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HIGH PERFORMANCE LIQUID CHROMATOGRAPHY (HPLC) HIGH PERFORMANCE LIQUID CHROMATOGRAPHY • High Performance Liquid Chromatography (HPLC) is one of the most widely used techniques for identification, quantification and purification of mixtures of organic compounds. • In HPLC, as in all chromatographic methods, components of a mixture are partitioned between an adsorbent (the stationary phase) and a solvent (the mobile phase). • The stationary phase is made up of very small particles contained in a steel column. Due to the small particle size (3-5 um), pressure is required to force the mobile phase through the stationary phase. • There are a wide variety of stationary phases available for HPLC. In this lab we will use a normal phase (Silica gel), although reverse phase (silica gel in which a 18 carbon hydrocarbon is covalently bound to the surface of the silica) columns are currently one of the most commonly used HPLC stationary phases. HIGH PERFORMANCE LIQUID CHROMATOGRAPHY http://www.chemistry.nmsu.edu/Instrumentation/Waters_HPLC_MS_TitlePg.html HIGH PERFORMANCE LIQUID CHROMATOGRAPHY TLC vs High Performance Liquid Chromatography (HPLC) HPLC Optimization http://www.labhut.com/education/flash/introduction07.php HPLC – Optimizing Separation Skoog and Leary: Principals of Instrumental Analysis, 5 th ed. Suanders, 1998 Schematic Presentation of a Chromatogram HPLC - Resolution • Resolution (RS) of a column provides a quantitative measure of its ability to separate two analytes Rs = DZ /1/2(WA+WB) Rs = HPLC - Resolution Rs Skoog and Leary: Principals of Instrumental Analysis, 4 th ed. Suanders, 1992 HPLC - Resolution Capacity Factor (k’): Also called retention factor. Is a measure for the position of a sample peak in the chromatogram. k’ = (tR1-to)/to • specific for a given compound and constant under constant conditions • A function of column and mobile phase chemistry • Primarily applicable under isocratic conditions • In general, a change in the k’ of one peak will move all peaks in the same direction. Selectivity Factor (a): Also called separation or selectivity coefficient is defined as a = k2’/k1’ = (tR2-to) / (tR1-to) • A function of column and mobile phase chemistry • Primarily applicable under isocratic conditions • Changes in selectivity will affect different compounds in different ways. Skoog and Leary: Principals of Instrumental Analysis, 4 th ed. Suanders, 1992 HPLC – Capacity Factor HPLC – Selectivity Factor HPLC - Resolution Theoretical Plates (N): The number of theoretical plates characterizes the quality or efficiency of a column. N = 5.54 [(tR) / w1/2]2 Skoog and Leary: Principals of Instrumental Analysis, 4 th ed. Suanders, 1992 (N = 16 (tR/W)2) Phenomenex catalog, 1999 HPLC - Resolution Theoretical Plates (N): The number of theoretical plates characterizes the quality or efficiency of a column. N = 5.54 [(tR) / w1/2]2 (N = 16 (tR/W)2) Plate Height (H): The height equivalent to a theoretical plate (HEPT = H) H=L/N Resolution (Rs) depends on the number of theoretical plates: Rs = Skoog and Leary: Principals of Instrumental Analysis, 4th ed. Suanders, 1992 Skoog and Leary: Principals of Instrumental Analysis, 4 th ed. Suanders, 1992 HPLC - General Elution Problem Skoog and Leary: Principals of Instrumental Analysis, 5 th ed. Suanders, 1998 HIGH PERFORMANCE LIQUID CHROMATOGRAPHY (TLC vs Normal Phase and Reverse Phase HPLC) Normal Phase (SiO2) TLC Normal Phase (SiO2) a b a c Time 0 b Reverse Phase (C18) c c x 0 b Time a Reverse Phase HPLC Skoog and Leary: Principals of Instrumental Analysis, 5th ed. Suanders, 1998 Normal Phase vs. Reverse Phase HPLC Skoog and Leary: Principals of Instrumental Analysis, 5 th ed. Suanders, 1998 RP-HPLC – Stationary Phase Skoog and Leary: Principals of Instrumental Analysis, 5 th