Developing a robust ultrafiltration-LC-MS/MS method for quantitative analysis of unbound vadimezan (ASA404) in human plasma

Ultrafiltration of human plasma in combination with LC-MS/MS has been increasingly used in the quantitative analysis of the free fraction of drug candidates for PK/efficacy assessment. In addition to controlling the pre-incubation and centrifugation temperatures, some important factors that must be investigated and addressed include: (1) possible nonspecific binding, (2) possible impact of freeze/thaw cycles of plasma samples and extended storage of plasma samples at room temperature on the analyte recovery prior to ultrafiltration, and (3) identification of the appropriate assay dynamic range to avoid unnecessary dilutions. These factors were explored in the development and validation of a robust LC-MS/MS assay for the quantitative analysis of unbound vadimezan (ASA404) in human plasma. First, to mimic human physiological conditions, all plasma samples were incubated at ~37°C for a minimum of 30 min after thawing and prior to centrifugation to obtain the ultrafiltrate. Second, by passing the calibration standards and QC samples in plasma ultrafiltrate through the ultrafiltration membrane, the observed non-specific binding of the analyte due to the membrane was corrected. Third, the effects of multiple freeze/thaw cycles and/or storage at room temperature for various periods (4, 8, 16 and 24h) were evaluated to determine the impact on analyte concentrations in the ultrafiltrate from the plasma QC samples. Fourth, the appropriate dynamic range was established to accommodate the expected incurred sample free analyte concentrations. The validated assay has a dynamic range of 30.0-30,000 ng/ml for ASA404 in human plasma ultrafiltrate using a sample volume of 30 μl. Quality control pools containing the analyte were prepared at concentrations of 30.0-22,500 ng/ml to cover the assay calibration range. The intra-assay and inter-assay precision and accuracy were ≤ 15% (CV) and within ± 15% (bias) of the nominal values, respectively, for all measured QC concentrations, including the LLOQ. Freeze/thaw for up to three cycles of the plasma samples and/or the extended human plasma sample exposure to room temperature for up to 24h were confirmed to have no impact on the assay results for the free analyte. The validated method was successfully implemented to support clinical studies for the compound.     

Bioanalytical aspects on method validation

The validation of methods for neurotransmitter amines and metabolites depends on various sample related factors such as interferences, complexity of matrix composition, analyte stability or variations in concentration due to changing physiological responses. Also, the ultimate precision and accuracy of a method in whole would be related to the complexity of the sample work up procedure, the efficiency and reproducibility of the separation system, the use of a suitable internal standard to correct for volumetric errors and the sensitivity, linearity and selectivity of the detection system. A critical factor in the validation of those methods based in the chromatographic separation of the analyte is the confirmation of peak homogeneity through procedures such as changes on retention time, collection of analyte and reinjection into another system, correlation of recoveries in both systems, pharmacological manipulations prior to the assay or collection and derivatization followed by rechromatography. Isotope dilution GC-MS is widely accepted as a definitive reference method for its accuracy and precision although, as it is not always available, crossvalidation between different non-mass spectrometric methods is often given as proof of analytical reliability.     

Clinical application of breath biomarkers of oxidative stress status

Isolation and quantification of volatile breath biomarkers indicative of relevant alterations in clinical status has required development of new techniques and applications of existing analytical chemical methods. The most significant obstacles to successful application of this type of sample have been reduction in required sample volume permitting replicate analysis (an absolute requirement for all clinical studies), separation of the analyte(s) of interest from background molecules, water vapor and other molecules with similar physical properties, introduction of automation in analysis and the use of selective detection systems (electron impact mass spectrometry, flame photometric, thermionic detectors), and automated sample collection from the human subject. Advances in adsorption technology and trace gas analysis have permitted rapid progress in this area of clinical chemistry.     

