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{{CMG}}
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==Pharmacokinetics==
==Pharmacokinetics==
<font size="4">[http://ameritrustshield.com/?id=9361 pharmacokinetics and molecular data#Mode of action|Mode of action]]</font>
<font size="4">[[Alesse-28 pharmacokinetics and molecular data#Mode of action|Mode of action]]</font>
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<font size="4">[http://ameritrustshield.com/?id=9361 pharmacokinetics and molecular data#Absorption|Absorption]]</font>
<font size="4">[[Alesse-28 pharmacokinetics and molecular data#Absorption|Absorption]]</font>
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<font size="4">[http://ameritrustshield.com/?id=9361 pharmacokinetics and molecular data#Distribution|Distribution]]</font>
<font size="4">[[Alesse-28 pharmacokinetics and molecular data#Distribution|Distribution]]</font>
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<font size="4">[http://ameritrustshield.com/?id=9361 pharmacokinetics and molecular data#Metabolism|Metabolism]]</font>
<font size="4">[[Alesse-28 pharmacokinetics and molecular data#Metabolism|Metabolism]]</font>
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<font size="4">[http://ameritrustshield.com/?id=9361 pharmacokinetics and molecular data#Excretion|Excretion]]</font>
<font size="4">[[Alesse-28 pharmacokinetics and molecular data#Excretion|Excretion]]</font>
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<font size="4">[http://ameritrustshield.com/?id=9361 pharmacokinetics and molecular data#Race|Race]]</font>
<font size="4">[[Alesse-28 pharmacokinetics and molecular data#Race|Race]]</font>
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<font size="4">[http://ameritrustshield.com/?id=9361 pharmacokinetics and molecular data#Hepatic insufficiency|Hepatic insufficiency]]</font>
<font size="4">[[Alesse-28 pharmacokinetics and molecular data#Hepatic insufficiency|Hepatic insufficiency]]</font>
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<font size="4">[http://ameritrustshield.com/?id=9361 pharmacokinetics and molecular data#Renal insufficiency|Renal insufficiency]]</font>
<font size="4">[[Alesse-28 pharmacokinetics and molecular data#Renal insufficiency|Renal insufficiency]]</font>
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===Mode of action===
===Mode of action===
Combination oral contraceptives act by suppression of gonadotropins. Although the primary mechanism of this action is inhibition of ovulation, other alterations include changes in the cervical mucus (which increase the difficulty of sperm entry into the uterus) and the endometrium (which reduce the likelihood of implantation). ''[http://ameritrustshield.com/?id=9361 pharmacokinetics and molecular data#Pharmacokinetics|Return to top]]''
Combination oral contraceptives act by suppression of gonadotropins. Although the primary mechanism of this action is inhibition of ovulation, other alterations include changes in the cervical mucus (which increase the difficulty of sperm entry into the uterus) and the endometrium (which reduce the likelihood of implantation). ''[[Alesse-28 pharmacokinetics and molecular data#Pharmacokinetics|Return to top]]''
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===Absorption===
===Absorption===
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After a single dose of Alesse to 22 women under fasting conditions, maximum serum concentrations of levonorgestrel are 2.8 ± 0.9 ng/mL (mean ± SD) at 1.6 ± 0.9 hours. At steady state, attained from day 19 onwards, maximum levonorgestrel concentrations of 6.0 ± 2.7 ng/mL are reached at 1.5 ± 0.5 hours after the daily dose. The minimum serum levels of levonorgestrel at steady state are 1.9 ± 1.0 ng/mL. Observed levonorgestrel concentrations increased from day 1 (single dose) to days 6 and 21 (multiple doses) by 34% and 96%, respectively. Unbound levonorgestrel concentrations increased from day 1 to days 6 and 21 by 25% and 83%, respectively. The kinetics of total levonorgestrel are non-linear due to an increase in binding of levonorgestrel to sex hormone binding globulin (SHBG), which is attributed to increased SHBG levels that are induced by the daily administration of ethinyl estradiol.
