Table of Contents
SUMMARY PRODUCT INFORMATION 1 INDICATIONS AND CLINICAL USE 1 CONTRAINDICATIONS 1 WARNINGS AND PRECAUTIONS 1 ADVERSE REACTIONS 5 DRUG INTERACTIONS 8 DOSAGE AND ADMINISTRATION 9 OVERDOSAGE 9 ACTION AND CLINICAL PHARMACOLOGY 10 STORAGE AND STABILITY 13 SPECIAL HANDLING INSTRUCTIONS 13 DOSAGE FORMS, COMPOSITION AND PACKAGING 13
PHARMACEUTICAL INFORMATION 14 CLINICAL TRIALS 15 DETAILED PHARMACOLOGY 20 TOXICOLOGY 22 REFERENCES 23
(tm)
Trospium Chloride
| Route of Administration | Dosage Form / Strength | Clinically Relevant Nonmedicinal Ingredients |
| oral | coated tablet/20 mg | lactose monohydrate For a complete listing of all nonmedicinal ingredients see "Dosage Forms, Composition and Packaging". |
TROSEC(tm) (trospium chloride) is indicated for: the treatment of overactive bladder with symptoms of urge or mixed urinary incontinence, urgency, and urinary frequency.
TROSEC is contraindicated in patients: with urinary retention, gastric retention, or uncontrolled narrow-angle glaucoma and in patients who are at risk for these conditions: who have demonstrated hypersensitivity to the drug, its ingredients, or any component of the container. For a complete listing, see "Dosage Forms, Composition and Packaging".
General
Patients should be informed that anticholinergic agents, such as TROSEC, may produce clinically significant adverse effects related to anticholinergic pharmacological activity. For example, heat prostration (fever and heat stroke due to decreased sweating) can occur when anticholinergics such as TROSEC are used in a hot environment. Because anticholinergics such as TROSEC may also produce dizziness or blurred vision, patients should be advised to exercise caution. Patients should be informed that alcohol may enhance the drowsiness caused by anticholinergic agents.
Gastrointestinal
TROSEC should be administered with caution to patients with gastrointestinal obstructive disorders because of the risk of gastric retention (see "CONTRAINDICATIONS"). TROSEC, like other anticholinergic drugs, may decrease gastrointestinal motility and should be used with caution in patients with conditions such as ulcerative colitis, intestinal atony and myasthenia gravis.
Ophthalmologic
In patients being treated for narrow-angle glaucoma, TROSEC should only be used if the potential benefits outweigh the risks and in that circumstance only with careful monitoring.
Cardiovascular
The effect of 20 mg twice daily (bid) and up to 100 mg bid TROSEC on QT interval was evaluated in a single-blind, randomized, placebo and active (moxifloxacin 400 mg qd) controlled 5 day parallel trial in 170 male and female healthy volunteer subjects aged 18 to 45 years. The QT interval was measured over a 24 hour period at steady state. The 100 mg bid dose of TROSEC was chosen because this dose achieves the Cmax expected in severe renal impairment. TROSEC was not associated with an increase in individual corrected (QTcI) or Fridericia corrected (QTcF) QT interval at any time during steady state measurement, while moxifloxacin was associated with a 6.4 msec increase in QTcF. In this study, asymptomatic, non-specific T wave inversions were observed more often in subjects receiving TROSEC than in subjects receiving moxifloxacin or placebo following five days of treatment. This finding was not observed during routine safety monitoring in two other U.S. placebo-controlled clinical trials in 591 TROSEC-treated overactive bladder patients (See "CLINICAL TRIALS"). The clinical significance of T wave inversion in this study is unknown. TROSEC is associated with an increase in heart rate that correlates with increasing plasma concentrations. In the study described above, TROSEC demonstrated a mean increase in heart rate compared to placebo of 9.1 bpm for the 20 mg dose and of 18.0 bpm for the 100 mg dose. In the two U.S. placebo-controlled trials in patients with overactive bladder, the mean increase in heart rate compared to placebo in Study 1 was observed to be 3.0 bpm and in Study 2 was 4.0 bpm. TROSEC has not been formally evaluated in patients with conditions such as congestive heart failure, hypokalemia, myocardial infarction, etc., which potentiate proarrhythmic risk.
Hepatic/Biliary/Pancreatic
Caution should be used when administering TROSEC in patients with moderate hepatic dysfunction (see "ACTION AND CLINICAL PHARMACOLOGY, Special Populations and Conditions"). There is no experience in patients with severe hepatic dysfunction.
Renal
TROSEC should be administered with caution to patients with clinically significant bladder outflow obstruction because of the risk of urinary retention. Dose modification is recommended in patients with severe renal insufficiency [Clcr 0.25 - 0.5 mL/sec (15 - 30 mL/min)]. In such patients, TROSEC should be administered as 20 mg once a day at bedtime (see "DOSAGE AND ADMINISTRATION"). The use of TROSEC in patients with renal function <0.25 mL/sec (15 mL/min) has not been studied.
