Basic Research Open Access
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World J Gastroenterol. May 7, 2006; 12(17): 2742-2748
Published online May 7, 2006. doi: 10.3748/wjg.v12.i17.2742
Pharmacokinetics and bioequivalence of ranitidine and bismuth derived from two compound preparations
Quan Zhou, Zou-Rong Ruan, Hong Yuan, Bo Jiang, Dong-Hang Xu, Department of Clinical Pharmacology, the 2nd Affiliated Hospital, School of Medicine, Zhejiang University, Hangzhou 310009, Zhejiang Province, China
Correspondence to: Associate Professor, Quan Zhou, Division of Clinical Pharmacology, the 2nd Affiliated Hospital, School of Medicine, Zhejiang University, Hangzhou 310009, Zhejiang Province, China. zhouquan142602@zju.edu.cn
Telephone: +86-571-87783891 Fax: +86-571-87213864
Received: December 12, 2005
Revised: December 20, 2005
Accepted: January 14, 2006
Published online: May 7, 2006

Abstract

AIM: To evaluate the bioequivalence of ranitidine and bismuth derived from two compound preparations.

METHODS: The bioavailability was measured in 20 healthy male Chinese volunteers following a single oral dose (equivalent to 200 mg of ranitidine and 220 mg of bismuth) of the test or reference products in the fasting state. Then blood samples were collected for 24 h. Plasma concentrations of ranitidine and bismuth were analyzed by high-performance liquid chromatography and inductively coupled plasma-mass spectrometry (ICP-MS), respectively. The non-compartmental method was used for pharmacokinetic analysis. Log-transformed Cmax, AUC(0-t) and AUC(0-∞) were tested for bioequivalence using ANOVA and Schuirmann two-one sided t-test. Tmax was analyzed by Wilcoxon’s test.

RESULTS: Various pharmacokinetic parameters of ranitidine derived from the two compound preparations, including Cmax, AUC(0-t), AUC(0-∞), Tmax and T1/2, were nearly consistent with previous observations. These parameters derived from test and reference drug were as follows: Cmax (0.67 ± 0.21 vs 0.68 ± 0.22 mg/L), AUC(0-t) (3.1 ± 0.6 vs 3.0 ± 0.7 mg/L per hour), AUC(0-∞) (3.3 ± 0.6 vs 3.2 ± 0.8 mg/L per hour), Tmax (2.3 ± 0.9 vs 2.1 ± 0.9 h) and T1/2 (2.8 ± 0.3 vs 3.1 ± 0.4 h). In addition, double-peak absorption profiles of ranitidine were found in some Chinese volunteers. For bismuth, those parameters derived from test and reference drug were as follows: Cmax (11.80 ± 7.36 vs 11.40 ± 6.55 μg/L), AUC(0-t) (46.65 ± 16.97 vs 47.03 ± 21.49 μg/L per hour), Tmax (0.50 ± 0.20 vs 0.50 ± 0.20 h) and T1/2 (10.2 ± 2.3 vs 13.0 ± 6.9 h). Ninety percent of confidence intervals for the test/reference ratio of Cmax, AUC(0-t) and AUC(0-) derived from both ranitidine and bismuth were found within the bioequivalence acceptable range of 80%-125%. No significant difference was found in Tmax derived from both ranitidine and bismuth.

CONCLUSION: The two compound preparations are bioequivalent and may be prescribed interchangeably.

Key Words: Ranitidine; Bismuth; Compound preparation; Bioequivalence; Pharmacokinetics; Healthy volunteers; High-performanace liquid chromatography; Inductively coupled plasma-mass spectrometry

INTRODUCTION

Ranitidine is a very common histamine H2 receptor antagonist. It exerts most prominent effect on basal acid secretion and less profound effect on acid production[1,2]. Bismuth potassium citrate has mucosal protective effects by blocking pepsin activity, retarding hydrogen-ion back-diffusion and stimulating prostaglandin synthesis. In addition, it has an inhibitory effect on Helicobacter pylori

(H pylori)[3-6]. Thus, ranitidine and bismuth potassium citrate have a synergistic effect and are usually concurrently prescribed in poly-therapy regimens for gastroduodenal ulcers and H pylori infection. Especially, the availability of ranitidine bismuth citrate and compound preparation of ranitidine and bismuth potassium citrate in market makes administration more conveniently and increases medication compliance in ulcer patients[7,8].