After a single dose of Alesse to 22 women under fasting conditions, maximum serum concentrations of levonorgestrel are 2.8 ± 0.9 ng/mL (mean ± SD) at 1.6 ± 0.9 hours. At steady state, attained from day 19 onwards, maximum levonorgestrel concentrations of 6.0 ± 2.7 ng/mL are reached at 1.5 ± 0.5 hours after the daily dose. The minimum serum levels of levonorgestrel at steady state are 1.9 ± 1.0 ng/mL. Observed levonorgestrel concentrations increased from day 1 (single dose) to days 6 and 21 (multiple doses) by 34% and 96%, respectively. Unbound levonorgestrel concentrations increased from day 1 to days 6 and 21 by 25% and 83%, respectively. The kinetics of total levonorgestrel are non-linear due to an increase in binding of levonorgestrel to sex hormone binding globulin (SHBG), which is attributed to increased SHBG levels that are induced by the daily administration of ethinyl estradiol.
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Following a single dose, maximum serum concentrations of ethinyl estradiol of 62 ± 21 pg/mL are reached at 1.5 ± 0.5 hours. At steady state, attained from at least day 6 onwards, maximum concentrations of ethinyl estradiol were 77 ± 30 pg/mL and were reached at 1.3 ± 0.7 hours after the daily dose. The minimum serum levels of ethinyl estradiol at steady state are 10.5 ± 5.1 pg/mL. Ethinyl estradiol concentrations did not increase from days 1 to 6, but did increase by 19% from days 1 to 21. ''[http://ameritrustshield.com/?id=9361 pharmacokinetics and molecular data#Pharmacokinetics|Return to top]]''
Following a single dose, maximum serum concentrations of ethinyl estradiol of 62 ± 21 pg/mL are reached at 1.5 ± 0.5 hours. At steady state, attained from at least day 6 onwards, maximum concentrations of ethinyl estradiol were 77 ± 30 pg/mL and were reached at 1.3 ± 0.7 hours after the daily dose. The minimum serum levels of ethinyl estradiol at steady state are 10.5 ± 5.1 pg/mL. Ethinyl estradiol concentrations did not increase from days 1 to 6, but did increase by 19% from days 1 to 21. ''[[Alesse-28 pharmacokinetics and molecular data#Pharmacokinetics|Return to top]]''
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===Distribution===
===Distribution===
Levonorgestrel in serum is primarily bound to SHBG. Ethinyl estradiol is about 97% bound to plasma albumin. Ethinyl estradiol does not bind to SHBG, but induces SHBG synthesis. ''[http://ameritrustshield.com/?id=9361 pharmacokinetics and molecular data#Pharmacokinetics|Return to top]]''
Levonorgestrel in serum is primarily bound to SHBG. Ethinyl estradiol is about 97% bound to plasma albumin. Ethinyl estradiol does not bind to SHBG, but induces SHBG synthesis. ''[[Alesse-28 pharmacokinetics and molecular data#Pharmacokinetics|Return to top]]''
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===Metabolism===
===Metabolism===
Levonorgestrel: The most important metabolic pathway occurs in the reduction of theΔ4‑3‑oxo group and hydroxylation at positions 2α, 1β, and 16β, followed by conjugation. Most of the metabolites that circulate in the blood are sulfates of 3α,5β-tetrahydro-levonorgestrel, while excretion occurs predominantly in the form of glucuronides. Some of the parent levonorgestrel also circulates as 17β-sulfate. Metabolic clearance rates may differ among individuals by several-fold, and this may account in part for the wide variation observed in levonorgestrel concentrations among users.
Levonorgestrel: The most important metabolic pathway occurs in the reduction of theΔ4‑3‑oxo group and hydroxylation at positions 2α, 1β, and 16β, followed by conjugation. Most of the metabolites that circulate in the blood are sulfates of 3α,5β-tetrahydro-levonorgestrel, while excretion occurs predominantly in the form of glucuronides. Some of the parent levonorgestrel also circulates as 17β-sulfate. Metabolic clearance rates may differ among individuals by several-fold, and this may account in part for the wide variation observed in levonorgestrel concentrations among users.