Sexual Function/Reproduction
No evidence of impaired fertility was observed in rats administered doses up to 200 mg/kg/day (about 10 multiples of the expected clinical exposure via AUC). The effect of TROSEC on sexual function/reproduction in humans has not been studied.
Special Populations
Trospium chloride has been shown to cause maternal toxicity in rats and a decrease in fetal survival in rats administered approximately 10 times the expected clinical exposure (AUC). The no effect levels for maternal and fetal toxicity were approximately equivalent to the expected clinical exposure in rats, and about 5-6 times the expected clinical exposure in rabbits. No malformations or developmental delays were observed. There are no adequate and well controlled studies in pregnant women. TROSEC should be used during pregnancy only if the potential benefit justifies the potential risk to the fetus.
Trospium chloride (2 mg/kg po and 50 ug/kg iv) was excreted, to a limited extent (<1%), into the milk of lactating rats. The activity observed in the milk was primarily from the parent compound. It is not known whether this drug is excreted in human milk. Because many drugs are excreted in human milk, caution should be exercised when TROSEC is administered to a nursing woman. TROSEC should be used during lactation only if the potential benefit justifies the potential risk to the newborn.
The safety and effectiveness of TROSEC in pediatric patients have not been established.
Of the 262 patients with overactive bladder who received treatment with TROSEC in the US 12-week clinical study, 120 patients (45.8%) were 65 years of age and older. Forty-two TROSEC-treated patients (16%) were
75 years of age.
Age did not, independently, affect trospium pharmacokinetics. However, the population older than 75 years has greater heterogeneity with respect to hepatic and renal function and has been shown to have an increased incidence of anticholinergic side effects. In this study, the incidence of commonly reported anticholinergic adverse events in patients treated with TROSEC (including dry mouth, constipation, dyspepsia, urinary tract infection (UTI), and urinary retention) was higher in patients 75 years of age and older as compared to younger patients. Therefore, based upon tolerability, the dose frequency of TROSEC may be reduced to 20 mg once daily in patients 75 years of age and older. Age did not, independently, affect trospium pharmacokinetics. However, the population older than 75 years has greater heterogeneity with respect to hepatic and renal function and has been shown to have an increased incidence of anticholinergic side effects.
Carcinogenesis and Mutagenesis
Carcinogenicity studies with trospium chloride were conducted in mice and rats. A 78-week carcinogenicity study in mice and a 104-week carcinogenicity study in rats were conducted at doses of 2, 20, and 200 mg/kg/day. No evidence of a carcinogenic effect was found in either mice or rats. The 200 mg/kg/day dose in the mouse and rat represents approximately 25 and 60 times, respectively, the human dose based on body surface area. At 200 mg/kg/day in the mouse and rat after 4 weeks the AUC was 34 and 753 ngAh/mL, respectively. The exposure in the rat is 8.6-fold higher than the AUC following 40 mg daily exposure in healthy young or elderly subjects (88 ngAh/mL). Trospium chloride was not mutagenic in tests for detection of gene mutations in bacteria (Ames test) and mammalian cells (L5178Y mouse lymphoma and Chinese Hamster Ovary [CHO] cells) or in vivo in the rat micronucleus test.
Adverse Drug Reaction Overview
Trospium chloride antagonizes the effect of acetylcholine on cholinergically innervated organs and exhibits parasympatholytic action by reducing smooth muscle tone, such as in the urogenital and gastrointestinal tracts. Adverse events characteristically associated with the use of anticholinergic agents are dry mouth, constipation, urinary retention, dry eyes, blurred vision, tachycardia, increased heart rate, and palpitation. These adverse effects have been investigated for trospium chloride in animal pharmacology studies and were monitored in human clinical trials.