The pharmacokinetics of ranitidine has been described previously[9-11]. After oral administration 50% of ranitidine is absorbed, resulting in the peak serum concentration of 2 ± 3 h after dosing, followed by elimination with a half-life of 2.5 ± 3 h. Ranitidine is metabolized to a small extent, primarily via flavin mono-oxygenases[12]. It is eliminated through kidney, with approximately 70% of the systemically available dose recovered in urine as unchanged drug. Bismuth is only minimally absorbed and its bioavailability ranges 0.16%-0.28%, but the median peak bismuth concentration occurs 30 min (range 15-105 min) post-dosing[13,14]. The concentration of bismuth in kidneys is high and it is also retained there for a long time. Elimination from blood displays multi-compartment pharmacokinetics[15].

Comparative bioavailability of different mono-preparations of ranitidine hydrochloride or colloidal bismuth sub-citrate in healthy volunteers or patients has been described previously[16-20]. However, to our knowledge, there is no report on the pharmacokinetic and bioequivalence evaluation of compound preparations containing these two drugs.

MATERIALS AND METHODS
Drugs and reagents

Ranitidine reference substance (purity> 99.5%) was provided by Shuguang Pharmaceutical Factory (Beijing, China). Bi2O3 reference substance (purity> 99.999%) and TlCl reference substance (purity> 99%) were provided by ALDRICH Chemical Company (USA). Nitric acid was of MOS grade. Ultra pure water was obtained from Milli-Q Academic (Millipore Co., USA). Acetonitrile was of HPLC grade. Potassium dihydrogen phosphate and perchloric acid were of analytical grade. Test preparation was compound ranitidine tablet (lot 041201, expiracy: 12/2006) from Chongqing Pharmaceutical Factory (Chongqing, China). Reference preparation was compound ranitidine capsule (lot 041002, expiracy: 9/2006) from Nuode Pharmaceutical Factory (Jiangsu, China). Each tablet or capsule contained ranitidine hydrochloride (equivalent to 100 mg of ranitidine) and bismuth potassium citrate (equivalent to 110 mg of bismuth).

Study subjects

After approval by the Ethics Committee of the 2nd Affiliated Hospital (School of Medicine, Zhejiang University), 20 male healthy Chinese volunteers (age, 24 ± 1 years; weight, 63.8 ± 6.1 kg; BMI, 22.1 ± 1.7 kg/m2) gave their written informed consent to participate in the study and all of them completed the study. All volunteers were considered to be in good health on the basis of physical examination, electrocardiogram (ECG), and laboratory tests including complete blood count, blood biochemistry testing and urinalysis. Each volunteer was required to be 18-40 years old, a nonsmoker, and to have a BMI between 19 and 25 kg/m2. Participants were excluded for the following reasons: any significant medical history, history of any localized or systemic infection within 4 wk before admission, use of prescription or over-the counter medication or alcohol within 2 wk before enrollment, history of alcohol or drug abuse, donation of blood within the past 2 mo.

Study design

The study had an open-label, randomized, two-period crossover design, with 1 wk washout between periods. All volunteers were not allowed to take any medications 2 wk before and during the study period. After fasting for l2 h overnight, the volunteers received a single oral dose (equivalent to 200 mg of ranitidine and 220 mg of bismuth) of the test or reference products with 200 mL water in a crossover fashion. No food was allowed until 4 h after dose administration. Water intake was allowed after 2 h of dose. Water, lunch and dinner were given to all volunteers according to a time schedule. The volunteers were under direct medical supervision at the study site. Blood samples (4 mL) were drawn into VacutainerTM tubes containing K2EDTA from a forearm vein using an indwelling catheter before drug intake and at 0.17, 0.33, 0.50, 0.75, 1.0, 1.5, 2.0, 3.0, 4.0, 5.0, 6.0, 8.0, 10.0, 12.0, 24 h for the two phases after dosing. Blood samples were centrifuged at 3000 r/min for 10 min, and plasma was separated and stored at -80 °C until assay. ECG, biochemical and hematological laboratory tests were performed for each volunteer to record any clinically abnormal finding.

