Orally administered moxifloxacin prolongs QTc in healthy Chinese volunteers: a randomized,single-blind,crossover study

Aim:

To investigate the QT/QTc effects of orally administered moxifloxacin in healthy Chinese volunteers.

Methods:

This was a single-blinded, randomized, single-dose, placebo-controlled, two-period cross-over study. A total of 24 healthy Chinese volunteers were enrolled, randomly assigned to two groups: one group received moxifloxacin (400 mg, po) followed by placebo with a 7-d interval, another group received placebo followed by moxifloxacin with a 7-d interval. On the days of dosing, 12-lead 24 h Holter ECGs were recorded and evaluated by an ECG laboratory blind to the treatments. Blood samples were collected to determine plasma concentrations of moxifloxacin.

Results:

The orally administered moxifloxacin significantly prolonged the mean QTc at all time points except 0.5 h post-dose. The largest time-matched difference in the QTcI was 8.35 ms (90% CI: 5.43, 11.27) at 4 h post-dose. The peak effect on QTcF was 9.35 ms (90% CI: 6.36, 12.34) at 3 h post-dose. A pharmacokinetic-QTc model suggested a 2.084 ms increase in the QTc interval for every 1000 ng/mL increase in plasma concentration of moxifloxacin. In addition, the orally administered moxifloxacin was well tolerated by the subjects.

Conclusion:

Orally administered moxifloxacin significantly prolongs QTc, which supports its use as a positive control in ICH-E14 TQT studies in Chinese volunteers.     

No cardiac effects of therapeutic and supratherapeutic doses of rupatadine: results from a ‘thorough QT/QTc study’ performed according to ICH guidelines

AIMS

To evaluate the effects of therapeutic and supratherapeutic doses of rupatadine on cardiac repolarization in line with a ‘thorough QT/QTc study’ protocol performed according to International Conference on Harmonization guidelines.

METHODS

This was a randomized (gender-balanced), parallel-group study involving 160 healthy volunteers. Rupatadine, 10 and 100 mg day⁻¹, and placebo were administered single-blind for 5 days, whilst moxifloxacin 400 mg day⁻¹ was given on days 1 and 5 in open-label fashion. ECGs were recorded over a 23-h period by continuous Holter monitoring at baseline and on treatment days 1 and 5. Three 10-s ECG samples were downloaded at regular intervals and were analysed independently. The primary analysis of QTc was based on individually corrected QT (QTcI). Treatment effects on QTcI were assessed using the largest time-matched mean difference between the drug and placebo (baseline-subtracted) for the QTcI interval. A negative ‘thorough QT/QTc study’ is one where the main variable is around ≤5 ms, with a one-sided 95% confidence interval that excludes an effect >10 ms.

RESULTS

The validity of the trial was confirmed by the fact that the moxifloxacin-positive control group produced the expected change in QTcI duration (around 5 ms). The ECG data for rupatadine at both 10 and 100 mg showed no signal effects on the ECG, after neither single nor repeated administration. Furthermore, no pharmacokinetic/pharmacodynamic relationship, gender effects or clinically relevant changes in ECG waveform outliers were observed. No deaths or serious or unexpected adverse events were reported.

CONCLUSIONS

This ‘thorough QT/QTc study’ confirmed previous experience with rupatadine and demonstrated that it had no proarrhythmic potential and raised no concerns regarding its cardiac safety.     

The Effects of Moxifloxacin on QTc Interval in Healthy Korean Male Subjects

Background and objective

Moxifloxacin 400 mg is a widely used positive control in thorough QT (TQT) studies, but its QT-prolonging effects in Korean subjects have not been studied. The present study was conducted to collect pilot data in Korean subjects after moxifloxacin administration to evaluate the adequacy of moxifloxacin as a positive control.

Methods

Thirty-eight, healthy, Korean, male subjects were recruited for pharmacokinetic (PK) blood sampling and electrocardiography (ECG) recordings at three different study sites. On day 1, a baseline 12-lead ECG was recorded, and on day 2, ECG recordings were conducted after placebo, or moxifloxacin 400- or 800-mg administration. Baseline-corrected, placebo-adjusted, corrected QT (ΔΔQTc) values were calculated. Blood samples were collected after moxifloxacin administration and PK parameters were assessed.

