Pioneers in LC/MS
- 1997-Jun-03
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Transcript
00:00:01 Good afternoon. I'd like to welcome everybody to the afternoon session on Pioneers and LC-MS.
00:00:12 Hopefully this session, this two-hour session, will be a little different than your standard technical session
00:00:19 in that the emphasis that will be presented is not really focused on technology,
00:00:30 but rather, paraphrasing John Fenn, those who fail to learn from the past are doomed to repeat it.
00:00:40 We've invited six speakers this afternoon to discuss the field of LC-MS from a historical perspective.
00:00:52 The presenters, even if I wanted to, I probably couldn't tell them what to say,
00:01:00 but I asked them to consider certain questions.
00:01:03 One of the questions I asked them to address was some of the barriers that they were faced with 15 or 20 years ago
00:01:13 in overcoming the, at least perceived, fundamental incompatibility between LC-MS and mass spectrometry at that time.
00:01:26 I also asked them to add a little more personal components to their lectures
00:01:37 and describe some of the serendipity and unexpected results that may have led to developments in LC-MS.
00:01:46 I asked them if there were any critical technologies that enabled or facilitated the growth of LC-MS.
00:01:54 Many of the people in the audience today are graduate students and weren't around 20 years ago,
00:02:01 and a lot's changed in the last 20 years.
00:02:04 It's not just the interfaces that have made LC-MS a multi-hundred million dollar industry, instrument industry,
00:02:14 and a tremendous analytical tool for many analytical chemists.
00:02:20 So, without further ado, I'd like to introduce the first speaker, Bruce Thompson,
00:02:28 and he will be discussing atmospheric pressure ionization and LC-MS together at last.
00:02:36 I'd also like to acknowledge his award for his contributions in analytical chemistry in Canada.
00:02:46 He was just awarded this past weekend the prestigious McBride Medal, and if you get a chance, you should congratulate him on that.
00:02:55 Bruce.
00:02:58 Thank you.
00:03:07 Thank you, Ross.
00:03:09 Thank you for inviting me to this session and including me amongst these other icons of mass spectrometry.
00:03:14 The inspiration for the title of this talk came partly from this cartoon that Patrick Arpino used to show at LC-MS talks back in the early 80s.
00:03:33 Patrick was another pioneer of LC-MS in the DLI method, some of you may know.
00:03:37 And he used to show this cartoon that represented to him the conundrum of getting the liquid-phase LC compounds and the gas-phase mass spectrometer together.
00:03:48 And you have the liquid-phase compounds looking longingly at the gas-phase mass spectrometry, wanting to get together, and how can we best put them together.
00:03:56 The other inspiration came from the fact that at the same time I was giving lectures or talks at ASMS and other places on LC-MS, and promoting the idea that atmospheric pressure was really the best way to do it.
00:04:08 And so I can finally say that I think LC and MS are together at last, and they fish fly, if you like.
00:04:17 Fish now fly. That may not be the best solution to it, but it's a solution that works today.
00:04:21 I really stretch a metaphor, I could say that whales fly now, that we have protein ions flying from electrospray.
00:04:29 Before I go any further, I want to recognize an even earlier pioneer of atmospheric pressure, LC-MS, and that was Evan Horning at the Baylor College of Medicine, who was really the first to show LC-MS by atmospheric pressure ionization.
00:04:41 He used a corona-discharge source and a heated block into which the LC-LU inflowed, and he showed this demonstration in a paper in 1974 of LC-MS using atmospheric pressure corona-discharge ionization.
00:04:53 It wasn't picked up on at that time, in fact it wasn't picked up on for a lot longer than that, but he was really the first to do it.
00:05:00 So I want to recognize his contribution, his earlier contribution.
00:05:04 My hook into this area came from being a graduate student with Julio Eberni at the Department of Physics at the University of Toronto in the mid-70s.