Analytical procedure

High performance liquid chromatography (HPLC) assay method for ranitidine was developed in our laboratory. In brief, 50 μL of perchloric acid solution (2.5 mol/L) was added to 200 μL plasma in the eppendorf tube (1.5 mL). The mixture was vortexed for 20 s and then centrifuged at 36 670 r/min for 10 min. The supernatant was transferred to vial on the rack of autosampler and 50 μL was injected onto the column. The HPLC injection sequence was as follows: calibration standards of 0.02, 0.05, 0.1, 0.2, 0.5, 1.0, 2.0 mg/L, volunteers’ plasma samples and quality-control samples of 0.04, 0.4 and 1.5 mg/L throughout all sequences.

The assay method for bismuth was as follows: plasma samples (0.5 mL) were added to Tl (internal standard) working solution and diluted to a volume of 5 mL with super pure water, followed by direct measurement in a PQ3 ICP-MS system (Thermo Electron Corporation, USA). The assay sequence was as follows: calibration standards of 0.2, 0.5, 1.0, 5.0, 10.0, 30.0, 60.0, 100.0 μg/L, volunteers’ plasma samples and quality-control samples of 0.30, 8.00, 20.0, 80.00 μg/L throughout all sequences.

The two assay methods were validated according to international guidelines[21].

Chromatography

Chromatography for ranitidine was performed on a Beckman SYSTEM GOLD® liquid chromatography system (USA) consisting of a 125 solvent module, 508 auto-sampler, 166 UV detector and AT-330 column oven (Medilab). The software package 32 Karat 5.0 was used to control the chromatographic system and produce UV-spectrometric data. Analytical column used was Kromasil C18 ODS (Sweden, 250 × 4.6 mm ID, 5 μm, particle size), protected by a security guard cartridge C18 ODS 4 × 3.0 mm ID (Phenomenex Inc, USA). The mobile phase consisted of 0.02 mol/L KH2PO4-acetonitrile (86:14, V/V). The flow rate was 1.0 mL/min. Column oven was kept at 25 °C. Auto-sampler was set at 4 °C. The UV detective wavelength was 320 nm.

Working condition of ICP-MS

ICP-MS measurements were carried out under the following operation conditions. The forward power was 1350 W, the coolant and auxiliary and nebulizer gas flow rate were 13, 0.70, and 0.73 L/min, respectively. Sample uptake flow rate was 1.2 mL/min. Mass-to-charge ratios detected (m/z) were 205 (205Tl) and 209 (209Bi). Sweep mode was peak hopping. Dwell time was 10 ms. Number of sweeps per run was 60. Uptake time was 60 s. Acquisition duration was 4 s.

Statistical analysis

Pharmacokinetic parameters were calculated by non-compartmental method. Bioequivalence evaluation was performed by the software BAPP2.0 (Center of Drug Metabolism & Pharmacokinetics, China Pharmaceutical University, Nanjing, China). Maximal plasma concentrations (Cmax) and the time points at which they occurred (Tmax) were determined by inspection of the plasma concentration-time profile. The terminal elimination rate constant (λz) was determined by linear regression of the terminal portion of the log concentration-time profile. The elimination half-life (T1/2) was calculated as 0.693/λz. Area under the plasma concentration-time curve (AUC) was determined by trapezoidal rule and extrapolated to infinity by calculation of Ct/λz. F=[AUC(0-t) (T)/AUC(0-t) (R)]×100%. Log transformed Cmax, AUC(0-t), AUC(0-) were analyzed using ANOVA analysis and Schuirmann two-one sided t-test. Tmax was analyzed by the non-parametric test and Wilcoxon’s test. A P value of less than 0.05 was considered statistically significant. Data were reported as mean  ±  SD. If the two preparations were bioequivalent, 90% confidence intervals (CI) for test/reference ratios of Cmax, AUC(0-t) and AUC(0-) should fall within the range of 80%-125% [22,23].

RESULTS
Validation of the assays

Typical chromatograms of spiked ranitidine plasma samples, plasma samples of patients before and after the administration of compound ranitidine preparation are shown in Figure 1. The retention time for ranitidine was 5.1 min. Under the chromatographic condition described, ranitidine and its metabolite were well resolved. Endogenous plasma components did not show any interfering peaks. The assay was linear from 20.0 to 2000.0 μg/L for ranitidine in plasma samples. The mean absolute recovery was about 97.2%, while the intra- and inter-day coefficients of variation and percent error values of the assay method were all lower than 8%. The limit of quantification (LOQ) was found to be 20.0 μg/L, with a precision of less than 20% (n = 5) and an accuracy of  ± 20% (n = 5). Ranitidine was stable in plasma samples at different storage conditions: immediately after 3 h at ambient temperature, after perchloric acid treatment and being on the auto-sampler at 4 °C for 24 h, after two freeze/thaw cycles and after 1 mo storage at -80 °C.