Results

A total of 33 subjects completed the study. The largest time-matched ΔΔQTc occurred approximately 4 h after dosing, with ΔΔQTcI (QT interval corrected by individual QT-RR regression model) values of 11.66 ms (moxifloxacin 400 mg) and 20.96 ms (800 mg). The mean and 90 % confidence intervals of ΔΔQTcI did not include zero at any of the measurement time points. There was a positive correlation between plasma moxifloxacin concentration and ΔΔQTcI (r = 0.422). Dose-proportional PK profiles were observed.

Conclusion

Moxifloxacin 400 mg is an adequate positive control in Korean TQT studies. Our results indicate that moxifloxacin 400 mg can be used to evaluate the cardiac safety of a drug in Korean subjects.     

Comparison of the effects of levofloxacin on QT/QTc interval assessed in both healthy Japanese and Caucasian subjects (pages

AIMS

There is no consensus as to what extent the results of thorough QT interval/corrected QT interval (QT/QTc) studies need to be bridged.

METHODS

The results of two studies using levofloxacin in Japanese and Caucasian subjects were compared in a post hoc analysis to investigate the similarity of dose–effect responses.

RESULTS

Concentration–response analysis based on the change of QT interval corrected using Fridericia''s formula (QTcF) from time-matched placebo was planned and performed in the combined data sets. At the geometric maximum mean concentration for the two doses in the Caucasian study, a predicted effect on QTcF comparable to the effects observed was found. For the Japanese study, the predicted effect was lower, but the difference was not statistically significant.

CONCLUSIONS

No statistically significant differences in QTc-prolonging effect between Japanese and Caucasian subjects were observed following levofloxacin dosing. However, a trend suggests that Caucasian subjects may be more sensitive. Age and sex did not have an impact.     

Lamotrigine does not prolong QTc in a thorough QT/QTc study in healthy subjects

AIM

To characterize the effects of lamotrigine on QT interval in healthy subjects.

METHODS

Healthy subjects received a single oral dose of moxifloxacin (400 mg) or placebo in crossover design, followed by a dose-escalating regimen of lamotrigine (n = 76) over a 77-day period, or matched placebo (n = 76). Blood samples were taken for determination of moxifloxacin and lamotrigine concentrations and digital 12-lead ECGs were recorded. The relationships between individual QT values and respective individual moxifloxacin or lamotrigine concentrations were explored using population pharmacokinetic–pharmacodynamic (PK–PD) modelling.

RESULTS

Moxifloxacin was associated with a maximum mean increase from baseline in QTcF of 14.81 ms [90% confidence interval (CI) 13.50, 16.11] 2.5 h after dosing. Steady-state exposure to lamotrigine (50, 150 or 200 mg b.d.) was not associated with an increase in QTc interval. Small reductions in QTcF (maximum mean difference from placebo −7.48 ms, 90% CI −10.49, −4.46) and small increases in heart rate (maximum mean difference from placebo 5.94 bpm, 90% CI 3.81, 8.06) were observed with lamotrigine 200 mg b.d. vs. placebo. No effect of lamotrigine on QRS duration or blood pressure was observed. No outliers with QTcF > 450 ms, or with an increase from baseline of >60 ms were observed in the lamotrigine group. PK–PD modelling indicated statistically significant decreases in individually corrected QT intervals for lamotrigine and statistically significant increases in individually corrected QT intervals for moxifloxacin over the concentration ranges studied.

CONCLUSIONS

Therapeutic doses of lamotrigine (50–200 mg b.d.) were not associated with QT prolongation in healthy subjects.

WHAT IS ALREADY KNOWN ABOUT THIS SUBJECT

• Drugs that inhibit the human cardiac delayed rectifier potassium current may lead to prolongation of the cardiac QT interval and are associated with a fatal, polymorphic, ventricular tachycardia known as torsades de pointes.
• Lamotrigine is indicated in the treatment of epilepsy and the prevention of mood episodes in patients with bipolar disorder.
• Lamotrigine inhibits the human cardiac delayed rectifier potassium current in vitro, and it has been hypothesized that QT prolongation may contribute to the risk of sudden unexpected death in epilepsy patients.

