1. بنام خدا عباس بهرامی عضو هیات علمی گروه بهداشت حرفه ای دانشکده بهداشت دانشگاه علوم پزشکی کاشان Bahrami_a@kaums.ac.ir

3. انتظار میروددر پایان جلسهدانشجویان بتوانند:1-اساس کار دستگاهگاز کروماتوگرافی راشرح دهند.2-اجزای دستگاهگاز کروماتوگرافی رانامببرند.3-تعدادی از موادی راکهدر بهداشت حرفهانتظار میروددر پایان جلسهدانشجویان بتوانند:1-اساس کار دستگاهگاز کروماتوگرافی راشرح دهند.2-اجزای دستگاهگاز کروماتوگرافی رانامببرند.3-تعدادی از موادی راکهدر بهداشت حرفه 1- اجزاء دستگاه گازکروماتوگرافی را بیان کند. 2- انواع دستگاه کروماتوگرافی را بیان کند. 3- مکانیسم های به تعادل رسیدن نمونه در فاز متحرک و ثابت را شرح دهد. 4- کاربردهای کروماتوگرافی را توضیح دهد. 5- انواع دتکتورهای مورد استفاده در گازکروماتوگرافی را بیان کند.

4. Gas Chromatography

5. Gas Chromatography Basics Gas Liquid Chromatography (GLC) Gas Solid Chromatography (GSC) Mobile phase does not interact with analyte Separation occurs by interaction of analyte differentially w/liquid stationary phase and temperature GC preferred method, only applicable to volatile substances derivitiazation

6. Carrier Gas Supply Must be at a constant flow rate so that retention times & retention volumes may be equated Choice of detector will often Dictate the gases that are used, need to be inert Ex. FID used H2, air, and He

7. Injection Port Heated so sample virtually instantly turns into a vapor as sample plug goes onto column Septum Split/ SplitlessSplitSplitless Want to reproducibly get in & get out Sample focusSample focus

8. Flow rate Measurement Why is a known flow rate critical?

9. GC Columns Capillary: - have i.d. <1mm - have wide unrestricted flow through center & inner surface is coated with liquid stationary phase Variety of functional groups have been blended into polysiloxane chain to provide different polarity & selectivity

10. Capillary columns AdvantagesDisadvantages

12. HO-CH 2 -CH 2 -(O-CH 2 -CH 2 ) n -OH polyethylene glycol

14. Temperature

15. Chromatography Catalog Exercise Determine the best type of column to achieve separation for drugs of abuse. Draw the chemical structures of the stationary phase as best you can. Indicate what chromatographic conditions you would do your separation under. Why do you think the catalog recommended the conditions they did? Compare with someone else who used a different catalog, explain any differences.

16. Detectors in GC The ideal detector should:

17. Flame Ionization Detector

18. Thermal conductivity detector

19. Thermionic Detector (NPD)

20. Electron Capture Detector (ECD)

21. Atomic Emission Detector

22. Mass Spectrometer as a GC Detector

23. Total Ion Chromatogram

24. Selected (single) ion chromatogram:

25. Connecting the GC to the MS This is difficult! Why?

26. How is a GC interfaced to an MS? 1. Direct Connection

27. How is a GC interfaced to an MS? (2) Open Split Interface

28. Advantages of Open Split Design

29. Jet Separator

30. Cryogenic Focussing Technique for Beer Headspace Analysis

31. Kovat ’ s Retention Index

34. Gas Chromatography

35. انتظار میرود در پایان جلسه دانشجو بتواند: 1- اجزاي دستگاه كاز گروماتو گراف را نام ببرد. 2- اساس كار دستگاه كاز گروماتو گراف را توضيح دهد. 3- انواع آشكارسازها را نام ببرد.

36. Filters/Traps Air Hydrogen Gas Carrier Column Gas Chromatography gas system inlet column detector data system Data system Syringe/Sampler Inlets Detectors Regulators H RESET

37. Schematic Diagram of Gas Chromatography

39. DETECTORS Flame Ionization Detector (Nanogram - ng) High temperature of hydrogen flame (H 2 +O 2 + N 2 ) ionizes compounds eluted from column into flame. The ions collected on collector or electrode and were recorded on recorder due to electric current.

40. Exhaust Chimney Igniter Hydrogen Inlet Column Effluent Polarizing Electrode Collector Electrode Schematic Diagram of Flame Ionization Detector

41. Collector Jet Flame Detector electronics  - 220 volts Column Chassis ground Signal output

42. Thermal Conductivity Detector Measures the changes of thermal conductivity due to the sample (  g). Sample can be recovered.