Clinical Trial Adverse Drug Reactions
Because clinical trials are conducted under very specific conditions the adverse reaction rates observed in the clinical trials may not reflect the rates observed in practice and should not be compared to the rates in the clinical trials of another drug. Adverse drug reaction information from clinical trials is useful for identifying drug-related adverse events and for approximating rates. The safety of TROSEC was evaluated in Phase 2 and 3 controlled clinical trials in a total of 2975 patients, who were treated with TROSEC (N = 1673), placebo (N = 1056) or active control medications (N = 246). Of this total, 1181 patients participated in two, twelve-week, Phase 3, US efficacy and safety studies and a 9-month open-label extension. Of this total, 591 patients received TROSEC 20 mg twice daily. In all controlled trials combined, 232 and 208 patients received treatment with TROSEC for at least 24 and 52 weeks, respectively. In all placebo-controlled trials combined, the incidence of serious adverse events was 2.9% among patients receiving TROSEC 20 mg bid and 1.5% among patients receiving placebo. Of these, 0.2% and 0.3% were judged to be at least possibly related to treatment with TROSEC or placebo, respectively, by the investigator. Table 1 lists treatment emergent adverse events from the combined 12-week US safety and efficacy trials that were judged to be at least possibly related to treatment with TROSEC by the investigator, were reported by at least 1% of patients, and were reported more frequently in the TROSEC group than in the placebo group. The two most common adverse events reported by patients receiving TROSEC 20 mg bid were dry mouth and constipation. The single most frequently reported adverse event for TROSEC, dry mouth, occurred in 20.1% of TROSEC treated patients and 5.8% of patients receiving placebo. In the two Phase 3 US studies, dry mouth led to discontinuation in 1.9% of patients treated with TROSEC 20 mg bid. For the patients who reported dry mouth, most had their first occurrence of the event within the first month of treatment.
Table 1 - Incidence (%) of adverse events judged at least possibly related to treatment with TROSEC, reported in $1% of all patients treated with TROSEC and more frequent with TROSEC (20 mg bid) than placebo in Studies 11 and 22
combined
TROSEC 20 mg bid (N=591)
| Gastrointestinal disorders | ||
| Dry mouth | 34 (5.8) | 119 (20.1) |
| Constipation | 27 (4.6) | 57 (9.6) |
| Abdominal pain upper | 7 (1.2) | 9 (1.5) |
| Constipation aggravated | 5 (0.8) | 8 (1.4) |
| Dyspepsia | 2 (0.3) | 7 (1.2) |
| Flatulence | 5 (0.8) | 7 (1.2) |
| Nervous system disorders | ||
| Headache | 12 (2.0) | 25 (4.2) |
| General Disorders | ||
| Fatigue | 8 (1.4) | 11 (1.9) |
| Renal and Urinary Disorders | ||
| Urinary retention | 2 (0.3) | 7 (1.2) |
Eye Disorders
Dry eyes NOS 2 (0.3) 7 (1.2)
Abbreviations: bid = twice daily, NOS = not otherwise specified
Other adverse events from the Phase 3, US placebo-controlled trials judged possibly related to treatment with TROSEC by the investigator, occurring in $0.5% of TROSEC-treated patients, and more common with TROSEC than placebo are: tachycardia NOS, vision blurred, abdominal distension, vomiting NOS, dysgeusia, dry throat, and dry skin. During controlled clinical studies, one event of angioneurotic edema was reported. Though not an adverse effect, heart rate was noted to increase by an average of 4 beats per minute in those subjects on active treatment.
Less Common Clinical Trial Adverse Drug Reactions (<1%)
Blood and lymphatic system disorders:
lymphadenopathy
Cardiac disorders:
angina pectoris, coronary artery disease, palpitations, supraventricular extrasystoles, tachycardia
Ear and labyrinth disorders:
ear pain
Endocrine disorders:
endocrine disorder
Eye disorders: Gastrointestinal disorders: General disorders and administration site conditions:
accommodation disorder, dry eye, eye pain, vision blurred
abdominal discomfort, abdominal distension, abdominal pain upper, constipation aggravated, gastrointestinal disorder, mouth ulceration, vomiting
chest pain, influenza like illness, oedema, oedema peripheral, thirst
Infections and infestations:
urinary tract infection
Investigations:
electrocardiogram abnormal, heart rate increased, QRS axis abnormal, residual urine volume, weight increased
Metabolism and nutrition disorders: Musculoskeletal and connective tissue disorders:
appetite decreased, fluid retention, hyperuricaemia
back pain, muscle cramps, pain in jaw, peripheral swelling
Nervous system disorders:
dysgeusia, migraine
Renal and urinary disorders: Reproductive system and breast disorders:
bladder pain, dysuria, haematuria, micturition disorder, micturition urgency, renal pain, urinary hesitation, urine abnormal, urine odour abnormal
vaginal pain
Respiratory, thoracic and mediastinal disorders:
dry throat, hoarseness, nasal dryness, respiratory tract congestion, rhinitis
Skin and subcutaneous tissue disorders:
dermatitis contact, dry skin, eczema, hair growth abnormal, photosensitivity reaction, pruritus, rash erythematous, rash, sweating increased, urticaria
Vascular disorders:
flushing, hot flushes, orthostatic hypotension
Abnormal Hematologic and Clinical Chemistry Findings
Analysis of laboratory data from 1 clinical pharmacology study and 2 controlled studies did not identify any trends to suggest that trospium chloride is associated with any relevant laboratory abnormalities in hematology, clinical chemistry, or urinalysis parameters.