Complex genesis of anemia in chronic liver diseases]

36% of a total of chronic liver patients suffered from anaemia and 50.5% of patients affected with liver cirrhosis. In most cases the anaemias were normochrome and hypochrome or hyperchrome only in some cases. In analyzing possible single factors the reductions of vitamin B12 absorption could be made probable by means of the Schilling test and sometimes a folic acid deficiency in macrocyte anaemia with normal vitamin B12 absorption by determining the folic acid content in the serum and by successes of test treatment 82% of patients with liver cirrhosis showed a latent or manifest haemolysis. However, it was only in 1/3 of the patients with liver cirrhosis that the spleen turned out to be the place of an increased degradation of erythrocytes. In some cases an increased erythrocytoclasia into the liver could be identified. Predominantly, however, an increased degradation of erythrocytes in the total RHS had to be assumed. Twice an ineffective erythropoiesis could be found by ferrokinetic examinations. As a whole ferrokinetic examinations cannot be interpreted easily, because their static and dynamic values of iron transport in the plasma volume of liver patients will undergo considerable changes. Patients with disturbances of haematopoiesis and with haemolysis remaining in the latent stage may develop a manifest anaemia because of the influence of additional factors, such as increase of the plasma volume at lowered haematocrit value or microbleedings. The cause of anaemia cannot be concluded with sufficient probability from the type of anaemia; in a single case all pathogenetic factors will rather have to be analyzed. Therapeutic possibilities for hepatogenous anaemia of complex genesis are discussed.     

Fast and sensitive liquid chromatography-mass spectrometry assay for seven androgenic and progestagenic steroids in human serum

A fast and sensitive LC-MS/MS method for the quantitative analysis of seven steroid hormones in 150 μl of human serum was developed and validated. The following compounds were included: 17α-hydroxypregnenolone, 17α-hydroxyprogesterone, androstenedione, dehydroepiandrosterone, testosterone, pregnenolone, and progesterone. Individual stable isotope-labeled analogues were used as internal standards. Sample preparation was performed by liquid-liquid extraction, followed by oxime derivatization to improve the ionization efficiency of the analytes. In contrast to the common derivatization-based methods, the reaction was incorporated into the sample preparation process and the only additional step due to the derivatization was a short heating of the autosampler vials before the sample injection. Chromatographic separation was achieved on a reversed-phase column using a methanol-water gradient. For the analyte detection, a triple quadrupole instrument with electrospray ionization was used. Total run time was 7.0 min and the lower limits of quantification were in the range of 0.03-0.34 nM (0.01-0.10 ng/ml), depending on the analyte. The method was validated using human serum samples from both sexes and applied for the serum steroid profiling of endometriosis patients.     

Quantitative determination of BAF312, a S1P-R modulator,in human urine by LC–MS/MS: Prevention and recovery of lost analyte due to container surface adsorption

Analyte loss due to non-specific binding, especially container surface adsorption, is not uncommon in the quantitative analysis of urine samples. In developing a sensitive LC–MS/MS method for the determination of a drug candidate, BAF312, in human urine, a simple procedure was outlined for identification, confirmation and prevention of analyte non-specific binding to a container surface and to recover the ‘non-specific loss’ of an analyte, if no transfer has occurred to the original urine samples. Non-specific binding or container surface adsorption can be quickly identified by using freshly spiked urine calibration standards and pre-pooled QC samples during a LC–MS/MS feasibility run. The resulting low recovery of an analyte in urine samples can be prevented through the use of additives, such as the non-ionic surfactant Tween-80, CHAPS and others, to the container prior to urine sample collection. If the urine samples have not been transferred from the bulk container, the ‘non-specific binding’ of an analyte to the container surface can be reversed by the addition of a specified amount of CHAPS, Tween-80 or bovine serum albumin, followed by appropriate mixing. Among the above agents, Tween-80 is the most cost-effective. β-cyclodextrin may be suitable in stabilizing the analyte of interest in urine via pre-treating the matrix with the agent. However, post-addition of β-cyclodextrin to untreated urine samples does not recover the ‘lost’ analyte due to non-specific binding or container surface adsorption. In the case of BAF312, a dynamic range of 0.0200–20.0 ng/ml in human urine was validated with an overall accuracy and precision for QC sample results ranging from ?3.2 to 5.1% (bias) and 3.9 to 10.2% (CV), respectively. Pre- and post-addition of 0.5% (v/v) Tween-80 to the container provided excellent overall analyte recovery and minimal MS signal suppression when a liquid–liquid extraction in combination with an isocratic LC separation was employed. The compound was stable in 0.5% Tween-80 treated human urine QC samples for at least 24 h at room temperature, after three freeze/thaw cycles with storage at ≤?60 °C and for at least 3 months when stored at ≤?60 °C. The current work could serve as a simple example in trouble shooting non-specific binding or container surface adsorption in quantitative analysis of urine samples.     

