Investigating Intestinal Permeability of Bortezomib Using a Validated HPLC-UV Method

• Abstract
• Introduction
• Materials
• Methods
• Animals
• Instrumentation
• Chromatographic conditions
• Preparation of stock, perfusion and working standard solutions
• Method validation
• Linearity
• Limit of detection (LOD) and quantitation (LOQ)
• Precision and accuracy
• Short-term stability study
• System suitability tests
• In situ single-pass intestinal perfusion (SPIP) studies
• HPLC analysis of the perfused solutions
• Biopharmaceutical class of BTZ
• Results and Discussion
• Linearity
• Limit of detection (LOD) and quantitation (LOQ)
• Precision and accuracy
• Stability
• System suitability tests
• Intestinal permeability and biopharmaceutical class of BTZ
• Conclusion
• References

Abstract

Bortezomib (BTZ), as a proteasome inhibitor, has been used for treatment of patients with relapsed/refractory multiple myeloma and mantle cell lymphoma. BTZ is available for intravenous injection or subcutaneous administration. In this study, for evaluating the potential of BTZ oral delivery, intestinal permeability of BTZ was determined using in situ single-pass intestinal perfusion (SPIP) technique and the perfused solutions were analyzed using a validated HPLC-UV method. The chromatographic separation was performed using a C18 column via isocratic mode at a flow rate of 0.5 mL/min at 270 nm. The mobile phase was a mixture of methanol/deionized water (50:50% v/v) with 0.1% glacial acetic acid. The results indicated that calibration curves were linear (r² ˃0.99) in a concentration range of 1.65–5 µg/mL for BTZ and 8.33–25 µg/mL for phenol red. A limit of quantitation of 1.03 and 6.67 µg/mL was obtained for BTZ and phenol red, respectively. The recovery values were in the range of 96.5–105.4% for BTZ, and 88–99.2% for phenol red. The relative standard deviations (RSD) were ≤4.9% for BTZ and ≤7% for phenol red. Stability studies indicated that the working standard solution is stable over a period of 48 h at room temperature. Finally, an effective permeability (P_eff) value of (3.36±0.5)×10⁻⁵ cm/sec (mean±SEM) was achieved for BTZ. Moreover, it was predicted that BTZ belongs to the biopharmaceutical class ІІІ.

Introduction

Proteasomes are intracellular protein complexes which play an important role in the cell division and apoptosis by degradation of ubiquitinated regulatory proteins. Aberrant degradation of regulatory proteins through ubiquitin-proteasome pathway, can lead to uncontrolled cell proliferation and cause tumor formation and metastasis [1] [2] [3]. In vitro and in vivo studies showed that proteasome inhibitors can induce apoptosis in cancer cells and inhibit tumor growth [4] [5] [6] [7] [8]. Thus, proteasome inhibitors have been considered as anticancer drugs in cancer treatment.

Bortezomib (BTZ; [Fig. 1]) is the first proteasome inhibitor approved by the US food and drug administration (FDA) for treatment of patients with relapsed/refractory multiple myeloma and mantle cell lymphoma. BTZ is given twice weekly for 2 weeks followed by 1 week rest period (21-day cycles), and is available for intravenous injection or subcutaneous administration [9] [10] [11].

In this study, for evaluating the potential of BTZ oral delivery, the intestinal permeability of BTZ was measured. Oral chemotherapy can improve the quality of life in cancer patients, reduce the cost of treatment and provide an easy way to chemotherapy as compared with i.v administration [12] [13] [14] [15].

The aim of this study, was to evaluate the intestinal permeability of BTZ. Intestinal permeability is an important factor that influence the bioavailability of orally delivered drugs [16] [17] [18]. Therefore, the results of this study, can give us new aspects for oral delivery of BTZ. Moreover, biopharmaceutical class of BTZ can be predicted.

The intestinal permeability of BTZ was measured by in situ single-pass intestinal perfusion (SPIP) model in rat. In the SPIP technique, a solution of respected drug is perfused through an intestinal segment in anesthetized animals [19] [20]. A non-absorbable marker, phenol red, is added to the perfusion solution for determining the water secretion or absorption in intestinal wall [21] [22].