Post-Market Adverse Drug Reactions
Additional spontaneous adverse events, regardless of relationship to drug, reported from marketing experience with trospium chloride include: gastritis, palpitations, supraventricular tachycardia, chest pain, Stevens-Johnson syndrome, anaphylactic reaction, syncope, rhabdomyolysis, vision abnormal, hallucinations and delirium, and "hypertensive crisis".
Overview
Possible drug interactions, based on the anticholinergic properties of trospium chloride, could include potentiation of the anticholinergic action of agents possessing these properties. Also, trospium chloride could theoretically alter the absorption of some concomitantly administered drugs due to anticholinergic effects on gastrointestinal motility. The major route of excretion of trospium chloride is the kidney. Consequently, concomitant drug therapy that significantly interferes with renal excretion of trospium chloride may cause drug-drug interactions (see "Drug-Drug Interactions").
Drug-Drug Interactions
The concomitant use of TROSEC with other anticholinergic agents that produce dry mouth, constipation, and other anticholinergic pharmacological effects may increase the frequency and/or severity of such effects. Anticholinergic agents may potentially alter the absorption of some concomitantly administered drugs due to anticholinergic effects on gastrointestinal motility. No in vivo drug-drug interaction studies have been performed to assess the effect of concomitant medications on the pharmacokinetics of TROSEC or to assess the effect of TROSEC on the pharmacokinetics of other drugs. TROSEC is metabolized by esterases and excreted by the kidneys by a combination of tubular secretion and glomerular filtration. Based on in vitro data, no clinically relevant interactions with the metabolism of trospium chloride are expected. However, drugs which are actively secreted (e.g. digoxin, procainamide, pancuronium, morphine, vancomycin, metformin and tenofovir) may interact with trospium chloride by competing for renal tubular secretion. Coadministration of TROSEC with drugs that are eliminated by active renal tubular secretion may increase the serum concentration of TROSEC and/or the coadministered drug due to competition for this elimination pathway. Careful patient monitoring is recommended in patients receiving such drugs (See "ACTION AND CLINICAL PHARMACOLOGY, Excretion").
Drug-Food Interactions
Coadministration of TROSEC with food has been shown to reduce drug absorption (See "ACTION AND CLINICAL PHARMACOLOGY, Pharmacokinetics, Effect of Food"). TROSEC should therefore be taken at least one hour prior to meals or on an empty stomach (See "DOSAGE AND ADMINISTRATION").
Drug-Herb Interactions
Interactions with herbal products have not been established.
Drug-Laboratory Test Interactions
Interactions between TROSEC and laboratory tests have not been studied.
Dosing Considerations
Patients with severe renal impairment [CLcr 0.25 - 0.5 mL/sec (15 - 30 mL/min)] (See "WARNINGS AND PRECAUTIONS, Renal). Geriatric patients $ 75 years of age (See "WARNINGS AND PRECAUTIONS, Special Populations").
Recommended Dose and Dosage Adjustment
The recommended dose is 20 mg twice daily. Dosage modification is recommended in the following patient populations: For patients with severe renal impairment [CLcr 0.25 - 0.5 mL/sec (15 - 30 mL/min)] , the recommended dose is 20 mg once daily at bedtime. The use of TROSEC in patients with renal function <0.25 mL/sec (15 mL/min) has not been studied. In geriatric patients $ 75 years of age, dose may be titrated down to 20 mg once daily based upon tolerability (See "WARNINGS AND PRECAUTIONS, Special Populations"). Caution should be used when administering TROSEC to patients with moderate or severe hepatic impairment.
Missed Dose
If a dose is skipped, patients are advised to take their next dose on an empty stomach 1 hour prior to their next meal.
Administration
TROSEC should be dosed at least one hour before meals or given on an empty stomach.
Overdosage with TROSEC may result in severe anticholinergic effects. Treatment should be supportive and provided according to symptoms. In the event of overdosage, electrocardiographic (ECG) monitoring is strongly recommended. A 7-month-old baby experienced tachycardia and mydriasis after administration of a single dose of trospium chloride 10 mg given by a sibling. The baby's weight was reported as 5 kg. Following admission into the hospital and about 1 hour after ingestion of the trospium chloride, medicinal charcoal was administered for detoxification. While hospitalized, the baby experienced mydriasis and tachycardia up to 230 beats/minute. Therapeutic intervention was not deemed necessary. The baby was discharged as completely recovered the following day.
Mechanism of Action
TROSEC is an antispasmodic, antimuscarinic agent. Trospium chloride antagonizes the effect of acetylcholine on muscarinic receptors in cholinergically innervated organs. Its parasympatholytic action reduces the tonus of smooth muscle in the bladder. Receptor assays showed that trospium chloride has negligible affinity for nicotinic receptors as compared to muscarinic receptors at concentrations obtained from therapeutic doses.
