Practical High Sensitivity LC-MS

2. Practical High Sensitivity LC-MS Fundamentals, Challenges, and Prospects Gary A. Valaskovic, Ph.D. New Objective, Inc.

3. Main Topics • Anatomy of Electrospray • Introduction to Nanospray • The Nanobore LC Advantage • Flow Splitting and Sample Injection • Nanobore LC to MS Interfacing • Keys to Success

4. Anatomy of ESI • Adapted from Kebarle & Tnag, Anal. Of Chem., 1993, 64, 972A

5. Anatomy of ESI

6. What is Nanospray?

7. Why Use Nanospray? • ESI-MS (as commonly implemented) is a concentration sensitive detector. There is little or no loss in signal/noise as you reduce the flow rate. You can obtain the same S/N for most compounds from 1 mL/min to 10 nL/min (with the right equipment)! Adapted From Cody, Appl. Elec. Mass. Spec., Pramanik, Ganguly, Gross Eds.

8. Why Use Nanospray? There are three reasons to use Nanospray: • Sensitivity • Sensitivity • Sensitivity • Nanospray is one of the key technologies for MS-based Proteomics

9. How Does Nanospray Yield Sensitivity? • Two ways to obtain sensitivity with Nanospray: • Off-line “Static” Nanospray • Extend the analysis time for a given sample • Sum spectra to increase S/N • Complete MS/MS or MSn possible • On-line LC-Nanospray • Analyze a small volume sample (1 µL or much less) • Concentrate your sample into as small a volume as possible

10. Static Nanospray Methodology • Direct infusion of 0.5 to 5 µL sample • Sample must be “clean” • No pumps - flow is generated by electrostatic “pressure” • Typical Tip ID: 1 - 4µm • Typical flow rate: 10 - 50 nL/min HV MS Inlet Glass needle - 0.7 mm bore Conductive Coating Tip ID 1 - 4 µm Liquid sample 1 - 5 µL

11. Static Nanospray Extends Analysis Time Adapted From Corey & Pinto, Appl. Elec. Mass. Spec., Pramanik, Ganguly, Gross Eds.

12. Static Nanospray Limitations • Sensitivity is good, but inferior to LC methods • Typically 10 -100 fmol proteins and peptides • Sample prep is not integral, sample must be clean and concentrated • Typically 100 nM to 10 µM • Limited utility on complex mixtures (OK on single bands but unable to handle “shotgun” methods) • Highly dependent on operator skill • Limited throughput • Automation is possible but $$$

13. “On-line” Nanospray with Nanobore LC • Integral sample clean-up • On-line injection of 1 - 20 µL • Gradient elution from split flow HPLC pump • Column ID ≤ 100 µm • Typical flow rate: 100 - 500 nL/min Gradient pump @ 200 µL/min MS Inlet In-line filter Column Tip Micro-injection valve (or autosampler) Flow split 1000:1

14. 4.6 mm 50 µm Why Use Nanospray LC? Elute your sample into the smallest practical volume for the highest S/N!

15. Why Use Nanobore LC? The Concentration Advantage! Adapted From Tomer & Moseley, Mass. Spec. Rev., 1994, 13, 431

16. Requirements for LC System • Gradient Operation • Binary required; tertiary, quaternary preferred • Injection • 1 - 20 µL Typical • Accommodate sample trapping • Flow rate ≈ 100 to 1000 nL/min • Typically pre-column flow split from conventional pump

17. Flow Splitting Methods • Simple “T” Splitter (build) • Inexpensive! Easy to do. Split is non-linear but reproducible. • Balanced Flow Splitter (build or buy) • Good performance, inexpensive • High-Pressure Flow Splitter (buy) • Good performance, $$$ • “Active” Mass Flow Control (buy) • Good performance, $$$

18. Simple Flow Splitting • Use a simple Tee • Use a small bore (20 - 50 µm ID) tubing to create a flow “calibrator” • Adjust split ratio by adjusting the length of the calibrator • Fine tune by setting the pump flow • Ratios from 1:10 to 1:1000 are readily obtained

19. Nanospray Source Requirements • Mechanical requirements • XYZ Stage for tip positioning • Tip and spray imaging system • Junction and proximal HV contact • Tip requirements • ID of 10 - 30 µm • Typically fused-silica, 360 µm OD • Uncoated or coated

20. Objective Lens Tip Holder HV Contact CCD Camera XYZ Stage Injection Valve On-line Nanospray Source www.newobjective.com

21. Monitor Illuminator Source On-line Nanospray Source

22. What About Sample Injection? • Gradient elution in reverse phase enables sample stacking: • Large (1 - 20 µL) injection volumes are OK If we ran isocratically, a 75 µm ID column would require a 10 - 20 nL injection volume!

