Validated HPLC method for quantification of copanlisib in mice Plasma: application to a pharmacokinetic study


doi: http://dx.doi.org/10.5599/admet.782 113 

ADMET & DMPK 8(1) (2020) 113-121; doi: http://dx.doi.org/10.5599/admet.782  

 
Open Access : ISSN : 1848-7718  

http://www.pub.iapchem.org/ojs/index.php/admet/index  

Original scientific paper  

Validated HPLC method for quantification of copanlisib in mice 
plasma: application to a pharmacokinetic study  

Ashok Zakkula
1
, Pavan Kumar Kurakula

2
, Sreekanth Dittakavi

1
, Prasanthi Daram

1
, 

Ram Murthi Bestha
1
, Mohd Zainuddin

1
, Ravi Kumar Trivedi

1
, Ramesh Mullangi

1
* 

1 
Drug Metabolism and Pharmacokinetics, Jubilant Biosys Ltd, Industrial Suburb, Yeshwanthpur, Bangalore -560 022, 

India 
2
 Department of Pharmacology, Raghavendra Institute of Pharmaceutical Education and Research, Anantapur-515721, 

A.P, India 

*Corresponding Author: E-mail: mullangi.ramesh@jubilantinnovation.com; Tel.: +91-80-66628339 

Received: January 29, 2020; Revised: February 18, 2020; Published online: March 04, 2020  

 

Abstract 

Copanlisib is a pan phosphatidylinositol 3-kinase (PI3K) inhibitor approved for follicular lymphoma. In this 
paper, we present the data of development and validation of a high-performance liquid chromatography 
(HPLC) method for the quantitation of copanlisib in mice plasma as per the FDA regulatory guideline. The 
method involves the extraction of copanlisib along with internal standard (IS, enasidenib) from mice plasma 
(100 µL) using ethyl acetate as an extraction solvent. The chromatographic resolution of copanlisib and the IS 
was achieved on a Hypersil Gold C18 column maintained at 40 °C using a binary gradient mobile phase [10 mM 
ammonium formate (pH 4.0) and acetonitrile]. The flow-rate was 0.8 mL/min. For the detection of copanlisib 
and the IS, the photo-diode array detector was set at λmax 310 nm. Copanlisib and the IS eluted at 6.60 and 7.80 
min, respectively with a total run time of 10 min. The calibration curve was linear over a concentration range of 

50 to 5000 ng/mL for copanlisib (r
2
 0.998). The results of intra- and inter-day accuracy and precision studies 

were within the acceptable limits. Copanlisib was stable on bench-top, in auto-sampler, up to three 
freeze/thaw cycle and long-term storage at -80 °C. The application of the validated method was shown in a 
mice pharmacokinetic study. 

©2020 by the authors. This article is an open-access article distributed under the terms and conditions of the Creative Commons 
Attribution license (http://creativecommons.org/licenses/by/4.0/). 

Keywords 

Copanlisib; HPLC; method validation; mice plasma; pharmacokinetics 

 

Introduction 

Phosphoinositide 3-kinases (PI3Ks) are lipid kinases, which play a pivotal role in cell cycle, cellular 

metabolism, apoptosis etc. along with α-serine/threonine-protein kinase (AKT)/mammalian target of 

rapamycin (mTOR) pathway [1]. Abnormal activation of PI3K pathway has been shown to drive 

tumorigenesis [2]. Among three classes of the PI3K enzyme, class I PI3K is linked with malignance and it 

exists in four isoforms: α, β, γ and δ [3,4]. PI3K inhibitors represent a novel class of targeted therapies for 

the treatment of human malignancies [5]. Preclinical and clinical studies demonstrated that inhibition of 

PI3K is an effective therapeutic strategy for lymphomas treatment [6]. Copanlisib (Fig. 1; BAY 80-6946), is a 

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mailto:mullangi.ramesh@jubilantinnovation.com
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R. Mullangi et al.   ADMET & DMPK 8(1) (2020) 113-121 

114  

pan-PI3K inhibitor with predominant activity against PI3K-α and PI3K-δ forms, which are expressed in 

malignant B-cells. The IC50 (half-maximal inhibitory concentration) against PI3K α, β, γ and δ isoforms was 

