Introduction
Hypertension is one of the most significant public issues with a high worldwide prevalence and its treatment can lead to reduced incidences of complications, such as stroke, myocardial infarction and renal disease (1). There are a number of antihypertensive drugs of various categories, including angiotensin-converting enzyme (ACE) inhibitors, calcium channel blockers, β-blockers and angiotensin II receptor antagonists. Thus far, clinical trials have indicated that monotherapy, the use of a single drug, is insufficient for achieving the goal blood pressure in patients with hypertension and ongoing trials have provided guidance on the appropriate combination regimens using ≥2 antihypertensive drugs for increasing the synergic effects and reducing the unexpected adverse effects (2,3). Furthermore, the combination regimens targeting functional improvement, as well as antihypertension, enhance the therapeutic effects even when the monotherapy is not evident in patients with renal dysfunction (4).
Perindopril is a long-acting ACE inhibitor that results in preventing the generation of angiotensin II in the renin-angiotensin-aldosterone system and subsequently lowering blood pressure. Numerous studies have revealed that perindopril is useful for treatment of hypertension (5), chronic heart failure (6) and diabetic nephropathies (7). Perindopril has good preclinical profiles with an LD50 at relatively high doses in various experimental animals (8), and clinical introduction and post-marketing surveillance studies have shown that perindopril is well-tolerated in a wide range of patients with hypertension (9). However, perindopril has a risk of severe hypotension despite low incidences and possible fetal and neonatal morbidity and mortality when used during pregnancy (9), indicating that the use of perindopril requires caution to avoid the unexpected adverse effects.
Natural products have received increasing attention in the development of novel drug materials. There are a number of natural herbal products based on Korean medicine that have been adjusted from traditional Chinese medicine and the commercially available herbal drugs have been evaluated for novel combination regimens as an adjunctive medication (10). Wu Ling San (Oryungsan, ORS) known as a five-ingredient formula with poria, is the most famous nephroprotective Korean traditional polyherbal formula (11). The accumulated clinical trials have shown that ORS is useful for various diseases involved in hypertension, such as kidney diseases, cardiac edema, ascites, diabetes, liver cirrhosis and hydrocephalus. In addition, the therapeutic improvement has been revealed in experimental animal models of renal damage (12), nephrotic syndrome (13) and renal dysfunction (14). Chungsinoryungsan (CSORS) is based on the materials of ORS and 20 types of herb exhibiting nephroprotective effects are also added additionally (15). CSORS is indicated to possibly be useful in combination with antihypertensive drugs as an adjunctive medication. Therefore, the aim of the present study was to examine the drug-drug interactions between CSORS and perindopril via comprehensive pharmacokinetic analyses.
Materials and methods
Animals
Six-week-old male Sprague-Dawley rats (170–190 g) were obtained from Japan SLC, Inc. (Shizuoka, Japan). A total of 20 rats were separated randomly to five per polycarbonate cage and acclimatized in a room controlled at 20–25°C and 40–45% humidity for 2 weeks. The rats were maintained on a 12-h light/dark cycle with free access to standard rodent chow and water. All the experimental procedures were approved by the Institutional Animal Care and Use Committee at Daegu Haany University (Gyeongsan, Korea).
Drugs and treatment
Perindopril was purchased from Panaaya Pharma Private, Ltd. (Hyderabad, India). CSORS was prepared at the Department of Herbology (College of Korean Medicine, Daegu Haany University). For producing CSORS, 25 types of herb were purchased from Jecheon Hanbang Yakcho (Jecheon, Korea) following confirmation of the complete morphology under microscopy (Table I). The herbs (1,420 g) were boiled in 2 l distilled water for 3 h, three times at 80°C and subsequently filtered. The resultant filtrate was decompressed with a rotary vacuum evaporator (Rotavapor R-144; Buchi, Flawil, Switzerland) and lyophilized in a programmable freeze dryer (FreeZone 1 Liter Benchtop; Labconco Corporation, Kansas City, MO, USA). Eventually, the acquired CSORS extract volume was 173.24 g as a light brown powder (yield, 12.2%). The perindopril and CSORS drugs were stored as a powder at 4°C in the dark until required.
