Source: Laboratory of Dr. B. Jill Venton – University of Virginia
Capillary electrophoresis (CE) is a separation technique that separates molecules in an electric field according to size and charge. CE is performed in a small glass tube called a capillary that is filled with an electrolyte solution. Analytes are separated due to differences in electrophoretic mobility, which varies with charge, solvent viscosity, and size. Traditional electrophoresis in gels is limited in the amount of voltage that can be applied because Joule heating effects will ruin the gel and the separation. Capillaries have a large surface area-to-volume ratio and thus dissipate heat better. Therefore, the voltages applied for a capillary electrophoresis experiment are quite large, often 10,000–20,000 V.
Capillary electrophoresis is useful for high-performance separations. Compared to liquid chromatography, CE separations are often faster and more efficient. However, capillary electrophoresis works best to separate charged molecules, which is not a limitation of liquid chromatography. CE has a greater peak capacity than high-performance liquid chromatography (HPLC), meaning the separations are more efficient and more peaks can be detected. The instrumentation can be very simple. However, HPLC is more versatile and many stationary and mobile phases have been developed for different types of molecules.
Capillary electrophoresis separates molecules due to their electrophoretic mobilities. A molecule's electrophoretic mobility depends on its charge and how much it is attracted or repelled by the voltage as well as the frictional drag force that resists movement. Friction is proportional to the radius of the molecule. Thus, electrophoretic mobility is based on size and charge. The velocity a charged molecule travels down a capillary is the product of its electrophoretic mobility and the applied electric field. Higher voltages therefore lead to faster velocities and faster separations.
Most capillary electrophoresis instruments are set up with the negative voltage at the detector end and the positive voltage at the inlet. This means that positively-charged molecules migrate towards the cathode at the end, while negatively-charged molecules migrate the other way. All molecules are seen at the detector however, because there is a bulk fluid flow called electroosmotic flow. The migration order is thus positively-charged, neutral, and then negatively-charged molecules.
Electroosmotic flow is caused by applying a high voltage to a small glass capillary filled with a salt solution. The positively-charged ions in the salt solution form a double layer with the negatively-charged silanol groups on the walls of the glass. When a negative voltage is applied to the end of the capillary, it pulls the cations from the double layer, which also pulls the solution around it due to frictional forces. This type of flow is plug-shaped and leads to less band-broadening than the parabolic-shaped flow plugs of HPLC.
Neutral molecules all flow at the same rate as the electroosmotic flow. However, a pseudo-stationary phase can be added to the run buffer to form micelles that molecules can partition in and out of. A typical pseudo-stationary phase is sodium dodecylsulfate. The micelles are negatively-charged on the outside, so they have an electrophoretic mobility, so the time spent in the micelle determines the migration time. This form of capillary electrophoresis is called micellar electrokinetic chromatography (MEKC).
Detection in CE is similar to that for HPLC. UV-Vis is general and does not require tagging as long as the molecule has a double bond. However, the absorbance depends on the path length, which is small for a 50-µm capillary. A bubble cell or z-cell will increase the path length. Laser-induced fluorescence is a more sensitive detection method. A laser is shone through a window in the capillary and fluorescence of the product measured. While fluorescence provides very high sensitivity, it generally requires molecules to be tagged because most are not fluorescent. Electrochemical detection and electrospray mass spectrometry detection are gaining in popularity. The issue with either of these detectors is that the high voltage from the separation must be brought to ground before the detection, as electrochemistry and electrospray require the application of a voltage and the CE voltage can interfere. New methods of decoupling the CE voltage, using electrodes to drain the current or a small crack in the capillary, are overcoming these challenges.
1. CE Instrumentation Setup
2. Preparation of the Standards and Soda Samples
3. Run the Samples on the CE
Capillary electrophoresis, or CE, is a technique used in chemical analysis to separate molecules in an electric field according to size and charge.