0.5, 3.7, 6.4 and 0.7 nmol/L, respectively [7]. It induces tumor cell death by apoptosis and inhibition of 

proliferation of primary malignant B cell lines. Copanlisib was approved for treatment of follicular 

lymphoma as an intravenous infusion for adults. In clinic, at 0.8 mg/kg (intravenous infusion), copanlisib 

showed promising efficacy in patients with solid tumors and hematological malignancies. Across the dose 

range of 0.1-1.2 mg/kg, it has shown dose proportional increase in Cmax (maximum concentration in 

plasma) and AUC0-t (area under curve from time zero to last measurable time point). Typically, Cmax attained 

between 0.5-1.0 h (Tmax). The human plasma protein binding of copanlisib is ~84 %. Copanlisib was majorly 

metabolized by CYP3A4 (>90 % metabolism) and to some extent by CYP1A1 (~10 % of metabolism) to yield 

M1, an active metabolite, which possess similar potency as copanlisib. The terminal half-life and clearance 

for copanlisib at 0.8 mg/kg were 39.1 h and 18.9 L/h. Copanlisib has high volume of distribution (871 L). Up 

to 50 % of unchanged drug and remaining amount in the form of metabolites is excreted in humans [8].  

 

Figure 1. Structural representation of copanlisib and enasidenib (internal standard, IS) 

Until date, only one bioanalytical method was published for quantification of copanlisib [9]. In the 

reported LC-MS/MS (liquid chromatography coupled with tandem mass spectrometry) method, authors 

used one step liquid-liquid extraction method for mice plasma samples processing. The linearity range was 

3.59-3588 ng/mL. Using an isocratic mobile phase, copanlisib and the internal standard were resolved on a 

HyPurity C18 column having a total run time of 3.0 min.  

Although LC-MS/MS is a powerful tool for the quantitation of drugs in various biological matrices with 

higher sensitivity in short run time, its high cost and maintenance limit its availability for most of the 

hospitals, academic institutes and research laboratories. The lower cost and affordability of the HPLC 

instrument compared to that of LC-MS/MS renders HPLC methods more eligible for wide routine use. 

In clinic, at efficacy dose of 0.8 mg/kg, copanlisib plasma concentrations were ~50 ng/mL at 8 h (both on 

day-1 and day-15) in patients with non-Hodgkin’s lymphoma and advanced solid tumors [10,11]. By 

achieving 50 ng/mL sensitivity for copanlisib on HPLC-UV, we believe our present method can be used in 

hospitals for routine therapeutic drug monitoring of copanlisib. Besides, the proposed method can also be 

in research laboratories for routine pharmacokinetic and/or toxicokinetic studies samples analysis. In order 

to ensure the reliability, reproducibility and sensitivity of the method, the developed analytical method 

was validated for various parameters in accordance with FDA guideline. The validated method was applied 

to investigate the pharmacokinetics of copanlisib post intravenous administration to mice.  



ADMET & DMPK 8(1) (2020) 113-121 Copanlisib quantification by HPLC in mice plasma 

doi: http://dx.doi.org/10.5599/admet.782  115 

Materials and methods  

Chemicals and reagents 

Copanlisib (purity: 99.7 %) was obtained from Beijing Yibai Biotechnology Co., Ltd, Beijing, China. 

Enasidenib (purity: 98 %) used as an internal standard (IS) was purchased from Aaron, Shanghai, China. 

Solutol, ethanol and dimethyl sulfoxide (DMSO) were purchased from Sigma-Aldrich, St. Louis, MO, USA. 

HPLC grade acetonitrile and methanol were purchased from J.T. Baker Avantor, PA, USA. Analytical grade 

hydrochloric acid and ammonium formate were purchased from S.D. Fine Chemicals, Mumbai, India. All 

other chemicals and reagents were of analytical grade and used without further purification. The control 

mice K2.EDTA plasma was procured from Animal House, Jubilant Biosys, Bangalore.  