One batch of 10 rats received single oral dosing of perindopril combination with CSORS (combination group) or perindopril with distilled water (control) and another batch of 10 rats received repeated oral dosing of combination and control once a day for a week. The co-administration with CSORS or distilled water was performed by the single dosing within 5 min after perindopril, or the repeated dosing at a 2-h interval after perindopril. The drug dosing was a volume of 5 ml/kg at 100 ml/kg CSORS and 50 mg/kg perindopril, based on its toxicity and clinical database (8). Body weights were measured prior to every administration using an automatic electronic balance (Precisa Instruments AG, Dietikon, Switzerland).
Collection of blood samples and sample preparation
The rats were fasted overnight a day before collection of the blood sample to avoid dietary effects. The blood sample via the retro-orbital route was collected in anticoagulant tubes, including 50 IU heparin, at 0.5 h prior to the administration and 0.5, 1, 2, 3, 4, 6, 8 and 24 h post-administration. The plasma sample was centrifuged at 11,400 × g for 10 min and the supernatant aliquot was stored at −70°C until pharmacokinetic analyses.
Sample preparation and calibrations
For a calibration, 1.0 mg/ml perindopril (Sigma, St. Louis, MO, USA) diluted with 50% acetonitrile was used as a primary stock solution and 500 ng/ml carbamazepine (Sigma) in acetonitrile was used as an internal standard (IS) solution. The working standard solutions were prepared by dilution of the primary stock solution with acetonitrile and stored in the dark at −20°C. The 100 μl working standard solutions were mixed with 100 μl blank plasma and IS solutions in 100 μl acetonitrile for the perindopril concentration standard curve. The 100-μl plasma sample was prepared as a mixture with 100-μl IS solution in 200 μl acetonitrile. The mixtures were centrifuged at 9,700 × g for 10 min at 4°C and the supernatant was transferred to injection vials for liquid chromatography-mass spectrometry/mass spectrometry (LC-MS/MS).
LC-MS/MS conditions
Chromatographic analysis was performed using an Agilent 1100 series HPLC (Agilent Technologies, Santa Clara, CA, USA) equipped with online degasser, binary pump, auto-sampler, column compartment and column oven at 30°C. Separation of the analyte from potentially interfering material was achieved using Waters XTerra MS C18 columns (2.1×50 mm, 3.5 μm) (Waters Corporation, Milford, MA, USA). The mobile phase for chromatographic separation was composed of 5–95% acetonitrile, including 0.1% formic acid, and it was delivered isocratically at a flow rate of 0.3 ml/min. The column effluent was monitored using an API 2000 triple quadrupole mass-spectrometer detector (Applied Biosystems, Foster City, CA, USA). The instrument was equipped with an electrospray interface in positive-ion mode, which was controlled by the Analyst version 1.4.2 software (Applied Biosystems). The samples were introduced to the interface through turbo ionspray at 400°C. A high positive voltage of 5.0 kV was applied to the ion spray. Nitrogen was used as nebulizer gas, curtain gas and collision gas with sets of 12, 6 and 8 PSI, respectively. The multiple reaction monitoring detection method was employed for the detection of perindopril; the transitions monitored were carbamazepine (IS): m/z 237>194 (retention time, 2.7 min); and perindopril: 369>172 (retention time, 2.5 min). Calibration curves of perindopril were linear over the ranges with r2>0.999. The lower limit of quantification was 0.1 ng/ml.
Pharmacokinetic analyses
The perindopril concentration in plasma was analyzed using a non-compartmental method on the commercial pharmacokinetics data analyzer program (PK Solutions 2.0; Summit Research Services, Montrose, CO, USA) (16). The elimination rate constant (Kel) was calculated by log-linear regression of perindopril concentration data during the elimination phase, and the terminal half-life (t1/2) was calculated by 0.693/Kel. The peak concentration (Cmax) of plasma perindopril and time to reach the Cmax (Tmax) were obtained by visual inspection in the concentration-time curve. The area under the perindopril concentration-time curve (AUC0-t) from time zero to the time of the measured concentration (Clast) was calculated using the linear trapezoidal rule (17). The AUC zero to infinity (AUC0-inf) was obtained by adding AUC0-t and the extrapolated area was determined by Clast/Kel. The mean residence time to infinity (MRTinf) was calculated by dividing the first moment curve (AUMC0-inf) by AUC0-inf.
