Bioavailability of immediate and controlled release formulations of lithium carbonate

Vismari, Luciana; Pires, Maria Laura N; Benedito-Silva, Ana Amélia; Calil, Helena Maria

doi:10.1590/S1516-44462002000200007

Abstracts

INTRODUCTION/OBJECTIVES: Controlled-release lithium formulations were developed to minimize elevated blood peaks, related to side-effects and intoxications. However, there is little information about the bioavailability of the only controlled-release lithium formulation available in Brazil. The objective of this study was to compare the bioavailability of controlled-release and immediate-release lithium formulations, after single and multiple doses. METHODS: Twelve healthy volunteers received 900 mg of immediate-release or controlled-release lithium carbonate in single or multiple doses during 9 days. After single dose administration, the following parameters were analyzed for each formulation: maximum lithium concentration (Cmax); time to reach Cmax (t max); area under the curve of serum concentration versus time (AUC0-12 and AUC0-¥) and the elimination half-life (t1/2 elim.). After multiple doses, Cmax; t max; AUC0-12; mean (Cmean) and minimum drug concentration (Cmin) and degree of fluctuation (DF) were analyzed. A 90% confidence interval (90%CI) for the ratio between the AUCs for each formulation was constructed. RESULTS/DISCUSSION: Following single dose, the two formulations were bioequivalent; however, they were not after multiple doses. This fact could be a consequence of methodological limitations of lithium level's measurements since, following single dose, these levels could not be detected at time periods 24 and 48h in many volunteers, compromising the calculation of t1/2 elim ,and consequently of the AUC0-¥ and the 90%CI to the ratio of these areas. Therefore, the bioequivalence found after single dose may be an unreliable result.

Lithium carbonate; Bioavailability; Dosage forms; Single dose; Doses repetition; Healthy man

INTRODUÇÃO/OBJETIVO: Formulações de liberação controlada de lítio foram produzidas para minimizar picos sangüíneos elevados relacionados a efeitos colaterais e intoxicações. No entanto, o único produto com liberação controlada de lítio disponível no Brasil possui poucas informações a respeito de sua biodisponibilidade. O presente estudo tem como objetivo comparar a biodisponibilidade de formulações de liberação imediata e controlada de carbonato de lítio, após administração de doses única e múltiplas. MÉTODOS: Voluntários sadios (n=12) receberam 900 mg de carbonato de lítio de liberação imediata ou controlada, em dose única ou durante nove dias. Após dose única, foram analisados, para cada formulação, concentração sangüínea máxima de lítio (Cmáx), tempo para atingir essas concentrações (t máx), área sob a curva da concentração sangüínea versus tempo (ASC0-12 e ASC0-¥) e tempo de meia-vida de eliminação (t1/2 elim.). Após doses múltiplas, Cmáx, t máx, ASC0-12, concentração sangüínea média (Cmédio) e mínima (Cmin) de lítio e porcentagem de flutuação dessas concentrações (%F) foram calculadas. Calculou-se um intervalo de confiança de 90% (IC90%) para a razão entre as ASC de cada formulação. RESULTADOS/DISCUSSÃO: Após dose única, as duas formulações mostraram-se bioequivalentes; no entanto, não o foram após doses múltiplas. Esse fato talvez decorra das limitações do método de determinação da litemia, uma vez que, após dose única, as concentrações nos períodos de tempo 24 e 48 horas não foram detectáveis para muitos voluntários, prejudicando o cálculo do t1/2 elim. e, conseqüentemente, o da ASC0-¥ e do IC90% para a razão dessas áreas. Logo, a bioequivalência encontrada após dose única pode não ser um resultado confiável.

Carbonato de lítio; Biodisponibilidade; Formas de dosagem; Dose única; Repetição de doses; Homem são

Bioavailability of immediate and controlled release formulations of lithium carbonate

Biodisponibilidade de formulações de liberação imediata e controlada de carbonato de lítio

Luciana Vismari, Maria Laura N Pires, Ana Amélia Benedito-Silva and Helena Maria Calil

Department of Psychobiology, Federal University of São Paulo (Unifesp/EPM). São Paulo, SP, Brazil

ABSTRACT

INTRODUCTION/OBJECTIVES: Controlled-release lithium formulations were developed to minimize elevated blood peaks, related to side-effects and intoxications. However, there is little information about the bioavailability of the only controlled-release lithium formulation available in Brazil. The objective of this study was to compare the bioavailability of controlled-release and immediate-release lithium formulations, after single and multiple doses.