HPLC operating conditions  

Analysis of copanlisib in plasma samples was performed on a Waters 2695 Alliance HPLC system 

(Waters, Milford, USA) equipped with performance PLUS inline degasser along with an auto-sampler, 

column oven and photo diode array (PDA) detector set at max 310 nm. Chromatographic resolution of 

copanlisib and the internal standard (IS) was achieved by injecting 25 µL of the processed sample on a 

Hypersil Gold C18 column (250  4.0 mm, 5 µm; Thermo Scientific, USA) maintained at 40±1 °C using a 

binary gradient mobile phase consisting 10 mM ammonium formate, pH: 4.0 (adjusted with formic acid) 

(solvent A) and acetonitrile (solvent B) delivered at a flow-rate of 0.8 mL/min. Initial eluent composition 

was 90 % A, maintained for 5.0 min, and followed by a linear 0.5 min ramp to 10 % A, which was 

maintained for until 5.5 min. The mobile phase composition returned to 90 % A at 8.0 min. Equilibration 

time was 2.0 min.  

Preparation of stock solutions for copanlisib and the IS 

For the preparation of calibration curve (CC) and quality control (QC) samples, two primary stock 

solutions of copanlisib were made at 1.0 mg/mL in 0.1 N HCl:DMSO (2:98, v/v). Due to copanlisib limited 

solubility in organic solvents we have used 0.1 N HCl. The primary stock solution of the IS (1.0 mg/mL) was 

prepared in DMSO and subsequently diluted with 80% methanol to get work stock at 0.60 μg/mL. The 

primary stock solutions of copanlisib and the IS were stored at -20±5 °C, which were found to be stable for 

50 days.  

Preparation of calibration curve standards and quality control samples  

The first set of primary stock solution of copanlisib was diluted appropriately and subsequently used to 

prepare a calibration curve (CC) standards. The calibration standard samples were made by spiking the 

blank mice plasma (90 µL) with each corresponding working solution of copanlisib (10 µL) thereby yielding 

final concentrations of 50, 100, 500, 750, 1250, 2500, 3750 and 5000 ng/mL.  

For the determination of precision and accuracy, samples were prepared by spiking blank mice plasma 

in bulk with the second working stock solution of copanlisib at appropriate concentrations and 100 L 

aliquots were distributed into different tubes. The QCs prepared were: 50 ng/mL (lower limit of 

quantification quality control; LLOQ QC), 150 ng/mL (low quality control; LQC), 2250 ng/mL (medium 

quality control; MQC) and 3500 ng/mL (high quality control; HQC). All the QCs were stored together at  

-80±10 °C until analysis.  

 

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116  

Sample preparation  

To an aliquot of 100 µL mice plasma sample, 1.0 mL of ethyl acetate was added and vortex mixed for 3 

min; followed by centrifugation for 5 min at 14,000 rpm in a refrigerated centrifuge (Eppendorf 5424R) 

maintained at 5 °C. The organic layer (800 µL) was separated and evaporated to dryness at 50 °C using a 

gentle stream of nitrogen (Turbovap®, Zymark®, Kopkinton, MA, USA). The residue was reconstituted in 

100 µL of the IS solution (600 ng/mL) and 25 µL was injected onto HPLC system for analysis.  

Validation procedures  

A full validation according to the US FDA guidance was performed for the quantitation of copanlisib in 

mice plasma [12].  

The selectivity of the proposed method was assessed by evaluating the presence of interfering the 

peaks at the retention times of copanlisib and the IS in six different batches of blank mice plasma samples. 

The auto-injector carry over was determined by injecting the highest calibration standard (5.0 µg/mL) 

followed by injection of mice plasma blank samples. Recovery of copanlisib was determined by comparing 

their respective response from QCs (LQC and HQC) after the extraction process against their non-extracted 

samples. Recovery of the IS was determined at 600 ng/mL. Intra- and inter-day accuracy and precision 

were determined at four QC levels [LLOQ QC (50 ng/mL), LQC (150 ng/mL), MQC (2250 ng/mL) and HQC 

(3500 ng/mL)] along with calibration curve (0.05-5.00 μg/mL). Stability (auto-sampler, bench-top, freeze-

thaw and long-term) studies, dilution effect and incurred sample reanalysis (ISR) were also evaluated as per 

regulatory guideline requirement [12]. 

Pharmacokinetic study in mice  

Twelve male Balb/C mice (weight range: 26-28 g) were procured from Vivo Biotech, Hyderabad, India. 