ed. Suanders, 1998 RP-HPLC – Mobile Phase vs k’ Skoog and Leary: Principals of Instrumental Analysis, 5 th ed. Suanders, 1998 RP-HPLC – Mobile Phase (k’, a) Skoog and Leary: Principals of Instrumental Analysis, 5th ed. Suanders, 1998 RP-HPLC – Mobile Phase (a) Skoog and Leary: Principals of Instrumental Analysis, 5 th ed. Suanders, 1998 RP-HPLC - Example Alltech Chromatography Sourcebook, 2004-04 catalog RP-HPLC - Optimization Alltech Chromatography Sourcebook, 2004-04 catalog RP-HPLC – Gradient Elution Alltech Chromatography Sourcebook, 2004-04 catalog Alltech Chromatography Sourcebook, 2004-04 catalog Alltech Chromatography Sourcebook, 2004-04 catalog HPLC – Resolution vs Column Efficiency (N, H) H=L/N van Deemter Equation H = A + B/u +(Cs + Cm)u Skoog and Leary: Principals of Instrumental Analysis, 5 th ed. Suanders, 1998 HPLC - Column Efficiency Skoog and Leary: Principals of Instrumental Analysis, 5 th ed. Suanders, 1998 HPLC - Column Efficiency van Deemter Equation H = A + B/u +Cu Skoog and Leary: Principals of Instrumental Analysis, 5 th ed. Suanders, 1998 HPLC - Column Efficiency H = A + B/u + Cu A = 2l d p 1. 2. 3. 4. l depends on particle size distribution, the narrower the distribution the smaller the l dp = particle size Independent of mobile phase flow rate Also known as eddy diffusion Skoog and Leary: Principals of Instrumental Analysis, 5th ed. Suanders, 1998 HPLC - Column Efficiency particle size Skoog and Leary: Principals of Instrumental Analysis, 5 th ed. Suanders, 1998 HPLC Column Efficiency Longitudinal Diffusion (B) H = A + B/u + Cu B/u = 2gDM/u 1. g = constant depending on quality of packing 2. DM is the mobile phase diffusion coefficient 3. Inversely related to mobile phase flow rate HPLC Column Efficiency Mass Transfer (Cs + Cm) H = A + B/u + (Cs + Cm)u CS = fS(k’)df2 / DS CM = fM(k’)dp2 / DM • • • • • DM is the mobile phase diffusion coefficient DS is the stationary phase diffusion coefficient df is film thickness dp is particle size Directly related to mobile phase flow rate Skoog and Leary: Principals of Instrumental Analysis, 5th ed. Suanders, 1998 RP-HPLC – Variables Alltech Chromatography Sourcebook, 2004-04 catalog HPLC OF ANALGESICS - UV Detection Standard Analgesics 2.82 min Acetaminophen 1.48 min. Aspirin 7.11 min. Caffeine 1.35 min. Ibuprofen Gradient = 0 min: 100% EtOAC (+ 0.2% HOAc) 3 min: 100% EtOAC (+ 0.2% HOAc) 5 min: 15% MeOH, 85% % EtOAc (+ 0.2% HOAc) 8 min: 15% MeOH, 85% % EtOAc (+ 0.2% HOAc) 10 min: 100% EtOAC (+ 0.2% HOAc) SiO2 Flow Rate = 1 mL/min UV detector set at 240 nm Analgesic Retention Time Acetaminophen 2.82 Aspirin 1.48 Caffeine 7.11 Ibuprofen 1.35 HPLC OF ANALGESICS - UV Detection Area % Excedrin ES 250 mg aspirin 250 mg acetaminophen 65 mg caffeine Aspirin 19.5% Acetaminophen 50.0% Caffeine 20.5% Question The peak areas of aspirin and acetaminophen are very different, even though they are present in equal amounts (250mg/tablet) in Excedrin ES. Caffeine is present at ~ ¼ the concentration of aspirin (65 mg/tablet vs. 250 mg/tablet), but it’s peak area is greater than the peak area of aspirin. WHY? UV Absorbance of analgesics vs UV setting of detector HPLC: Peak Area vs Detector setting Detector set at 240 nm UV Max Aspirin 225, 296 nm Acetaminophen 248 nm Caffeine 272 nm Area % Aspirin 19.5% Acetaminophen 50.0% Caffeine 20.5% Detector set at 254 nm Area % Aspirin 7.3% Acetaminophen 81.9% Caffeine 10.8% Detector set at 280 nm Area % Aspirin 24.8% Acetaminophen 39.3% Caffeine 35.9% HPLC – UV Detection (A) Figure 2. HPLC (SiO2) of crude tumeric extract. Gradient 0-2 min, 4% EtOAc/Hexane; 2-9 min 4 to 80% EtOAc; 9-11 min , 80% EtOAc/hexane; 11-13 min, 80 to 4% EtOAc/hex, 13-15 min, 4% EtOAc /hexane. (B) (A) Detector set at 420 nm. (B) Detector set at 254 nm. (C) Detector set at 254 nm (0-3.5 min), 420 nm 3.5-15 min. (C)