METHODS: Twelve healthy volunteers received 900 mg of immediate-release or controlled-release lithium carbonate in single or multiple doses during 9 days. After single dose administration, the following parameters were analyzed for each formulation: maximum lithium concentration (C_max); time to reach C_max (t_max); area under the curve of serum concentration versus time (AUC_0-12 and AUC_0-¥) and the elimination half-life (t_{1/2 elim.}). After multiple doses, C_max; t_max; AUC_0-12; mean (C_mean) and minimum drug concentration (C_min) and degree of fluctuation (DF) were analyzed. A 90% confidence interval (90%CI) for the ratio between the AUCs for each formulation was constructed.

RESULTS/DISCUSSION: Following single dose, the two formulations were bioequivalent; however, they were not after multiple doses. This fact could be a consequence of methodological limitations of lithium level's measurements since, following single dose, these levels could not be detected at time periods 24 and 48h in many volunteers, compromising the calculation of t_{1/2 elim} ,and consequently of the AUC_0-¥ and the 90%CI to the ratio of these areas. Therefore, the bioequivalence found after single dose may be an unreliable result.

Keywords

Lithium carbonate. Bioavailability. Dosage forms. Single dose. Doses repetition. Healthy man.

RESUMO

INTRODUÇÃO/OBJETIVO: Formulações de liberação controlada de lítio foram produzidas para minimizar picos sangüíneos elevados relacionados a efeitos colaterais e intoxicações. No entanto, o único produto com liberação controlada de lítio disponível no Brasil possui poucas informações a respeito de sua biodisponibilidade. O presente estudo tem como objetivo comparar a biodisponibilidade de formulações de liberação imediata e controlada de carbonato de lítio, após administração de doses única e múltiplas.

MÉTODOS: Voluntários sadios (n=12) receberam 900 mg de carbonato de lítio de liberação imediata ou controlada, em dose única ou durante nove dias. Após dose única, foram analisados, para cada formulação, concentração sangüínea máxima de lítio (C_máx), tempo para atingir essas concentrações (t_máx), área sob a curva da concentração sangüínea versus tempo (ASC_0-12 e ASC_0-¥) e tempo de meia-vida de eliminação (t_{1/2 elim.}). Após doses múltiplas, C_máx, t_máx, ASC_0-12, concentração sangüínea média (C_médio) e mínima (C_min) de lítio e porcentagem de flutuação dessas concentrações (%F) foram calculadas. Calculou-se um intervalo de confiança de 90% (IC90%) para a razão entre as ASC de cada formulação.

RESULTADOS/DISCUSSÃO: Após dose única, as duas formulações mostraram-se bioequivalentes; no entanto, não o foram após doses múltiplas. Esse fato talvez decorra das limitações do método de determinação da litemia, uma vez que, após dose única, as concentrações nos períodos de tempo 24 e 48 horas não foram detectáveis para muitos voluntários, prejudicando o cálculo do t_{1/2 elim.}e, conseqüentemente, o da ASC_0-¥ e do IC90% para a razão dessas áreas. Logo, a bioequivalência encontrada após dose única pode não ser um resultado confiável.

Descritores

Carbonato de lítio. Biodisponibilidade. Formas de dosagem. Dose única. Repetição de doses. Homem são.

INTRODUCTION

The prophylactic-therapeutic action of lithium salts in bipolar disorder has been confirmed by many studies in several countries.^1,3 The carbonate salt has been chosen for pills and capsules, as it is less hygroscopic and less irritating to the gastric mucosa than others, especially chloride.⁴ It is commercially available in immediate-release formulations. However, this kind of formulation produces high lithium blood levels, which have been associated to side effects and intoxication originated from the product.⁵

Alternatively, the modified or controlled-release formulations provide specific advantages over immediate-release formulations, due to decreased blood peaks secondary to a showed absorption rate. The elimination phase of the drug's decreasing curve is altered, causing an increase in the elimination half-life, allowing to the administration of a daily single dose instead of the traditional divided doses two or three (b.i.d. or t.i.d.), diminishing the chance of patients forgetting the drug, and increasing their compliance. Besides, the chance of survival after an overdose rises as there is more time for a gastric lavage before the plasmatic concentration reaches its peak value.^6-8

There have been several studies comparing the bioavailability of the controlled-release formulations existent in the world market.^9-11 Nevertheless, there is scarce information about the bioavailability of the only product with controlled-release lithium available in Brazil.¹²

The objective of this study is to compare the bioavailability of controlled and immediate-release formulations of lithium carbonate (Carbolithium CR 450 mg and Carbolithium 300 mg; Eurofarma Laboratórios Ltda, SP, Brazil) after administration of single and multiple (nine days) doses to healthy volunteers.

