Lecture 5: Basic Chromatography: HPLC (RP & IEC) & Capillary Electrophoresis 1. High performance liquid chromatography (HPLC) 2. Components of an HPLC system 3. Mechanism of reverse phase HPLC (RP HPLC) 4. Gradient Elution 5. Ion pairing agents 6. Organic modifiers 7. UV detection 8. Typical gradients 9. Other types of chromatography 10. Capillary electrophoresis (CE) 1 1. High performance liquid chromatography (HPLC) The various techniques used for High Pressure Liquid Chromatography are: - Reverse Phase Chromatography. - Size Exclusion Chromatography. - Ion Exchange (cation or anion) Chromatography. - Hydrophobic interaction Chromatography. The high resolving power of Reverse Phase [RP] Chromatography has made it the dominant mode of HPLC for both analytical and preparative separation of peptides and proteins, as well as other biomolecules. 2 1
1. HPLC (cont) The term Reverse Phase Chromatography was used because RP is a form of partition chromatography where chemically bonded phase is hydrophobic or non-polar (e.g. octadecyl group), and the starting mobile phase (e.g. water) must be more polar than the stationary phase. This is reversed from normal phase chromatography, where the stationary phase is polar or hydrophilic and the starting mobile phase is more non-polar or hydrophobic than the stationary phase, hence the term Reverse Phase Chromatography. 3 New stationnary Phase Monolithic stationary phase: made of non-porous particles of 2 μm macropores, which constitute the through-pores in which fluid convection takes place, and 13 nm mesopores. They also incorporate either a C8- or C18-bonded surface phase. In pellicular beads, retentive distances in the particle are decoupled from the hydraulic distances between particles resulting in both high efficiency and permeability especially for high molecular weight substances. [U. Tallarek, F.C. Leinweber and A. Seidel-Morgenstern, Chem. Eng.Technol., 25, 1177 (2002).] Commercial source: Chromolith by Phenomenex come as C8 and C18, which advertise the packing as a variations of perfusion chromatography column packings where convection in large intraparticle pores inside a particulate bed augments intraparticle diffusion, except that in this case a single perfusive particle occupies the entire column. 4 2
2. Components of an HPLC system Pump Mixer Detector Injector Column Fraction Collector Basic Components of an HPLC System 5 Column Sizes Description Dimension Approx. typical flowrate (velocity 1 10 mm/s) Open tubular liq chromtgrphy < 25 μm i.d. < 25 nl/min Nanobore column HPLC 25 μm < i.d. <100 μm 25 4000 nl/min Capillary column HPLC 100 μm < i.d. <1 mm 0.4 200 μl/min Microbore column HPLC 1 mm < i.d. < 2.1 mm 50 1000 μl/min Narrow(small)-bore column HPLC 2.1 mm < i.d. <4 mm 0.3 3.0 ml/min Normal-bore column HPLC 4 mm < i.d. <5 mm 1.0 10.0 ml/min Semipreparative column HPLC 5 mm <i.d. <10 mm 5.0 40 ml/min Preparative column HPLC i.d. > 10 mm > 20 ml/min The above table shows that HPLC is an extremely reliable separation technique, that can be scaled to the need of the user, as its range starts at very narrow i.d. capillaries to centimetres i.d. for preparative columns, while providing a uniform mechanism that allows easy adaptation of parameters to separation problems, thus allowing the use of the same technique whether you are separatimg femtomoles or millimoles or more of material 6 3
3. Mechanism of reverse-phase HPLC Protein (solute) Protein Protein support support support Adsorption solvent Solvation Desorption Peptides and proteins are adsorbed onto the hydrophobic surface of the column and remain there until the concentration of the organic modifier is high enough to elute the molecules from the hydrophobic surface. The elution order is related to the increasing hydrophobic nature of the solute, the more soluble a solute is in water or the more hydrophilic the solute, the faster it will be eluted. 7 3. Mechanism of reverse-phase HPLC (cont) Silica gel with chemically bonded phases is the packing of choice because of excellent efficiency, rigidity, and ability to be functionalized. 3 5 m diameter particles are the norm, smallest ~ 1.5- m. Smaller particles shortens path length of the diffusion process, improves mass transfer, and provides better efficiency. Smaller particles decrease column permeability resulting in increase in backpressure, which is inversely proportional to the particle diameter squared. Schematics of various particle types, incl. (a) totally porous, (b) perfusion, (c) nonporous, and (d) superficially porous particles. 8 4