43. Thermal Conductivity Detector Principal: The thermal balance of a heated filament Electrical power is converted to heat in a resistant filament and the temperature will climb until heat power loss form the filament equals the electrical power input. The filament may loose heat by radiation to a cooler surface and by conduction to the molecules coming into contact with it.

44. Thermal Conductivity Basics When the carrier gas is contaminated by sample, the cooling effect of the gas changes. The difference in cooling is used to generate the detector signal. The TCD is a nondestructive, concentration sensing detector. A heated filament is cooled by the flow of carrier gas. Flow

45. When a compound elutes, the thermal conductivity of the gaseous mixture of carrier gas and compound gas is lowered, and the filament in the sample column becomes hotter than the other control column. Its resistance increased, and this imbalance between control and sample filament resistances is measured by a simple gadget and a signal is recorded Thermal Conductivity Detector

47. Relative Thermal Conductivity Compound Relative Thermal Conductivity Carbon Tetrachloride0.05 Benzene0.11 Hexane0.12 Argon0.12 Methanol0.13 Nitrogen0.17 Helium1.00 Hydrogen1.28

48. Responds to all compounds Adequate sensitivity for many compounds Good linear range of signal Simple construction Signal quite stable provided carrier gas glow rate, block temperature, and filament power are controlled Nondestructive detection Thermal Conductivity Detector

49. Electron Capture Detector For pesticide analysis (picogram). Accept electrons of carrier gas.

50. Electron Capture Detector ECD detects ions in the exiting from the gas chromatographic column by the anode electrode. 3 H or 63 Ni which emits  particles. Ionization : N 2 (Nitrogen carrier gas) +  (e) = N 2 + + 2e These N 2 + establish a “base line” X (F, Cl and Br) containing sample +  (e)  X - Ion recombination : X - + N 2 + = X + N 2 The “base line” will decrease and this decrease constitutes the signal. Insecticides, pesticides, vinyl chloride, and fluorocarbons

51. Electron Capture Detector

53. Retention Times

54. GLC ADVANTAGES 1.Very good separation 2.Time (analysis is short) 3.Small sample is needed -  l 4.Good detection system 5.Quantitatively analyzed

55. Thermal Conductivity Detector The TCD will respond to any substance different from the carrier gas as long as its concentration is sufficiently high enough.

56. DISADVANTAGES OF GAS CHROMATOGRAPHY Material has to be volatilized at 250C without decomposition.

57. THIN LAYER CHROMATOGRAPHY Stationary Phase --------->Silica Gel Mobile Phase ------------->Solvent (developing)

58. http://www.chem.wits.ac.za/chem212-213-280/0%20Introduction%20-%20Lecture.ppt

59. The detector contains two filaments: one exposed only to carrier gas, while the other is exposed to the carrier gas for sample analysis. When the gas for the sample analysis is only carrier gas, the two filaments can be balanced. Instead of a direct measurement of filament temperature, the filament resistant, which is a function of temperature, is measured. Thermal Conductivity Detector

60. The ability of a colliding molecule to carry off heat depending on its thermal conductivity. Hydrogen and helium have high thermal conductivity and therefore will be more efficient at “cooling” a heated filament than other gases will Thermal Conductivity Detector

63. Electron capture compound, X (highly electonegative element), tends to capture free electrons and increase the amount to ion recombination X (F, Cl and Br) + e  X - Ion recombination : X - + N 2 + = X + N 2 The current will decrease and this decrease constitutes the signal. Halogens, lead, phosphorous, nitro groups, silicone and polynuclear aromatics. Insecticides, pesticides, vinyl chloride, and fluorocarbons Electron Capture Detector

65. Principals of Separation 1.Column is selected, packed with Liquid Phase, and installed. 2.Sample injected with microliter syringe into the injection port where it is vaporized and mixed into the Carrier Gas stream (helium, nitrogen, argon). 3.Sample vapor becomes partitioned between Moving Gas Phase and Stationary Liquid Phase. 4.The time the different compounds in the sample spend in the Vapor Phase is a function of their Vapor Pressure. 5.The more volatile (Low Boiling Point / Higher Vapor Pressure) compounds arrive at the end of the column first and pass into the detector. Gas Chromatography – Acetates

67. The Beginning 4 concept of GC announced in 1941 by Martin and Synge (also did liquid partition chromatography) 4 10+ years later GC used experimentally 4 1955, first commercial apparatus for GC appeared on the market

68. Today 4 estimate : 200, 000 gas chromatographs are currently used through out the world. 4 30+ instrument manufactures 4 130 different models 4 cost 1,500 to 40,000 dollars 4 improvements: computers- automatic control open tubular columns-separate a multitude of analytes in relatively short times