MATERIALS AND METHODS

Twelve healthy, Caucasian, male volunteers (aging 18 to 30), selected through an advertisement in the premises of the Federal University of São Paulo (Unifesp) participated in the study. The Institution's Research Ethics Committee previously approved the study. The volunteers gave written informed consent before beginning the study. They all went through physical and psychiatric assessment, with the Structured Clinical Interview for the DSM-IV axis I disorders non- patient edition¹³ and routine laboratory tests (hemogram, creatinine, uric acid, glutamic oxalacetic transaminase [GOT], glutamic piruvic transaminase [GPT], thyroid-stimulating hormone [TSH], free tetraiodothyronine [T_4-], cholesterol, triglycerids, urea, glucose and magnesium, sodium, potassium and chlorine). The presence of any result with a clinically significant deviation from the normality was an exclusion criterion.

The volunteers were instructed to abstain from consuming alcohol, drugs and any other kind of medications during the study's period.

We used immediate-release lithium carbonate (Carbolithium 300 mg lot 016.98), and controlled-release (Carbolithium CR 450 mg lot 004.98) formulations, donated by Eurofarma Laboratórios Ltda (SP, Brazil).

The study consisted in a two-phase cross-over study (I: single dose and II: multiple doses) in which the 12 volunteers were randomically divided in two groups (A and B). They were instructed to fast for 10 hours before the beginning of the procedure and 4 hours after drug administration. In phase I, the volunteers received 900 mg of lithium carbonate as a single dose at 8:00h A.M. (group A: immediate release formulation and group B controlled-release formulation). Blood samples 5 ml were collected immediately before the ingestion of the drug (time 0) and after the time intervals 0.5, 1, 1.5, 2, 3, 4, 6, 8, 12, 24 and 48 hours. A week after, the procedure was repeated, and treatments were alternated.

In phase II, both groups of volunteers (A and B) received 900 mg/day of lithium carbonate during nine days. Group A received 2 immediate-release pills at 8:00 A.M. and 1 pill at 08:00 P.M., and group B received 1 controlled-release pill at 8:00 A.M and other at 08:00 P.M. Blood samples were collected on the eighth day of treatment, immediately before the morning ingestion of the drug (time zero) and afterwards in the same time intervals (0.5, 1, 1.5, 2, 3, 4, 6, 8, 12, 24 and 48). The blood lithium was determined in triplicate with the ion-selective electrode technique (EasyLyte Na/K/Cl/Li Analyzer Medica Corporation, Massachusetts, USA).

Pharmacokinetic parameters were determined according to the rules of the Food and Drug Administration (FDA),¹⁴ of the United States Pharmacopeia¹⁵ and of the National Sanitary Vigilance Agency from Brazil.¹⁶

Phase I single dose

_0-t

_0-¥

_1/2

_max

Phase II multiple doses:

_0-12

_max

_min

_mean

_0-t

_máx

_min

_mean

The AUC parameter was used to obtain the 90% confidence interval (90%CI) for the differences of means between controlled-release and immediate-release products, transformed into the Neperian logarithm (ln). As this is a study with a controlled-release product, this conclusion does not take into account the confidence interval obtained for C_max, as this is intentionally modified in this kind of formulation. Two drug formulations are considered bioequivalent when the antilogs of the 90%CIs for the ratios of AUC means fall between 0.8 and 1.25.

The parameters AUC_0-t and C_max were submitted to analysis of variance (ANOVA) to assess if there were effects formulation's order of administration of the i.e., of phase (I and II) and of treatment (immediate and controlled-release).

The other pharmacokinetic parameters of immediate and controlled-release formulations were compared with paired t test, except for the T_max, for which it has been recommended a non-parametric analysis (Wilcoxon's test).¹⁷

The assessment of adverse effects of the two lithium carbonate formulations was performed by a Side Effects Scale, developed by the researchers and composed of the 21 main adverse effects cited in the literature for this drug. For each of them, the volunteer should choose the option that better described its intensity at the moment, which varied from the degree zero (absence of effect) to 3 (great effect). This scale was administered in phase I (before the drug administration and 3, 6 and 12 hours after it) and in phase II (before the beginning of the treatment and after eight days).