WHAT THIS STUDY ADDS

• This is the first reported thorough QT/QTc study with lamotrigine conducted to International Conference on Harmonization guidelines.
• The mean QTc interval was not prolonged by lamotrigine in healthy subjects, as assessed by the standard heart rate correction methods (Fridericia''s and Bazett''s).
• The in vitro inhibition of the delayed rectifier potassium current does not translate into an effect on QT in man.

     

Lenalidomide at Therapeutic and Supratherapeutic Doses Does Not Prolong QTc Intervals in the Thorough QTc Study Conducted in Healthy Men

The effect of lenalidomide on the corrected QT (QTc) interval was evaluated in healthy men and extended to patients based on the lenalidomide concentration–QTc (C–QTc) relationship. A rigorous assessment of the effect of lenalidomide on QTc intervals was conducted in healthy volunteers who each received, in randomized order, a single oral dose of 10 mg lenalidomide, 50 mg lenalidomide, 400 mg moxifloxacin (positive control) and placebo. Plasma lenalidomide exposure was compared between healthy volunteers and patients with multiple myeloma or myelodysplastic syndromes. In healthy volunteers, moxifloxacin produced the expected significant prolongation in QTcI (individual correction). For lenalidomide 10 mg and 50 mg, the time‐matched changes from placebo in the baseline‐adjusted least‐squares mean QTcI were <3 ms with the upper limit of the two‐sided 90% confidence interval for the change <10 ms at all time‐points. No subjects experienced QTcI >450 ms or change from baseline >60 ms after lenalidomide administration. Similar results were seen with QT interval data corrected by Fridericia and Bazett methods. The C–QTc analysis yielded no significant association between lenalidomide concentrations and QTcI changes up to 1522 ng/mL; this range was close to that observed in patients receiving lenalidomide doses up to 50 mg, including those with reduced drug clearance due to renal impairment. In conclusion, single doses of lenalidomide up to 50 mg were not associated with prolonged QTc intervals in healthy males. The C–QTc analysis further assured that lenalidomide doses up to 50 mg are not expected to prolong QTc intervals in patients.     

Assessment of the cardiac safety of prucalopride in healthy volunteers: a randomized, double-blind, placebo- and positive-controlled thorough QT study

AIMS

To assess steady-state effects of therapeutic and supra-therapeutic doses of prucalopride on the QT interval using a novel design involving a parallel placebo group with nested crossover for positive control.

METHODS

A double-blind, double-dummy, placebo- and active-controlled study was conducted in 120 healthy male and female volunteers ({"type":"clinical-trial","attrs":{"text":"NCT00903747","term_id":"NCT00903747"}}NCT00903747). Volunteers were randomized to receive prucalopride 2–10 mg once daily (therapeutic and supratherapeutic doses, respectively) (group 1), placebo with 400 mg moxifloxacin on day 1 (group 2a), or placebo with moxifloxacin on day 15 (group 2b). Twelve-lead 24 h Holter ECGs recorded at various time-points were evaluated blind and centrally.

RESULTS

Estimated mean difference in study specific corrected QT interval (QT_cSS) time-matched change from baseline between prucalopride (2 and 10 mg) and placebo was <5 ms at all time points (maximum mean difference: 3.83 ms at 3.5 h post dose on day 5 with 2 mg [90% Cl −0.33, 6.38 ms]). Upper limits of the two-sided 90% CI for QT_cSS were all <10 ms. There were no outlying QT_cSS values >450 ms and no subjects had an increase >60 ms following prucalopride. Moxifloxacin produced the expected significant changes in QT_cSS (>5 ms, maximum of +12.7 ms at 5 h post dose) at all time-points except 1 h post dose. Prucalopride resulted in small increases in heart rate (maximum of 5.8 beats min^–1), which were similar for 2 and 10 mg. Prucalopride was well tolerated after first day of treatment.

CONCLUSION

Prucalopride at both therapeutic and supra therapeutic doses has no clinically significant effects on cardiac repolarisation in healthy volunteers.     

A repeat-dose thorough QT study of inhaled fluticasone furoate/vilanterol combination in healthy subjects

AIMS

This study was designed as a thorough QT (TQT) study to evaluate the effects of fluticasone furoate(FF)/vilanterol (VI) in healthy subjects. Supportive data from a TQT study conducted with FF are also presented.