Capillary Electrophoresis is performed in a sub-millimeter diameter tube, called a capillary, which contains a flowing electrolyte solution. The sample is injected into the capillary, and an electric field is applied. The molecules are then separated based on the difference in their velocity, which is influenced by charge, size, and the solvent's viscosity. CE is ideal for the separation of charged molecules and has a greater resolution than high-performance liquid chromatography, making it more efficient and sensitive.
This video will introduce the basics of capillary electrophoresis and demonstrate its use by determining the composition of a soft drink.
In CE, an electric field is applied to a capillary filled with an electrolyte. The electric field induces a positive charge at the capillary inlet, and a negative charge at the outlet.
The electrolyte flows within the capillary, induced by the electric field. This flow, called electro-osmotic flow, is caused by the movement of a discrete layer of positively-charged salt ions along the negatively-charged capillary walls.
As the electric current runs through the capillary, the cations along the wall move toward the negative end. This ion flow pulls the solution in the center through the tube.
The sample molecules are then separated based on their velocity within the capillary. This velocity, called electrophoretic mobility, depends on the molecules' charge and size, and how much it is attracted or repelled by an electric field.
Positively-charged molecules flow faster through the capillary, as they are more attracted to the potential at the outlet. Negatively-charged molecules flow much slower, as they are more attracted to the potential at the inlet. Neutral molecules are carried along with the bulk flow. Thus, the order of molecules exiting the capillary is positively-charged, neutral, and then negatively-charged. Additionally, the electrolyte flow pulls smaller molecules faster than larger molecules due to frictional forces.
Molecules are recorded by a detector, such as UV-Vis, as they exit the column, and are visualized in a plot of detector signal intensity versus time, called an electropherogram.
Electropherograms can yield a range of information; such as how many different compounds are present in a sample and the amount of each substance.
Now that you've seen a brief synopsis of capillary electrophoresis, let's take a look at how it is performed in the laboratory.
First, turn on the capillary electrophoresis instrument and computer. Then switch on the UV detector to allow it to warm up.
Set the parameters for running the experiment. First, set the temperature for the cartridge and sample storage to 35 °C and the wavelength for UV detection to 214 nm.
Next, set the two rinse steps. The first rinse is with sodium hydroxide to ensure that the silanol groups on the capillary wall are protonated. The second rinse uses running buffer to equilibrate the capillary. Then, set the sample to inject at 0.5 psi for 5 s.
Set the electrophoresis step, by selecting the separation voltage. In this case, use 20 kV for 5 min using normal polarity, meaning that the electric field is positive at the inlet and negative at the outlet.
First, prepare 50 mL stock solutions of the soda components aspartame, caffeine, and benzoic acid at 500 parts-per-million in water.
From the stock solutions, make a standard solution of 150 ppm aspartame, 150 ppm caffeine, and 100 ppm benzoic acid.
Then, make 4 standard solutions of caffeine at 50, 100, 150, and 200 ppm. These samples will be used to make a calibration curve. Fore more information, see this collection's video on calibration curves.
Finally, prepare the soda samples by degassing them with nitrogen. The soda samples will be analyzed with no dilution.
Place the vials containing either standard or soda samples into the vial holder. Place the vials containing the run buffer and the sodium hydroxide rinse solution into the sample holder as well. Make sure to record the location of each.
In the CE instrument software, indicate which slots contain the two rinse solutions and the first sample vial. Now, run the first sample.
Then, run the combination standard, the 4 concentrations of caffeine, and a regular and diet soda sample by changing the input vial.
When all of the solutions have been separated, analyze the data.
First, use the standards to identify the peaks in the soda samples. A comparison of the three peaks observed in the diet soda sample to the standards shows that caffeine, aspartame, and benzoic acid are present in the diet soda. In the regular soda sample, only the caffeine peak is present, but not the aspartame and benzoic acid peaks.
Then, calculate the peak area for each caffeine standard solution, and make a calibration curve. The calibration curve for caffeine can be used to calculate the concentration of caffeine in each sample.
Capillary electrophoresis is used for many specialty separations in academic and industrial settings.
