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Liquid Chromatography HPLCUPLC

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Title: Liquid Chromatography HPLCUPLC


1
Liquid ChromatographyHPLC/UPLC
  • Kevin Lankford
  • Chem 6200
  • Topics in Analytical

2
Liquid Chromatography
  • There are many ways to classify Liquid
    Chromatography (LC). Normally it is described by
    the nature of the stationary phase and separation
    process.
  • Ion exchange chromatography
  • Size exclusion chromatography
  • Adsorption chromatography

Reference 1
3
Ion exchange
  • Stationary bed has particles with a charged
    surface opposite of sample ions.
  • Exclusively used for ionizable samples
  • Buffers are used as the mobile phase using pH and
    ionic strength to control the elution time.

Reference 1
4
Size exclusion chromatography
  • These columns are filled with a particular pore
    size serving to filter the sample
  • Large molecules wash through the column faster
    than the smaller ones giving the larger molecules
    a lower retention time.

Reference 1
5
Adsorption Chromatography
  • These columns are packed with a stationary phase
    such as silica that serves as an adsorbent to the
    specific compound.
  • This separation is based on adsorption and
    desorption steps using different solvent ratios
    to interact with the sample.

Reference 1
6
Different Phases
  • Normal Phase This is where the stationary bed
    is strongly polar (silica gel) and the mobile
    phase is largely non-polar such as hexane or THF.
  • Reverse Phase The stationary phase is non-polar
    and the mobile phase are polar liquids such as
    methanol, acetonitrile, or water. The more
    non-polar substances have longer retention.

Reference 1
7
Elution Types
  • Isocratic where the eluent is at a fixed
    concentration.
  • Gradient where the eluent concentration and
    strength are changing.

Reference 1
8
Types of Liquid Chromatography


Gravity Chrom. Tsvett, 1903
Flash Chrom. 1978
HPLC 1952
UPLC 2004
(TLC) Paper Chrom.
9
HPLC Characteristics
  • Columns have small internal diameters (2-10 mm)
    usually made with a reusable material like
    stainless steel
  • High inlet pressures of several thousand psis
    and controlled flow of mobile phase
  • Precise sample introduction and small sample
    requirements
  • Special continual flow detectors that use small
    flow rates and low detection limits
  • Some are equipped with automated sampling devices
  • Rapid analysis with high resolution

Reference 3
10
Stationary Phase in HPLC
  • Particle size 3 to 10 µm packed tightly with a
    pore size of 70 to 300 Å
  • Surface area of 50 to 250 m2/g
  • Bond phase density number of adsorption sites
    per surface unit (1 to 5 per 1 nm).
  • Typical surface coatings
  • Normal phase (-Si-OH, -NH2)
  • Reverse phase (C8, C18, Phenyl)
  • Anion exchange (-NH4)
  • Cation exchange (-COO-)

Reference 3
11
Mobile Phase in HPLC
  • Purity of the solvents
  • Detector compatibility
  • Solubility of the sample
  • Low viscosity
  • Chemical inertness
  • Reasonable price

Reference 3
12
Path of Mobile Phase
13
Mobile phase degassing and storage
  • It is recommended that you degas your solvents
    for several minutes before use (Helium) Special
    containers can prevent exchange with the ambient
    air (shown in this figure).
  • This Waters 1525 HPLC is set up to do solvent
    gradients alternatively, you could premix the
    solvent and use one reservoir for isocratic runs.

Reference 3
14
Mobile Phase mixing
  • Solvent proportioning valves allow for gradient
    elution by being programmed to mix the solvents
    with respect to time

15
HPLC Pump
  • Reciprocating piston pumps are commonly used
    which have pistons that pull the mobile phase in
    and push it out into the head of the column

Reference 4
16
Rotary Sample Loop Injector
  • Injector needles are used ranging from 10 µL to
    500 µL to inject a sample onto the sample loop
  • Upon a 60 rotation the pump introduces the
    sample onto the column in a reverse direction
    that it was loaded.
  • http//www.restek.com/info_sixport.asp

Reference 5
17
HPLC Columns
  • HPLC Columns come in various sizes and many
    factors involving your analyte or the function of
    the column should be considered when selecting
    the appropriate one. Some common dimensions
    10, 15, and 25 cm in length 3, 5, or 10 mm
    diameters 4 to 4.6 internal diameters

Reference 3
18
Column Cost and Sensitivity
  • Costs generally range from 200 to 1000 per
    column.