METHODS

This was a randomized, placebo-and positive-controlled, double-dummy, double-blind, four-way crossover study, in which healthy subjects (n = 85) were randomized to 7 days of once-daily treatment of FF/VI (200/25 or 800/100 μg) or placebo or single-dose oral moxifloxacin (single-blind, 400 mg). In the supportive TQT study, subjects (n = 40) were randomized to single-dose inhaled FF(4000 μg), oral moxifloxacin (400 mg) or placebo.

RESULTS

There was a lack of effect of FF/VI (200/25 μg) on QTcF (Fridericia''s correction); all time-matched mean differences from baseline relative to placebo (0–24 h) were <5 ms, with upper 90% confidence intervals (CI) of <10 ms. At 800/100 μg, FF/VI had no significant clinicaleffect on QTcF except at 30 min postdose when the 90% CI was >10 ms [mean (90% CI), 9.6 ms (7.2, 12.0)]. No effect on QTci (individually corrected) was observed at either strength of FF/VI, with mean time-matched treatment differences <5 ms at all time points [upper 90% CIs <10 ms (0–24 h)]. Assay sensitivity was confirmed; moxifloxacin prolonged QTcF and QTci, with time-matched mean differences from baseline relative toplacebo of >10 ms (1–8 h postdose).

CONCLUSIONS

Repeat once-daily dosing of FF/VI (200/25 μg), which is the highest therapeutic strength used in phase III studies, is not associated with QTc prolongation in healthy subjects. Supratherapeutic strength FF/VI (800/100 μg) demonstrated a small transient effect on QTcF but not on QTci.     

Effects of atomoxetine on the QT interval in healthy CYP2D6 poor metabolizers

Aim

The effects of atomoxetine (20 and 60 mg twice daily), 400 mg moxifloxacin and placebo on QT_c in 131 healthy CYP2D6 poor metabolizer males were compared.

Methods

Atomoxetine doses were selected to result in plasma concentrations that approximated expected plasma concentrations at both the maximum recommended dose and at a supratherapeutic dose in CYP2D6 extensive metabolizers. Ten second electrocardiograms were obtained for time-matched baseline on days −2 and −1, three time points after dosing on day 1 for moxifloxacin and five time points on day 7 for atomoxetine and placebo. Maximum mean placebo-subtracted change from baseline model-corrected QT (QT_cM) on day 7 was the primary endpoint.

Results

QT_cM differences for atomoxetine 20 and 60 mg twice daily were 0.5 ms (upper bound of the one-sided 95% confidence interval 2.2 ms) and 4.2 ms (upper bound of the one-sided 95% confidence interval 6.0 ms), respectively. As plasma concentration of atomoxetine increased, a statistically significant increase in QT_c was observed. The moxifloxacin difference from placebo met the a priori definition of non-inferiority. Maximum mean placebo-subtracted change from baseline QT_cM for moxifloxacin was 4.8 ms and this difference was statistically significant. Moxifloxacin plasma concentrations were below the concentrations expected from the literature. However, the slope of the plasma concentration−QT_c change observed was consistent with the literature.

Conclusion

Atomoxetine was not associated with a clinically significant change in QT_c. However, a statistically significant increase in QT_c was associated with increasing plasma concentrations.     

Assessment of the cardiac safety of fampridine-SR sustained-release tablets in a thorough QT/QTc evaluation at therapeutic and supratherapeutic doses in healthy individuals

Objective: To characterize the effects of a sustained-release formulation of fampridine (fampridine-SR) on QT interval in healthy subjects. Methods: In a double-blind, double-dummy trial, healthy subjects were randomized to 5 days treatment with fampridine-SR at therapeutic (10 mg twice daily) or supratherapeutic (30 mg twice daily) doses, placebo or moxifloxacin (400 mg on treatment day 5). Digital 12-lead electrocardiograms were recorded before treatment and on day 5; blood samples determined fampridine concentrations. Central tendency analysis determined whether the upper limit of the CI for the QT (individual-corrected QT; QTcI) interval change exceeded 10 ms. Outlier analysis determined new-onset QT (corrected QT; QTc) intervals; maximum change in QTc from baseline of 30 – 60 ms and maximum change from baseline ≥ 60 ms. The relationship between pharmacokinetic parameters and QTcI values is explored. Results: Moxifloxacin was associated with a QTcI interval increase > 5 ms at 7 time points; no increase was observed with either dose of fampridine-SR; there were no fampridine outliers. Pharmacokinetic evaluation failed to find dose-dependent cardiac effects. Fampridine was well tolerated, with a higher frequency of adverse events at the supratherapeutic dose. Conclusion: This study showed that fampridine-SR at therapeutic and supratherapeutic doses was not associated with QT prolongation in healthy subjects.     