00:05:14 We were working on the ways in which charged droplets lost charge, cloud droplets lost charge, evaporated and lost charge.
00:05:23 We came up with this conceptual model of the fact that as the droplets shrunk and evaporated, that individual ions would pop out into the gas phase.
00:05:29 That was a mechanism for their losing charge.
00:05:33 The conceptual model is represented here by the ions surrounded by some water molecules.
00:05:37 We were working with water always at the time.
00:05:40 It would come out into the gas phase surrounded with a few clusters of water and then they could eventually be evaporated away and you'd be left with the individual ion.
00:05:46 We used ion mobility and mass spectrometry to study these ions.
00:05:51 From that we developed the model of ion evaporation, which is probably the best accepted model now for the process that goes on, at least reluctantly accepted in many cases.
00:06:05 From a conceptual point of view, which was really what we intended to do with this model, it still explains best the process that goes on in the spray electrified methods of LC-MS and spray evaporation.
00:06:18 Where you create charged droplets and the ions in the droplet, which are initially solvated and so sit in the bottom of a large potential well,
00:06:26 then their potential is raised as the droplet evaporates and the electric field due to the net charge in the droplet eventually kicks them out into the gas phase.
00:06:34 We actually put a lot of numbers and detail around this model, but probably wasn't meant to go beyond the general concept of the fact that individual ions would come out probably clustered with some water molecules.
00:06:45 Sometimes it's over-analyzed today in terms of the details of that model, but I think from a conceptual point of view it still holds water, if you like.
00:06:52 There's obviously lots of things still to be understood about it, particularly in the case of proteins, where this simple model may not be the one that works.
00:07:00 This was the instrument that we put together at the University of Toronto. Just focus on the top part of it now.
00:07:11 It shows a mass spectrometer, a quadrupole mass spectrometer, some ion optics and a sprayer out in the gas phase, where we were just spraying water with some various inorganic ions in it and they would come off and we'd sample them into the mass spectrometer.
00:07:24 We used this orthogonal sprayer, if you like, with the spray directed through an elbow, so it was directed across the front of the orifice.
00:07:32 That's an idea that seems to be coming back into popularity today with another name.
00:07:39 This is a picture of the instrument that we had, this tank of a mass spectrometer, but a tank of a vacuum chamber with the mass spectrometer in it and the quadrupole, or the ion source, would be in this region.
00:07:50 It's not shown here, but just sitting in the air, spraying in this region in front of the front flange there.
00:07:57 This was the sprayer that we used. These were the days before color film, obviously.
00:08:07 This was a cross-flow nebulizer, the liquid coming out here and the air coming out here to spray in this direction.
00:08:15 This was a grounded sprayer, which is also often used in electrospray today.
00:08:20 The high voltage was applied by means of what we called an induction electrode, or it could be called a counter electrode here.
00:08:25 This rod was supported at a high voltage and it charged the droplets by what we called induction, basically by applying a high field at the tip of the sprayer.
00:08:33 The net result was a lot of charged water droplets.
00:08:36 They were driven through here by the airflow and then in front of the mass spectrometer through this high-tech copper elbow.
00:08:44 Now, although we were looking at inorganic ions and processes and so on,
00:08:47 Ira Barney was enough of a chemist to know there may be an analytical application for this.
00:08:52 In fact, he was a physical chemist from the old days.
00:08:55 So he ran across the street to some people in pharmacy at the University of Toronto and said,
00:08:58 what's a good application, organic ion, for us to look at?
00:09:02 And they gave us an example of these catecholamines.
00:09:05 Unfortunately, he didn't go into biochemistry and have them suggest a peptide or a protein.
00:09:10 So we had to look at these as our model compounds initially.
00:09:13 And after I graduated and I moved to SCIEX and started working there,
00:09:16 and we were working on an atmospheric pressure mass spectrometer,
00:09:19 then we cooperated, Ira Barney and I, on just demonstrating some of the applications of ion evaporation
00:09:24 with what was in those days the TAGA mass spectrometer.
