Chronic hepatitis B (CHB) is caused by the Hepatitis B virus (HBV) and affects millions of people worldwide. Developing an effective CHB therapy requires using in vivo screening methods, such as mouse models reflecting CHB based on hydrodynamic delivery of plasmid vectors containing a replication-competent HBV genome. However, long-term expression of HBV proteins is accompanied by production of progeny virions, thereby requiring a Biosafety Level (BSL) 3 animal facility. In the present study, we introduced a point mutation in the START codon of the HBV polymerase to develop a mouse model reflecting chronic hepatitis B infection without formation of viral progeny. We induced the mouse model by hydrodynamic injection of adeno-associated virus plasmid vector (pAAV) and minicircle plasmid (pMC) constructs into C57Bl/6 and C3H/HeN mouse strains, monitoring HBV antigens and antibodies in blood by enzyme-linked immunosorbent assay and analyzing liver expression of HBV core antigen by immunohistology. Persisting expression of viral antigens over 140 days (study endpoint) was observed only in the C3H/HeN mouse strain when using pAAV/1.2HBV-A and pMC/1.0HBV-D with pre-C and pre-S recombination sites. In addition, pAAV/1.2HBV-A in C3H/HeN sustained HBV core antigen positivity up to the study endpoint in C3H/HeN mice. Moreover, introducing the point mutation in the START codon of polymerase effectively prevented the formation of viral progeny. Our study establishes an accessible and affordable experimental paradigm for developing a robust mouse model reflecting CHB suitable for preclinical testing of anti-HBV therapeutics in a BSL2 animal facility.
- MeSH
- Hepatitis B, Chronic * genetics MeSH
- Codon, Initiator MeSH
- Disease Models, Animal MeSH
- Mutation MeSH
- Mice, Inbred C3H MeSH
- Mice MeSH
- Hepatitis B virus genetics MeSH
- Animals MeSH
- Check Tag
- Mice MeSH
- Animals MeSH
- Publication type
- Journal Article MeSH
For connecting flow-through analytical methods with capillary electrophoresis, a chip working in the air-assisted flow gating interface regime is cast from poly(dimethylsiloxane). In the injection space, the exit from the delivery capillary is placed close to the entrance to the separation capillary. Prior to injecting the sample into the separation capillary, the background electrolyte is forced out of the injection space by a stream of air. In the empty space, a drop of the sample with a volume of <100 nL is formed between the exit from the delivery capillary and the entrance into the separation capillary, from which the sample is injected hydrodynamically into the separation capillary. After injection, the injection space is filled with BGE, and the separation can be begun. Three geometric variants for the mutual geometric arrangement of the delivery and separation capillaries were tested: the delivery capillary is placed perpendicular to the separation capillary, from either above or below, or the capillaries are placed axially, that is, directly opposite one another. All of the variants are equivalent from the analytical and separation efficiency viewpoints. The repeatability expressed by RSD is up to 5%. The tested flow gating interface variants are also suitable for continuous and discontinuous sampling at flow rates of the order of units of μL/min. The developed instrument for sequential electrophoretic analysis operates fully automatically and is suitable for rapid sequential monitoring of dynamic processes.
- MeSH
- Electrophoresis, Capillary * MeSH
- Electrolytes MeSH
- Publication type
- Journal Article MeSH
- Research Support, Non-U.S. Gov't MeSH
An analytical apparatus is described, based on on-line connection of electrophoresis in a short capillary with a dialysis unit enabling dialysis in micro-litre sample volumes into submicro-litre volumes of an acceptor solution in a dialysing fibre. After a defined dialysis time, the dialysate from the dialysing fibre is injected into a separation capillary through an air-assisted flow-gating interface cast from PDMS. In the flow-gating injection space, the exit from the delivery capillary bringing the dialysate is placed directly opposite the entrance into the separation capillary at a distance of 380 μm. In order to enable injection of a very small volume of dialysate, the background electrolyte is forced out of the injection space with air before the injection, so that a drop of dialysate with a volume of about 0.1 μL is formed between the exit from the delivery and the entrance into the separation capillary; the dialysate is injected hydrodynamically from this dialysate drop. Then the injection space is filled with the background electrolyte and the separation is commenced. The basic properties of the apparatus were tested on model mixtures of inorganic cations (K+, Ba2+ and Na+) and organic molecules (creatinine, histidine and arginine). The applicability to real samples was tested on the determination of basic amino acids (histidine, lysine and arginine) in a blood serum sample.