Measuring the effects of supratherapeutic doses of levofloxacin on healthy volunteers using four methods of QT correction and periodic and continuous ECG recordings

A clinical trial was conducted in healthy volunteers using both periodic and continuous ECG recordings to assess the effect of increasing doses of levofloxacin on the QT and QTc interval. Periodic and continuous ECGs were recorded before and after subjects were dosed with placebo and increasing doses of levofloxacin (500 mg, 1000 mg, 1500 mg) that included doses twice the maximum recommended dose of 750 mg in a double-blind, randomized, four-period, four-sequence crossover trial. Mean heart rate (HR) and the QT and QTc interval after dosing with levofloxacin and placebo were compared, and HR-QT interval relationships defined by linear regression analysis were calculated. After single doses of 1000 and 1500 mg of levofloxacin, HR increased significantly, as measured by periodic and continuous ECG recordings. This transient increase occurred at times of peak plasma concentration and was without symptoms. Mean QT intervals after placebo and mean intervals after levofloxacin were indistinguishable. Using periodic ECG recordings, single doses of 1500 mg were associated with small increases in QTc that were statistically significant. In contrast, an effect on QTc was shown only using the Bazett formula with data obtained from continuous ECG recordings. Together with the finding that levofloxacin does not influence HR-QT relationships, these findings suggest that levofloxacin has little effect on prolonging ventricular repolarization and that small increases in HR associated with high doses of levofloxacin contribute to the drug's apparent effect on QTc. Single doses of 1000 or 1500 mg of levofloxacin transiently increase HR without affecting the uncorrected QT interval. Differences in mean QTc after levofloxacin compared to placebo vary depending on the correction formula used and whether the data analyzed are from periodic or continuous ECG recordings. This work suggests that using continuous ECG recordings in assessing QT/QTc effects of drugs may be of value, particularly with drugs that might influence HR.     

Eltrombopag does not affect cardiac repolarization: results from a definitive QTc study in healthy subjects

AIM

To evaluate the effect of eltrombopag on cardiac repolarization and to characterize the relationship between plasma eltrombopag concentrations and change in QT_c.

METHODS

This was a double-blind, placebo- and active-controlled, randomized, balanced four-period, crossover study in healthy men and women. Subjects were randomized to receive eltrombopag 50 mg and 150 mg, moxifloxacin 400 mg (positive control) and placebo in one of four sequences.

RESULTS

Eighty-seven subjects entered the study and 48 completed. There was no prolongation of QT_c (Fridericia) following eltrombopag treatment, as the upper limit of the 90% confidence interval (CI) for the time-matched change from baseline in QT_cF between drug and placebo (ddQT_cF) did not exceed 10 ms for eltrombopag at either dose. Maximum observed mean treatment difference was 2.29 ms (90% CI 0.34, 4.24) for eltrombopag 150 mg at 1 h post-dose and 11.64 ms (90% CI 9.64, 13.64) for moxifloxacin 400 mg at 4 h. Eltrombopag C_max and AUC(0,24 h) increased in a dose proportional manner between 50 mg and 150 mg after 5 days'' dosing. Proportions of subjects with adverse events were similar across treatments (52–66% of subjects). Most withdrawals (26/39 subjects) were due to elevated platelets. Three subjects were withdrawn for ventricular premature beats (one following each active treatment) reported as related to the study drug.

CONCLUSIONS

No clinically significant QT_c prolongation was observed for eltrombopag at therapeutic and supratherapeutic doses.     

