M. Orme

Clinical pharmacokinetics of oral contraceptive steroids.

SummaryOral contraceptive steroids are of 2 types: oestrogens, of which ethinyloestradiol is the most important, and progestagens, of which levonorgestrel and norethisterone are the most commonly used. All these steroids can be measured by a number of analytical techniques but there is little doubt that radioimmunoassay is the most convenient. All the steroids are well absorbed in humans but while levonorgestrel is completely bioavailable, norethisterone has an average bioavailability of 70%. Ethinyloestradiol, too, is subject to presystemic metabolism with a mean bioavailability of 40 to 45%. The main site of presystemic metabolism is the gut wall, with the production of ethinyloestradiol sulphate. The progestagens norethynodrel, ethynodiol diacetate and lynoestrenol are quantitatively metabolised to norethisterone.The pharmacokinetics of the contraceptive steroids are best described by a 2-compartment open model. The terminal plasma half-life of levonorgestrel varies from 11 to 45 hours and of norethisterone from 5 to 14 hours. The β-phase half-life of ethinyloestradiol varies from 6 to 20 hours. The apparent volume of distribution of these contraceptive steroids (after intravenous administration) is between 1.5 and 4.3 L/kg. During long term treatment with oral contraceptive steroids, steady-state plasma concentrations of ethinyloestradiol (24 hours after administration) are between 10 and 200 pg/ml. Plasma concentrations of norethisterone and levonorgestrel at steady-state are higher than predicted from the single-dose kinetics because of enhanced binding of the progestagens following the induction of sex hormone binding globulin (SHBG) by ethinyloestradiol. Concentrations are in the range of 1.6 to 15.2 ng/ml for norethisterone and 0.8 to 4.5 ng/ml for levonorgestrel.All the contraceptive steroids are bound to proteins in plasma. Ethinyloestradiol is 97 to 98% bound to plasma albumin. The progestagens are bound both to albumin (levonorgestrel 93 to 95%; norethisterone 79 to 80%) and more specifically to SHBG. The binding capacity of SHBG can be enhanced by treatment with ethinyloestradiol or with more conventional enzyme-inducing drugs such as phenobarbitone, carbamazepine or rifampicin.Norethisterone and levonorgestrel are chiefly metabolised by reduction in the A ring and this is followed by conjugation with glucuronide or sulphate. The metabolism of levonorgestrel is stereoselective. Ethinyloestradiol is primarily hydroxylated at the 2 position but a wide variety of hydroxylated and methylated metabolites are formed and these are present both free and as glucuronide and sulphate conjugates. Ethinyloestradiol is conjugated directly at the 3 position (unlike the progestagens) and thus is liable to enterohepatic recirculation. Ethinyloestradiol sulphate concentrations in plasma are many times higher than that of the unchanged drug.The oral contraceptive steroids are involved in drug interactions of clinical significance. While the effect of contraceptive steroids on other drugs is small and unlikely to be of clinical significance, failure of contraception often occurs if enzyme-inducing agents such as rifampkin, phenobarbitone or carbamazepine are coadministered. Oral antibiotics do not seem to cause a significant loss of contraception in the large majority of women. Vitamin C will enhance the effect of contraceptive steroids by competing for sulphate conjugation in the gut wall, thus leading to increased bioavailability of ethinyloestradiol.

The interaction of phenobarbital and other anticonvulsants with oral contraceptive steroid therapy

In a group of 5 women on long-term anticonvulsant and oral contraceptive therapy, the plasma ethynylestradiol (EE) concentration on 50 microgram EE daily was 11.1 +/- 4.5 pg/ml. These values were at the lower end of the range found in normal women in this laboratory taking 30 microgram EE daily (6-190 pg/ml). Four women have been studied prospectively for 3 months, over 1 cycle before and 2 cycles during phenobarbital 30 mg b.i.d. therapy. Significant falls in the plasma EE concentration were seen in two women (from 104.8 +/- 13.4 to 37.7 +/- 2.0 pg/ml and from 125.6 +/- 23.8 to 34.8 +/- 6.7 pg/ml p less than 0.01) and breakthrough bleeding was seen in both women. No changes in plasma concentrations of follicle stimulating hormone, progesterone, norethindrone or norgestrel were seen. There was a significant increase in the sex hormone binding globulin capacity from 100.7 +/- 5.8 to 133.3 +/- 1.2 nmoles/1 (p less than 0.05). These changes are consistent with the known microsomal enzyme inducing effect of phenobarbital.