Pharmacodynamics
Placebo-controlled studies employing urodynamic variables were conducted in patients with conditions characterized by involuntary detrusor contractions. The results demonstrate that TROSEC increases maximum cystometric bladder capacity and volume at first detrusor contraction.
Pharmacokinetics
A summary of mean (+- standard deviation) pharmacokinetic parameters for a single 20 mg dose of TROSEC is provided in Table 2.
| C m ax (ng/mL) | AUC 0 - 4 (ng/mL @ hr) | T m ax (hr) | t 1/2 (hr) |
| 3.5 +- 4.0 | 36.4 +- 21.8 | 5.3 +- 1.2 | 18.3 +- 3.2 |
The mean plasma concentration-time (+ SD) profile for TROSEC is shown in Figure 1.
Absorption: After oral administration, less than 10% of the dose is absorbed. Mean absolute bioavailability of a 20 mg dose is 9.6% (range: 4.0-16.1%). Peak plasma concentrations (Cmax) occur between 5 to 6 hours post-dose. Mean Cmax increases greater than dose-proportionally; a 3-fold and 4-fold increase in Cmax was observed for dose increases from 20 mg to 40 mg and from 20 mg to 60 mg, respectively. AUC exhibits dose linearity for single doses up to 60 mg. TROSEC exhibits diurnal variability in exposure with a decrease in Cmax and AUC of up to 59% and 33%, respectively, for evening relative to morning doses. Effect of Food: Administration with a high fat meal resulted in reduced absorption, with AUC and Cmax values 70-80% lower than those obtained when TROSEC was administered while fasting. Therefore, it is recommended that TROSEC should be taken at least one hour prior to meals or on an empty stomach. (See "DOSAGE AND ADMINISTRATION").
Protein binding ranged from 50 to 85% when therapeutic concentration levels (0.5
- 50 ng/mL) were incubated with human serum in vitro. The 3H-trospium chloride ratio of plasma to whole blood was 1.6:1. This ratio indicates that the majority of 3H-trospium chloride is distributed in plasma. The apparent volume of distribution for a 20 mg oral dose is 395 (+- 140) liters. Metabolism: The metabolic pathway of trospium chloride in humans has not been fully defined. Of the 10% of the dose absorbed, metabolites account for approximately 40% of the excreted dose following oral administration. The major metabolic pathway is hypothesized as ester hydrolysis with subsequent conjugation of benzylic acid to form azoniaspironortropanol with glucuronic acid. Cytochrome P450 is not expected to contribute significantly to the elimination of trospium chloride. In vitro data from human liver microsomes investigating the inhibitory effect of trospium chloride on seven cytochrome P450 isoenzyme substrates (CYP1A2, 2A6, 2C9, 2C19, 2D6, 2E1, and 3A4) suggest a lack of inhibition at clinically relevant concentrations of trospium chloride3. Excretion: The plasma half-life for TROSEC following oral administration is approximately 20 hours. After administration of oral 14C-trospium chloride, the majority of the dose (85.2%) was recovered in feces and a smaller amount (5.8% of the dose) was recovered in urine; 60% of the radioactivity excreted in urine was unchanged trospium chloride. The mean renal clearance for trospium chloride 8 mL/sec (29.07 L/hour) is 4-fold higher than average glomerular filtration rate, indicating that active tubular secretion is a major route of elimination for trospium chloride. There may be competition for elimination with other compounds that are also renally eliminated (See "DRUG INTERACTIONS").
Special Populations and Conditions
The pharmacokinetics of TROSEC were not evaluated in pediatric patients.
Geriatrics: Age did not appear to significantly affect the pharmacokinetics of TROSEC however, increased anticholinergic side effects unrelated to drug exposure were observed in patients $ 75 years of age. (See "WARNINGS AND PRECAUTIONS, Special Populations", and "DOSAGE AND ADMINISTRATION"). Gender: Studies comparing the pharmacokinetics in different genders had conflicting results. When a single 40 mg TROSEC dose was administered to 16 elderly subjects, exposure was 45% lower in elderly females compared to elderly males. When 20 mg TROSEC was dosed bid for 4 days to 6 elderly males and 6 elderly females (60 to 75 years), AUC and Cmax were 26% and 68% higher, respectively, in females without hormone replacement therapy than in males.
Pharmacokinetic differences due to race have not been studied.