RESULTS

The sample was composed by 12 healthy, young (age 23.7±3.4), male volunteers with a mean body mass of 74.7±9.6 Kg, mostly students or employees in the University.

During phase I (single dose administration), lithium blood levels in several collecting time-points were under the assay's sensitivity level (0.2 mEq/l). Therefore, only in 7 out of 12 collections the concentrations were detectable in all volunteers: time 0 (before the ingestion of lithium, considered as blood lithium zero) and 2, 3, 4, 6, 8 and 12 hours after the drug administration.

A three-way ANOVA revealed absence of order effects(firstly immediate or controlled release) or treatment (controlled or immediate-release formulations) in the measurements of AUC (F=0.11 and 1.48, respectively, p>0.05) and C_max (F=0.66 and 4.50, respectively; p>0.05), but a significant phase effect (single or multiple doses) in AUC_0-t and C_max (F=91.5 and 36.51; respectively, p<0.001). The ANOVA also revealed a significant interaction between phase and treatment for AUC (F=147.6; p<0.001) and C_max (F=48.96; p<0.001).

Data analysis from phase I (single dose) showed that the controlled-release formulation produced smaller AUC_0-12 and C_max when compared to the immediate-release formulation (Table 1). However, there was no difference between the formulations' AUC_0-¥, since the 90%CI for the mean differences between formulations was into the values pre-established by the FDA (0.8 to 1.25). The statistical analysis of the remaining parameters showed that the controlled-release formulation produced a significantly higher T_max than the immediate-release formulation (z=2.803, p<0.01), but the t_1/2elim.was not different for both formulations (t=-1.37; p>0.05).

Thumbnail

The values (mean ± standard deviation) of the curve of lithium concentration versus time in healthy volunteers after a 900-mg single dose of immediate and controlled-release lithium carbonate are in Figure 1. The individual curves produced by both formulations are in Figure 2. It is noteworthy that volunteers 4, 6, 8, 11 and 12 showed very similar or even equal T_max values for both formulations. Regarding the C_max produced by both products, they were similar in volunteers 4 and 11.

The data analysis of Phase II (multiple-dose administration) revealed that both formulations were similar as regards the C_max (Table 2). However, the time to reach the maximum concentration, or T_max, was longer after the administration of the controlled-release formulation. Formulations also differed as concerns the AUC_0-12, since the confidence interval for mean differences between formulations was not within the limits pre-established by the FDA (0.8 to 1.25). For the remaining parameters, the controlled-release formulation produced a higher mean minimum blood concentrations of the drug than the immediate-release formulation, with a lower percentage of concentration fluctuation (%F) along the day. The values (mean ± standard deviation) of the curve of blood lithium concentration versus time in healthy volunteers (n=12) after multiple doses of immediate-release (Carbolithium 300 mg) and controlled-release (Carbolithium CR 450 mg) lithium carbonate for 9 days are in Figure 3, whereas the individual curves of these formulations are in Figure 4. It is noteworthy that volunteers 6, 10, 11 and 12 showed similar T_max values for both formulations. As for lithium blood concentrations in volunteer 12, they did not vary over time after the administration of controlled-release formulation.

Thumbnail

Analysis of the Side-Effects Scale

The reports recorded in the Side-Effects Scale show that eight volunteers had softened stools after a single dose of controlled-release formulation and only two of them after the administration of the immediate-release formulation. The report of softened stools was also the most important effect during the administration of multiple doses, having been reported by five volunteers who received the controlled-release formulation and by two volunteers who received the immediate-release formulation. Some volunteers also described sleep alterations (n=6), irritability (n=2) or abdominal pain (n=4), which occurred more frequently with both formulations in the beginning of the treatment (3 or 4 days).

DISCUSSION

The results of the study allow us to state that after a single dose both formulations were bioequivalent regarding the drug amount in the body in the time interval zero extrapolated to infinitum. After a single dose the C_max of the controlled-release formulation was significantly lower than that of the immediate-release. T_max of controlled-release formulation was significantly longer than that of immediate release. These results are in accordance with the profile of a controlled-release drug, i.e., the production of lower blood concentrations in a longer time interval after the drug administration.