The Effect of Rifampicin on Norethisterone Pharmacokinetics

SummaryThe pharmacokinetics of norethisterone have been studied in 8 women during and one month after treatment with rifampicin (450–600 mg/day). Rifampicin caused a significant reduction in the A. U. C. of a single dose of 1 mg norethisterone from 37.8±13.1 to 21.9±5.9 ng/ml X h (p<0.01). The plasma norethisterone half life (β-phase) was also reduced from 6.2±1.7 to 3.2±1.0 h (p<0.0025). In one additional woman on long term oral contraceptive therapy the 12 hour plasma norethisterone concentration was reduced by rifampicin from 12.3 ng/ml to 2.3 ng/ml. Rifampicin caused a significant increase in antipyrine clearance, 6β-hydroxycortisol excretion and plasma gamma-glutamyltranspeptidase activity but there were no significant correlations between changes in these indices of liver microsomal enzyme induction. There was a significant correlation between the percentage increase in antipyrine clearance and the percentage decrease in norethisterone A. U. C. during rifampicin. The changes in norethisterone pharmacokinetics during rifampicin therapy are compatible with the known enzyme inducing effect of rifampicin.

The biliary and urinary metabolites of [3H]17α-ethynylestradiol in women

1. The metabolism of 17α-ethynyl[6,7-3H]estradiol (3H-EE2) (50 μg) given orally was studied in two groups of women: (a) six subjects from whom duodenal bile samples were obtained after 4h by endoscopic aspiration; (b) two subjects with bile-duct (T-tube) drainage.2. The first group eliminated 16.6 ± 7.8% (mean ± S.D.) of the dose in urine over 72 h, the second group 28.6% and 27.5%. Biliary excretion by the latter was 41.9% and 28.3% of the dose, respectively, during the first 24 h after dosing.3. The metabolites excreted in bile and urine were largely polar conjugates: 1–12% of the 3H was ether extractable. Approx. 70–90% of urinary and biliary 3H was extractable following β-glucuronidase-arylsulphohydrolase hydrolysis. Both β-glucuronidase and arylsulphates were excreted.4. Unchanged 3H-EE2 was the principal 3H-labelled component of the glucuronide and arylsulphate fractions of bile, and it was a major component of urinary fractions. 2-Hydroxy-EE2 and 2-methoxy-EE2 were identified as conjugated biliary ...

The pharmacokinetics of ethynylestradiol in the presence and absence of gestodene and desogestrel

Single doses of ethynylestradiol (30 micrograms) were given alone and in combination with either gestodene (75 micrograms) or desogestrel (150 micrograms) to 10 healthy female volunteers. The doses of steroids were given both orally and by i.v. infusion over 5-7 minutes. Blood samples were taken at regular intervals over 24 hours. The area under the plasma concentration versus time curve (AUC) for oral EE2 alone was 867 +/- 338 pg/ml x h, for oral EE2 in the presence of gestodene it was 795 +/- 206 pg/ml x h and for oral EE2 in the presence of desogestrel it was 614 +/- 132 pg/ml x h. With either gestodene or desogestrel present, the AUC of EE2 was not significantly different from that found when EE2 was given alone. In addition, there was no significant difference between EE2 + gestodene and EE2 + desogestrel. Comparing the relative oral and iv doses, the bioavailability of EE2 (alone) was 59.0 +/- 13% (n = 6), for EE2 plus gestodene it was 62.1 +/- 10% and for EE2 in the presence of desogestrel it was 62.1 +/- 4.4%. The clearance of EE2 (alone) was 19.9 +/- 5.5 l/h and in the presence of gestodene it was 19.4 +/- 9.6 l/h. The clearance of EE2 in the presence of desogestrel appeared slightly greater at 27.7 +/- 8.9 l/h but none of these clearance values were significantly different from each other. The urinary excretion of 6-beta-hydroxy cortisol was similar after all 6 doses of EE2. These data strongly suggest that following single dose administration, neither gestodene nor desogestrel have any inhibitory effect on the metabolism of EE2 or alter its kinetics to any clinically significant extent.

Plasma concentrations of 3-keto-desogestrel after oral administration of desogestrel and intravenous administration of 3-keto-desogestrel.

The plasma concentrations of 3-keto-desogestrel have been measured by radioimmunoassay in a crossover study in nine healthy female volunteers given oral desogestrel (150 micrograms) and ethinyloestradiol (30 micrograms) and intravenous (i.v.) 3-keto-desogestrel (150 micrograms) and ethinyloestradiol (30 micrograms). Bioavailability ranged between 40.0 and 113% with a mean value ( +/- SD) of 76.1 +/- 22.5%. Only 3 subjects had a bioavailability of less than 70%. There was no significant difference in the elimination half life of 3-keto-desogestrel which was 12.6 +/- 4.1h following i.v. administration and 11.9 +/- 4.1h after oral administration of desogestrel.

Interaction of ethinyloestradiol with ascorbic acid in man.

