Post on 15-Jun-2022
ProcessesNeeded toGenerate a
MassSpectrum
1) Generate desolvated ions(Sources)
2) Transfer ions into massspectrometer vacuum(Interface Region)
3) Mass analyze ions(Quadrupoles)
4) Detect ions(Detector)
5) Process the data(Software)
Liquid ChromatographyCoupled to Tandem Mass
Spectrometry
The Source
The Source
Ionization Sources
Turbo IonSpray - IonSpray (pneumaticallyassisted Electrospray) option which utilizesa heated auxiliary gas flow.Heated Nebulizer - Atmospheric PressureChemical Ionization (APCI) source whichionizes compounds in the gas phase.
Ion Evaporation andFormation
++ +
++
++ ++ +
++ --
---
+++++
+ +- ---
+ +
+
++
- +++++-
IonSpray (ESI)
IonSpray: - Electrospray ionization (ESI)- Gentlest ionization technique- Applicable to polar and ionic substances
Multiply Charged Ions
Molecules which can be multiplyprotonated or deprotonated can exist inmore than one charge statePeaks at [M ± nH]n± (n = number ofcharges)
1.56e6 cps+Q1: from myoglobina
1060.5
1414.01542.5
1696.0
8 0 9 .0
8 4 8 .5
8 9 3 .0
9 4 2 .5
9 9 8 .01 1 3 1 .0
1 2 1 2 .0
1 3 0 5 .0
800 1000 1200 1400 1600m/z, amu
5.0e5
1.0e6
Inte
nsity
, cps
10+11+12+
13+14+
16+15+
etc.
Nebulizer
Primary Flash Zone
Secondary Flash Zone
Cool Zone
Heated Nebulizer(APCI)
Heated Nebulizer: - Atmospheric Pressure Chemical Ionization (APCI) - corona discharge - polar to non-polar thermally stable compounds
Corona Discharge Chemistry – Positive Ions1) EI on atmosphere causes e- removal from
N2 & O2 forming N2+• & O2
+• (primaryions)
2) In a complex series of reactions N2+• &
O2+• react with H2O & CH3OH forming
H3O+ & CH3OH2+ as reagent ions for CI.
3) H3O+ & CH3OH2+ donate protons to
analyte forming [M+H]+
Atmospheric Pressure ChemicalIonization (APCI)
GC-MS vs. LC-MS
IonSpray
APCI
GC-MS
IonicA
naly
te P
olar
ity
Molecular Weight101 102 103 10104 105
Non-Ionic
Ion ProductionAPI Chemistry
andExample Spectra
Ion ProductionAPI Chemistry
andExample Spectra
GAS PHASE Acid-Base Scalefor Positive Ions & Neutral Molecules
Reagent IonsWeak Base
HCOOH2+
CH3COOH2+
H3O+
CH3OH2+
C6H6OH2+
HCHOH+
N2OH+
CH5+
C2H5+
C6H6H+
CH3CNH+
C2H5OCOC2H6+
NH4+
C6H15NH+
Strong Base
• Addition of acetic acid or formic acid willincrease intensity in positive ion mode byhigher concentration of H+.
• Trifluoroacetic acid (TFA) works well inpositive ion mode at a concentration up to0.05%, but lingers for a long time in negativeion mode. (TFA ions are at m/z 113 and m/z227—dimer)
• Changing from acetonitrile to methanol mayincrease signal intensity.
Neutral MoleculesStrong acid
formic acidacetic acid
watermethanol
phenolformaldehyde
N2Omethane
ethanebenzene
acetonitrileethyl acetate
ammoniatriethylamine
Weak acid
Incr
easin
g A
cidi
ty
Reagent IonsStrong Base
NH2-
OH-
C6H5CH2-
CH3O-
C2H5O-
CH2CN-
CH3COCH2-
CH3S-
CH2NO2-
CN-
C6H5O-
CH3COO-
C6H5COO-
Cl-
Weak Base
• For R-COOH compounds use NH4ac buffer(pH = 6.4).
• Try addition of NH3 in case of neutral analytesin negative ion mode.
• Stay away from triethylamine, it collects in thesource!
GAS PHASE Acid-Base Scalefor Negative Ions & Neutral Molecules
Neutral moleculesWeak Acid
NH3
WaterToluene
MethanolEthanol
AcetonitrileAcetoneCH3SH
CH3NO2
HCNPhenol
Acetic acidBenzoic acid
HClStrong Acid
Incr
easin
g B
acic
ity
Ionization SuppressionCompounds That Cause Sensitivity Suppression– Salts can interfere with ionization and can cluster to
complicate spectrum (but also aid in identification)– Strong bases or quaternary amines can interfere with
positive mode analytes, e.g. Triethylamine (TEA)– Acids - Sulfuric/Sulfonic acids and TFA interfere in
negative mode experiments– Phosphate buffer and non-volatile ion pairing agents (e.g.