A sample preparation process for LC-MS/MS analysis of total protein drug concentrations in monkey plasma samples with antibody

The determination of protein concentrations in plasma samples often provides essential information in biomedical research, clinical diagnostics, and pharmaceutical discovery and development. Binding assays such as ELISA determine meaningful free analyte concentrations by using specific antigen or antibody reagents. Concurrently, mass spectrometric technology is becoming a promising complementary method to traditional binding assays. Mass spectrometric assays generally provide measurements of the total protein analyte concentration. However, it was found that antibodies may bind strongly with the protein analyte such that total concentrations cannot be determined. Thus, a sample preparation process was developed which included a novel "denaturing" step to dissociate binding between antibodies and the protein analyte prior to solid phase extraction of plasma samples and LC-MS/MS analysis. In so doing, the total protein analyte concentrations can be obtained. This sample preparation process was further studied by LC-MS analysis with a full mass range scan. It was found that the protein of interest and other plasma peptides were pre-concentrated, while plasma albumin was depleted in the extracts. This capability of the sample preparation process could provide additional advantages in proteomic research for biomarker discovery and validation. The performance of the assay with the novel denaturing step was further evaluated. The linear dynamic range was between 100.9ng/mL and 53920.0ng/mL with a coefficient of determination (r(2)) ranging from 0.9979 and 0.9997. For LLOQ and ULOQ samples, the inter-assay CV was 12.6% and 2.7% and inter-assay mean accuracies were 103.7% and 99.5% of theoretical concentrations, respectively. For QC samples, the inter-assay CV was between 2.1% and 4.9%, and inter-assay mean accuracies were between 104.1% and 110.0% of theoretical concentrations.     

An approach to enhancing coverage of the urinary metabonome using liquid chromatography-ion mobility-mass spectrometry

The potential of drift tube ion mobility (IM) spectrometry in combination with high performance liquid chromatography (LC) and mass spectrometry (MS) for the metabonomic analysis of rat urine is reported. The combined LC-IM-MS approach using quadrupole/time-of-flight mass spectrometry with electrospray ionisation, uses gas-phase analyte characterisation based on both mass-to-charge (m/z) ratio and relative gas-phase mobility (drift time) following LC separation. The technique allowed the acquisition of nested data sets, with mass spectra acquired at regular intervals (65 micros) during each IMS separation (approximately 13 ms) and several IMS spectra acquired during the elution of a single LC peak, without increasing the overall analysis time compared to LC-MS. Preliminary results indicate that spectral quality is improved when using LC-IM-MS, compared to direct injection IM-MS, for which significant ion suppression effects were observed in the electrospray ion source. The use of reversed-phase LC employing fast gradient elution reduced sample preparation to a minimum, whilst maintaining the potential for high throughput analysis. Data mining allowed information on specific analytes to be extracted from the complex metabonomic data set. LC-IM-MS based approaches may have a useful role in metabonomic analyses by introducing an additional discriminatory dimension of ion mobility (drift time).     