A simple HPLC-UV method was validated according to the International Conference on Harmonization (ICH) guidelines on bioanalytical method validation for simultaneous quantification of BTZ and phenol red in the perfused samples [23].

Materials

Bortezomib and phenol red was obtained from Sigma-Aldrich (St.Louis, MO, USA). Sodium pentobarbital was provided from Kela (Hoogstraten, Belgium). Methanol was HPLC grade and purchased from Ameretat Shimi (Mamounyeh Ind., Iran). Na₂HPO₄ (anhydrous), NaH₂PO₄.2H₂O, NaCl, NaOH and glacial acetic acid were obtained from Merck (Darmstadt, Germany). Double distilled water was used during the study.

Methods

Animals

3 Male Wistar rats, 180–250 g, were used in perfusion studies. All animals were fasted 24 h with free access to water before experiments. In all animal studies “Guide to the care and use of experimental animals” by Canadian Council on Animal Care, was followed [24].

Instrumentation

A liquid chromatographic system (Knauer-Smartline, Germany) comprising of; manager 5000, pump 100 and UV detector 2500, with a C18 (Varian-Polaris 5 100×2.1 mm) column was used for chromatographic separations. System EZChrom Elite software was used for data acquisition, reporting and analysis.

Chromatographic conditions

The mobile phase was a mixture of methanol/deionized water (50:50% v/v) with 0.1% glacial acetic acid and degassed for 10 min with an ultrasonic bath. A 50 μL sample was injected into the column and analyzed in an isocratic mode at a flow rate of 0.5 mL/min at ambient temperature. The HPLC chromatograms monitored at 270 nm.

Preparation of stock, perfusion and working standard solutions

Prior to preparation of perfusion and working standard solutions, a stock solution of BTZ (methanol, 4000 µg/mL) and phenol red (PBS, 500 µg/mL) was prepared and kept at 4+°C. A perfusion solution that consisted of BTZ (10 µg/mL) and phenol red (50 µg/mL) was prepared using a suitable volume of the stock solution which was reached to a proper volume in a volumetric flask with PBS (37+°C). BTZ concentration in perfusion solution was selected on the basis of BTZ human dose (1.3 mg/m²). Dose is equally related to the body weight although it is not the alone factor which influences the scaling for dose calculation. The correction factor (K_m) is estimated by dividing the average body weight (kg) of species to its body surface area (m²) which are available in the literature. The following equation was used for equivalent dose calculation:

Human dose (mg/kg)= Rat dose (mg/kg)×(Rat K_m/Human K_m) (1)

where human dose is 0.035 mg/kg for BTZ, rat K_m is 6 and human K_m is 37. Therefore, assuming the 4 mL volume of fasted rat GIT content, the Dose 10.7 µg/mL is achieved for BTZ administration in rats. We have used 10 µ/mL in perfusion solution. The perfusion buffer consisted of Na₂HPO₄ (anhydrous, 5.77 g/L), NaH₂PO₄.2H₂O (4.08 g/L) and NaCl (7 g/L), adjusted to pH 7.2 with sodium hydroxide solution. The perfusion solution was diluted with PBS to make working standard solutions with concentrations of 1.65, 2.5, 3.3, 4, and 5 µg/mL for BTZ and 8.3, 12.5, 16.6, 20, and 25 µg/mL for phenol red.

Method validation

The HPLC method was validated for linearity, limit of detection and quantitation, precision, accuracy and stability according to the ICH guidelines on bioanalytical method validation [23].

Linearity

Linearity of the method was evaluated by plotting the peak area vs. concentration for calibration curves, over 3 consecutive days in triplicate. The least-square method was used for linear regression analysis.

Limit of detection (LOD) and quantitation (LOQ)

The LOD and LOQ for BTZ and phenol red were calculated using Eq. (2):

LOD or LOQ=A (SD_y-intercept/S) (2)

where A, the signal to noise ratio, is 3 for LOD and 10 for LOQ, SD _y-intercept is the standard deviation of y-intercept, and S is the mean value of slope for calibration curves [25] [26].