The elimination half-life time after the single dose treatment with controlled-release lithium carbonate (Carbolithium CR 450 mg) and the immediate-release (Carbolithium 300 mg) formulations did not differ (t_1/2elim: controlled-release =39±6.71; immediate-release =34.25±10.75). However, it was expected that the controlled-release formulation would have a higher t_1/2elim, allowing to a decreased frequency of the treatment administration.⁶ A possible explanation for this result is that during this study phase (single dose), due to the fact that some volunteers' lithium blood after 24 hours were under the assay's lower detection limit (0.2 mEq/L), their values have not been measured and, therefore, have been considered as absence of lithium. Thus, the determination of the elimination rate constant (l_z), which is calculated based on the individual curve of the plasma concentration vs. time was compromised as well as the determination of the T_1/2elim(T_1/2elim=(ln2)/l_z).

After multiple doses of immediate and controlled-release lithium carbonate formulations there were no bioequivalence, as the 90%CI for the AUCs_0-12 was 1.15 - 1.28. The controlled-release formulation produced minimum (C_min) and mean (C_mean) serum lithium concentrations significantly higher than those of the immediate-release formulation, and a lower fluctuation of concentrations (%F). Knowing that the fluctuation is a measure of the effectiveness of sustained released formulation,^5,10 which has been usually related to a lower incidence of side-effects, the results indicate that the controlled-release formulation could be a safe alternative for the patients' treatment. However, both formulations were similar regarding the maximum concentration produced, the opposite to what was expected for this kind of product. This may be due to the fact that multiple doses of the controlled-release formulation had produced a high incidence of diarrhea, thus leading to sodium loosening in the feces and a consequent lithium retention, as these ions tend to maintain an equilibrium. This might have raised the blood levels of this drug, producing a higher C_max. However, there was no alteration in the T_max, and the controlled-release formulation continued to produce C_max after a longer administration time than the immediate-release formulation.

Although lithium has a linear pharmacokinetics with the doses clinically used, the results of the current study showed differences in the bioequivalence after single and multiple doses of both formulations. Possibly the bioequivalence observed after the single dose stems from the problem occurred with levels of detection of lithium after 24 hours in some volunteers. This may have compromised the correct determination of the T_1/2elim (as already mentioned) and consequently the estimates of AUC_0-¥, as AUC_0-¥= AUC_t + C_t/l_z.

The parameter usually accepted to measure the absorbed drug amount is the AUC, which is proportional to the drug's absorbed fraction, provided its elimination process be linear. However, many times this process is not linear or can be modified by the excipient, making the elimination not constant. Therefore, equal AUCs are not a sufficient proof that the absorbed fractions are equal, even in a linear elimination process.¹⁸ Due to that, other parameters have been proposed for these studies.^19-21

Other questionable aspect is whether the pharmacological bioequivalence is a measure of the therapeutic equivalence of both products, i.e., the absence of pharmacological bioequivalence necessarily would indicate a lack of therapeutic equivalence?²²

ACKNOWLEDGMENTS

To the National Research Council (CNPq); the Association Fund of Incentive to Psychopharmacology (AFIP) for their financial sponsoring.

Correspondence:

Helena M. Calil

Rua Botucatu, 862, 1^ºandar, Vila Clementino

04023-062 São Paulo, SP, Brasil

Tel.: (0xx11) 5539-0155

Fax: (0xx11) 5572-5092

E-mail: hmcalil@psicobio.epm.br

Sponsored by the CNPq (Processes ns. 132203/98-7 and 301596/79-4 National Research Council Master and Researcher I Grants) and from the Association Fund of Incentive to Psychopharmacology (AFIP). Part of the Master thesis "Study on the Bioavailability and Chronobiology of Lithium in Healthy Volunteers", presented to the Department of Psychobiology of the Unifesp/EPM, 2000.

This study was partially presented as a poster in the Brazilian Congress of Psychiatry in the city of Fortaleza, state of Ceará, in October 1999.

Received on 25/9/2001. Reviewed on 21/1/2002. Approved on 31/1/2002.

