Julie Schappler

Drug–protein binding: a critical review of analytical tools

AbstractThe extent of drug binding to plasma proteins, determined by measuring the free active fraction, has a significant effect on the pharmacokinetics and pharmacodynamics of a drug. It is therefore highly important to estimate drug-binding ability to these macromolecules in the early stages of drug discovery and in clinical practice. Traditionally, equilibrium dialysis is used, and is presented as the reference method, but it suffers from many drawbacks. In an attempt to circumvent these, a vast array of different methods has been developed. This review focuses on the most important approaches used to characterize drug–protein binding. A description of the principle of each method with its inherent strengths and weaknesses is outlined. The binding affinity ranges, information accessibility, material consumption, and throughput are compared for each method. Finally, a discussion is included to help users choose the most suitable approach from among the wealth of methods presented. FigureRange of binding constants (log Ka) assessable by the main separative and non-separative analytical tools used to characterize drug-protein interactions. ED: equilibrium dialysis, UF: ultrafiltration, PAMPA: parallel artificial membrane permeability assay, HPAC/ZE: high-performance affinity chromatography/zonal elution approach, HPAC/FA: high-performance affinity chromatography/frontal analysis approach, ACE: affinity capillary electrophoresis (mobility shift assay), CE/FA: capillary electrophoresis/frontal analysis, Spectro.: spectroscopic assays, ITC: isothermal titration calorimetry, comp.: competition studies, titration: titration studies, DSC: differential scanning calorimetry, SPR: surface plasmon resonance-based assays.

Intact protein analysis in the biopharmaceutical field

In recent years, a growing number of biopharmaceutical proteins have been produced and are already available, or will be soon available, in the market. These molecules are more complex to analyze than conventional low molecular weight drugs, and thus need powerful analytical approaches for the entire development and delivery process. This review summarizes the analytical techniques available for intact protein determination and the main development steps in which they are applicable. A strong emphasis has been put on separation techniques, liquid chromatography and electrophoretic techniques, but mass spectrometry and spectroscopic approaches are also mentioned. Overall, we highlight how several analytical strategies are necessary to obtain global information.

Capillary electrophoresis-electrospray ionization-mass spectrometry interfaces: Fundamental concepts and technical developments

Capillary electrophoresis (CE) hyphenated to electrospray ionization (ESI) mass spectrometry (MS) is a powerful tool for analyzing a wide variety of analytes in different matrices. The major issue with CE-ESI-MS lies in finding a suitable and versatile interface to ensure the best CE and ESI operations. Thus, the development and improvement of CE-ESI-MS interfaces have been the subjects of much research. The first part of the present review focuses on the fundamental aspects of the three steps of the ESI process, i.e., spray formation, droplet evolution, and the production of gas-phase ions. In the second part of the review, the electrochemical reactions involved in the ESI and CE processes and their influences on the sensitivity and performance are discussed in detail. Then, the existing interfaces are divided into two major classes according to their operating flow rate (electrospray vs. nanospray regime). The particular characteristics of these two regimes are discussed by considering their practical impacts on ionization and the MS response. Finally, the current CE-ESI-MS interfaces are summarized, including their major advantages, drawbacks, and fields of application.

CE-TOF/MS: fundamental concepts, instrumental considerations and applications

This review discusses the fundamental principles of TOF analyzers and covers the great progress that has been made in this area in recent years (i.e. orthogonal acceleration, reflectron). This paper also gives an overview of applications performed by CE coupled to TOF/MS detection. The main domains of interest include the analysis of biomolecules and natural compounds.

Coupling ultra high-pressure liquid chromatography with single quadrupole mass spectrometry for the analysis of a complex drug mixture.

The coupling of ultra high-pressure liquid chromatography with a single quadrupole mass spectrometer was investigated for the analysis of several cytochromes P450 (CYP450) substrates and respective metabolites. The effect of numerous operating parameters (e.g. mobile phase pH, flow rate, gradient length, MS acquisition mode, dwell time, polarity switching, etc.) on selectivity, sensitivity and acquisition rate was studied. It was demonstrated that basic pH conditions provided the best compromise in terms of sensitivity and chromatographic selectivity with both acidic and basic compounds. The optimal mobile phase flow rate for UHPLC-MS experiments should be comprised between 300 and 600 microL/min for 2.1mm ID columns, while a higher flow rate generated up to 3-fold loss in sensitivity. It was also demonstrated that the fast polarity switching mode represented a valuable tool to improve throughput, maintaining acceptable performance. Finally, limits of detection were included in the range [1-50 ng/mL] in positive ionization mode and [50-250 ng/mL] in negative ionization mode, for investigated compounds.

Reliable low-cost capillary electrophoresis device for drug quality control and counterfeit medicines

The proportion of counterfeit medicines is dramatically increasing these last few years. According to numerous official sources, in some pharmaceutical wholesalers in African countries, the proportion has reached 80%. Unfortunately, this situation is far to be improved due to lack of suitable analytical equipment allowing rapid actions of the Regulatory Agencies based on scientific consideration, at affordable cost and all over the drug supply chain. For that purpose, a network group considered that mater by building a low-cost original capillary electrophoresis (CE) equipment equipped with a new deep UV detector based on LED technology. The generic conditions for analysis were investigated: capillary zone electrophoresis (CZE) performed at acidic pH for basic drug molecules (i.e., quinine, highly used as the last antimalarial rampart), basic pH for compounds such as furosemide (a common diuretic drug) and at neutral pH for a well known antibiotic combination, trimethoprim/sulfamethoxazol. To evaluate the ability of the CE equipment for quantification, a full validation and a method comparison study were carried out for the CZE method dedicated to quinine determination. The validation involved the use of accuracy profile and total error concept to monitor the adequacy of the results obtained by the new prototype. The method comparison was based on the Bland and Altman approach by comparing results obtained by the low-cost CE and a conventional set-up. Subsequent validation studies were realized with neutral and acidic drug molecules, each focusing on a single concentration level calibration curve in order to maintain as low as possible the expenses due to reagents and thus the cost of analysis, as important advantages of CE for drug quality control.