Hepatic Insufficiency: There is no information regarding the effect of severe hepatic impairment on exposure to TROSEC. Maximum trospium chloride concentration (Cmax) increased 12% and 63% in subjects with mild and moderate hepatic impairment, respectively, compared to healthy subjects. Mean area under the plasma concentration-time curve (AUC) was similar. Caution should be used when administering TROSEC to patients with moderate and severe hepatic dysfunction. (See "WARNINGS AND PRECAUTIONS, Hepatic/Biliary/Pancreatic"). Renal Insufficiency: Severe renal impairment significantly altered the disposition of TROSEC. A 4.5-fold and 2-fold increase in mean AUC0-4 and Cmax, respectively, and the appearance of an additional elimination phase with a long half-life (- 33 hr) was detected in patients with severe renal insufficiency [Clcr 0.25 - 0.5 mL/sec (15 - 30 mL/min)] compared with healthy, nearly age-matched subjects. The different pharmacokinetic behavior of TROSEC in patients with severe renal insufficiency necessitates adjustment of dosage frequency. The pharmacokinetics of TROSEC have not been studied in people with moderate or mild renal impairment [CLcr ranging from 0.5 - 1.3 mL/sec (30-80 mL/min)]. (See "WARNINGS AND PRECAUTIONS, Renal", and "DOSAGE AND ADMINISTRATION"). The use of TROSEC in patients with renal function <0.25 mL/sec (15 mL/min) has not been studied.
Store at controlled room temperature 15deg to 30degC. Keep in a safe place out of reach of children.
None.
Brownish yellow, biconvex, glossy coated tablets, imprinted with a 'T'.
Each tablet contains 20 mg of trospium chloride. Each tablet also contains the following inactive ingredients: sucrose, wheat starch, microcrystalline cellulose, talc, lactose monohydrate, calcium carbonate, titanium dioxide, stearic acid, croscarmellose sodium, povidone, polyethylene glycol 8000, colloidal silicon dioxide, ferric oxide, carboxymethylcellulose sodium, white wax, magnesium stearate, carnauba wax.
Blister packs of 10.
PART II: SCIENTIFIC INFORMATION
Proper name: Trospium chloride Chemical name: Spiro[8-azoniabicyclo[3,2,1]octane-8,1'-pyrrolidinium]-3-[(hydroxydiphenyl-acetyl)- oxy]-chloride(1", 3$, 5")-(9Cl) Molecular formula and molecular mass: Molecular formula: C25H30ClNO3 Molecular mass: 427.97 Structural formula: Physicochemical properties: Trospium chloride is a white to almost white crystalline powder The compound's solubility in water is approximately 1 g/2 mL. n-Octanol/phosphate buffer (pH 7.4) = 0.038. The molecule is hydrophylic and highly charged.4
TROSEC was evaluated for the treatment of patients with overactive bladder who had symptoms of urinary frequency, urgency, and urge incontinence in two US 12-week, placebo-controlled studies and one 9-month open label extension1, 2. Study 11 was a randomized, double-blind, placebo-controlled, parallel-group study in 523 patients. A total of 262 patients received TROSEC 20 mg twice daily and 261 patients received placebo. The majority of patients were Caucasian (85%) and female (74%) with a mean age of 61 years (range 21 to 90 years). Entry criteria required that patients have urge or mixed incontinence (with a predominance of urge), urge incontinence episodes of at least 7 per week, and greater than 70 micturitions per week. The patient's medical history and urinary diary during the treatment-free baseline confirmed the diagnosis. Study 22 was nearly identical in design to Study 1. A total of 329 patients received TROSEC 20 mg twice daily and 329 patient received placebo. The majority of patients were Caucasian (88%) and female (82%) with a mean age of 61 years (range 19 to 94 years). Entry criteria were identical to Study 1.
| Table 3 - Summary of patient demographics: Studies 1 and 2 | |||||
| Trial design | Dosage (route) and duration | Study subjects (n=number) | Mean age (Range) | Gender | |
| Study 1 | Randomized, double- blind, placebo- controlled, parallel- group plus open-label treatment phase | TROSEC 20 mg bid (oral) Placebo bid (oral) 12-week double-blind treatment phase plus 9-month open-label treatment phase | TROSEC: N = 262 Placebo: N = 261 | 61 yrs (21-90 yrs) | 134M/389F |
| Study 2 | Randomized, double- blind, placebo- controlled, parallel- group | TROSEC 20 mg bid (oral) Placebo bid (oral) 12-week double-blind treatment phase | TROSEC: N = 329 Placebo: N = 329 | 61 yrs (19-94 yrs) | 122M/536F |
M = male, F = female, yrs = years
: Reductions in urinary frequency, urge incontinence episodes and urinary void volume for placebo and TROSEC treatment groups are summarized in Table 4 and Figures 2 and 3.