00:09:27 And these are just some spectra of these three simple catecholamines done by this, what we called, ion evaporation method.
00:09:35 And then we decided to couple an LC to it, and I found this slide.
00:09:41 This was a figure that was prepared for the Asilomar meeting in 1981.
00:09:45 And Ira Barney had done some LC-MS at SCIEX, and he put these,
00:09:48 this was not a computer-controlled instrument,
00:09:50 put these graphs together and glued them on a piece of paper and pinned this note on it.
00:09:54 You can see the date on it, August 7th, 1981,
00:09:56 showing left side, three separate runs at corresponding masses for the three catecholamines here.
00:10:02 And on the right side, sensitivity, injections.
00:10:04 Now this is online LC-MS at a milliminute,
00:10:07 probably with injections of something like half a mil or a mil,
00:10:09 because we didn't really know what we were doing in terms of LC.
00:10:14 And you can see the lowest amount here, 10 to the minus 7th molar of dopamine,
00:10:17 with a little bit of a signal there.
00:10:18 So this is about, I think, about 20 nanograms injected on column.
00:10:24 So we were proving principle those days that you could do LC-MS by ion evaporation.
00:10:27 Here's just a separation of some amino acids and creatine, not outstanding sensitivity.
00:10:34 One of the things that was happening was that we were running a milliminute of mostly aqueous water,
00:10:39 sometimes with some organic,
00:10:40 spraying that without the application of any heat at all.
00:10:43 And any of you who do electrospray today
00:10:45 knows how much sensitivity you're going to lose under that situation.
00:10:48 We weren't smart enough to think of lowering the flow.
00:10:52 So one of the things that limited us, I guess,
00:10:54 was that low-flow LC wasn't something that people used commonly in those days.
00:11:01 And all I thought about was a milliminute for LC.
00:11:07 This is a really impressive slide.
00:11:11 The title is off the top.
00:11:12 This was actually on column, two nanograms of antipyrene injected on column.
00:11:16 Sometimes the sensitivity was amazingly good.
00:11:18 This was full scan LC-MS,
00:11:20 where we did have a computer system now attached, a PDP-8 attached to the system.
00:11:24 And you can see extracted ion current profile for the parent ion there
00:11:27 and the mass spectrum down below.
00:11:31 And then we, in the early days of developing the TAGA6000 triple-quad system,
00:11:35 this would be in about 1982,
00:11:37 did some SRM or MRM, 20 nanogram, 200 nanogram of arginine,
00:11:42 which was another model compound
00:11:43 because it was considered challenging, involatile, labile, difficult to do.
00:11:47 This was an MRM. There should be an arrow here.
00:11:53 And one of the interesting things was, I think, in 1981,
00:11:55 ASMS, we showed this spectrum of a multiply-charged ion from ion evaporation.
00:11:58 This was, again, the title is off the top,
00:12:00 adenosine triphosphate, the disodium salt.
00:12:03 So what we saw when we ran that was the doubly-charged anion.
00:12:06 And that actually elicited a fair bit of interest at the time
00:12:09 because it was reported, or reputedly,
00:12:11 the first negative doubly-charged anion that had been observed in the gas phase at that time.
00:12:17 And you can see the MSMS spectrum down below,
00:12:19 if you can see below the floor,
00:12:20 of how it fragmented to the two halves of the molecule very nicely.
00:12:25 Now it kind of languished because
00:12:28 another of the impediments to the development of this technique
00:12:30 was nobody else really had atmospheric pressure mass spectrometers at the time
00:12:33 to even try this or play with it.
00:12:35 So it sat there and languished.
00:12:37 Although there were a couple of visionaries,
00:12:40 one of them was Steve Unger at Squibb
00:12:42 who had a compound that he thought might work by this method.
00:12:45 This was about 1983. It's TRENAM.
00:12:47 And we ran that.