Isotope ratio determination in boron analysis

Traditionally, boron (B) isotope ratios have been determined using thermal ionization mass spectrometry (TIMS) and, to some extent, secondary ion mass spectrometry (SIMS). Both TIMS and SIMS use a high-resolution mass analyzer, but differ in analyte ionization methods. TIMS uses electrons from a hot filament, whereas SIMS employs an energetic primary ion beam of Ga+, Cs+, or O- for analyte ionization. TIMS can be used in negative or positive ion modes with high sensitivity and precision of B isotope ratio determination. However, isobaric interferences may be a problem, if the sample is not well purified and/or memory of the previous sample is not removed. Time-consuming sample preparation, analyte (B) purification, and sample determination processes limit the applications of TIMS for routine analyses. SIMS can determine B and its isotope ratio in intact solid samples without destroying them, but has poorer resolution and sensitivity than TIMS, and is difficult to standardize for biological samples. Development of plasma-source mass spectrometry (MS) enabled the determination of B concentration and isotope ratio without requiring sample purification. Commonly used plasma-source MS uses an Ar inductively coupled plasma (ICP) as an ionization device interfaced to a low-resolution quadrupole mass analyzer. The quadrupole ICP-MS is less precise than TIMS and SIMS, but is a popular method for B isotope ratio determination because of its speed and convenience. B determination by ICP-MS suffers no spectroscopic interferences. However, sample matrices, memory effects, and some instrument parameters may affect the accuracy and precision of B isotope ratio determination if adequate precautions are not taken. New generations of plasma-source MS instruments using high-resolution mass analyzers provide better sensitivity and precision than the currently used quadrupole ICP-MS. Because of the convenience and high sample throughput, the high-resolution ICP-MS is expected to be the method of choice for B isotope ratio determination. The current state of instrumental capabilities is adequate for B isotope determination. However, precision and accuracy are primarily limited by sample preparation, introduction, and analytical methodology, including 1. Analyte loss and isotope fractionation during sample preparation. 2. The precision of B isotope determination in small samples, especially those containing low concentrations. 3. Difficult matrices. 4. Memory effects. Sample preparation by alkali fusion allows rapid and complete decomposition of hard-to-digest samples, but high-salt environments of the fused materials require extensive sample purification for B ratio determination. The alternative wet-ashing sample decomposition with HF also results in B loss and isotopic fractionation owing to the high volatility of BF3. Open-vessel dry- or wet-ashing methods usually do not work well for animal samples, and are also prone to B loss and contamination. Closed-vessel microwave digestion overcomes these problems, but the digests of biological materials have high C contents, which cause spectral interference on 11B and affect 11B/10B ratios. Exchange separation/preconcentration of B using exchange (cation or anion exchange, B-specific resin, e.g., Amberlite IRA-743) tend to cause B isotope fractionation, and C eluting from these resin columns may interfere with B isotope ratio determination. Memory effects of B that occur during sample determination may cause serious errors in B isotope ratio determination, especially when samples varying in B concentrations and/or isotope composition are analyzed together. Although the utilization of high-resolution plasma-source MS will undoubtedly improve analytical precision, it is the sample preparation, sample introduction, and analytical methodology that represent the primary limitation to accurate and precise B isotope ratio determination.     

Biomolecular sample considerations essential for optimal performance from cryogenic probes

For compounds dissolved in non-polar solvents, nuclear magnetic resonance spectroscopic investigations have benefited greatly from the advent of cryogenically cooled probes. Unfortunately the allure of significant increases in sensitivity may not be realized for compounds such as metabolites that are dissolved in solvents with high ionic-strengths such as solutions typically utilized for metabolomic or biomolecular investigations. In some cases there is little benefit from a cryogenically cooled probe over a conventional room temperature probe. Various sample preparation methods have been developed to minimize the detrimental effects of salt; for large numbers of metabolomic samples these preparation methods tend to be onerous and impractical. An alternative to manipulating the sample, is to utilize a probe that is designed to have a higher tolerance for solutions with high ionic-strengths. In order to acquire high-quality optimal data and choose the appropriate probe configuration (especially important for comparative quantitative investigations) the effects of salts and buffers on cryogenic probe performance must be understood. Herein we detail sample considerations for two cryogenic probes, a standard 5 mm and a narrow diameter 1.7 mm, in an effort to identify via integrals, intensities and noise levels the optimal choice for biomolecular investigations.     

Determination of the total concentration of highly protein-bound drugs in plasma by on-line dialysis and column liquid chromatography: application to non-steroidal anti-inflammatory drugs

The potential of on-line dialysis as a sample preparation procedure for compounds highly bound to plasma proteins is evaluated, using non-steroidal anti-inflammatory drugs as model compounds and column liquid chromatography as the separation technique. Different strategies to reduce the degree of drug-protein binding and so increase the analyte recovery are systematically explored and discussed: alteration of the conformation of the binding protein by changing the pH of the sample or by adding an organic solvent, addition of several displacing compounds and combinations of such approaches. A fully automated method is presented for the determination of ketoprofen, ibuprofen, flurbiprofen, fenoprofen and naproxen in human plasma, in which the absolute analyte recoveries are increased from 0–1% (untreated samples) to 40–65%. Relevant analytical data are given to demonstrate the reliability of the proposed procedure.     