SDS) can cause severe suppression and complex spectraDimerization ([2M+H]+) can occur at highconcentration, leading to non-linearity duringquantitation– Dimer Signal at m/z = (MW*2)+1
– Can cause non-linearity at high concentrations
Progesterone in Positive Ion ESI-MS
[M+ Na]+
Effect of Phosphate Buffer8.78e7 cps–Q1 MCA (10 scans): from cck q1 -ve nano
254.43424.53
566.44
733.93
835.93
898.22 1000.42
1164.611 1 4 2 . 4 1
CCK dissolved in Phosphate Buffer
300 400 500 600 700 800 900 1000 1100m/z, amu
1e7
2e7
3e7
4e7
5e7
6e7
7e7
8e7
Inte
nsity
, cps
4.44e7 cps–Q1 MCA (10 scans): from CCK PURIFIED Q1 SACN 16.7
292.82 377.02
439.03497.03
570.44
700.63 798.63879.23
1142.03Phosphate Buffer removed from CCK sample
300 400 500 600 700 800 900 1000 1100m/z, amu
5.0e6
1.0e7
1.5e7
2.0e7
2.5e7
3.0e7
3.5e7
4.0e7
Inte
nsity
, cps
Adducts & Clusters formed in LC/MSAdduct Ion Formed Cause
Adduct*/ Ionic APCI ESI +/- m/z of Ion
Lithium [M+Li]+ Lithium Salts Ionic + [M + H + 6]+ Ammonia [M + NH4]+
Ammonia/ NH4OH Adduct + [M + H + 17]+
Water [M + H3O]+
Water/ Acids Adduct + [M + H + 18]+
Sodium [M + Na]+ Sodium salts Ionic + [M + H + 22]+ Methanol [M + H + CH3OH]+
Methanol in Solvent Adduct +/-
[M + H + 32]+ [M - H + 32]-
Chloride [M + Cl]- Chlorinated solvent Ionic - [M + 35 (& 37)]- Potassium [M + K]+ Potassium salts Ionic + [M + H + 38]+ Acetonitrile [M + H + CH3CN)+
Acetonitrile in solvent Adduct +/-
[M + H + 41]+ [M - H + 41]-
Formic Acid [M - H + HCO2H]- Formic Acid Adduct - [M - H + 46]- Acetic Acid [M - H + CH3CO2H]- Acetic Acid Adduct - [M - H + 60]- TFA [M - H + CF3CO2H]- TFA Adduct - [M- H + 114]-
* Adducts can often be broken up by using a higher DP voltage.
Ion TransferIon Transfer
Ion Path“Electronic Ion Ski SlopeElectronic Ion Ski Slope”
Lens (IQn) and rod (ROn) voltages are linkedKeep ions moving at correct speed through system For bestsensitivity, proper mass filtering
OR =45V
Q0= -10V RO1 =-11V
Moves with C.E.0V, SK at ground
RO3, moves withRO2 (-2-3V)
Q0
IQ1
ST RO1 ST2 RO3
DF
CEM
OR SK
EXITRO2 (LINAC)ST3
MS &MS/MS (tandem)
MS &MS/MS (tandem)
Quadrupole TheoryQuadrupole acts as a mass filter– Separates ions based on m/z ratio
Quad. made of 4 rods– “A” pole - vertical rods; “B” pole -
horizontal rods (by convention)DC & RF voltages are imposed:– U = (DC)A - (DC)B (FDC)– V = RF voltage (RFp-p)– V = Const.•M•r0
2•ν2
Note: M α V• ν = RF frequency– r0 = ½ distance between rods
Stability DiagramDC/RF
Operating Line(through the apices) →
V (RF)
U (D
C)
High
Unit
Low
MS OperationScan Modes
MS OperationScan Modes
Q1 MS Scans
Start/Stop Mode
Q3 Single-Stage MS Scans
Start/Stop Mode
MS/MS Scan ModesAvailable Scan Modes– Product Ion
Provides structural information– Precursor Ion
Provides structural information complementary toProduct Ion
– Neutral LossProvides compound class specificity
– MRMUsed for Quantitation
In all MS/MS modes, Q3 is a mass filter– Q3 may scan or be fixed at a given m/z– Q2 is “source” of product ions entering Q3
MS/MS – Product Ion Scanm1
+ fixed
m3+ scanned
MS/MS – Precursor Ion Scan
m3+ fixed
m1+ scanned
MS/MS – Neutral Loss Scan
m1+ scanned
m3+ scanned
δm
MS/MS – MRM(Multiple Reaction Monitoring)
Precursor ion fixed
Product ion fixed
Fragmentation(CAD)
FragmentationWhen an ion fragments the following formulas apply:– Positive mode: [Precursor]+ → Product+ + Neutral– Negative mode: [Precursor]- → Product- + Neutral
Two modes of fragmentation on Sciex Instruments:– CAD = Collisionally Activated Dissociation
Energy controlled by CE; occurs in Q2 (collision cell)Ions collide with N2 molecules (CAD gas), collision energy isconverted into vibrational energy, and bonds break
– CID = Collision-Induced DissociationEnergy controlled by DP; occurs between orifice and skimmerIons collide with N2 (from curtain gas) and solvent molecules,collision energy is converted…
Ion DetectionIon Detection
Detector & Signal Handling
CEM BiasVoltage (+)
DeflectorIon Path
Signal Output
1000 pF10 kV
1 Mž
CEM HornVoltage (-)
CEM
Signal HandlingBoard
System Controller(in System
Electronics Box)