Animal study protocol used in this study was approved by the Institutional Animal Ethics Committee, 

Jubilant Biosys (IAEC/JDC/2019/188R). Mice were housed for a period of seven days having free access to 

feed and water before the pharmacokinetic study. Mice received copanlisib intravenously [2 % 0.1 N HCl, 

10 % DMSO, 10 % Solutol:absolute alcohol (1:1, v/v) and 78 % normal saline; strength: 0.5 mg/mL; dose 

volume: 10 mL/kg] at 5.0 mg/kg as a bolus dose. Blood samples (100 µL) were collected at pre-determined 

time points (0.12, 0.25, 0.5, 1, 2, 4, 8 and 24 h) through retro-orbital plexus (using Micropipettes, 

Drummond Scientific, PA, USA; catalogue number: 1-000-0500) into polypropylene tubes (having K2.EDTA 

as an anti-coagulant). Sparse sampling technique (three mice per time point) was adopted during blood 

collection so that blood loss from each mouse was kept less than 10 % of total blood volume. Plasma was 

harvested by centrifuging the blood using Biofuge (Hereaus, Germany) at 1760 g for 5 min and stored 

frozen at -80±10 °C until analysis. Mice were allowed to access feed 2 h post-dosing. 

Pharmacokinetic analysis 

Pharmacokinetic parameters were calculated by a non-compartmental method using Phoenix 

WinNonlin 8.1 software (Pharsight, Mountain View, CA, USA). Key pharmacokinetic parameters like 

extrapolated plasma drug concentration at time zero following intravenous bolus injection (C0), area under 

the curve from time zero to infinity (AUC0-), volume of distribution (Vd), total body clearance (CL) and half-

life (t½) were determined for copanlisib.  

 
 



ADMET & DMPK 8(1) (2020) 113-121 Copanlisib quantification by HPLC in mice plasma 

doi: http://dx.doi.org/10.5599/admet.782  117 

Results and discussion  

Method development and optimization 

Several trials were taken with various columns, mobile phase compositions to select the 

chromatographic conditions, which will give a good resolution of copanlisib and the IS from the 

endogenous matrix substances within a suitable run time. Several mobile phases were tried by changing 

the combination of different organic solvents (acetonitrile and methanol) and buffers (eg: formic acid, 

ammonium acetate, phosphate buffer etc.) with altered flow-rates (in the range of 0.60-1.20 mL/min). To 

choose a stationary phase a variety of columns namely X-Terra Phenyl, Atlantis, Hypersil Gold C18 were 

evaluated. Our trials revealed that mobile phase comprising 10 mM ammonium formate (pH 

4.0):acetonitrile delivered in a gradient program at a flow-rate of 0.8 mL/min on Hypersil Gold C18 column 

gave a stable base line with good resolution between copanlisib and the IS with a total run time of 10 min 

with no interference of endogenous plasma peaks. The UV detector was set at λmax 310 nm. For the 

optimized conditions, enasidenib was found to be a suitable internal standard as it exhibited good 

resolution, retention time and UV absorbance intensity (UV λmax 287 nm) at the same wave length of 

copanlisib.  

Method validation 

With protein precipitation technique the recovery of copanlisib and IS was very poor (<40 %). Liquid-

liquid extraction with ethyl acetate gave best results in terms of extraction recovery, reproducibility and 

cleaner samples. The mean ± S.D recovery of copanlisib at LQC and HQC was 83.8 ± 4.51 and 83.9 ± 1.17 %, 

respectively. The recovery of the IS was 99.5 ± 1.33 %. As shown in Fig. 2, both copanlisib and the IS peaks 

were well resolved and no interference at the retention times of copanlisib and the IS from the 

endogenous components of mice. The retention time of copanlisib and the IS was 6.60 and 7.80 min, 

respectively. The calibration curves (n=4) for copanlisib were observed to be linear in the range of 50-5000 

ng/mL. A representative equation for the calibration curves is as follows: y = 0.0005 x + 0.003. A regression 

equation with a weighting factor of 1/X
2
 of each drug to the IS concentration was found to produce the 

best fit for the concentration-detector response relationship. The correlation coefficients (r
2
) were more 

than 0.999, indicating an acceptable linearity of our method. The accuracy observed for the mean of back-

calculated concentrations for four calibration curves was within 89.3-109 %; while the precision (%RE) 

values ranged from 0.95-1.05 %. We did not observe any carry-over produced by the highest calibration 

sample on the following injected mice blank plasma extracted sample for copanlisib.  