Figure 1
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Figure 1 Chromatograms of spiked plasma sample (B), plasma samples of patients before (A) and after (C) the administration of 200 mg ranitidine. M1 and M2 are metabolites of ranitidine.

The ICP-MS assay was linear from 0.2-100.0 μg/L for bismuth in plasma samples. The mean absolute recovery of bismuth from quality control samples was about 100.5%, while the intra- and inter-day coefficients of variation and percent error values of the assay method were all lower than 8%. LOQ was found to be 0.2 μg/L, with a precision of less than 10% (n = 30) and an accuracy of ± 15% (n = 30).

The validity study demonstrated that the HPLC assay was reliable for quantification of plasma ranitidine and the ICP-MS assay was reliable for determination of plasma bismuth levels. The specificity, sensitivity, accuracy and precision all met the requirement for PK study.

Concentration-time curves and PK of ranitidine

The average concentration-time curves are shown in Figure 2. The main PK parameters including Cmax, AUC(0-t), AUC(0-), Tmax and T1/2 are given in Table 1. The variation sources of P values and 90% CI for the parameter ratios are presented in Table 2. No statistically significant formulation or period effect was encountered, with P value greater than 0.05. Inter-subject differences were the main source of variability in log-transformed AUC(0-t) and AUC(0-). The 90% CI for the ratio of Cmax (86.7%-113.6%), AUC(0-t) (96.0%-113.4%), and AUC(0-) (95.3%-112.5%) values for the test and reference products was entirely within the FDA acceptable range of 80%-125%. The data indicated that the 2 preparations were bioequivalent with respect to ranitidine. In addition, no significant difference was obtained in Tmax.

Table 1 Pharmacokinetic parameters of ranitidine and bismuth after a single oral dose of compound ranitidine preparation (equivalent to 200 mg of ranitidine and 220 mg of bismuth) in 20 Chinese volunteers (mean ± SD).
ComponentParametersTestReference
RanitidineTmax (h)2.3 ± 0.92.1 ± 0.9
Cmax (mg/L)0.67 ± 0.210.68 ± 0.22
T1/2 (h)2.8 ± 0.33.1 ± 0.4
AUC(0-t) (mg/L per hour)3.1 ± 0.63.0 ± 0.7
AUC(0-∞) (mg/L per hour)3.3 ± 0.63.2 ± 0.8
BismuthTmax (h)0.50 ± 0.200.50 ± 0.20
Cmax (μg/L)11.80 ± 7.3611.40 ± 6.55
T1/2 (h)10.2 ± 2.313.0 ± 6.9
AUC(0-t) (μg/L per hour)46.65 ± 16.9747.03 ± 21.49
AUC(0-∞) (μg/L per hour)55.38 ± 21.2757.81 ± 23.31
Table 2 ANOVA for assessment of the drugs, subjects and period effects, and 90% CI for the test/reference ratio of Cmax, AUC(0-t) and AUC(0-∞), using logarithmic transformed data, after administration of two compound ranitidine preparations (equivalent to 200 mg of ranitidine and 220 mg of bismuth) to 20 Chinese volunteers (ɑ= 0.05).
ComponentParametersANOVA (P-value)
90% CI (%)
Variation source
DrugSubjectsPeriod
RanitidineCmax0.91910.06860.767986.7-113.6
AUC(0-t)0.39170.01530.836696.0-113.4
AUC(0-∞)0.47330.021180.906495.3-112.5
BismuthCmax0.656950.515150.3955189.8-120.0
AUC(0-t)0.660660.113470.7124588.1-124.0
AUC(0-∞)0.751490.158040.8716985.3-111.5
Figure 2
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Figure 2 Concentration-time curves of ranitidine in 20 Chinese volunteers after oral administration of two compound preparations. n = 20. Mean ± SD. Bars indicate standard deviations (lower bars for test drug and upper bars for reference drug).

Interestingly, double-peak plasma profiles of ranitidine were observed in some volunteers receiving either test drug or reference drug. Typical double-peak plasma profiles of ranitidine in two volunteers (№ 14 and № 16) after oral administration of two compound preparations are shown in Figure 3.