5 female volunteers were studied who had been taking oral contraceptives containing 30 mcg of ethinylestradiol (Ovranette and Eugynon) to determine the effect of ascorbic acid in women receiving long-term oral contraceptive treatment. Clearly at all study periods (6 hours and 24 hours after ascorbic acid administration) the vitamin caused the plasma concentration of ethinylestradiol to rise; at 6 hours the mean percent increase was 16.3 and at 24 hours the increase was 47.6%. The dose of ascorbic acid given (1 gm) is that prescribed for prevention of colds. This drug interaction may allow reduction of amounts of ethinylestradiol in oral contraceptive preparations.

Interindividual Variation and Drug Interactions with Hormonal Steroid Contraceptives

SummaryLarge inerindividual differences occur in the plasma concentration of contraceptive steroids. With the present tendency to decrease the dose of progestagen and oestrogen any factor which reduces the bioavailability of the lower dose preparations becomes very important. The possibility that other drugs and environmental chemicals may interact with contraceptive steroids is currently being investigated. Clinical reports suggest that the most important interacting drugs are the antituberculosis agent rifampicin, anticonvulsants and antibiotics. In the case of the first two, evidence is available suggesting that microsomal enzyme induction, either in the liver or the gut wall, is the operative mechanism. Antibiotics interfere with the pharmacokinetics of contraceptive steroids by interfering with their enterohepatic circulation in animal species; whether this is operative in man is still unclear.Other environmental and constitutional factors such as smoking, variations in diet, and concurrent disease may alter the disposition of contraceptive steroids and affect response accordingly. Additional studies are needed to estimate the significance of such interactions.

The effect of cotrimoxazole on oral contraceptive steroids in women

Nine women taking long-term oral contraceptive steroids (Trinordiol) were studied during a cycle while taking cotrimoxazole (1 gm twice daily) and the results were compared to the previous control cycle. During the cotrimoxazole cycle, there was a significant increase in the plasma concentration of ethynylestradiol (EE). In plasma samples taken on 4 successive days 10-12 hours after dosing, the plasma EE concentration rose from 29.3 +/- 5.0 pg/ml to 38.2 +/- 5.8 pg/ml (mean +/- S.E. P less than or equal to 0.02). In samples taken 24 hours after dosing, the increase was from 18.9 +/- 2.5 pg/ml to 27.8 +/- 4.0 pg/ml (P less than or equal to 0.05). Plasma F.S.H. values in these latter samples, decreased from 4.8 +/- 0.6 mIu/ml to 3.4 +/- 0.5 mIu/ml (P less than or equal to 0.01). No significant changes were noted in the plasma concentrations of levonorgestrel or progesterone. The rise in plasma concentration of EE during cotrimoxazole therapy is attributed to an inhibition of the metabolism of EE by cotrimoxazole as has been shown with other drugs. Short courses of cotrimoxazole are unlikely to cause any adverse effects on contraceptive control when given to women taking long-term oral contraceptive steroids.

Interactions between oral contraceptive steroids and broad‐spectrum antibiotics

A problem that faces oral contraceptive (OC) users is that of decreased effectiveness of their contraceptive preparation caused by a drug interaction. Over the last decade this has occurred periodically as the dose of the contraceptive steroids has been progressively reduced. It now is accepted that rifampicin and anticonvulsants such as phenobarbitone phenytoin and carbamazepine may cause contraceptive failure in women taking OCs. All these drugs induced microsomal drug-metabolizing enzymes in the liver thereby decreasing the plasma concentrations of the 2 contraceptive steroids and causing contraceptive failure. In the case of the anticonvulsants efficacy can be restored by increasing the dose of the contraceptive used but with rifampicin an increased dose usually is not helpful. Broad-spectrum antibiotics also have been implicated in causing contraceptive failure in women taking OCs. There have been a few reports in the literature of women who have become pregnant after taking antibiotics with their OC steroids. The Committee on Safety of Medicines (CSM) has received over 63 reports of women whose contraceptive had failed in this way. The most commonly implicated antibiotics have been ampicillin the tetracyclines and cotrimoxazole. OC steroids both estrogens and progestogens are excreted extensively in the bile as glucuronide and sulphate conjugates. On reaching the gut these conjugates are hydrolysed by enzymes present in intestinal microorganisms and the chief organisms responsible seem to be Clostridia sp. In the case of progestogens this hydrolytic process only generates inactive metabolites since the unchanged drug cannot be conjugated directly. Ethinylestradiol can itself be conjugated and thus on hydrolysis by gut bacteria the unchanged estrogen is formed which is then available to be reabsorbed into the body. In animal studies there is clear evidence that the enterohepatic recirculation is important and that broad spectrum antibiotics do cause a significant fall in plasma concentrations of steroids. 1 objection to some of these studies is that prolonged antibiotic therapy may lead to the development of resistant organisms in the gut and this is particularly likely in the long-term use of tetracycline in acne patients. Although the data sheet for contraceptive steroids states that women treated with broad-spectrum antibiotics should use alternative contraceptive precautions it is doubtful that this advice is often given.