 
Figure 2. HPLC chromatograms of a 25 µL injection of (a) blank mice plasma (b) blank mice plasma spiked with 

copanlisib (LLOQ: 50 ng/mL) along with the IS (c) a 0.5 h plasma sample showing the peak of copanlisib 
(concentration: 3500 ng/mL) following intravenous administration of copanlisib  to mice at 5.0 mg/kg. 

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118  

Table 1.  Intra- and inter-day precision and accuracy determination of 
copanlisib quality controls in mice plasma 

Accuracy and precision data for 

intra- and inter-day mice plasma 

samples determined for copanlisib 

(from four different batches) at LLOQ 

QC (50 ng/mL), LQC (150 ng/mL), MQC 

(2250 ng/mL) and HQC (3500 ng/mL) 

are presented in Table 1. The intra- and 

inter-day precisions (RSD) were within 

7.59 %, and accuracy (RE) ranged 

between 0.97-1.07 %. The assay values 

on both the occasions (intra- and inter-

day) were found to be within the 

accepted variable limits indicating that 

the present method is reproducible, 

accurate and precise. Table 2 

summarizes the results of stability 

studies conducted for copanlisib in 

mice plasma. The measured 

concentrations for copanlisib at LQC 

(150 ng/mL) and HQC (3500 ng/mL) 

deviated within ±15 % of the nominal 

concentrations in a battery of stability 

tests namely in-injector (16 h), bench-

top (6 h), repeated three freeze/thaw 

cycles and freezer stability at -8010 °C 

for 30 days (Table 2) supported the 

stability of copanlisib at various 

stability conditions. The dilution 

integrity was confirmed for QC samples that exceeded the upper limit of the quantitation (ULOQ) of 

calibration curve (up to 35000 ng/mL). The mean accuracy and precision for 15 times diluted samples were 

found to be less than 7.62 and 6.25 %, respectively, which show the ability to dilute samples up to a 

dilution factor of ten in a linear fashion (Table 2). All the samples selected for ISR met the acceptance 

criteria. The back-calculated accuracy values ranged between 89.2-110 % from the initial assay results as 

shown in Fig. 3 using a Bland-Altman plot. 

Pharmacokinetic study 

Plasma samples collected during pharmacokinetic study were thawed at room temperature and 

processed as mentioned in Sample preparation section. Along with plasma samples, LQC, MQC and HQC 

samples (made in blank plasma) were assayed in duplicate and were distributed among unknown samples 

in the analytical run. Plasma samples showed high concentration above the high calibration standard 

(5.00 µg/mL) were diluted appropriately with mice blank plasma to bring the concentration within linearity 

range. The criteria for acceptance of the analytical runs encompassed the following: (i) ≥67 % of QC 

Theoretical 
concentration 

(ng/mL) 

 
Batch 

Measured concentration (ng/mL) 

Mean ± SD RSD Accuracy, % 

Intra-day (Six  replicates at each concentration) 

50.0 

1 49.4 ± 4.76 9.63 98.9 

2 50.8 ± 3.89 7.65 101 

3 54.3 ± 1.35 2.49 108 

4 51.0 ± 3.26 6.53 103 

150 

1 139 ± 1.95 1.39 93.2 

2 151 ± 5.77 3.80 101 

3 146 ± 2.88 1.98 97.3 

4 145 ± 3.46 2.36 97.3 

2250 

1 2155 ± 46.5 2.16 95.8 

2 2120 ± 78.9 3.72 94.2 

3 2297 ± 38.1 1.66 102 

4 2190 ± 54.1 2.50 97.4 

3500 

1 3460 ± 81.2 2.32 112 

2 3507 ± 70.0 2.00 104 

3 3545 ± 53.3 1.50 105 

4 3516 ± 68.1 1.94 107 

Inter-day (Twenty four  replicates at each concentration) 

50.0 

 

51.2 ± 3.91 7.59 103 

150 146 ± 6.22 4.28 97.3 

2250 2190 ± 95.1 4.35 96.9 

3500 3504 ± 72.0 2.06 99.9 

RSD: relative standard deviation (SD  100/Mean) 
RE: relative error (measured value/actual value) 
SD: standard deviation 



ADMET & DMPK 8(1) (2020) 113-121 Copanlisib quantification by HPLC in mice plasma 

doi: http://dx.doi.org/10.5599/admet.782  119 

samples should be ±15 % of the nominal concentration values (ii) ≥ 50 % of QC samples per level should be 

±15 % of their nominal concentration values [12].  