Reference 4
19
HPLC Detectors
  • Most HPLC instruments are equipped with optical
    detectors.
  • Light passes through a transparent low volume
    flow cell where the variation in light by UV
    Absorption, fluorescent emission, or change in
    refractive index are monitored and integrated to
    display Retention Time and Peak Area.
  • Typical flow rates are 1 mL/min. and a flow cell
    volume of 5-50 µL.

Reference 3
20
Common HPLC Detectors
  • Refractive Index (RI) - universal
  • Evaporative Light Scattering Detector (ELSD)
    universal
  • UV/VIS light selective
  • Fluorescence selective
  • Electrochemical (ECD) selective
  • Mass Spec (MS) - universal

Reference 3
21
Refractive Index detector
  • Analytes change the refractive index of the light
    in a proportional amount to the concentration.
  • Heat can change the RI of the mobile phase so
    thermo control important
  • RI changes cause a shift in a beams focal
    location which is detected on a photo-sensor.
  • RI is ideal for analyzing complex sugars and
    carbohydrates which have no chromophores,
    fluorescence or electrochemical activities

Reference 3
22
ELSD
  • Light scatters in response to the dimension of
    the analyte particles.
  • Light does not scatter in the mobile phase and
    must be nebulized and evaporated
  • This universal detector is more sensitive that RI
    and shows a response to compound lacking UV
    absorption or fluorescence.
  • Downfall is the sample is destroyed.

Reference 3
23
UV/VIS Detectors
  • Scan a range of UV light to detect molecules with
    chromophores. Commonly 254 nm.
  • Usually having a range of 190 nm to 600 nm
  • Low flow cell volume 1 10 µL
  • Single wavelength filter photometers -uses a
    source lamp to emit a single wavelength (Hg, 254
    nm)
  • Dispersive monochromator detectors -selects a
    narrow wavelength band
  • Diode array detector -light from flow cell
    disperses and is directed towards different
    diodes

Reference 3
24
Fluorescent Detectors
  • Higher signal to noise ratio than UV/VIS
  • Greater sensitivity than UV/VIS
  • Many compounds do not fluoresce and are
    derivatized with chemicals such as Dansyl
    chloride. This works well with primary and
    secondary amines, amino acids and phenolic
    compounds.

Reference 3
25
Electrochemical Detectors
  • Selective detection commonly used with reverse
    phase and isocratic elution with buffers and
    salts as the mobile phase
  • The two types of ECDs are voltammetric and
    conductometric
  • The mobile phase must carry charged electrolytes
    eliminating normal phase as an option
  • ECDs respond to analytes that are oxidizable or
    reducible at an electrode surface.

Reference 3
26
Mass Spectrometer
  • Problem interfacing the mobile phase with a MS
    detector
  • The first interface system was a moving conveyer
    belt that passed through vacuum systems leaving
    the analyte on a solid adsorbent material
  • Thermospray mobile phase is directed to a
    capillary column that is heated and points at a
    skimmer cone. (Too much build up on orifice)
  • Electrospray (ESI) analytes are charged upon
    exiting the capillary tube and cross sprayed with
    nitrogen. The charge particles cause a Coulomb
    explosion making smaller droplets of analyte to
    enter the skimmer cone.
  • Atmospheric Pressure Chemical Ionization (APCI)
    Analyte is heated by a ceramic tip on the column,
    cross flow of nitrogen decreases the droplet
    size, and a corona discharge charges the
    particles to enter the detector.

Reference 3
27
Detector Summary
Reference 3
28
Automated Waste Collection
29
Typical Program Screen Waters software Breeze
30
Why HPLC?
  • HPLC works with compounds of higher molecular
    weights and polarity.
  • Many biological samples are charged such as DNA
    and proteins.
  • HPLC can be used in a prepatory manner with
    larger sample sizes and sample recovery to
    continue synthesis
  • Good at separating stereoisomers techniques that
    employ heat (GC) can cause racemization during
    analysis.