- Publication type
- Journal Article MeSH
A new kind of flow gating interface (FGI) has been designed for online connection of CE with flow-through analytical techniques. The sample is injected into the separation capillary from a space from which the BGE was forced out by compressed air. A drop of sample solution with a volume of 75 nL is formed between the outlet of the delivery capillary supplying the solution from the flow-through apparatus and the entrance to the CE capillary; the sample is hydrodynamically injected into the CE capillary from this drop. The sample is not mixed with the surrounding BGE solution during injection. The functioning of the proposed FGI is fully automated and the individual steps of the injection process are controlled by a computer. The injection sequence lasts several seconds and thus permits performance of rapid sequential analyses of the collected sample. FGI was tested for the separation of equimolar 50 μM mixture of the inorganic cations K+ , Ba2+ , Na+ , Mg2+ , and Li+ in 50 mM acetic acid/20 mM Tris (pH 4.5) as BGE. The obtained RSD values for the migration times varied in the range 0.7-1.0% and the values for the peak area were 0.7-1.4%; RSD were determined for ten repeated measurements.
In this article, optimization of BGE for simultaneous separation of inorganic ions, organic acids, and glutathione using dual C4 D-LIF detection in capillary electrophoresis is presented. The optimized BGE consisted of 30 mM 2-[4-(2-hydroxyethyl)piperazin-1-yl]ethanesulfonic acid, 15 mM 2-amino-2-hydroxymethyl-propane-1,3-diol, and 2 mM 18-crown-6 at pH 7.2 and allowed simultaneous separation of ten inorganic anions and cations, three organic acids and glutathione in 20 min. The samples were injected hydrodynamically from both capillary ends using the double-opposite end injection principle. Sensitive detection of anions, cations, and organic acids with micromolar LODs using C4 D and simultaneously glutathione with nanomolar LODs using LIF was achieved in a single run. The developed BGE may be useful in analyses of biological samples containing analytes with differing concentrations of several orders of magnitude that is not possible with single detection mode.
- MeSH
- Breath Tests methods MeSH
- Equipment Design MeSH
- Electric Conductivity MeSH
- Electrophoresis, Capillary methods MeSH
- Spectrometry, Fluorescence methods MeSH
- Glutathione analysis isolation & purification MeSH
- Ions analysis isolation & purification MeSH
- Carboxylic Acids analysis isolation & purification MeSH
- Humans MeSH
- Limit of Detection MeSH
- Linear Models MeSH
- Reproducibility of Results MeSH
- Tears chemistry MeSH
- Check Tag
- Humans MeSH
- Publication type
- Journal Article MeSH
- Research Support, Non-U.S. Gov't MeSH
Perampanel is a novel antiepileptic drug used in paediatric patients. Existing methods that determine serum perampanel are of limited practicability. We developed a novel capillary electrophoresis (CE) method using a new version of acetonitrile stacking for on-line sample pre-concentration, and fluorescence detection (FD). CE separations were performed in a fused-silica capillary where the electroosmotic flow was reduced by coating the inner surface using a INST coating solution. The optimised background electrolyte composition was 50 mM chloroacetic acid with addition of 0.5% m/v polyvinylalcohol (pH 2.15) and separation was driven by application of positive voltage + 30 kV. Serum samples (25 μL) treated by the addition of acetonitrile in a ratio of 1:3 v/v were each injected into the capillary at a large volume that corresponded to the length (129 mm) of the sample zone (hydrodynamic pressure impulse 6000 mbars). Acetonitrile stacking is based on the forcing the sample zone out of the capillary with simultaneous application of the separation voltage. Under such conditions, the enhancing factor achieves the value 57 for peak area compared to the small sample injection length (3.2 mm, hydrodynamic pressure impulse 150 mbar.s). A fluorescence detector with a broad excitation filter (240-400 nm) and an emission filter (495 nm) was used for visualisation of the native fluorescence of perampanel. The calibration dependence of the method was linear (in the range of 10-1000 ng mL-1), with adequate accuracy (99.8-103.3 %) and precision (13.1%). LOD and LOQ for perampanel were 2.9 ng mL-1 and 9.5 ng mL-1, respectively. Clinical applicability was validated using serum samples from patients treated with perampanel and the results corresponded with reference LC-MS/MS values. Our method offers a promising alternative for determining serum perampanel with several advantages. In particular, the low quantity of serum (25 μL) required means that testing can be performed on samples obtained for monitoring other antiepileptic medications, and thus reduces the test-burden on paediatric patients.