Precision and accuracy

Precision demonstrates a scattering degree between acquired data from a multiple evaluation of the same sample and is expressed as the relative standard deviation (RSD). Accuracy represents the closeness between the found and reference values and is expressed as the recovery. The precision and accuracy of the method were determined by analyzing 3 standard working solutions with concentrations of 2.5, 3.3, and 4 µg/mL for BTZ and 12.5, 16.6, and 20 µg/mL for phenol red, over 3 consecutive days.

Short-term stability study

Short-term stability study was performed to ensure that drug concentration declining in the perfusion solution is due to the intestinal permeability not to the stability problems. The stability study was conducted by analyzing the working standard solution at concentration of 3.3 µg/mL for BTZ and 16.6 µg/mL for phenol red over a period of 48 h. The samples were kept at room temperature and analyzed at beginning, 24 h and 48 h.

System suitability tests

System suitability tests are conducted to ensure the adequacy of the HPLC system for the sample analysis. Capacity factor (k′), selectivity factor (α), resolution (R), tailing factor (T), number of theoretical plates per column (N), and dead volume are parameters that calculated in system suitability evaluation using USP guidelines.

In situ single-pass intestinal perfusion (SPIP) studies

Animal investigations were approved locally by the Ethics Committee of the Tabriz University of Medical Sciences (Tabriz, Iran) with an identification code number of TBZMED.REC.1394.255. The intestinal permeability of BTZ was evaluated using SPIP model as reported previously [27] [28] [29]. Briefly, rats were anaesthetized using an intraperitoneal injection of sodium pentobarbital (60 mg/kg) and placed on a heated pad under a surgical lamp. The abdomen was opened by making a midline incision and a jejunal segment (approximately 25 cm away from pylorus and a length of 10 cm) was cannulated with plastic tubes (3 mm o.d.). The inlet tube was connected to a syringe (60 mL) which was placed in an infusion pump (Palmer, UK). The entire surgical area was covered with a wetted-sterile gauze and parafilm to reduce moisture loss. The solution was perfused at a flow rate of 1 mL/min for 10 min, to remove intestinal debris and to reach a steady-state concentration for BTZ across the intestinal wall. Then, the flow rate was set at 0.2 mL/min and outlet solution was collected at 10 min intervals and kept at 4+°C. At the end of the experiments, the location and length of the intestinal segment was determined. The effective permeability (P_eff) of BTZ was calculated according to the “parallel-tube” model that expressed by Eq. (3):

P_eff=[−Q ln (C_out (corr) / C_in)] / 2πrL (3)

where Q is the rate of infusion (0.2 mL/min), r is the radius of the intestinal segment (0.18 cm), L is the length of the intestinal segment (cm), C_in is the inlet concentration (µg/mL) of BTZ, C_out(corr) is the outlet concentration (µg/mL) of BTZ which was corrected for water flux according to the Eq. (4):

C_out (corr)=(C_{phenol red (in)} / C_{phenol red (out)}) C_out (4)

where C_out is the outlet concentration (µg/mL) of BTZ, C_{phenol red (in)} and C_{phenol red (out)} are the inlet and outlet concentrations (µg/mL) of phenol red, respectively. The P_eff value was expressed as mean±standard error of mean (SEM) for 3 experiments.

HPLC analysis of the perfused solutions

The collected samples were filtered through a syringe filter (CA 0.2 µm) and analyzed by the proposed HPLC method after dilution with methanol/PBS (50:50% v/v) at a ratio of 1:2.

Biopharmaceutical class of BTZ

According to previously published study by Zakeri-Milani et al. [30], biopharmaceutical class of BTZ was predicted based on the P_eff and dose number (D_o). D_o is a criterion for solubility and is calculated using Eq. (5):

D_o=(M / V_o) / C_s (5)

where M is the maximum dose strength (3.5 mg for BTZ), V_o is the volume of water taken with the dose (generally set to be 250 mL) and C_S is the solubility of drug, which was considered 3.3 mg/mL for BTZ [31].