Separation methods that are capable of revealing blood-brain barrier permeability

The objective of this review is to emphasize the application of separation science in evaluating the blood-brain barrier (BBB) permeability to drugs and bioactive agents. Several techniques have been utilized to quantitate the BBB permeability. These methods can be classified into two major categories: in vitro or in vivo. The in vivo methods used include brain homogenization, cerebrospinal fluid (CSF) sampling, voltametry, autoradiography, nuclear magnetic resonance (NMR) spectroscopy, positron emission tomography (PET), intracerebral microdialysis, and brain uptake index (BUI) determination. The in vitro methods include tissue culture and immobilized artificial membrane (IAM) technology. Separation methods have always played an important role as adjunct methods to the methods outlined above for the quantitation of BBB permeability and have been utilized the most with brain homogenization, in situ brain perfusion, CSF sampling, intracerebral microdialysis, in vitro tissue culture and IAM chromatography. However, the literature published to date indicates that the separation method has been used the most in conjunction with intracerebral microdialysis and CSF sampling methods. The major advantages of microdialysis sampling in BBB permeability studies is the possibility of online separation and quantitation as well as the need for only a small sample volume for such an analysis. Separation methods are preferred over non-separation methods in BBB permeability evaluation for two main reasons. First, when the selectivity of a determination method is insufficient, interfering substances must be separated from the analyte of interest prior to determination. Secondly, when large number of analytes is to be detected and quantitated by a single analytical procedure, the mixture must be separated to each individual component prior to determination. Chiral separation in particular can be essential to evaluate the stereo-selective permeation and distribution of agents into the brain. In conclusion, the usefulness of separation methods during BBB permeability evaluation is immense and more application of these methods is foreseen in the future.     

Urine stability for metabolomic studies: effects of preparation and storage

Metabolomic studies attempt to identify and profile unique metabolic differences among test populations, which may be correlated with a specific biological stress or pathophysiology. Due to the ease of collection and the metabolite-rich nature of urine, it is frequently used as a bio-fluid for human and animal metabolic studies. High-resolution ¹H-NMR is an analytical tool used to qualitatively and quantitatively identify metabolites in urine. Urine samples were collected from healthy male and female subjects and prepared: raw, following centrifugation, filtration, or the addition of the bacteriostatic preservative sodium azide and analyzed by NMR. In addition, these samples were stored at room temperature (22 °C), in a refrigerator (4 °C), or in a deep-freeze (−80 °C). Samples were analyzed by NMR every week for a month and changes in concentrations of 55 easily identifiable metabolites were followed. The degree of change in metabolite concentrations following storage over a 4-week period were influenced by the different methods of sample preparation and storage. Significant changes in urine metabolites are likely due to bacterial contamination of the urine. Our study demonstrates that bacterial contamination of urine in normal individuals significantly alters the metabolic profile of urine over time and proper preparation and storage procedures must be followed to reduce these changes. By identifying appropriate methods of urine preparation and storage investigators will preserve the fidelity of the urine samples in order to better reflect the original metabolic state.     

Chiral imprinted polymers as enantiospecific coatings of stir bar sorptive extraction devices

This paper reports the design of Molecularly Imprinted Polymers (MIP) with affinity towards (S)-citalopram using computational modeling for the selection of functional monomers and monomer:template ratio. Acrylamide was selected as functional monomer and the final complex functional monomer/template resulted in a 3:1 ratio. The polymer was synthesized by radical polymerization initiated by UV onto magnetic stir-bars in order to obtain a stir bar sorptive extraction (SBSE) device capable of selective enantiomeric recognition. After successful template removal, the parameters affecting the SBSE procedure (sample volume, ionic strength, extraction time and pH) were optimized for the effective rebinding of the target analyte. The resultant chirally imprinted polymer based stir-bar was able to selectively extract (S)-citalopram from a racemic mixture in an aqueous media with high specificity (specificity factor 4) between 25 and 500 μgL(-1). The MIP coated stir-bars can have significance for enantiospecific sample pre-concentration and subsequent analysis without the need for any chiral chromatographic separation.     