CE is often used as one component of pharmaceutical industry quality control testing. Drugs, either as small molecules or biologics, can be run through capillary electrophoresis to see if any side products are present. It can also be used to determine whether proteins are properly folded, as folding can affect protein charge.
CE can also be used to separate DNA. Using a microwell plate and multiple arrays of capillaries, researchers can increase the throughput of a single experiment, as shown here. DNA fragments were separated based on size, with a resolution down to 1 base pair. This makes sequencing fragments of DNA possible, along with determining other parameters like copy number variants, which is used to diagnose potential genetic diseases.
A protein can be modified by various functional groups that are chemically attached to different locations. Different copies of the same protein can vary with different modifications, which will change the charge and size of each protein. Running the purified proteins through a CE that is attached to a mass spectrometer can separate proteins based on which modifications are present, and also identify the type and location of the modification.
You've just watched JoVE's introduction to capillary electrophoresis. You should now understand how CE separates molecules based on charge and mass, and how to run a sample on the CE in the lab.
Thanks for watching!
Electropherograms collected for diet Pepsi and Pepsi samples are shown in Figures 1 and 2, respectively. The three peaks for caffeine, aspartame, and benzoic acid are observed in diet Pepsi and have similar migration times as the standards. For regular Pepsi, the caffeine peak is present but not the aspartame and benzoic acid peaks. The CE analysis is fast as the migration times are only 3–4 min.
The calibration curve for caffeine is shown in Figure 3. This curve can be used to calculate the concentration of caffeine in each sample.
Figure 1. CE analysis of Diet Pepsi. The red are standards of caffeine, aspartame, and benzoic acid. The black is a diet Pepsi sample. Please click here to view a larger version of this figure.
Figure 2. CE analysis of Pepsi. The black is a Pepsi sample while the red is a sample of standards of caffeine, aspartame, and benzoic acid. There is no aspartame or benzoic acid, indicating the soda is not diet. Please click here to view a larger version of this figure.
Figure 3. Caffeine calibration plot with CE. A plot of the peak area vs concentration for caffeine standards measured with CE. Please click here to view a larger version of this figure.
Capillary electrophoresis is used for many specialty separations. For example, it is used in the pharmaceutical industry for quality testing, to make sure there are no side products or interferents. CE is particularly useful for separating drugs with a basic amino group, as the walls of the capillary can be made neutral with an acidic pH and thus the drug will not stick to the capillary.
A mode of CE was also used to sequence the human genome and separate DNA. This mode of CE is capillary gel electrophoresis and for these separations, a polymer is injected into the CE capillary. The polymer gives an additional mode of separation based on size, as the smaller fragments can travel faster through the gel. This is called sieving, and along with the electrophoretic separation, it has 1 base pair resolution for DNA analysis.
Capillary electrophoresis, or CE, is a technique used in chemical analysis to separate molecules in an electric field according to size and charge.
Capillary Electrophoresis is performed in a sub-millimeter diameter tube, called a capillary, which contains a flowing electrolyte solution. The sample is injected into the capillary, and an electric field is applied. The molecules are then separated based on the difference in their velocity, which is influenced by charge, size, and the solvent’s viscosity. CE is ideal for the separation of charged molecules and has a greater resolution than high-performance liquid chromatography, making it more efficient and sensitive.
This video will introduce the basics of capillary electrophoresis and demonstrate its use by determining the composition of a soft drink.
In CE, an electric field is applied to a capillary filled with an electrolyte. The electric field induces a positive charge at the capillary inlet, and a negative charge at the outlet.
The electrolyte flows within the capillary, induced by the electric field. This flow, called electro-osmotic flow, is caused by the movement of a discrete layer of positively-charged salt ions along the negatively-charged capillary walls.
As the electric current runs through the capillary, the cations along the wall move toward the negative end. This ion flow pulls the solution in the center through the tube.
The sample molecules are then separated based on their velocity within the capillary. This velocity, called electrophoretic mobility, depends on the molecules’ charge and size, and how much it is attracted or repelled by an electric field.