Results and Discussion

In this study, for evaluating the potential of BTZ oral delivery, the intestinal permeability of BTZ was determined using the SPIP technique. Phenol red, as a non-absorbable marker, was added to the perfusion solution to correct the effect of water flux on the concentration of perfused-drug. Simultaneous quantification of BTZ and phenol red can be time saving for sample analysis. For this, a simple HPLC-UV was conducted. The chromatograms of the drug containing and drug-free perfusion solutions represent no interfering peak ([Fig. 2]). A short retention time of 1.45 and 2.96 min was observed for phenol red and BTZ. The method was more validated for the linearity, accuracy, precision and also short-term stability study was performed.

Linearity

Linearity of the method was assessed by constructing 5-point calibration curves on 3 consecutive days in replicate (n=3). Regression parameters (slope, y-intercept and determination coefficient) were determined using least-square method. The regression data were listed in [Table 1], and indicate a linearity with a determination coefficient greater than 0.99.

Limit of detection (LOD) and quantitation (LOQ)

The LOD value of 0.18 and 3.45 µg/mL was obtained for BTZ and phenol red, respectively. Moreover, the LOQ value of 1.03 and 6.67 µg/mL was achieved for BTZ and phenol red, respectively.

Precision and accuracy

Accuracy and precision of the method were determined by analyzing 3 quality control samples. The concentrations were selected based on the obtained LOD and LOQ values for BTZ and phenol red. Intraday and interday precision and accuracy data were summarized in [Table 2]. The intraday precision values were ≤4.9% for BTZ, and ≤7% for phenol red while the interday precision values were ≤1.8% for BTZ, and ≤1.9% for phenol red. The values obtained for intraday accuracy were within 96.5–105.4% for BTZ, and 92–99.2% for phenol red. However, interday accuracy values were in the range of 100–101.2% for BTZ, and 88–98.6% for phenol red. According to the ICH guidelines, recovery and RSD criteria on bioanalytical method validation should be within ±15%. Thus, the precision and accuracy values of the method are within the recommended limit.

Stability

Short-term stability of working standard solution, at a nominal concentration of 3.33 (µg/mL) for BTZ and 16.66 (µg/mL) for phenol red, was determined over a period of 48 h at room temperature. The mean measured concentrations were summarized in [Table 3]. Variation in the concentration was <1% for BTZ, and ≤4.5% for phenol red over a period of 48 h. The stability of solution is acceptable when variation in the concentration will be ±15%. Therefore, the working standard solution is stable over a period of 48 h at room temperature.

System suitability tests

System suitability tests were performed according to the USP guidelines. Capacity factor was measured as 1.41 and 3.93 for phenol red and BTZ, respectively. Selectivity factor was obtained 2.78, and resolution value achieved 1.95 for separation of phenol red and BTZ (R should be ˃1.5). For evaluating the asymmetry of the peaks, tailing factors were determined 1.83 for phenol red, and 1.71 for BTZ (recommended limit for T is ≤2). Number of theoretical plates per column was calculated as 53 for phenol red and 250 for BTZ. Meanwhile, a dead volume of 0.3 mL was determined from the chromatogram. The system suitability data indicated a compliance for the HPLC system.

Intestinal permeability and biopharmaceutical class of BTZ

In this study, biopharmaceutical class of BTZ was predicted based on the obtained rat P_eff and D_o according to previously published study by Zakeri-Milani et al. [30]. [Table 4], represents the borderlines of P_eff and D_o for different drug classes. A P_eff value (mean±SEM) of (3.36±0.5)×10⁻⁵ cm/sec was achieved for BTZ, and D_o was calculated as 0.004. Therefore, by considering these data it seems that BTZ belongs to the third biopharmaceutical class (High solubility, low permeability). On the other hand, the human intestinal permeability of BTZ was predicted based on the correlation found between human and rat intestinal permeability values which was published by the same authors (P_{eff (human)}=11.04 P_{eff (rat)}–0.0003; R2=0.93, P<0.0001) [32]. Using this equation, BTZ human P_eff is predicted to be 9.3×10⁻⁵ cm/s, confirming its low intestinal permeability and consequently low oral absorption in human. That means for its adequate and reproducible absorption following oral administration of BTZ, various formulation strategies have to be adopted. For example, a variety of lipid-based formulations (self-emulsifying systems, mixed micelles, liposomes, solid lipid nanoparticles, and etc.) could be used to enhance BTZ intestinal permeability and subsequent oral bioavailability.