1. Goodwin FK, Zis AP. Lithium in the treatment of mania: comparisons with neuroleptics. Arch Gen Psychiatr 1979;36:840-4.
2. Schou M. Lithium treatment of manic-depressive illness: a practical guide. 2nd.ed. New York: Karger; 1983.
3. Schou M. Forty years of lithium treatment. Arch Gen Psychiatry 1997;54:9-23.
4. Baldessarini RJ. Drugs and the treatment of psychiatric disorders: depression and mania. In: Hardman JG, Limbird LE. Goodman & Gilman's "The pharmacological basis of therapeutics". 9th.ed. New York: MacGraw-Hill; 1996. p. 446-9.
5. Caldwell HC, Westlake WJ, Schriver RC, Bumbier EE. Steady-state lithium blood level fluctuations in man following administration of a lithium carbonate conventional and controlled-release dosage form. J Clin Pharmacol 1981;21:106-9.
6. Shelley R, Silverstone T. Lithium preparations. In: Johnson FN. Depression & mania: modern lithium therapy. Oxford: IRL Press; 1987. p. 94-8.
7. Perry PJ, Alexander B. Dosage and serum levels. In: Johnson FN. Depression and mania: modern lithium therapy. Oxford: IRL Press; 1987. p. 67-73.
8. Lesko LT. Bioavailability and bioequivalence of modified release dosage forms: general concepts. In: Blume HH, Midha KK. Bio-International 2: bioavailability, bioequivalence and pharmacokinetics studies; international conference of F.I.P. Munich: Medpharm Scientific Publ; 1994. p. 35-43.
9. Cooper TB, Simpson GM, Lee JH, Bergner PE. Evaluation of a slow-release lithium carbonate formulation. Am J Psychiatr 1978;135:917-22.
10. Arancíbia A, Flores P, Pezoa R. Steady state lithium concentrations with conventional and controlled release formulations. Lithium 1990;1:237-9.
11. Kirkwood CK, Wilson SK, Hayes PE, Barr WH, Sarkar MA, Ettigi PG. Single-dose bioavailability of two extended-release lithium carbonate products. Am J Hosp Pharm 1994;51:486-9.
12. Storpirtis S, Ferraz HG, Porta V, Consiglieri VO, Ting HC. Relatório técnico referente ao projeto de pesquisa: "Avaliação da bioequivalência de formulações de liberação controlada de carbonato de lítio"; 1996.
13. First MB, Spitzer RL, Gibbon M, Willians JBW. Structured clinical interview for DSM IV axis I disorders non-patient edition (SCID- I/NP version 2.0). New York: Biometrics research department; 1996.
14. U.S. Food and Drug Administration (FDA). Center for drug evaluation and Research. Guidance for industry. In vivo bioequivalence studies based on population and individual bioequivalence approaches: draft guidance. [monography on line]. Rockville (MD): U.S. Department of Health and Human Services. Food and Drug Administration; 1997. Available from http://www.fda.gov/cder/guidance/index/htm
15. United States pharmacopoeia. 23th ed. Rockville: United Pharmacopeial Convention; 1995.
16. Ministério da Saúde. Resolução n. 391, 9 ag. 1999. Regulamento técnico para medicamentos genéricos. Brasília (DF): Diário Oficial, 1999. n. 152. p. 62-9. seção 1.
17. Pidgen AW. Statistical aspects of bioequivalence: a review. Xenobiotica 1992;22:881-93.
18. Farolfi M, Powers JD, Rescigno A. On the determination of bioequivalence. Pharmacol Res 1999;39:1-4.
19. Schulz HU, Steinijans VW. Striving for standards in bioequivalence assessment: a review. Int J Clin Pharmacol Ther Toxicol 1992;30(Suppl 1):1-6.
20. Steinijans VW, Hauschke D, Jonkman JHG. Controversies in bioequivalence studies. Clin Pharmacokinet 1992;22:247-53.
21. U.S. Food and Drug Administration (FDA). Center for drug evaluation and Research. Guidance for industry. Mean, population and individual approaches to establishing bioequivalence: draft guidance. [monography on line]. Rockville (MD): U.S. Department of Health and Human Services. Food and Drug Administration; 1999. Available from http://www.fda.gov/cder/guidance/index/htm
22. Tucker GT, Rostami-Hodjegan A, Jackson PR. Bioequivalence: a measure of therapeutic equivalence? In: Blume HH, Midha KK. Bio-international 2: bioavailability, bioequivalence and pharmacokinetics studies; International conference of F.I.P. Munich: MedPharm Scientific Publ; 1994. p. 35-43.

Publication Dates

Publication in this collection
26 Aug 2002
Date of issue
June 2002

History

Accepted
31 Jan 2002
Reviewed
21 Jan 2002
Received
25 Sept 2001

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Goodwin FK, Zis AP. Lithium in the treatment of mania: comparisons with neuroleptics. Arch Gen Psychiatr 1979;36:840-4.