Effect of Ponesimod,a Selective S1P1 Receptor Modulator,on the QT Interval in Healthy Individuals

Ponesimod is an orally active selective sphingosine‐1‐phosphate receptor 1 modulator under investigation for the treatment of multiple sclerosis. This was a single‐centre, double‐blind, randomized, placebo‐ and positive‐controlled parallel‐group study investigating the effects of ponesimod on the QTc interval in healthy individuals. A nested cross‐over comparison between moxifloxacin and placebo was included in the combined moxifloxacin/placebo treatment group. Subjects in group A received multiple doses of 10–100 mg ponesimod according to an uptitration regimen on days 2–23 and moxifloxacin‐matching placebo on days 1 and 24. Subjects in group B received ponesimod‐matching placebo on days 2–23 and were randomized to receive either a single dose of 400 mg moxifloxacin or matching placebo on days 1 and 24. The primary end‐point was the baseline‐adjusted, placebo‐corrected effect on the individually corrected QT interval (QTcI) on days 12 (after 5 days of 40 mg ponesimod) and 23 (after 5 days of 100 mg ponesimod). Ponesimod caused a mild QTcI prolongation with a largest effect of 6.9 ms (90% two‐sided confidence interval (CI): 2.5–11.3) and 9.1 ms (90% CI: 4.1–14.0) for doses of 40 mg and 100 mg, respectively. A concentration–effect analysis confirmed the QTcI‐prolonging effect of ponesimod with a shallow slope of 0.0053 ms per ng/mL. Using the concentration–effect analysis, the QTc prolongation caused by 20 mg ponesimod and the current highest therapeutic dose was predicted to be below the level of clinical concern (i.e. an upper bound of the two‐sided 90% CI of ≥10 ms).     

Preladenant, a selective adenosine A2A receptor antagonist, is not associated with QT/QTc prolongation

Purpose

Preladenant is an orally administered adenosine_2A (A_2A) receptor antagonist in phase III development for Parkinson’s disease treatment. This thorough QT/QTc study evaluated its potential effects on cardiac repolarization.

Methods

This was a randomized, double-blind, positive- and placebo-controlled, four-period crossover study performed under steady-state exposure of clinical and supratherapeutic doses of preladenant (10 mg BID and 100 mg BID, respectively, for 5 days), moxifloxacin (400 mg on day 5), or placebo in 60 healthy adult volunteers. The potential effect on QTcF was measured by the largest upper bound of 95 % one-sided CIs for the mean changes from time-matched baseline ECG recordings compared with placebo. Plasma preladenant concentrations were also determined on day 5.

Results

The QTcF difference for moxifloxacin compared with placebo exceeded 5 ms from 1 to 12 h postdose, establishing assay sensitivity. The QTcF interval was similar between the preladenant and placebo treatment groups: the upper bound of the 95 % one-sided CI for the mean difference in QTcF between preladenant and placebo was less than 10 ms at all time points for the supratherapeutic treatment group (1.3 to 5.7 ms, mean difference: ?1.3 to 2.7 ms) and the therapeutic treatment group (0.4 to 4.3 ms, mean difference: ?2.1 to 1.5 ms), substantially below the threshold of regulatory concern. The supratherapeutic dose (100 mg BID) provided a C_max margin of 6.1-fold and AUC margin of 6.9-fold, respectively, compared with 10 mg BID.

Conclusions

At clinical and supratherapeutic doses, preladenant is not associated with QTc prolongation.     

Thorough QT/QTc study of ritonavir-boosted saquinavir following multiple-dose administration of therapeutic and supratherapeutic doses in healthy participants

The effect of saquinavir-boosted ritonavir at therapeutic (1000/100 mg twice daily [bid]) and supratherapeutic (1500/100 mg bid) doses was evaluated in a double-blind, placebo- and positive-controlled (moxifloxacin 400 mg) 4-way crossover thorough QT/QTc study. Least squares mean estimated study-specific QTc (QTcS) change from dense predose baseline (ddQTcS(dense)) was the primary endpoint. Greatest mean increase in ddQTcS(dense) occurred 12 hours postdose for the 1000/100-mg group (18.9 ms) and 20 hours for the 1500/10-mg group (30.2 ms). The upper 1-sided 95% confidence interval was >20 ms from 2 to 20 hours postdose in both groups. ddQTcB(dense) and ddQTcF(dense) were similar to ddQTcS(dense). No QTcS, QTcF, or QTcB measurements were >500 ms. One participant receiving 1000/100 mg and 3 receiving 1500/100 mg had a maximum ddQTcS(dense) >60 ms. More participants with ≥1 adverse event received saquinavir/ritonavir. PubMed search and Roche postmarketing data did not reveal publications or reports directly presenting the effect of saquinavir on QT/QTc or causing torsade de pointes.     