Positively-charged molecules flow faster through the capillary, as they are more attracted to the potential at the outlet. Negatively-charged molecules flow much slower, as they are more attracted to the potential at the inlet. Neutral molecules are carried along with the bulk flow. Thus, the order of molecules exiting the capillary is positively-charged, neutral, and then negatively-charged. Additionally, the electrolyte flow pulls smaller molecules faster than larger molecules due to frictional forces.
Molecules are recorded by a detector, such as UV-Vis, as they exit the column, and are visualized in a plot of detector signal intensity versus time, called an electropherogram.
Electropherograms can yield a range of information; such as how many different compounds are present in a sample and the amount of each substance.
Now that you’ve seen a brief synopsis of capillary electrophoresis, let’s take a look at how it is performed in the laboratory.
First, turn on the capillary electrophoresis instrument and computer. Then switch on the UV detector to allow it to warm up.
Set the parameters for running the experiment. First, set the temperature for the cartridge and sample storage to 35 °C and the wavelength for UV detection to 214 nm.
Next, set the two rinse steps. The first rinse is with sodium hydroxide to ensure that the silanol groups on the capillary wall are protonated. The second rinse uses running buffer to equilibrate the capillary. Then, set the sample to inject at 0.5 psi for 5 s.
Set the electrophoresis step, by selecting the separation voltage. In this case, use 20 kV for 5 min using normal polarity, meaning that the electric field is positive at the inlet and negative at the outlet.
First, prepare 50 mL stock solutions of the soda components aspartame, caffeine, and benzoic acid at 500 parts-per-million in water.
From the stock solutions, make a standard solution of 150 ppm aspartame, 150 ppm caffeine, and 100 ppm benzoic acid.
Then, make 4 standard solutions of caffeine at 50, 100, 150, and 200 ppm. These samples will be used to make a calibration curve. Fore more information, see this collection’s video on calibration curves.
Finally, prepare the soda samples by degassing them with nitrogen. The soda samples will be analyzed with no dilution.
Place the vials containing either standard or soda samples into the vial holder. Place the vials containing the run buffer and the sodium hydroxide rinse solution into the sample holder as well. Make sure to record the location of each.
In the CE instrument software, indicate which slots contain the two rinse solutions and the first sample vial. Now, run the first sample.
Then, run the combination standard, the 4 concentrations of caffeine, and a regular and diet soda sample by changing the input vial.
When all of the solutions have been separated, analyze the data.
First, use the standards to identify the peaks in the soda samples. A comparison of the three peaks observed in the diet soda sample to the standards shows that caffeine, aspartame, and benzoic acid are present in the diet soda. In the regular soda sample, only the caffeine peak is present, but not the aspartame and benzoic acid peaks.
Then, calculate the peak area for each caffeine standard solution, and make a calibration curve. The calibration curve for caffeine can be used to calculate the concentration of caffeine in each sample.
Capillary electrophoresis is used for many specialty separations in academic and industrial settings.
CE is often used as one component of pharmaceutical industry quality control testing. Drugs, either as small molecules or biologics, can be run through capillary electrophoresis to see if any side products are present. It can also be used to determine whether proteins are properly folded, as folding can affect protein charge.
CE can also be used to separate DNA. Using a microwell plate and multiple arrays of capillaries, researchers can increase the throughput of a single experiment, as shown here. DNA fragments were separated based on size, with a resolution down to 1 base pair. This makes sequencing fragments of DNA possible, along with determining other parameters like copy number variants, which is used to diagnose potential genetic diseases.
A protein can be modified by various functional groups that are chemically attached to different locations. Different copies of the same protein can vary with different modifications, which will change the charge and size of each protein. Running the purified proteins through a CE that is attached to a mass spectrometer can separate proteins based on which modifications are present, and also identify the type and location of the modification.
You’ve just watched JoVE’s introduction to capillary electrophoresis. You should now understand how CE separates molecules based on charge and mass, and how to run a sample on the CE in the lab.
Thanks for watching!