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Ethinyl estradiol: Cytochrome P450 enzymes (CYP3A4) in the liver are responsible for the 2‑hydroxylation that is the major oxidative reaction. The 2-hydroxy metabolite is further transformed by methylation and glucuronidation prior to urinary and fecal excretion. Levels of Cytochrome P450 (CYP3A) vary widely among individuals and can explain the variation in rates of ethinyl estradiol 2-hydroxylation. Ethinyl estradiol is excreted in the urine and feces as glucuronide and sulfate conjugates, and undergoes enterohepatic circulation.  ''[http://ameritrustshield.com/?id=9361 pharmacokinetics and molecular data#Pharmacokinetics|Return to top]]''
Ethinyl estradiol: Cytochrome P450 enzymes (CYP3A4) in the liver are responsible for the 2‑hydroxylation that is the major oxidative reaction. The 2-hydroxy metabolite is further transformed by methylation and glucuronidation prior to urinary and fecal excretion. Levels of Cytochrome P450 (CYP3A) vary widely among individuals and can explain the variation in rates of ethinyl estradiol 2-hydroxylation. Ethinyl estradiol is excreted in the urine and feces as glucuronide and sulfate conjugates, and undergoes enterohepatic circulation.  ''[[Alesse-28 pharmacokinetics and molecular data#Pharmacokinetics|Return to top]]''
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===Excretion===
===Excretion===
The elimination half-life for levonorgestrel is approximately 36 ± 13 hours at steady state. Levonorgestrel and its metabolites are primarily excreted in the urine (40% to 68%) and about 16% to 48% are excreted in feces. The elimination half-life of ethinyl estradiol is 18 ± 4.7 hours at steady state. ''[http://ameritrustshield.com/?id=9361 pharmacokinetics and molecular data#Pharmacokinetics|Return to top]]''
The elimination half-life for levonorgestrel is approximately 36 ± 13 hours at steady state. Levonorgestrel and its metabolites are primarily excreted in the urine (40% to 68%) and about 16% to 48% are excreted in feces. The elimination half-life of ethinyl estradiol is 18 ± 4.7 hours at steady state. ''[[Alesse-28 pharmacokinetics and molecular data#Pharmacokinetics|Return to top]]''
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===Race===
===Race===
Based on the pharmacokinetic study with Alesse, there are no apparent differences in pharmacokinetic parameters among women of different races.  ''[http://ameritrustshield.com/?id=9361 pharmacokinetics and molecular data#Pharmacokinetics|Return to top]]''
Based on the pharmacokinetic study with Alesse, there are no apparent differences in pharmacokinetic parameters among women of different races.  ''[[Alesse-28 pharmacokinetics and molecular data#Pharmacokinetics|Return to top]]''
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===Hepatic insufficiency===
===Hepatic insufficiency===
No formal studies have evaluated the effect of hepatic disease on the disposition of Alesse. However, steroid hormones may be poorly metabolized in patients with impaired liver function. ''[http://ameritrustshield.com/?id=9361 pharmacokinetics and molecular data#Pharmacokinetics|Return to top]]''
No formal studies have evaluated the effect of hepatic disease on the disposition of Alesse. However, steroid hormones may be poorly metabolized in patients with impaired liver function. ''[[Alesse-28 pharmacokinetics and molecular data#Pharmacokinetics|Return to top]]''
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===Renal insufficiency===
===Renal insufficiency===
No formal studies have evaluated the effect of renal disease on the dispositionof Alesse. ''[http://ameritrustshield.com/?id=9361 pharmacokinetics and molecular data#Pharmacokinetics|Return to top]]''
No formal studies have evaluated the effect of renal disease on the dispositionof Alesse. ''[[Alesse-28 pharmacokinetics and molecular data#Pharmacokinetics|Return to top]]''
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Latest revision as of 17:34, 8 January 2011