Effects of aliskiren, a direct Renin inhibitor, on cardiac repolarization and conduction in healthy subjects

This multicenter, double-blind study evaluated the effects of aliskiren, a direct renin inhibitor approved for hypertension, on cardiac repolarization and conduction. Healthy volunteers (n = 298) were randomized to aliskiren 300 mg, aliskiren 1200 mg, moxifloxacin 400 mg (positive control), or placebo once daily for 7 days. Digitized electrocardiograms were obtained at baseline and day 7 of treatment over 23 hours postdose. Placebo-adjusted mean changes from baseline in QTcF (Fridericia corrected), QTcI (individualized correction), PR, and QRS intervals were compared at each time point (time-matched analysis) and for values averaged across the dosing period (baseline-averaged analysis). In time-matched analysis, mean changes in QTcF with aliskiren were below predefined limits for QTc prolongation (mean increase <5 milliseconds; upper 90% confidence interval [CI] <10 milliseconds) except aliskiren 1200 mg at 23 hours (5.2 milliseconds; 90% CI 2.2, 8.1). With moxifloxacin, significant QTcF prolongation occurred at most time points, confirming the sensitivity of the assay. Baseline-averaged analysis was consistent with time-matched analysis. Instances of QTcF interval >450 milliseconds or a >30-millisecond increase from baseline with aliskiren (< or = 1%) were similar or lower than placebo (< or = 4%). Results were similar for QTcI. Aliskiren had no effect on PR or QRS duration. In conclusion, aliskiren at the highest approved dose (300 mg) and a 4-fold higher dose had no effect on cardiac repolarization or conduction in healthy volunteers.     

Aclidinium bromide, a long-acting antimuscarinic, does not affect QT interval in healthy subjects

In this phase I trial, the effect of aclidinium, a novel, inhaled long-acting muscarinic antagonist, on QT interval was evaluated, and its cardiovascular safety was assessed in 272 healthy subjects. Aclidinium 200 μg, aclidinium 800 μg, matching placebo, or open-label moxifloxacin 400 mg was administered daily for 3 days. The primary outcome was mean change in individual heart rate-corrected QT interval (QTcI). Secondary measures included Bazett-corrected QT interval (QTcB), Fridericia-corrected (QTcF) intervals, 12-lead electrocardiogram (ECG) readings, and 24-hour 12-lead Holter ECG parameters. Adverse events, vital signs, and laboratory and pharmacokinetic parameters were also assessed. Maximum mean QTcI change from time-matched baseline on day 3 was -1.0 milliseconds at 2 hours for aclidinium 200 μg, -1.8 milliseconds at 5 minutes for 800 μg, +11.0 milliseconds at 4 hours for moxifloxacin, and -1.2 milliseconds at 23.5 hours for placebo. Aclidinium had no significant effects on secondary ECG measures. Aclidinium plasma concentrations were generally below the lower limit of quantitation (0.05 ng/mL) after 200 μg and were detected only up to 1 hour after the 800-μg dose in the majority of cases. It is concluded that aclidinium bromide, at doses up to 800 μg, has a favorable cardiovascular safety profile with no effect on QT interval.     

Role of mixed ion channel effects in the cardiovascular safety assessment of the novel anti-MRSA fluoroquinolone JNJ-Q2

BACKGROUND AND PURPOSE

JNJ-Q2, a novel broad-spectrum fluoroquinolone with anti-methicillin-resistant Staphylococcus aureus activity, was evaluated in a comprehensive set of non-clinical and clinical cardiovascular safety studies. The effect of JNJ-Q2 on different cardiovascular parameters was compared with that of moxifloxacin, sparfloxacin and ofloxacin. Through comparisons with these well-known fluoroquinolones, the importance of effects on compensatory ion channels to the cardiovascular safety of JNJ-Q2 was investigated.

EXPERIMENTAL APPROACH

JNJ-Q2 and comparator fluoroquinolones were evaluated in the following models/test systems: hERG-transfected HEK293 cells sodium channel-transfected CHO cells, guinea pig right atria, arterially perfused rabbit left ventricular wedge preparations and in vivo studies in anaesthetized guinea pigs, anaesthetized and conscious telemetered dogs, and a thorough QT study in humans.

