3H]E1; [3H]E2; [3H]EE2, [3H]Ngmate; [3H]E1-SO4; 1 nM; 0.2 microCi) was added and incubation was for 24 or 48 h. Following incubation, the medium was removed and radioactive steroid extracted with ether. Metabolites were analysed by on-line radiometric HPLC. All the cell lines were able to interconvert E1 and E2; the equilibrium favouring the formation of E2 in MCF-7 and ZR-75-1 and E1 in Huma 7 cells. E1 and E2 also underwent phase II metabolism to form their respective estrogen sulphates, this activity being most marked in the Huma 7 cell line. In addition to sulphotransferase activity, the study with E1 sulphate demonstrated sulphatase activity in both normal and cancer cells. There appeared to be no difference in extent of hydrolysis, with both E1 and E2 formed. With EE2 as substrate there was no evidence of phase I metabolism in any of the cell lines but there was conversion to the presumed 3-sulphate conjugate. The percentage formation of this metabolite was very much greater in Human 7 cells (64.1 +/- 9.6% after 24 h) than in MCF-7 and ZR-75-1 cells (7.4 +/- 5.3% and 10.6 +/- 4.1%, respectively after 24 h). In all the cell lines deacetylation of the progestogen Ngmate to norgestrel oxime was complete within 24 h. In addition there was evidence of loss of the oxime moiety to give norgestrel.(ABSTRACT TRUNCATED AT 400 WORDS)