00:12:48 This was a compound that didn't work at all well by FAB,
00:12:50 didn't work at all well by thermospray,
00:12:52 but we got this beautiful spectrum of just the parent ion here from it.
00:12:56 And he was very excited about this.
00:12:58 Unfortunately, he wasn't excited enough to be able to convince his management
00:13:01 to buy a system based on it,
00:13:03 but he recognized the power of this technique in any event.
00:13:10 Now, from there, at the same time,
00:13:12 really simultaneous with all this,
00:13:14 we were working on a heated nebulizer interface
00:13:17 for our corona discharge ion source.
00:13:19 And the genesis of this was from a little bit of work
00:13:22 that we did with Jack Kenyon and Peter Dawson.
00:13:25 And Jack really stimulated this.
00:13:27 He's going to tell you the story of that early work initially.
00:13:30 But that got us going on developing the heated nebulizer interface at SIACS.
00:13:34 And this was the conceptual idea of the heated nebulizer,
00:13:37 a sprayer where the liquid would be sprayed through a heated tube to vaporize it
00:13:41 and then ionized by corona discharge in the ion source.
00:13:45 And this was the ion source that we had with the Tega at this time,
00:13:48 corona discharge ion source.
00:13:50 It turned out that it was a bit more complicated than that.
00:13:55 Droplets didn't just evaporate in the gas phase.
00:13:57 We finally had to nebulize it to a very fine mist
00:14:00 and try to ensure that the droplets actually impacted on the walls of this heated tube
00:14:04 in order to vaporize and without decomposing these fairly fragile molecules.
00:14:10 So we did a lot of work on optimizing the sprayer
00:14:13 and the gas flows around here and the mixing
00:14:15 to make sure these were fully vaporized
00:14:17 and what we called flash vaporized on the walls of the tube.
00:14:21 We ran this heater at about 450 degrees centigrade
00:14:25 in order to maintain the walls hot enough.
00:14:27 Of course, the sample was never exposed to that kind of temperature.
00:14:30 But you needed that to get where this liquid was impinging
00:14:33 the temperature enough to flash vaporize the liquid at that sort of flow rate.
00:14:36 But it scared a lot of people at the time to see a temperature controller
00:14:39 reading 450 degrees for an LC interface
00:14:41 and thinking that their sample was actually exposed to that temperature.
00:14:48 We used dexamethasone as our thermometer for this compound.
00:14:51 This is the parent ion here at mass 333
00:14:54 and this was a decomposition product at mass 333
00:14:57 and we could tell when the temperature of the probe was too low
00:15:00 because you got this more fragmentation and tailing on the fragment ion.
00:15:04 So this was a matter of turning up the heat
00:15:07 in order to get better chromatographic integrity and less decomposition.
00:15:13 This was the heated nebulizer probe as we commercialized it
00:15:16 in about 1983 or 1984
00:15:19 as an inlet on the Tega 6000 triple quad
00:15:22 which was mostly an environmental application instrument at that time.
00:15:27 But we had this inlet probe designed
00:15:29 and again, not many people took up that torch
00:15:32 except for Jack Hennion and his group at Cornell
00:15:35 who really picked up the torch on this and carried it forward
00:15:38 and developed a lot of really beautiful applications
00:15:41 for LC-MS using atmospheric pressure ionization.
00:15:44 This is a picture of the probe on the Tega instrument in their lab
00:15:48 in about 1984, the Tega 6000.
00:15:51 And they did some beautiful applications of that, of course,
00:15:54 simultaneous with working on taking electrospray and turning it into ion spray
00:15:58 and making it a very practical LC-MS instrument.
00:16:01 That was eventually where ion evaporation ended up
00:16:04 was with ion spray and electrospray as very practical implementations
00:16:07 of this spray electrification process.
00:16:13 And this is really a quintessential, I think a beautiful application
00:16:16 that was done at Cornell in those years, 1985-1986
00:16:19 of very rapid quantitation.