KEY RESULTS

The trend for effects of JNJ-Q2 on Tp–Te, QT, QRS and PR intervals in the non-clinical models and the plateau in QTc with increasing plasma concentration in humans are consistent with offsetting sodium and calcium channel activities that were observed in the non-clinical studies. These mixed ion channel activities result in the less pronounced or comparable increase in QTc interval for JNJ-Q2 compared with moxifloxacin and sparfloxacin despite its greater in vitro inhibition of I_Kr.

CONCLUSIONS AND IMPLICATIONS

Based on the non-clinical and clinical cardiovascular safety assessment, JNJ-Q2 has a safe cardiovascular profile for administration in humans with comparable or reduced potential to prolong QT intervals, compared with moxifloxacin. The results demonstrate the importance of compensatory sodium and calcium channel activity in offsetting potassium channel activity for compounds with a fluoroquinolone core.     

Clinically relevant QTc prolongation due to overridden drug–drug interaction alerts: a retrospective cohort study

AIMS

To investigate whether, in patients in whom drug–drug interaction (DDI) alerts on QTc prolongation were overridden, the physician had requested an electrocardiogram (ECG), and if these ECGs showed clinically relevant QTc prolongation.

METHODS

For all patients with overridden DDI alerts on QTc prolongation during 6 months, data on risk factors for QT prolongation, drug class and ECGs were collected from the medical record. Patients with ventricular pacemakers, patients treated on an outpatient basis, and patients using the low-risk combination of cotrimoxazole and tacrolimus were excluded. The magnitude of the effect on the QTc interval was calculated if ECGs before and after overriding were available. Changes of the QTc interval in these cases were compared with those of a control group using one QTc-prolonging drug.

RESULTS

In 33% of all patients with overridden QTc alerts an ECG was recorded within 1 month. ECGs were more often recorded in patients with more risk factors for QTc prolongation and with more QTc overrides. ECGs before and after the QTc override were available in 29% of patients. Thirty-one percent of patients in this group showed clinically relevant QTc prolongation with increased risk of torsades de pointes or ventricular arrhythmias. The average change in QTc interval was +31 ms for cases and −4 ms for controls.

CONCLUSIONS

Overriding the high-level DDI alerts on QTc prolongation rarely resulted in the preferred approach to subsequently record an ECG. If ECGs were recorded before and after QTc overrides, clinically relevant QTc prolongation was found in one-third of cases. ECG recording after overriding QTc alerts should be encouraged to prevent adverse events.     

The effect of tafamidis on the QTc interval in healthy subjects

Aims

The transthyretin (TTR) stabilizer, tafamidis, has demonstrated efficacy and safety in the treatment of TTR familial amyloid polyneuropathy (20 mg day⁻¹). Tafamidis use in TTR cardiomyopathy led to the study of the potential effect of tafamidis on the QT_c interval in healthy subjects.

Methods

This randomized, three treatment, three period, six sequence crossover study with placebo, a positive control (moxifloxacin 400 mg) and tafamidis (400 mg, to achieve a supra-therapeutic C_max of ∽20 µg ml⁻¹) was conducted in healthy volunteers at three clinical research units. Oral dosing in each of the three treatment periods was separated by a washout period of  ≥ 14 days. Serial triplicate 12-lead electrocardiograms were performed. QT_c intervals were derived using the Fridericia correction method. Safety and tolerability were assessed by physical examination, vital signs measurement, laboratory analyses and monitoring of adverse events (AEs).

Results

A total of 42 subjects completed the study. The upper limit of the two-sided 90% confidence intervals (CIs) for the difference in baseline-adjusted QT_cF between tafamidis 400 mg and placebo was <10 ms (non-inferiority criterion) for all time points. The lower limit of the two-sided 90% CI between moxifloxacin 400 mg and placebo exceeded 5 ms at the pre-specified moxifloxacin t_max of 3 h post-dose, confirming assay sensitivity. C_max and AUC(0,24 h) for tafamidis were 20.36 µg ml⁻¹ and 305.4 µg ml⁻¹ h, respectively. There were no serious/severe AEs or treatment discontinuations due to AEs.

Conclusions

This thorough QT_c study suggests that a supra-therapeutic single 400 mg oral dose of tafamidis does not prolong the QT_c interval and is well-tolerated in healthy volunteers.