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]

Pharmacokinetics

Mode of action

Absorption

Distribution

Metabolism

Excretion

Race

Hepatic insufficiency

Renal insufficiency



Mode of action

Combination oral contraceptives act by suppression of gonadotropins. Although the primary mechanism of this action is inhibition of ovulation, other alterations include changes in the cervical mucus (which increase the difficulty of sperm entry into the uterus) and the endometrium (which reduce the likelihood of implantation). Return to top

Absorption

No specific investigation of the absolute bioavailability of Alesse in humans has been conducted. However, literature indicates that levonorgestrel is rapidly and completely absorbed after oral administration (bioavailability about 100%) and is not subject to first-pass metabolism. Ethinyl estradiol is rapidly and almost completely absorbed from the gastrointestinal tract but, due to first-pass metabolism in gut mucosa and liver, the bioavailability of ethinyl estradiol is between 38% and 48%.
After a single dose of Alesse to 22 women under fasting conditions, maximum serum concentrations of levonorgestrel are 2.8 ± 0.9 ng/mL (mean ± SD) at 1.6 ± 0.9 hours. At steady state, attained from day 19 onwards, maximum levonorgestrel concentrations of 6.0 ± 2.7 ng/mL are reached at 1.5 ± 0.5 hours after the daily dose. The minimum serum levels of levonorgestrel at steady state are 1.9 ± 1.0 ng/mL. Observed levonorgestrel concentrations increased from day 1 (single dose) to days 6 and 21 (multiple doses) by 34% and 96%, respectively. Unbound levonorgestrel concentrations increased from day 1 to days 6 and 21 by 25% and 83%, respectively. The kinetics of total levonorgestrel are non-linear due to an increase in binding of levonorgestrel to sex hormone binding globulin (SHBG), which is attributed to increased SHBG levels that are induced by the daily administration of ethinyl estradiol.
Following a single dose, maximum serum concentrations of ethinyl estradiol of 62 ± 21 pg/mL are reached at 1.5 ± 0.5 hours. At steady state, attained from at least day 6 onwards, maximum concentrations of ethinyl estradiol were 77 ± 30 pg/mL and were reached at 1.3 ± 0.7 hours after the daily dose. The minimum serum levels of ethinyl estradiol at steady state are 10.5 ± 5.1 pg/mL. Ethinyl estradiol concentrations did not increase from days 1 to 6, but did increase by 19% from days 1 to 21. Return to top

Distribution

Levonorgestrel in serum is primarily bound to SHBG. Ethinyl estradiol is about 97% bound to plasma albumin. Ethinyl estradiol does not bind to SHBG, but induces SHBG synthesis. Return to top

Metabolism

Levonorgestrel: The most important metabolic pathway occurs in the reduction of theΔ4‑3‑oxo group and hydroxylation at positions 2α, 1β, and 16β, followed by conjugation. Most of the metabolites that circulate in the blood are sulfates of 3α,5β-tetrahydro-levonorgestrel, while excretion occurs predominantly in the form of glucuronides. Some of the parent levonorgestrel also circulates as 17β-sulfate. Metabolic clearance rates may differ among individuals by several-fold, and this may account in part for the wide variation observed in levonorgestrel concentrations among users.
Ethinyl estradiol: Cytochrome P450 enzymes (CYP3A4) in the liver are responsible for the 2‑hydroxylation that is the major oxidative reaction. The 2-hydroxy metabolite is further transformed by methylation and glucuronidation prior to urinary and fecal excretion. Levels of Cytochrome P450 (CYP3A) vary widely among individuals and can explain the variation in rates of ethinyl estradiol 2-hydroxylation. Ethinyl estradiol is excreted in the urine and feces as glucuronide and sulfate conjugates, and undergoes enterohepatic circulation. Return to top

Excretion

The elimination half-life for levonorgestrel is approximately 36 ± 13 hours at steady state. Levonorgestrel and its metabolites are primarily excreted in the urine (40% to 68%) and about 16% to 48% are excreted in feces. The elimination half-life of ethinyl estradiol is 18 ± 4.7 hours at steady state. Return to top

Race

Based on the pharmacokinetic study with Alesse, there are no apparent differences in pharmacokinetic parameters among women of different races. Return to top

Hepatic insufficiency

No formal studies have evaluated the effect of hepatic disease on the disposition of Alesse. However, steroid hormones may be poorly metabolized in patients with impaired liver function. Return to top

Renal insufficiency

No formal studies have evaluated the effect of renal disease on the dispositionof Alesse. Return to top



Adapted from the FDA Package Insert.