| Table 4: Mean (SE) change from baseline to end of treatment (Week 12 or last observation carried forward) for urinary frequency, urge incontinence episodes, and void volume in Study 1 |
| Placebo TROSEC Efficacy endpoint N=256 N=253 P-value |
| Urinary frequency/24 hours a, * Mean baseline 12.9 12.7 <0.001 Mean change from baseline -1.3 (0.2) -2.4 (0.2) Urge incontinence episodes/week b, * Mean baseline 30.1 27.3 0.012 Mean change from baseline -13.9 (1.2) -15.4 (1.1) Urinary void volume/toilet void (mL) a, c Mean baseline 156.6 155.1 <0.001 Mean change from baseline 7.7 (3.1) 32.1 (3.1) |
| a Treatment differences assessed by analysis of variance for ITT:LOCF data set. b Treatment differences assessed by ranked analysis of variance for ITT:LOCF data set. c Placebo N=253, TROSEC N=248. * Denotes co-primary endpoint. ITT=inent-to-treat, LOCF=last observation carried forward. |
: Reductions in urinary frequency, urge incontinence episodes, and urinary void volume for placebo and TROSEC treatment groups are summarized in Table 5 and Figures 4 and 5.
| Table 5: Mean (SE) change from baseline to end of treatment (Week 12 or last observation carried forward) for urinary frequency, urge incontinence episodes, and void volume in Study 2 |
| Placebo TROSEC Efficacy endpoint N=325 N=323 P-value |
| Urinary frequency/24 hours a, * Mean baseline 13.2 12.9 <0.001 Mean change from baseline -1.8 (0.2) -2.7 (0.2) Urge incontinence episodes/week b Mean baseline 27.3 26.9 <0.001 Mean change from baseline -12.1 (1.0) -16.1 (1.0) Urinary void volume/toilet void (mL) a, c Mean baseline 154.6 154.8 <0.001 Mean change from baseline 9.4 (2.8) 35.6 (2.8) |
| a Treatment differences assessed by analysis of variance for ITT:LOCF data set. b Treatment differences assessed by ranked analysis of variance for ITT:LOCF data set. c Placebo N=320, TROSEC N=319. * Denotes co-primary endpoint. ITT=inent-to-treat, LOCF=last observation carried forward. |
In addition to the placebo-controlled studies, active-controlled, randomized, double-blind, multi- centre trials, ranging from 2 to 52 weeks in duration, compared trospium chloride to oxybutynin hydrochloride, in patients with detrusor instability or detrusor hyperreflexia. Trospium chloride had comparable efficacy to oxybutynin, but better tolerability5, 6.
Pharmacodynamics
Intravenous administration of trospium chloride to female rats produced marked inhibition of cholinergic spasms when acetylcholine was dripped onto the exteriorised bladder. Effects of trospium chloride have also been demonstrated on lower urinary tract functions in the dog.
2 3
Trospium chloride demonstrates high affinity for muscarinic receptors, with equipotent binding to M and M receptors (pKi values: 9.2 and 9.3)4.
Pharmacokinetics
Placental transfer and distribution in milk
Gestating rats were given 50 :g/kg 3H-trospium chloride by i.v. injection on the 10th, 16th and 20th day of gestation. Only small amounts of the hydrophilic trospium chloride crossed into the placenta. Trospium chloride concentrations in the placenta were similar to those in blood but lower than in the liver, kidneys and heart. The highest radioactivity concentrations in the fetal organs occurred in the livers. The transfer of 3H-trospium chloride and its metabolites into the milk of lactating rats after oral and i.v. administration was determined between the 7th and 9th day postpartum. The percentage of i.v. injected trospium chloride activity excreted into the milk within 24 hours was 4.36 x 10-2. Generally, trospium chloride and azoniaspironortropanol (as the only metabolite) were present. After oral administration, the milk levels never exceeded the blood levels.
HUMAN
Pharmacokinetics
Absorption and bioavailability
Linear dependence of dose was established for PK parameters. Mean absolute bioavailabilities for oral doses of 20, 40, and 60 mg were 9.6%, 10.8%, and 12%, respectively, with an overall absolute bioavailability of 10.8%. Mean absorption rates for oral doses of 20, 40, and 60 mg were 14.6%, 13.2%, and 14.3%, respectively, with an overall absorption rate of 14% of dose. Cmax occurred approximately 5 hours post-dose, showing slow drug absorption. Following 20 mg bid dosing for 6 days, trospium chloride plasma concentrations at steady-state on Day 6 were 1.56 ng/mL vs. 1.2 ng/mL following a single dose of 20 mg. AUC and Cmax values were 70-80% lower under fed versus fasted conditions. 90% CIs for the PK parameters of AUC0-4 and Cmax fell outside the CI limits of acceptance. The CI for half value duration (HVD) slightly overlapped the CI limits of acceptance. Thus, the absorption of trospium chloride from the GI tract may be altered by concomitant food intake. Due to the food effects observed, it is recommended that TROSEC be taken on an empty stomach (see "DOSAGE AND ADMINISTRATION"). Cmax and AUC values decreased up to 59% and 33%, respectively, when TROSEC was administered in the evening compared to in the morning. (See "ACTION AND CLINICAL PHARMACOLOGY").