Table 2. Stability and dilution integrity data for copanlisib in mice plasma 

Experiment 
Spiked 

concentration  
(ng/mL) 

Measured 
concentration 

(ng/mL) 
Mean ± SD

a 

(n  =  6) 

Accuracy 
(%)

b 
Precision 

(% CV) 

Bench-top (6 h) stability 
150 150 ± 2.72 99.8 1.80 

3500 3548 ± 66.6 101 1.88 

In-injector (16 h) stability 
150 146 ± 4.77 98.0 3.25 

3500 3808 ± 34.0 107 0.89 

Freeze-thaw (3 cycles) 
stability 

150 159 ± 12.3 106 7.70 

3500  3774 ± 107 107 2.84 

Long-term stability at -80°C 
(30 days) 

150 146 ± 3.44 97.3 2.35 

3500 3758 ± 23.0 106 0.61 

*Dilution integrity 2333 2522 ± 403 108 6.25 

RSD: relative standard deviation (SD x 100/Mean) 
RE: relative error (measured value/actual value) 
*Plasma samples prepared at 35,000 ng/mL (10-fold above HQC) diluted with blank plasma by 15-fold and analyzed 

 

 

 

 

 

 

Figure 3. Bland-Altman plot showing the 
incurred sample reanalysis (ISR) data for 

copanlisib 

 

 

In the mice, plasma concentrations of copanlisib decreased mono-exponentially after intravenous 

administration. Fig. 4 depicts the mean ± S.D plasma concentrations versus time for copanlisib following 

intravenous administration to mice at 5.0 mg/kg. Copanlisib was quantifiable up to 8.0 h post intravenous 

administration to mice. Post intravenous administration, the CL and Vd were found to be 42.1 mL/min/Kg 

and 27.6 L/kg, respectively. The AUC0-∞ attained post intravenous administration was 1978 (ng h)/mL. The 

t½ was 7.58 h. In summary the validated method was sensitive enough to calculate the pharmacokinetic 

parameters of copanlisib.  

Patnaik et al. [10] and Kim et al. [11] reported the plasma concentrations of copanlisib post 

administration at efficacy dose (0.8 mg/kg as 1 h intravenous infusion) to patients with advanced solid 

tumors and non-Hodgkin’s lymphoma. Plasma samples collected in these studies on day-1 and day-15 were 

analyzed using an LC-MS/MS method. We have digitalized the reported plasma concentrations versus time 

plots of copanlisib reported by Patnaik et al. [10] and Kim et al. [11] using DigitizeIt software [13] and found 

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R. Mullangi et al.   ADMET & DMPK 8(1) (2020) 113-121 

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that in both studies copanlisib showed ~50 ng/mL till 8 h. By achieving 50 ng/mL sensitivity for copanlisib 

on HPLC-UV in the present method, we believe our present method can be reliably used in hospitals for 

routine therapeutic drug monitoring of copanlisib. By increasing the plasma volume for sample processing 

and injection volume for HPLC analysis, there is a great possibility that our validated HPLC-UV can be used 

to quantify the copanlisib plasma concentration at terminal time points at therapeutic doses. 

 

 

 

 

 

Figure 4. Mean plasma concentration versus 
time profile for copanlisib in mice plasma 

following intravenous administration to mice. 

 

 

Conclusions 

A simple reversed-phase HPLC method for determination of copanlisib in mice plasma has been 

developed and validated. The proposed method is highly specific, accurate, precise and reproducible. All 

the validation parameters were within the acceptable limits for a bioanalytical method as per regulatory 

guideline. This method has been successfully applied to a pharmacokinetic study in mice.  

 

Conflict of interest: The authors are scientists at Jubilant Biosys Ltd. 

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©2020 by the authors; licensee IAPC, Zagreb, Croatia. This article is an open-access article distributed under the terms and 
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