Conclusion

In this study, the intestinal permeability of BTZ was evaluated using SPIP technique. A P_eff value (mean±SEM) of (3.36±0.5)×10⁻⁵ cm/s was obtained for BTZ. Moreover, it was predicted that BTZ belongs to the third biopharmaceutical class (High solubility, low permeability).

Conflict of interest

The authors declare that there are no conflicts of interest.

Acknowledgments

The financial support from the “Drug Applied Research Center”, Tabriz University of Medical Sciences is greatly acknowledged. This paper is based on a PhD thesis (Dissertation number: 108) submitted by Mohammad Mahmoudian in Faculty of Pharmacy, Tabriz University of Medical Sciences.

• References

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Correspondence

• References

• 1 Adams J. The proteasome: A suitable antineoplastic target. Nature Reviews Cancer. 2004; 4: 349-360
  CrossrefPubMedGoogle Scholar
• 2 Adams J, Palombella VJ, Sausville EA. et al. Proteasome inhibitors: A novel class of potent and effective antitumor agents. Cancer Research. 1999; 59: 2615-2622
  PubMedGoogle Scholar
• 3 Orlowski RZ, Kuhn DJ. Proteasome inhibitors in cancer therapy: Lessons from the first decade. Clinical Cancer Research. 2008; 14: 1649-1657
  CrossrefPubMedGoogle Scholar
• 4 LeBlanc R, Catley LP, Hideshima T. et al. Proteasome inhibitor PS-341 inhibits human myeloma cell growth in vivo and prolongs survival in a murine model. Cancer Research. 2002; 62: 4996-5000
  PubMedGoogle Scholar
• 5 Sunwoo JB, Chen Z, Dong G. et al. Novel proteasome inhibitor PS-341 inhibits activation of nuclear factor-κB, cell survival, tumor growth, and angiogenesis in squamous cell carcinoma. Clinical Cancer Research. 2001; 7: 1419-1428
  PubMedGoogle Scholar
• 6 Shah SA, Potter MW, McDade TP. et al. 26S proteasome inhibition induces apoptosis and limits growth of human pancreatic cancer. Journal of Cellular Biochemistry. 2001; 82: 110-122
  CrossrefPubMedGoogle Scholar
• 7 Frankel A, Man S, Elliott P. et al. Lack of multicellular drug resistance observed in human ovarian and prostate carcinoma treated with the proteasome inhibitor PS-341. Clinical Cancer Research. 2000; 6: 3719-3728
  PubMedGoogle Scholar
• 8 Imajohohmi S, Kawaguchi T, Sugiyama S. et al. Lactacystin, a specific inhibitor of the proteasome, induces apoptosis in human monoblast U937 cells. Biochemical and Biophysical Research Communications 1995; 217: 1070-1077
  CrossrefPubMedGoogle Scholar
• 9 Chen D, Frezza M, Schmitt S. et al. Bortezomib as the first proteasome inhibitor anticancer drug: Current status and future perspectives. Current Cancer Drug Targets. 2011; 11: 239
  CrossrefPubMedGoogle Scholar
• 10 Bold R. “Development of the Proteasome Inhibitor Velcade™(Bortezomib)” by Julian Adams, Ph. D., and Michael Kauffman, MD, Ph. D. Cancer Investigation 2004; 22: 328-329
  CrossrefPubMedGoogle Scholar
• 11 Pennisi A, Li X, Ling W. et al. The proteasome inhibitor, bortezomib suppresses primary myeloma and stimulates bone formation in myelomatous and nonmyelomatous bones in vivo. American Journal of Hematology. 2009; 84: 6-14
  CrossrefPubMedGoogle Scholar
• 12 Mazzaferro S, Bouchemal K, Ponchel G. Oral delivery of anticancer drugs I: general considerations. Drug Discovery Today. 2013; 18: 25-34
  CrossrefPubMedGoogle Scholar