Validation of chiral capillary electrophoresis‐electrospray ionization‐mass spectrometry methods for ecstasy and methadone in plasma

Due to its selectivity and sensitivity, CE coupled to MS (CE‐MS) has evolved as a useful analytical tool for determining drugs and metabolites in biological samples. A generic CE‐ESI/MS method was developed for the enantioselective determination of basic compounds in plasma. The use of protein precipitation (PP) prior to a hydrodynamic injection (HD) was well adapted to high‐concentration samples (>1 ppm) and allowed high throughput. In contrast, the combination of liquid–liquid extraction (LLE) and electrokinetic injection (EK) was time‐consuming but did allow detection at the ppb level. Both approaches were fully validated according to ICH guidelines and SFSTP protocols for two pharmaceutical compounds (ecstasy and methadone (MTD)). Deuterated internal standards (IS) in the analytical procedures were used and good quantitative performance was obtained in terms of trueness and precision (repeatability and intermediate precision) since accuracy profiles were within the acceptance limits (30% for biological assay). Methods were linear over the concentration range of 0.50–175 ng/mL and 0.25–5 μg/mL for LLE‐EK and PP‐HD procedures, respectively. The LLE‐EK methodology was finally successfully applied to quantitation of ecstasy and MTD in real cases obtained from toxicology.

Dispersive liquid–liquid microextraction combined with capillary electrophoresis and time-of-flight mass spectrometry for urine analysis

The combination of dispersive liquid-liquid microextraction (DLLME) with capillary electrophoresis (CE) and a time-of-flight mass spectrometer (TOF-MS) was evaluated for the toxicological screening in urine samples. A methodology based on design of experiments (DOE) was implemented to increase the extraction efficiency. Dichloromethane and isopropanol were selected as the extraction and dispersing solvents, respectively. Seven factors for DLLME were screened with the help of a Plackett-Burmann DOE using two model compounds before fine investigation of the important parameters to maximise the compound extraction. These experiments were performed in the CE-UV configuration to overcome potential MS matrix effects. The performance of the entire procedure was then evaluated using CE-ESI-TOF-MS. With a preconcentration factor of more than 130, the highly sensitive DLLME-CE-ESI-TOF-MS method allowed for the detection of 30 toxicological compounds (i.e., amphetamines and their derivatives, opiates, cocaine and its metabolites and pharmaceuticals) in urine with limits of detection in the sub-ng/mL level and was used to analyse real toxicological samples. The combination of DLLME and CE was particularly attractive because of the small amount of organic solvents required.

Fast chiral separation of drugs using columns packed with sub‐2 μm particles and ultra‐high pressure

The use of columns packed with sub-2 microm particles in liquid chromatography with very high pressure conditions (known as UHPLC) was investigated for the fast enantioseparation of drugs. Two different procedures were evaluated and compared using amphetamine derivatives and beta-blockers as model compounds. In one case, cyclodextrins (CD) were directly added to the mobile phase and chiral separations were carried out in less than 5 min. However, this strategy suffered from several drawbacks linked to column lifetime and low chromatographic efficiencies. In the other case, the analysis of enantiomers was carried out after a derivatization procedure using two different reagents, 2,3,4-tri-O-acetyl-alpha-D-arabinopyranosyl isothiocyanate (AITC) and N-alpha-(2,4-dinitro-5-fluorophenyl)-L-alaninamide (Marfeys reagent). Separation of several amphetamine derivatives contained within the same sample was achieved in 2-5 min with high efficiency and selectivity. The proposed approach was also successfully applied to the enantiomeric purity determination of (+)-(S)-amphetamine and (+)-(S)-methamphetamine. Similar results were obtained with beta-blockers, and the separation of 10 enantiomers was carried out in less than 3 min, whereas the individual separation of several beta-blocker enantiomers was performed in 1 min or less.

Evaluation and comparison of various separation techniques for the analysis of closely-related compounds of pharmaceutical interest.

The aim of the present work was to compare various separation techniques for the fast analysis of closely-related compounds, including structurally-related compounds, positional isomers, diastereoisomers, Z/E isomers. Three analytical techniques were evaluated, namely ultra high performance liquid chromatography (UHPLC), ultra high performance supercritical fluid chromatography (UHPSFC), both with sub-2μm particles, and capillary electrophoresis (CE) using non-aqueous solvents. To fairly compare the three analytical techniques, only two starting conditions for further method development were considered. All the selected mobile phases or background electrolyte were MS-compatible. As expected, CE often provided excellent results for the analysis of basic compounds but it was difficult to find out conditions that could be widely applied. On the other hand, UHPLC and UHPSFC were more generic and the performance was better than CE for the analysis of neutral and acidic compounds. In all cases, the analysis time was systematically lower than 3min. In conclusion, UHPLC was the most versatile strategy for the analysis of closely-related compounds and should be tested in a first instance. UHPSFC and CE approaches offered some drastic changes in selectivity and should be considered a second choice to reach alternative selectivity as they also allow high throughput separations.