3. Mechanism of reverse-phase HPLC (cont) a.totally Porous packing is dominated by diffusive pores. The surface area of the particle is contained within the pores. A reduction in particle size improves both the interparticle mass transfer and the intraparticle mass transfer. In a porous particle, solutes transfer from moving mobile phase into the stagnant mobile phase within the pores to interact with the stationary phase, then solute molecule must diffuse out of the particle and continue its journey down the column. Such a transfer occurs as the differential separation process proceeds and the solute is eluted from the column. b.the diffusive pores are the same type present in the porous particles, the through - pores allow mobile phase to pass through the packing increasing the rate of mass transfer in mobile phase. When compared with a porous packing of the same particle and pore size, perfusion packings give better efficiency for large molecules 9 3. Mechanism of reverse-phase HPLC (cont) c. Nonporous packings (1.5 2.5 m) allows faster rates (few minutes) of mass transfer and separations for both large and small molecules. Unfortunately, the thin layer of stationary phase limits the capacity of the packing, making it unsuitable for preparative separations. d. Superficially porous packings are similar to nonporous silica but the particle size (5 m) and surface area are larger resulting in lower pressure drop and increased sample capacity. Recommended for larger biomolecules. 10 5
Buffer A: 0.1% TFA water Buffer B: 0.1% TFA acetonitrile A B S Injection artifact 1 2 3 Gradient Wavelength 214 nm Time % A % B 0 100 0 3 100 0 30 70 30 0 10 20 30 Retention Time in minutes # Peptide Sequence MW RT Hydrophobicity 1 RGGGGIGIGK 871.0 10.5-0.180 2 RGGGGIGLGK 871.0 15.0-0.250 3 RGGGGLGLGK 871.0 20.5-0.320 Retention Time: The time between injection and the appearance of the peak maximum. 11 4. Gradient elution Technique for decreasing separation time by increasing mobile phase strength over time during the chromatographic separation. Gradient can be linear or stepwise. Binary, ternary and quaternary solvent gradients can be used. The most widely used is the linear binary gradient. Types of reversed phase column: Type MW in Da C 18 < 5,000 C 8 5,000 10,000 C 4 > 10,000 %B %B Linear Time Step Time 12 6
5. Ion-pairing agents Ion-pairing agents are ionic compounds that contain a hydrocarbon chain that imparts a certain hydrophobicity so that the ion pair can be retained on a reversed-phase column. Ion Pairing agents are added at concentrations of 0.05 to 0.2. All ion-pairing agents are potentially capable of ion-pairing with the positively charged basic residues of peptides or proteins, thus reducing hydrophilicity and increasing their retention time. Hydrophobic counterions such as TFA and HFBA in addition to ion-pairing with the positively charged solute also increase the affinity of the solute (peptide or protein) for the hydrophobic stationary phase. While hydrophilic counterions such as H 3 PO 4 following ion-pair formation with positive charged residues would be unlikely to interact with the stationary phase. 13 5. Ion-pairing agents (cont) 1 2 3 4 H3 PO 4 1 2 3 4 1 2 3 4 TFA HFBA RT RT RT -Trifluoroacetic acid (TFA). -Heptafluorobutyric acid (HFBA). -Hexafluoroacetone (HFA). -Formic Acid (FA) -Phosphoric Acid. -Hydrochloric Acid. -Triethylamine Phosphate (TEAP). The longest retention times are observed with HFBA and the shortest with HCI. Also the highest resolution is obtained with HCI and HFBA. 14 7
6. Organic modifiers Additive that changes the character of the mobile phase. In RP chromatography, water is the weak solvent, and acetonitrile, the strong solvent is added gradually to generate a gradient. Acetonitrile. Isopropanol. Methanol. Ethanol Acetonitrile is the reverse phase solvent of choice because the UV cut off for acetonitrile is190 nm, allowing detection at lower wavelengths. It is less viscous than methanol, thus causing less fluctuations in pressure. Less buble formation occurs when it is mixed with water. It has also better selectivity for peptides and proteins. Isopropanol is used either alone or in combination with acetonitrile to elute large or hydrophobic proteins. 15 7. UV detection Peptides and proteins are detected by UV absorption at wave length from 210-220 nm which detect the amide bond. The aromatic side chains of tyrosine, phenylalanine and tryptophan absorb light in the 250 to 290 nm ultraviolet range. H O H Amide Bond C C N The two most widely used wavelength are 214 and 280 nm 16 8
8. Typical gradients When dealing with an unknown mixture, although time consuming the following is a good starting gradient. Once you find where your compounds of interest elute, you can greatly shorten the analysis time. Buffer A: 0.1% TFA water Buffer B: 0.1% TFA acetonitrile Time %A %B 0 100 0 5 100 0 75 30 70 85 0 100 95 0 100 96 100 0 120 100 0 17 9. Other types of chromatography Size Exclusion chromatography: Mainly used for very large proteins. Cation exchange chromatography: Very useful when peptides or proteins contain an inordinate number of negatively charged residues (Asp and Glu). Also useful for proteins containing posttranslational modifications that make them more hydrophilic. Mixed mode chromatography: uses a mixture of reverse-phase and cationic or anionic sorbents. 18 9