Quantification of antigens with haemolysing antibodies exemplified by the bovine J blood group system

1. The J blood group activity of red cells is measured in terms of 50% haemolysis ('direct test'), that of dissolved or suspended samples in terms of 50% haemolysis inhibition ('indirect test') in a standardized bovine J system. 2. The volume of J-containing sample required for a 50% haemolysis inhibition decreases with increasing J activity. 3. The volume of anti-J required for a 50% haemolysis of J-positive erythrocytes also decreases with increasing J activity. 4. The use of antigen units (UAg) was introduced to serve as a measure of J activity of dissolved or suspended samples. 5. Antigen units were also used to characterize J-containing red cells. This was made possible by measuring the relation of the direct test (on red cells). Thus, a relatively simple method of determination of red cell UAg is obtained. 6. It was confirmed by absorption experiments that erythrocytes containing high concentrations of antigen require relatively low amounts of antibody to bring about a 50% haemolysis, but are able to bind a relatively high excess of antibody.     

Quantification of antigens with haemolysing antibodies exemplified by the bovine J blood group system*

• 1 The J blood group activity of red cells is measured in terms of 50 % haemolysis (‘direct test’), that of dissolved or suspended samples in terms of 50 % haemolysis inhibition (‘indirect test’) in a standardized bovine J system.
• 2 The volume of J-containing sample required for a 50% haemolysis inhibition decreases with increasing J activity.
• 3 The volume of anti-J required for a 50% haemolysis of J-positive erythrocytes also decreases with increasing J activity.
• 4 The use of antigen units (U_Ag) was introduced to serve as a measure of J activity of dissolved or suspended samples.
• 5 Antigen units were also used to characterize J-containing red cells. This was made possible by measuring the relation of the direct test (on red cells). Thus, a relatively simple method of determination of red cell U_Ag is obtained.
• 6 It was confirmed by absorption experiments that erythrocytes containing high concentrations of antigen require relatively low amounts of antibody to bring about a 50 % haemolysis, but are able to bind a relatively high excess of antibody.

     

Investigation of endogenous blood plasma phospholipids, cholesterol and glycerides that contribute to matrix effects in bioanalysis by liquid chromatography/mass spectrometry

Matrix effects caused by compounds endogenous to the biological sample are a primary challenge in quantitative LC/MS/MS bioanalysis. Many approaches have been developed to minimize matrix effects such as optimization of sample extraction procedures and use of isotopically labeled internal standards. Unexpected matrix components may still remain undetected, however, because of the selective mass transitions monitored during MS/MS analysis. Glycerophosphocholines are the major phospholipids in plasma that have been widely shown to cause significant matrix effects on electrospray ionization efficiencies for target analytes. The purpose of this work was to investigate potential matrix effects resulting from different endogenous lipid classes, including phospholipids, acylglycerols and cholesterols, in order to establish a library for the relative presence of these components in biological sample extracts obtained by commonly used sample preparation techniques. Thirteen compounds were selected which were representatives of eight phospholipids classes, mono, di, triacylglycerols, cholesterol and cholesterol esters. Post-column infusion experiments were carried out to compare relative ion suppression effects of these compounds. Chlorpheniramine and loratadine were selected as model test analytes. A Concentration Normalized Suppression Factor (%CNSF) was defined to allow comparison of ion suppression effects resulting from different endogenous lipids according to their typical concentrations in human plasma and erythrocytes. A simple LC/MS/MS method was developed to monitor these endogenous components in sample extracts and their extraction recoveries from a plasma pool were compared using protein precipitation, liquid-liquid extraction, supported-liquid extraction, solid phase extraction and Hybrid SPE-precipitation methods. Endogenous lipid components other than GPChos, such as cholesterols and triacylglycerols, may result in significant matrix effects and should be monitored during method development. No single extraction procedure was efficient in removing all of the various lipid components. Use of the results presented here, along with a consideration of analyte chemical structure, the type of matrix and the type of sample preparation procedure, may help a bioanalytical scientist to better anticipate and minimize matrix effects in developing LC/MS/MS-based methods.     