Statistical analyses
All the data are presented as average values ± standard error of the mean (SEM). Data for body weights and perindopril concentration were examined by testing the homogeneity of variance, followed by analysis of variance (ANOVA) with the group as a main effect. The day on which the body weights were measured or the time collected for plasma samples was treated as repeated measurements. When the data passed at the test of homogeneity of variance, they were compared by independent t-test for post hoc test, otherwise, the data were compared by Mann-Whitney U test. All the pharmacokinetic parameters were examined by Mann-Whitney U test as a non-parametric comparison due to the small sample sizes, which have difficulties reaching a normal distribution. For all analyses, P<0.05 was considered to indicate a statistically significant difference.
Discussion
The effects of CSORS administration on pharmacokinetics of perindopril were examined in the present study. When perindopril was co-administered with CSORS within 5 min, the perindopril plasma concentration was different from the normal pharmacokinetics of the control (Fig. 1). The pharmacokinetic parameters showed reduced t1/2 and increased Tmax and MRTinf in the combination compared to the control group. This indicates a drug-drug interaction between perindopril and CSORS (Fig. 2). Perindopril was hypothesized to possibly have a limited interaction with CSORS co-administration at an interval gap that was more than perindopril MRTinf of the control treatment (1.51±0.09 h). When perindopril was co-administered with CSORS at a 2-h interval, the perindopril concentration and pharmacokinetic parameters were not different between the combination and control groups following the initial and last administration of a weekly repeated dosing (Figs. 3 and 4). These results provide detailed information for the drug regimen of perindopril combination with CSORS.
Perindopril has been shown to have various drug-drug interactions with diuretics (18,19), gentamicin (20) and lithium (21,22). However, there have been limited studies regarding the interactions between perindopril and natural herbal products, except for digoxin (23,24). In the present study, single oral administration of perindopril combination with CSORS within 5 min markedly delayed the absorption of perindopril and its excretion, whereas the co-administration of the combination at a 2-h interval showed no interaction between perindopril and CSORS even by a weekly repeated dosing. Perindopril is well-absorbed in the gastrointestinal tract with a high bioavailability of 75% via the oral route (25), however, it is extensively metabolized to six metabolites, including perindoprilat, an active metabolite, in the liver (26,27). The maximal concentration of plasma perindoprilat is reached 2–6 h after oral administration of perindopril and 70% of perindoprilat is cleared by the kidneys. Food does not influence the rate or extent of perindopril absorption but reduces conversion to perindoprilat by ~35% (28). The present study results showed a Tmax of 1 h in the control group, which had a similarity with that of humans (Figs 2B and 4B) (26). However, perindopril combination with CSORS within 5 min resulted in 2 h of Tmax. Although the exact mechanism regarding how CSORS interacted with perindopril is unclear, it may be due to partial interruption of perindopril absorption by coexistence with CSORS or delayed conversion of perindopril to perindoprilat.
In the present study, CSORS had no interaction with perindopril in a weekly repeated co-administration at 2-h intervals, which indicates the suitable dosing regimen for the combination therapy. However, there are numerous clinical factors that alter perindopril pharmacokinetics. Since the active metabolites of perindopril are hydrolyzed in the liver and primarily excreted into the urine, the elimination kinetics can be altered in hepatic impairment (26,29), renal failure (30) or chronic heart failure (31). Ageing is also associated with the alteration in enhanced conversion to perindoprilat and the reduced renal clearance (32). Therefore, perindopril combination therapy requires further clinical studies for the pharmacokinetics in specific disease conditions. To the best of our knowledge, this is the first study to monitor the use of CSORS in combination with antihypertensive drugs. The results showed CSORS co-administration has limited interaction with perindopril at an interval that was more than mean residence time of perindopril. These results provide detailed information for a drug dosing regimen of perindopril with CSORS in human clinical studies of novel combination therapy.