For Chromatography in a hurry: New faster shorter columns are available from every manufacturer. These columns claim to do separation in a tenth of the time needed by conventional columns. However their peak resolution is not as good as conventional columns from the same manufacturers. Waters IS (Intelligent Speed) columns are supposed to be 10 times more speedy than the conventional XTerra C 18 column. Applied Biosystems Poros columns also have a series of fast columns. For purification of very hydrophilic Proteins or peptides: which are usually glycosilated, phosphorylated or contain a high percentage of basic, acidic or polar residues, use HFBA as a pairing agent. HFBA is the ion pairing reagent of choice. In some cases both HFBA and a mixed mode column ( C 18 or C 4 + Cation or C 18 or C 4 + Anion) could separate such compounds. This regimen is also successful for separation of glycolipids and oligosaccharides. 19 The Pitfalls of Nano-LC It is crucial to understand the difference between analytical HPLC and the capillary setup. Though the general principles of operation are identical (column, pumps, gradient, solvents, etc.). Minimization often than not causes major problems. -Expense:Replacement parts and columns are expensive -Clogging:The presence of even submicroscopic solids in a sample may effectively clog the column. Columns, after clogging are permanently damaged. -Changes in pressure: of the eluent often permanently damage the column. -Column overloading: does not lead to permanent damage but, when the sample is in excess, it is necessary to run 3 to 4 blank runs to remove the Excess material in order not to contaminate the next sample you run. Noga M, Sucharski F, Suder P and SilberringJ. A practical guide to nano-lc troubleshooting. J. Sep. Sci., 30, 2179 2189 (2007) 20 10
21 10. Capillary electrophoresis (CE) CE is a cross between gel electrophoresis and high pressure liquid chromatography. Separation is based on size to charge ratio. It uses high voltage generating electroosmotic [EOF] and electrophoretic flow of buffer solutions and ionic species, respectively within the capillary. capillary buffer HV Detector Data acquisition The basic instrument is made of a fused silica capillary, a controllable high voltage power supply, two electrode assemblies, two buffer reservoirs, a UV detector and a data acquisition system. The ends of the capillary are placed in the buffer. After filling the capillary with buffer the sample can be introduced by dipping the end of the capillary in the sample solution. In CE nothing is retained so the analogous term to retention time is migration time. 22 11
10. CE (cont) -The fused silica capillaries have ionizable silanol group in contact with the buffer within the capillary. The pi of the silica is about 1.5. The degree of ionization is controlled by the ph of the buffer. -The negatively charged wall attracts positively charged ions from the buffer, creating an electrical double layer. -When voltage is applied across the capillary, cations in the diffuse portion of the double layer migrate in the direction of the cathode carrying water with them. The result is a net flow of buffer solution in the direction of the negative electrode. + + + + + + + + + EOF - + + + + + + + + + The EOF makes possible the simultaneous analysis of cations, anions and neutral species in a single analysis. At neutral to alkaline ph, the EOF is sufficiently stronger than electrophoretic migration, such that all species are swept towards the negative electrode. The order of migration is: cations, neutrals, and anions 23 10. CE (cont) Zwitterionic molecules such as peptides are easily separated. At high ph the EOF is large and the peptide is negatively charged. Despite the peptide migration towards the positive electrode, the EOF is overwhelming and the peptide migrates toward the negative electrode. At low ph the peptide is positively charged EOF is very small. Thus peptide electrophoretic migration and EOF are towards the negative electrode. In silica capillaries most solutes migrate towards the negative electrode regardless of charge when the buffer ph is is above7.0. At acidic ph, most zwitterions and cations will also migrate towards the negative electrode. Buffers for capillary electrophoresis Buffer ph range Zwitterionic buffer ph range Phosphate 1.14-3.14 MES 5.15 7.15 Acetate 3.76 5.76 PIPES 5.80 7.80 Borate 8.14 10.14 HEPES 6.55 8.55 Tricine 7.15 9.15 24 12
10. CE (cont) Advantage of CE: -Separation takes minutes rather than hours. -Uses much less reagents. -Better separation of peptide with similar hydrophobicity index. Disadvantage: -Requires much more skill and technical ability. 25 From Skoog, Holler and Nieman, Principles of Instrumental Methods, 5 th. Ed., p. 726. Liquid Chromatography (Chapter 28): Four types of high performance liquid chromatography (HPLC): partition adsorption (liquid-solid) ion exchange size exclusion or gel 26 13
Liquid Chromatography Columns Tomer KB, Moseley MA, Deterding LJ and Parker CE, "Review- Liquid Chromatography Mass Spectrometry" Mass Spectrometry Reviews (1994) 13. Normal phase HPLC: nonpolar solvent and polar column. polar solutes elute first Reversed phase HPLC: polar solvent and non polar column, Non polar solutes elute first 27 Size Exclusion Chromatography (Gel Permeation): Used for large mw compounds - proteins and polymers Separation mechanism is sieving not partitioning Stationary phase porous silica or polymer particles (polystyrene, polyacrylamide) (5-10 mm) - well-defined pore sizes (40-2500 Å) 1. Large molecules excluded from pores - not retained, first eluted (exclusion limit - terms of mw) 2. Intermediate molecules - retained, intermediate elution times 3. Small molecules permeate into pores - strongly retained, last eluted (permeation limit - terms of mw) 28 14