Reference 3
31
Contrasting HPLC and UPLC
  • UPLC gives faster results with better resolution
  • UPLC uses less of valuable solvents like
    acetonitrile which lowers cost
  • The reduction of solvent use is more
    environmentally friendly
  • Increased productivity can increase you revenue
    in an industrial setting

Reference 6
32
Chromatograms of simvastatin
Reference 6
33
Why is UPLC more efficient
  • Peak capacity (P) is the number of peaks that can
    be resolved in a specific amount of time.
  • P is proportional to the inverse of the square
    root of the Number of theoretical plates (N) N
    L/H
  • Lower plate heights generate a smaller number of
    plates
  • Plate heights are correlated through the Van
    Deemter equation

Reference 8
34
Van Deemter Eqn.
  • H A B/u Cu
  • A is related to the mobile phase movement through
    paths in the stationary phase.
  • B describes longitudinal diffusion
  • C relates the analyte to mass transfer between
    the pores of the stationary phase
  • Halasz eqn.

Reference 8
35
Haslaz Eqn.
  • Eqn.
  • u relates to the velocity of the mobile phase
  • dp depends on the particle size
  • This formula implicates that decreasing particle
    size decreases the plate height which increases
    resolution.

Reference 8
36
Synthetic ApplicationSemi-Prep
37
Derivatization
38
Typical Chiral Separation
  • Biological activity depends on the
    stereochemistry of a particular enantiomer
  • A common column is a cytodextrin packing with
    various glucopyranose units this column creates
    hydrophobic cavities with hydrophilic surfaces.
  • The analyte is trapped in the cavity and can be
    separated from the polar solvents

Reference 8
39
Quantitative Analysis Application
  • HPLC can be use in conjunction with size
    exclusion to determine the molecular weight of
    proteins
  • In this application molecules with larger weights
    have lower retention times.
  • By plotting standard retention times in excel you
    can extrapolate the molecular weight (MW) of your
    protein
  • Lactate Dehydrogenase MW analysis in an
    experiment was determined using a 280 nm
    wavelength with a TSKGel Super SW 3000 size
    exclusion 4.6mm 30 cm column, 50 mM phosphate
    buffer pH 7.2 containing 0.3 M NaCl as a mobile
    phase, a flow rate of 0.6 mL/min., 20 µL
    injection volume, and a Rheodyne injection valve.

Reference 9
40
Standard protein molecular weight data
Reference 9
41
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42
References
  • http//mtsu32.mtsu.edu11233/471toc.html
    (accessed 06/19/09).
  • http//en.wikipedia.org/wiki/Chromatography
    (accessed 06/25/09).
  • Robinson, J. W. Skelly Frame, E.M. Frame II,
    G.M. Undergraduate Instrumental Analysis, 6th
    ed. Marcel Dekker Inc. NY, 2005 pp 797-835.
  • http//www.chem.queensu.ca/courses/08/CHEM321/Lect
    ureNotes/Chapter202520part20one.doc (accessed
    06/23/09).
  • http//www.restek.com/info_sixport.asp (accessed
    06/20/09).
  • http//www.waters.com/waters/promotionDetail.htm?i
    d10048693ev10007792localeen_US (accessed
    06/20/09).
  • Dionex, Technical Note 75. Easy Method Transfer
    from HPLC to RSLC with the Dionex Method
    Speed-Up Calculator
  • Levin, S. Abu-Lafi, S. The Role of
    Enantioselective Liquid Chromatography
    Separations Using Chiral Stationary Phases in
    Pharmaceutical Analysis, in Advances in
    Chromatography. Grushka, E. Brown, P. R.,
    Ed. Marcel Dekker Inc. NY, 1993 Vol. 33 pp
    233-236.
  • Kline, P. Analysis of Lactate Dehydrogenase
    Determination of Molecular Weight and Purity,
    Middle Tennessee State University, Murfreesboro,
    TN, 2009.
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