1. 1 Separation & Analysis of Mixtures using Capillary Electrophoresis & Laser-induced Fluorescence Detection
2. 2 Electrophoresis: analytes are separated based on their ability to move through a conductive medium, usually an aqueous buffer, in response to an applied electric field.
3. 3 Electrosmetic
Electrophoretic
4. 4 Why CE ? the high separation power
short analysis time & lower operating cost
Only small sample volume
Heat dissipation by surface area of capillary
Limit zone dispersion
Use high E
5. 5 Characteristics of Selected Detectors for CE
6. 6 Advantages of Detection via Laser-induced Fluorescence Spectral Selectivity
Sensitivity
Time response
Dynamic range attainable
High spatial coherence of a laser beam allow for high efficient excitation
High power laser facilitates the detection of small concentration of fluorophore
7. 7 Common lasers in CELIF He-Cd (CW) 320 - 442 nm
He- Ne (CW) 544 - 593 nm
Ar+ ion (CW) 275 - 488 nm
Diode (CW) >630 nm
8. 8
9. 9
10. 10 Resolution of a Racemic Mixture of� Amino Acids They are just different in chiral properties.
Making Diasteromers by reaction the racemic mixture with a chiral reagent .
Diasteromers behave as distinct substances and different in all properties.
11. 11 Role of laser system: To induce on- column fluorescence of the dansyl fluorophore in both derivatized amino acids and in the diastereomerice complex formed between the amino acids and the Cu (II) complex of L- histidine.��Useful characteristics of the laser light for this application: wavelength tunability for direct excitation of the dansyl fluorophore
12. 12 D- & L- amino acids are labeled with 5- dimethyl -amino naphthalene -1- sulfonyl.
Different interaction with a chiral support electrolyte (Cu (II) complex of L- histidine) in the capillary column.
He- Cd laser (325 nm)
Fused silica capillary 75 cm 75 m i. d.
Collection by a 0.6 mm fused silica optical fiber.
?ex 325 nm
?em 600 nm
13. 13 Enzymatic Assays (Analysis of -Galactosidase) Objective: To quantify the amounts of enzyme in picoliter volume of cell extracts using an enzymatic assay that generates multiple fluorescent products.
Role of laser system: To enable ultrasensitive off-column laser- induced fluorescence detection of species eluting from capillary column.
Useful characteristics of the laser light for this application: wavelength tunability & high power for direct excitation of a fluorophore present at low concentartion.
14. 14 Fluorometric assay: The measurement of enzyme concentration involves the reaction of the enzyme with nonfluorescencent species to produce a phluorophore. First-order kinetics.
Ratetot = [E]
d[F]/dt = d[?f]/dt = [Et]
FDG FMG + galactose
FMG fluorecein + galactose
15. 15 Analysis of alkaloids�in plants They were analyzed with a simple, rapid & sensitive method of nanaqueous capillary electrophoresis with laser induced native fluorescence (NACE-LIF).
Ar ion laser (488 nm)
Fused silica capillary 30 cm 75 m i. d.
?exc 488 nm
?emi 500- 700 nm
16. 16 Sensitive detection and separation of Biological compounds using CEILF detection with Nd:YAG Diode pumped, frequency-doubled cw Nd:YAG laser with wavelength 532 nm and power 5mW.
CE, fused silica 37 350 m o. d. & 50 -70 m i. d.
Power supply 10- 18 kV
Injection: Electrokinetic 5kV in 5 s or hydrodynamic ?h= 2 cm, t= 30 s
Injection volume 2.0 10-9 L
17. 17 Capillary Electrophoresis with Laser-Induced Fluorescence Polarization Detection
18. 18 Fluorescence Polarization
19. 19 DNA sequencing using 96-capillary array electrophoresis High speed
High-throughput
96 capillaries, 75 m i.d., 150 m o.d., 35 cm effective length.
96 gold-coated pins
A CCD detector was used to monitor all capillaries simultaneously with laser-induced fluorescence at 1.75 frames per second
No moving parts
Ar+ ion laser
20. 20 Using high power laser (excimer laser, 308 nm,30 ns pulsed width)
Complete coating removal when the blue fluorescence emission isnt observed.