Distribution and protein binding
In plasma protein binding studies with human serum, binding rates between the range of approximately 48 to 78% over various concentration ranges were observed. These rates do not suggest any likely interference with other drugs. Competitive plasma protein binding is also unlikely due to low plasma concentration exposure at the therapeutic dose (<10 ng/mL after a single 40 mg dose). The plasma to whole blood ratio of non-volatile 3H-trospium chloride was 1:6:1 at 0.75 hours post-dose (single i.v. target dose of 1 mg in healthy male subjects). Given that the normal hematocrit is approximately 45% in healthy men, the 1:6:1 ratio translates to a 12% distribution of 3H-trospium chloride in blood cells.
Metabolism and excretion
Trospium chloride has negligible inhibitory effects on seven cytochrome P450 isoenzymes, including CYP3A4 and CYPD26 based on in vitro data3. After oral administration, 60% of the radioactivity excreted in urine was unchanged trospium, demonstrating first pass metabolism. The mean renal clearance rate observed (29.07 L/hour) indicates that trospium is actively secreted into the urine. Following intravenously administered radio-labelled trospium chloride, more than 90% of the dose was recovered; approximately 70% in urine and 20% in faeces. Greater than 80% of the radioactivity excreted in urine was [3H]-trospium. The major metabolite, azoniaspironortropanol, represented approximately 10% of the excreted dose in urine. In addition, 2 unknown metabolites combined to represent less than 10% of the excreted dose.
In mice and rats, oral and i.v. dosing of trospium chloride produced similar effects: The calculated LD50 for mice is 425 mg/kg oral and 7.5 mg/kg i.v. for males and 365 mg/kg oral and 8.4 mg/kg i.v. for females. In rats, high oral doses (630 - 1260 mg/kg) produced clinical signs of hyperactivity, tremor, spasms, and tonoclonic convulsions after 10 minutes. After 1 hour, reduced activity was observed. During the first 24 hours of dosing, impaired coordination (males), postural abnormalities, diminished elicitation of reflexes (females), reduction in grip strength and tone of the extremities (females), changes in the colour of the skin and mucous membranes, piloerection (males) and lowered body temperature were observed. Death occurred within 24 hours after dosing. The LD50 calculated for rats is 940 mg/kg for males and 800 mg/kg for females [the maximum recommended daily dosing for humans is 40 mg (20 mg bid)]. Similar reactions were observed after i.v. administration, with additional effects of cyanosis and bradypnoea. The animals died within 5 minutes after injection. The calculated LD50 is 10.7 mg/kg for males and 12.3 mg/kg for females.
In rats dosed orally with 200 mg/kg trospium chloride for approximately 35 weeks, body weight gain was observed. In dogs, food consumption and body weight gain were slightly lower after receiving 60 mg/kg for 26 weeks. Mydriasis with photophobia, impaired pupillary accommodation, corneal lesions as well as raised mucus production were also observed. One male died of bacterial bronchopneumonia, possibly due to a treatment-related increase of mucus secretion.
Trospium chloride was not genotoxic in a number of in-vitro assays such as the Ames test, mouse lymphoma test and mitotic gene conversion and chinese hamster ovary assays. In an in-vivo micronucleus test in rats, trospium chloride did not induce significant levels of micronucleated polychromatic erythrocytes in bone marrow cells following administration of a single oral dose of 400 mg/kg.
In a 78 week study in mice, body weight gain and intestinal distension similar to that seen in rats, described below, were observed. Increased lung adenomas in males (20 mg/kg) and females (2 mg/kg) were observed. The incidences of proliferative lung lesions were most likely due to chance and not an effect of trospium chloride. In a 24-month rat study, there was a distinct reduction in body weight gain at a 200 mg/kg doses in males and females and in females only at 20 mg/kg. Bowel distension was observed in all treated groups. Trospium chloride did not increase the overall tumor incidence, and no tumor types were found that are uncommon in the rat strain used.
In the rat, trospium chloride caused no impairment of male and female fertility in treated parents (Fo) or their untreated offspring. Furthermore, the breeding and rearing behaviour and the postnatal development were entirely normal throughout. Trospium chloride was well tolerated by dams of trospium chloride treated rats and examination of the fetuses revealed no embryotoxic or teratogenic effects. A test on rabbits showed no compound-specific effects in either dams or fetuses. In female rats given trospium chloride from the 15th day of gestation until the end of the lactation period, .dose-related effects occurring at doses of 2, 20 and 200 mg/kg consisted of rapid and irregular breathing, pupillary dilatation and increased excitability. Towards the end of the lactation period, two females died within one hour of dosing (200 mg/kg). Rearing performance of the dams was normal, and only the females given 200 mg/kg gained slightly less body weight in the gestation period than the controls. The postnatal development of the offspring was invariably normal.
Good local (gastro-intestinal) tolerance has been shown in various long-term studies.
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Data on file, Oryx Pharmaceuticals, Inc.
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