Figure 3
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Figure 3 Typical double-peak plasma profiles of ranitidine in two Chinese volunteers (№14 and №16) after oral administration of two compound preparations.
Concentration-time curves and PK of bismuth

The average concentration-time curves are shown in Figure 4. The main PK parameters including Cmax, AUC(0-t), AUC(0-), Tmax and T1/2 are given in Table 1. The variation sources of P values and 90% CI for the parameter ratios are presented in Table 2. No statistically significant formulation or period effect and inter-subject differences were encountered, with P value greater than 0.05. The 90% CI for the ratio of Cmax (89.8%-120.0%), AUC(0-t) (88.1%-124.0%), and AUC(0-) (85.3%-111.5%) values for the test and reference products was also entirely within the FDA acceptable range of 80%-125%. In addition, no significant difference was obtained in Tmax (P > 0.05).

Figure 4
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Figure 4 Concentration-time curves of bismuth in 20 Chinese volunteers after oral administration of two compound preparations. n = 20, mean ± SD. Bars indicate standard deviations (lower bars for test drug and upper bars for reference drug).
Safety

The two preparations were well tolerated by the volunteers. Unexpected incidents that could have influenced the outcome of the study did not occur. There was no drop-out and all volunteers participating in the study continued to the end. Post-study clinical laboratory tests revealed normal results.

DISCUSSION

The assay methods we developed for ranitidine and bismuth are reliable and applicable in bioavailability study. With respect to HPLC assay for ranitidine, direct injection of the plasma samples after deproteination using perchloric acid warranted high sensitivity, good accuracy and precision and least time for sample preparation. Most literature on ranitidine determination in plasma involves solid-phase extraction (SPE)[24-26] or liquid-liquid extraction (LLE)[27-29]. However, the methods employing LLE not only consume large time for sample preparation but also give highly variable and relatively low recoveries. The SPE techniques are quite good, but they still involve several steps and need several hundred cartridges. With respect to the ICP-MS assay we developed for bismuth, sample preparation method is more simple and has less matrix effect than the method provided by Mauras Y et al[30].

The PK of ranitidine derived from ranitidine bismuth citrate is consistent with observations for ranitidine administered alone[31]. However, literature on PK of ranitidine derived from compound preparation is not yet available. Wen et al[32] showed that. Cmax and AUC(0-)

derived from a single 300 mg dose of ranitidine alone are 0.91 mg/L and 4.78 mg/L per hour, respectively. However, when 300 mg colloidal bismuth sub-citrate capsules are co-administered, the two parameter values are significantly decreased by 41.8% and 33.7%, respectively. No significant differences have been observed with respect to Tmax and T1/2 under the two different circumstances, suggesting that ranitidine granules are partially enwrapped by colloidal precipitation as presented by Wen et al[32], which can explain the loss in ranitidine absorption. Ranitidine is characterized by a dose-proportional PK. So Cmax and AUC(0-) for ranitidine mono-preparations are both standardized to dose (200 mg), ranging 0.60-1.20 mg/L and 3.0-4.5 mg/L per hour, respectively[16-19,33]. The mean Cmax and AUC(0-) values for ranitidine derived from combined formulation in our study were 0.67 mg/L and 3.1 mg/L per hour, respectively, falling within the above range for ranitidine administered alone. If significant loss exists at absorption phase of ranitidine derived from test compound formulation and the decreased percentage is similar with the results of Wen et al[32]. Cmax and AUC(0-) values for ranitidine mono-preparation would be estimated to be 1.15 mg/L and 4.7 mg/L per hour, respectively, still being within/or near the mean range. Thus, the possible effects of bismuth potassium citrate on ranitidine absorption could not be excluded, thus more relative studies are needed to confirm the results presented by Wen et al[32]. Moreover, it would be useful to investigate the difference between the bioavailability of ranitidine in the compound preparation relative to the administration of two mono-preparations that are ingested simultaneously, although compound preparation has advantages such as more convenience in administration and better medication compliance in ulcer patients. However, the main purpose of this study was to confirm whether the two compound preparations can be prescribed interchangeably by bioequivalence evaluation.

The PK of oral drugs exhibiting double peaks cannot be adequately described by conventional compartmental models[34]. So we used non-compartmental method. The double-peak phenomenon of ranitidine plasma profile in several volunteers is consistent with previous reports[34,35,38]. However, this PK profile has not been revealed in Chinese. The proposal mechanism responsible for the existence of secondary peaks, presented by Yin et al[34] and Schaiquevich et al[35], includes enterohepatic recirculation and the existence of multiple sites of absorption along the gastrointestinal tract.