23. Injection Strategies • On-column Injection (Pressure Bomb) • High sensitivity • Zero sample loss or waste • Time consuming (manual) • “Micro” Injection Valve • 0.1 - 5 µL • Easy to use • Sample Trapping • Faster injection of large volumes (5 - 20 µL) • Trap protects columns for increased lifetime • Some peptides lost during injection and analysis

24. To Column Pressure Bomb Gas In Sample Vial Bomb Injection

25. Fused Silica Column Sample Trapping • Trap Cartridge/Column • 100 - 500 µm ID • 1 - 25 mm in length • Typically C18 or SCX • Loading rate 1 - 20 µL/min • Enable hundreds/thousands of injections on an analytical column

26. Sample Trapping Load Injection Loop

27. Sample Trapping Load Sample Trap & Wash

28. Sample Trapping Elute into Column

29. How Do We Interface? • Liquid sheath for make-up flow (The Early Days) • Generally not used, compromised sensitivity • “Direct Connect” interface with fused-silica tip • No “make-up” or sheath liquid • Reasonable sensitivity • Plumbing can be a challenge • Integration of LC column with emitter • Highest sensitivity • Robust interface • Greater ease of use

30. HV ZDV Metal Union Tip 5 - 30 µm HV Union PEEK or Teflon Distal Coating Direct Connect InterfaceJunction Contact

31. SIC, 653.5 m/z SIC, 653.5 75 µm ID, C18 Distal Coated 10 µm PicoTip™ Water/CH3CN/Formic Acid 45 Minute gradient Micromass Q-TOF Base Peak, RIC Performance BenchmarkTryptic Digest of BSA - 125 fmol Data courtesy Art Moseley, GlaxoSmithKline

32. Direct Connect InterfaceCommon Problems • Poor peak shape • Difficult post-column plumbing, requiring a “perfect” connection • Impractical with columns smaller than ≈75 µm • Clogged tips and columns • Difficult to distinguish point of plug - is it the column or the tip? • Air bubbles in line • Out-gassing, leaks, electrolysis, etc.

33. 75 µm ID, C18 Frit Tip: 8 - 15 µm PicoFrit™ Packed Tip Performance Pack the LC column directly into the tip! “Zero” post column volume Emmett & Caprioli, J. Am. Soc. Mass. Spec. 1994, 5, 605-613

34. HV Pt electrode PEEK “T” Packed C18 PicoFrit™ Packed Tip Approach • Junction style HV contact for robustness (arc immunity) • Junction can be far behind tip (10 cm or more) • Pre-column volume does not hurt chromatography

35. PicoFrit™ ApproachAnalytical Advantages • Tip size optimal for column flow rate • Typically 8 -15 µm for 75 µm ID column • HV contact on inlet side of column • Minimal contribution to band broadening w/sample stacking • Eliminates air bubbles (high pressure side of column) • Robust and easy to use • Economical • Concurrent fabrication of tip and column

36. Packed Tip AppraochAnalytical Advantages • Optimal sensitivity and resolution • Spray directly from column • Virtually zero post-column volume • Virtually eliminates tip clogging • Robust lifetime • 500+ injections/column with sample trapping • Easy to use • Fewer connections to make

37. PicoFrit™ ColumnsPerformance Benchmark Data courtesy James P. Murphy III, Ph.D.

38. PicoFrit™ ColumnsPerformance Benchmark

39. Keys to Success

40. Minimize Particle Contamination

41. Minimize Particle Contamination Contaminated Column Head Clean Column Head • Mobile Phase Stocks • Change Stocks Regularly (weekly or better) • Use bottled water, preferrably distilled in glass • Avoid “ultrpure” meg-ohm water from in-house systems • These can contain high levels of carbon particulates Poor quality water is the primary cause of clogged columns!

42. Minimize Particle Contamination • Fittings and Unions • Use PEEK or FEP adapter sleeves • Don’t over tighten fittings • Avoid graphitized ferrules (common in GC) • Discard contaminated fittings OUCH!

43. Minimize Particle Contamination • Injection valves • Avoid “scribing” surface of rotor with fused-silica • Inspect surfaces often • Pump components • Inspect/replace seals, fittings, check valves and filters Watch out!

44. Measuring Column Flow Rate • Let a droplet collect at tip for 5-10 minutes (ESI is off) • Collect the droplet by capillary action • Measure the volume and calculate flow rate

45. Source Tuning: Go For the Best Spray 850V Stream and Plume 50% ACN, 0.1% Formic Acid 500 nL/min, 15 µm Picofrit™ tip, LCQ™ Deca XP Inlet

46. 1150V Stream and Plume Source Tuning: Go For the Best Spray 850V Stream and Plume 50% ACN, 0.1% Formic Acid 500 nL/min, 15 µm Picofrit™ tip, LCQ™ Deca XP Inlet

47. 1450V Good Plume Source Tuning: Go For the Best Spray 850V Stream and Plume 50% ACN, 0.1% Formic Acid 500 nL/min, 15 µm Picofrit™ tip, LCQ™ Deca XP Inlet

48. 1850V Optimal Plume Source Tuning: Go For the Best Spray 850V Stream and Plume 50% ACN, 0.1% Formic Acid 500 nL/min, 15 µm Picofrit™ tip, LCQ™ Deca XP Inlet

49. 2050V Split Plume Source Tuning: Go For the Best Spray 850V Stream and Plume 50% ACN, 0.1% Formic Acid 500 nL/min, 15 µm Picofrit™ tip, LCQ™ Deca XP Inlet

50. Spray Morphology: Composition 5% ACN 50% ACN 95% ACN 1700V 1900V 2100V 2300V 2500V 30 µm Tip @ 500 nL/min 0.1% Formic Acid 3100V