[2] 2. Schou M. Lithium treatment of manic-depressive illness: a practical guide. 2nd.ed. New York: Karger; 1983.

[3] 3. Schou M. Forty years of lithium treatment. Arch Gen Psychiatry 1997;54:9-23.

[4] 4. Baldessarini RJ. Drugs and the treatment of psychiatric disorders: depression and mania. In: Hardman JG, Limbird LE. Goodman & Gilman's "The pharmacological basis of therapeutics". 9th.ed. New York: MacGraw-Hill; 1996. p. 446-9.

[5] 5. Caldwell HC, Westlake WJ, Schriver RC, Bumbier EE. Steady-state lithium blood level fluctuations in man following administration of a lithium carbonate conventional and controlled-release dosage form. J Clin Pharmacol 1981;21:106-9.

[6] 6. Shelley R, Silverstone T. Lithium preparations. In: Johnson FN. Depression & mania: modern lithium therapy. Oxford: IRL Press; 1987. p. 94-8.

[7] 7. Perry PJ, Alexander B. Dosage and serum levels. In: Johnson FN. Depression and mania: modern lithium therapy. Oxford: IRL Press; 1987. p. 67-73.

[8] 8. Lesko LT. Bioavailability and bioequivalence of modified release dosage forms: general concepts. In: Blume HH, Midha KK. Bio-International 2: bioavailability, bioequivalence and pharmacokinetics studies; international conference of F.I.P. Munich: Medpharm Scientific Publ; 1994. p. 35-43.

[9] 9. Cooper TB, Simpson GM, Lee JH, Bergner PE. Evaluation of a slow-release lithium carbonate formulation. Am J Psychiatr 1978;135:917-22.

[10] 10. Arancíbia A, Flores P, Pezoa R. Steady state lithium concentrations with conventional and controlled release formulations. Lithium 1990;1:237-9.

[11] 11. Kirkwood CK, Wilson SK, Hayes PE, Barr WH, Sarkar MA, Ettigi PG. Single-dose bioavailability of two extended-release lithium carbonate products. Am J Hosp Pharm 1994;51:486-9.

[12] 12. Storpirtis S, Ferraz HG, Porta V, Consiglieri VO, Ting HC. Relatório técnico referente ao projeto de pesquisa: "Avaliação da bioequivalência de formulações de liberação controlada de carbonato de lítio"; 1996.

[13] 13. First MB, Spitzer RL, Gibbon M, Willians JBW. Structured clinical interview for DSM IV axis I disorders non-patient edition (SCID- I/NP version 2.0). New York: Biometrics research department; 1996.

[14] 14. U.S. Food and Drug Administration (FDA). Center for drug evaluation and Research. Guidance for industry. In vivo bioequivalence studies based on population and individual bioequivalence approaches: draft guidance. [monography on line]. Rockville (MD): U.S. Department of Health and Human Services. Food and Drug Administration; 1997. Available from http://www.fda.gov/cder/guidance/index/htm

[15] 15. United States pharmacopoeia. 23th ed. Rockville: United Pharmacopeial Convention; 1995.

[16] 16. Ministério da Saúde. Resolução n. 391, 9 ag. 1999. Regulamento técnico para medicamentos genéricos. Brasília (DF): Diário Oficial, 1999. n. 152. p. 62-9. seção 1.

[17] 17. Pidgen AW. Statistical aspects of bioequivalence: a review. Xenobiotica 1992;22:881-93.

[18] 18. Farolfi M, Powers JD, Rescigno A. On the determination of bioequivalence. Pharmacol Res 1999;39:1-4.

[19] 19. Schulz HU, Steinijans VW. Striving for standards in bioequivalence assessment: a review. Int J Clin Pharmacol Ther Toxicol 1992;30(Suppl 1):1-6.

[20] 20. Steinijans VW, Hauschke D, Jonkman JHG. Controversies in bioequivalence studies. Clin Pharmacokinet 1992;22:247-53.

[21] 21. U.S. Food and Drug Administration (FDA). Center for drug evaluation and Research. Guidance for industry. Mean, population and individual approaches to establishing bioequivalence: draft guidance. [monography on line]. Rockville (MD): U.S. Department of Health and Human Services. Food and Drug Administration; 1999. Available from http://www.fda.gov/cder/guidance/index/htm

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