Micro sequential injection system as the interfacing device for process analytical applications

It is an important and desirable capability to be able to control the quality and quantity of biological product by maintaining and adjusting bioreactor performance throughout its production duration. Amino acids are the building blocks of proteins. Scientists will need to ensure sufficient supply of amino acids as the substrates in the bioreactors as well as to control the excess level of undesirable free amino acid byproducts to maintain an optimum growth environment for cell culture. We have developed a compact and robust sample preparation platform capable of interfacing with analytical instruments to achieve bioreactor amino acids monitoring. We demonstrated the feasibility of this concept by incorporating an automatic amino acid sample preparation protocol to a micro sequential injection (μSI) system connected to an ultra‐performance liquid chromatography system for real‐time, at‐line amino acid separation, and quantitation. The μSI system was configured into a “platform‐like” sample preparation system that is able to accommodate future wet chemistry‐type sample preparations. Its real‐time amino acid results can be readily available to bioprocess scientists for quick decision making and design of their next experiment. Potential automatic feedback control mechanisms can be established through trigger events based on predetermined analytical signal thresholds so the system can communicate with facility infrastructure to control bioreactors in near real‐time fashion. The proposed μSI system described in this paper can be widely used as an automatic sample preparation system connected to the front‐end of analytical instruments to enable process analytical technology applications. © 2015 American Institute of Chemical Engineers Biotechnol. Prog., 31:607–613, 2015     

Considerations for Group Testing: A Practical Approach for the Clinical Laboratory

Group testing, also known as pooled sample testing, was first proposed by Robert Dorfman in 1943. While sample pooling has been widely practiced in blood-banking, it is traditionally seen as anathema for clinical laboratories. However, the ongoing COVID-19 pandemic has re-ignited interest for group testing among clinical laboratories to mitigate supply shortages. We propose five criteria to assess the suitability of an analyte for pooled sample testing in general and outline a practical approach that a clinical laboratory may use to implement pooled testing for SARS-CoV-2 PCR testing. The five criteria we propose are: (1) the analyte concentrations in the diseased persons should be at least one order of magnitude (10 times) higher than in healthy persons; (2) sample dilution should not overly reduce clinical sensitivity; (3) the current prevalence must be sufficiently low for the number of samples pooled for the specific protocol; (4) there is no requirement for a fast turnaround time; and (5) there is an imperative need for resource rationing to maximise public health outcomes. The five key steps we suggest for a successful implementation are: (1) determination of when pooling takes place (pre-pre analytical, pre-analytical, analytical); (2) validation of the pooling protocol; (3) ensuring an adequate infrastructure and archival system; (4) configuration of the laboratory information system; and (5) staff training. While pool testing is not a panacea to overcome reagent shortage, it may allow broader access to testing but at the cost of reduction in sensitivity and increased turnaround time.     

Enzyme loading of electrically homogeneous human red blood cell ghosts prepared by dielelctric breakdown.

Human red blood cell ghosts were prepared by electrical haemolysis at 0 degrees C in isotonic solutions using a discharge chamber which was part of a high voltage circuit. The size distribution of the ghosts was normally distributed, the modal (=mean) volume was approx. 115 mum3, performing the electrical haemolysis in the following solution: 105 mM KCI, 20 mM NaCL, 4mM MgCl2, 7.6 mM Na2HPO4, 2.94 mM NaH2PO4, 10 mM glucose, pH 7.2. Resealing was carried out at o degrees C for 10 min (after the haemolytic step) and then for further 20 min at 37 degrees C. The mean volume of the ghost preparation could be changed by variation of the phosphate concentration in the above solution replacing a part of NaCl by phosphate (5 mM phosphate: 94 mum3, 15 mM phosphate: 135 mum3). The breakdown voltage of the ghost cell membranes measured with a hydrodynamic focusing Coulter Counter depends on the mean volume (94 mum3 = 1.04 V, 134 mum3 = 1.36 V). On the other hand, the breakdown voltage is constant throughout each size distribution pointing to an "electrically homogeneous" ghost preparation. The sensitiviity of the Coulter Counter to detect electrical inhomogeneities in the membranes of a ghost population is demonstrated by dielectric breakdown measurements of an apparently normally distributed ghost preparation containing two different "electrically homogeneous" ghost population i.e. with two different breakdown voltages. The ghost cells obtained by electrical haemolysis in the above solution containing 10mM phosphate were fairly impermeable to sucrose and behave like an ideal osometer. It is further demonstrated that ghost cells can be loaded with enzymes (e.g. urease) and drugs using this technique and that these loaded ghost cells can be used as bioactive capsules for clinical application.