The mean Tmax value for bismuth derived from compound preparations in this study was 0.50 h, indicating that bismuth is rapidly absorbed by Chinese volunteers. The result is similar with those presented by Nwokolo et al[13] and Benet et al[14]. Peak bismuth plasma concentrations in our study ranged 3.24 μg/L-27.50 μg/ L, the mean Cmax value was 11.60 μg/L, suggesting that bismuth neurotoxicity is not associated with steady-state concentrations of 50-100 μg/L. The mean terminal half-lives for bismuth derived from the test compound preparation (equivalent to 220 mg bismuth) in this study was 10.2 h, which is nearly similar with the mean values of 9.1 h derived from a single dose of 350 mg ranitidine bismuth citrate capsules for 10 Chinese health volunteers[36]. Benet et al[14] considered that the intermediate half-life of 5-11 d derived from colloidal bismuth sub-citrate represents most of the clearance and elimination. Moreover, the plasma terminal half-lives averaging 21 d are derived from oral doses of 800 mg ranitidine bismuth citrate, twice daily for 28 d[31]. These different results are suggestive of possible ethnic differences in bismuth elimination or indicate that multiple-dose administration of bismuth may result in its prolonged elimination. In this way, further investigations should be carried out.

A placebo-controlled crossover study showed that daily oral administration of 40 mg omeprazole for 1 wk increases the systemic availability of 240 mg bismuth derived from tripotassium dicitrate bismuthate. The explanation by Treiber et al[37] is that absorption of bismuth may be dependent on intragastric pH which is elevated by omeprazole. However, the mean AUC(0-t) of bismuth derived from test compound preparation (equivalent to 200 mg of ranitidine and 220 mg of bismuth) in our study was 46.65 μg/L per hour, which is nearly similar with the value of 46 μg/L per hour derived from mono-preparation of tripotassium dicitrate bismuthate (equivalent to 220 mg of bismuth)[37]. Thus, additional experiments are also needed to address whether ranitidine increases the systemic availability of bismuth.

The most important objective of bioequivalence testing is to assure the safety and efficacy of generic formulations. Two drugs are considered to be bioequivalent and thus therapeutically equivalent if they are pharmaceutical equivalents (i.e., similar dosage forms made, perhaps by different manufacturers) or pharmaceutical alternatives (i.e., different dosage forms) and if their rates (Cmax) and extents of absorption (AUC) do not show a significant difference when administered at the same molar dose of the therapeutic moiety under similar experimental conditions[39]. Interpretation of Tmax is difficult in some oral bioequivalence studies, because of the occurrence of multiple peaks. Comparison between the formulations is based on the overall Cmax, Tmax, and AUC. Therefore, the presence or absence of a double peak can not affect the accuracy of measurements[40].

It is generally accepted that the standard equivalence range is 0.8-1.25 for basic pharmacokinetic characteristics, such as AUC and Cmax[22,23]. For ranitidine derived from the two compound preparations in this study, no significant difference was obtained in Tmax (P > 0.05) and 90% CI for the test/reference ratio of Cmax, AUC(0-t) and AUC(0-) was found within the range 80%-125%. Therefore the two compound preparations can be expected to be equally effective with respect to the action of ranitidine. To support equal clinical efficacy of compound preparations, it is necessary to show the equivalent gastric availability (local effect) of the bismuth component. Its effect for a large part is determined by the pharmaceutical form in which this component is delivered. Coghill et al[20] have developed a novel means of comparing the bioequivalence of the two preparations of tripotassium dicitrate bismuthate (De-Noltab) in patients attending a gastroscopy clinic by examining duodenal biopsies with electron microscopy. However, this method is invasive, thus lacking applicability. We performed a comparative bioavailability study to reflect the equal gastric availability indirectly. The results have confirmed the equivalent rates and extents of absorption of bismuth derived from the two compound preparations. Thus, we consider that these two compound preparations have equal clinical efficacy with respect to bismuth.

In conclusion, the 2 compound preparations are bioequivalent with respect to both ranitidine and bismuth and can be prescribed interchangeably.

Footnotes

Co-correspondence: Zou-Rong Ruan

S- Editor Wang J L- Editor Wang XL E- Editor Bi L

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