A sensitive capillary electrophoretic method with on-line sample preconcentration by large volume sample stacking has been developed for determination of the anti-microbial agent pentamidine. The separation is performed in a fused silica capillary coated with covalently bound hydroxypropyl cellulose, with an internal diameter of 50 μm and length of 31.5 cm; the background electrolyte was 100 mM acetic acid/Tris at pH 4.7. The stacking is tested using a model sample of 1 μM pentamidine dissolved in 25% infusion solution and 75% acidified acetonitrile. Stacking permits the injection of a sample zone with a length of 95% of the total capillary length to achieve an enhancing factor of 77 compared to low injection into 1.8% of the total capillary length, with simultaneous high separation efficiency of approximately 1 350 000 plates/m. Stacking is based on simultaneous application of a separation field and a hydrodynamic pressure to force the acetonitrile zone out of the capillary. This approach allows the determination of pentamidine in rat blood plasma using only 12.5 μL of plasma treated by the addition of acetonitrile in a ratio of 1:3 v/v. The attained LOD is 0.03 μM and the intra-day repeatability is 0.1% for the migration time and 1.0% for the peak area at the injection 28.3% of capillary length. The performed pharmacokinetic study with ten-second scanning of the blood reveals rapid dynamics of pentamidine in the arterial bloodstream, while the changes are much slower in the venous system.
- MeSH
- Anti-Infective Agents blood MeSH
- Electrophoresis, Capillary methods MeSH
- Rats MeSH
- Limit of Detection MeSH
- Linear Models MeSH
- Pentamidine blood MeSH
- Rats, Wistar MeSH
- Reproducibility of Results MeSH
- Pressure MeSH
- Animals MeSH
- Check Tag
- Rats MeSH
- Male MeSH
- Animals MeSH
- Publication type
- Journal Article MeSH
- Research Support, Non-U.S. Gov't MeSH
An electrophoretic apparatus with a flow-gating interface has been developed, enabling hydrodynamic sequence injection of the sample into the separation capillary from the liquid flow by underpressure generated in the outlet electrophoretic vessel. The properties of the apparatus were tested on an artificial sample of an equimolar mixture of 100μM potassium and sodium ions and arginine. The repeatability of the injection of the tested ions expressed as RSD (in%) for the peak area, peak height and migration time was in the range 0.76-2.08, 0.18-0.68 and 0.28-0.48, respectively. Under optimum conditions, the apparatus was used for sequence monitoring of the reaction between the antidiabetic drug phenyl biguanide and the glycation agent methyl glyoxal. The reaction solution was continuously sampled by a microdialysis probe from a thermostated external vessel using a syringe pump at a flow rate of 3μLmin(-1) and was injected into a separation capillary at certain time intervals. The electrophoretic separation progressed in a capillary with an internal diameter of 50μm with a length of 11.5cm and was monitored using a contactless conductivity detector.
- MeSH
- Arginine MeSH
- Biguanides chemistry MeSH
- Time Factors MeSH
- Potassium MeSH
- Electrophoresis, Capillary instrumentation methods MeSH
- Hydrodynamics * MeSH
- Hypoglycemic Agents chemistry MeSH
- Microdialysis MeSH
- Pyruvaldehyde chemistry MeSH
- Solutions MeSH
- Sodium MeSH
- Publication type
- Journal Article MeSH
A coaxial flow-gating interface is described in which the separation capillary passes through the sampling capillary. Continuous flow of the sample solution flowing out of the sampling capillary is directed away from the injection end of the separation capillary by counter-current flow of the gating solution. During the injection, the flow of the gating solution is interrupted, so that a plug of solution is formed at the inlet into the separation capillary, from which the sample is hydrodynamically injected. Flow-gating interfaces are originally designed for on-line connection of capillary electrophoresis with analytical flow-through methods. The basic properties of the described coaxial flow-gating interface were obtained in a simplified arrangement in which a syringe pump with sample solution has substituted analytical flow-through method. Under the optimized conditions, the properties of the tested interface were determined by separation of K+ , Ba2+ , Na+ , Mg2+ and Li+ ions in aqueous solution at equimolar concentrations of 50 μM. The repeatability of the migration times and peak areas evaluated for K+ , Ba2+ and Li+ ions and expressed as relative standard deviation did not exceed 1.4%. The interface was used to determine lithium in mineral water and taurine in an energy drink.
- MeSH
- Electrophoresis, Capillary * MeSH
- Energy Drinks analysis MeSH
- Ions analysis MeSH
- Lithium analysis MeSH
- Mineral Waters analysis MeSH
- Publication type
- Journal Article MeSH
Online electrokinetic preconcentration of magnetite core/carboxylic shell nanoparticles (MNPs) was studied by capillary electrophoresis using reversed and suppressed electroosmotic flow (EOF). 50mM sodium borate pH 9.5 was used as a background electrolyte. CTAB additive was used to reverse EOF and commercial polyvinylalcohol (PVA)-coated capillaries were used for EOF suppressed studies. Analyses in PVA-coated capillaries were more reproducible and therefore, the setup was further optimized in terms of water plug injection time, sample injection time, and voltage. Within the optimal conditions, the MNPs dispersed in water are electrokinetically loaded into BGE consisting of 50mM sodium borate pH 9.5 using -10kV for 120s. In comparison with the hydrodynamic injection of 5s by 50mbar, the electrokinetic injection allows 860-fold preconcentration of MNPs.