• 13 Mei L, Zhang Z, Zhao L. et al. Pharmaceutical nanotechnology for oral delivery of anticancer drugs. Advanced Drug Delivery Reviews. 2013; 65: 880-890
  CrossrefPubMedGoogle Scholar
• 14 Thanki K, Gangwal RP, Sangamwar AT. et al. Oral delivery of anticancer drugs: challenges and opportunities. Journal of Controlled Release. 2013; 170: 15-40
  CrossrefPubMedGoogle Scholar
• 15 Bardelmeijer HA, van Tellingen O, Schellens JH. et al. The oral route for the administration of cytotoxic drugs: Strategies to increase the efficiency and consistency of drug delivery. Investigational New Drugs. 2000; 18: 231-241
  CrossrefPubMedGoogle Scholar
• 16 Varma MV, Khandavilli S, Ashokraj Y. et al. Biopharmaceutic classification system: A scientific framework for pharmacokinetic optimization in drug research. Current Drug Metabolism. 2004; 5: 375-388
  CrossrefPubMedGoogle Scholar
• 17 Veber DF, Johnson SR, Cheng H-Y. et al. Molecular properties that influence the oral bioavailability of drug candidates. Journal of Medicinal Chemistry 2002; 45: 2615-2623
  CrossrefPubMedGoogle Scholar
• 18 Aungst BJ. Intestinal permeation enhancers. Journal of pharmaceutical sciences 2000; 89: 429-442
  CrossrefPubMedGoogle Scholar
• 19 Incecayir T, Tsume Y, Amidon GL. Comparison of the permeability of metoprolol and labetalol in rat, mouse, and Caco-2 cells: Use as a reference standard for BCS classification. Molecular Pharmaceutics. 2013; 10: 958-966
  CrossrefPubMedGoogle Scholar
• 20 Zur M, Gasparini M, Wolk O. et al. The low/high BCS permeability class boundary: Physicochemical comparison of metoprolol and labetalol. Molecular Pharmaceutics. 2014; 11: 1707-1714
  CrossrefPubMedGoogle Scholar
• 21 Gupta D, Varghese Gupta S, Dahan A. et al. Increasing oral absorption of polar neuraminidase inhibitors: A prodrug transporter approach applied to oseltamivir analogue. Molecular Pharmaceutics. 2013; 10: 512-522
  CrossrefPubMedGoogle Scholar
• 22 Cao F, Jia J, Yin Z. et al. Ethylene glycol-linked amino acid diester prodrugs of oleanolic acid for PepT1-mediated transport: Synthesis, intestinal permeability and pharmacokinetics. Molecular Pharmaceutics. 2012; 9: 2127-2135
  CrossrefPubMedGoogle Scholar
• 23 Huber L. Validation of analytical methods. Agilent Technologies 2010; 13-28
  PubMedGoogle Scholar
• 24 Olfert ED, Cross BM, McWilliam AA. Guide to the care and use of experimental animals: Canadian council on animal care ottawa. vol 1, 1993
  PubMed
• 25 Islambulchilar Z, Ghanbarzadeh S, Emami S. et al. Development and validation of an HPLC method for the analysis of sirolimus in drug products. Advanced Pharmaceutical Bulletin 2012; 2: 135-139
  PubMedGoogle Scholar
• 26 Zakeri-Milani P, Valizadeh H, Azarmi Y. et al. Simultaneous determination of metoprolol, propranolol and phenol red in samples from rat in situ intestinal perfusion studies. DARU Journal of Pharmaceutical Sciences 2006; 14: 102-108
  PubMedGoogle Scholar
• 27 Salphati L, Childers K, Pan L. et al. Evaluation of a single-pass intestinal-perfusion method in rat for the prediction of absorption in man. Journal of Pharmacy and Pharmacology 2001; 53: 1007-1013
  CrossrefPubMedGoogle Scholar
• 28 Song N-N, Li Q-S, Liu C-X. Intestinal permeability of metformin using single-pass intestinal perfusion in rats. World Journal of Gastroenterology 2006; 12: 4064
  CrossrefPubMedGoogle Scholar
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