00:16:21 This is a pharmacokinetic study, basically,
00:16:24 doing with the heated nebulizer
00:16:27 from administered phenylbutazone to a horse
00:16:30 extracts of plasma and urine interjected with standards
00:16:33 at the rate of one sample a minute using an autosampler
00:16:36 doing LC-MS-MS and measuring
00:16:39 quantitating on the residual
00:16:42 parent drug plus the metabolites, the number of metabolites.
00:16:45 And this was done at a milliminute with a very short
00:16:48 small particle column, a 3 micron
00:16:51 by 3 centimeter long column.
00:16:54 And separations actually in less than a minute
00:16:57 for each of these. So these were 60 samples injected
00:17:00 in an hour's time, one a minute.
00:17:03 So that's 10 years old and it stands amongst
00:17:06 the best of the LC-MS-MS today
00:17:09 and the applications it's being put to in these high throughput
00:17:12 quantitation labs.
00:17:15 And you can see that even in that
00:17:18 doing this MRM study, they were separating in the course of
00:17:21 less than a minute metabolites, oxyphenylbutazone
00:17:24 and hydroxyphenylbutazone from the parent drug
00:17:27 in that time. So that was really cutting edge LC-MS.
00:17:30 This is a parent ion scan now for the same
00:17:33 sample showing separation of
00:17:36 3 or actually 4 metabolites plus the parent drug by
00:17:39 scanning, doing a parent ion scan and monitoring mass 93
00:17:42 which is common to all of these fragments. And that was published in
00:17:45 1986. So
00:17:48 the final thing I want to recognize here in terms of pioneers
00:17:51 are some of the visionaries who really eventually
00:17:54 took these methods and turned them
00:17:57 into practical instruments and started to use them
00:18:00 in their laboratories and show the rest of the world what could be done
00:18:03 with these atmospheric pressure techniques. People like
00:18:06 David Wang-Iverson of the Sanfuda and the pharmaceutical
00:18:09 labs, Jerry DiDonato. They were some of the early visionaries
00:18:12 who took the chance on this new dedicated
00:18:15 LC-MS method, an instrument that later became
00:18:18 the API-3 and started to
00:18:21 make it the popular method that it is today.
00:18:24 Thank you very much.
00:18:35 Are there any questions for Bruce?
00:18:46 I have one. The original
00:18:49 API work used steel wool.
00:18:52 Did you ever do that?
00:18:55 That's a story that Jack will tell you in the next talk. Yes, it did.
00:18:58 No, we didn't follow up on that.
00:19:04 Thanks, Bruce.
00:19:10 The next speaker
00:19:13 is Jack Hanyon
00:19:16 and his topic is
00:19:19 From DLI to Ion Spray and LC-MS
00:19:22 MS and
00:19:25 LC-MS Journey.
00:19:28 Thank you, Ross. I have mixed feelings about giving a lecture like this.
00:19:31 It's an indication of age when you're talking about history.
00:19:34 I'm a long ways from being ready to stop this stuff.
00:19:37 I'd like to start
00:19:40 with LC-MS as I have seen it.
00:19:44 The first slide. There we go.
00:19:47 If we could get that focused a bit and take you through
00:19:50 what I would see in my
00:19:53 world, the steps that were important to me
00:19:56 in leading us to where we are in our laboratory now.
00:19:59 I'm going to talk about direct liquid induction. This goes back
00:20:02 a few years before Bruce just entered into the
00:20:05 picture he talked about. I'm going to talk about atmospheric pressure
00:20:08 ionization for LC-MS. It will pick up on what he described
00:20:11 in ion spray or pneumatically assisted electrospray.
00:20:14 That's where we're going on this journey.
00:20:17 I hesitate to put my in here. These are not milestones in LC-MS.
00:20:20 These are milestones in my world of LC-MS.
00:20:23 There are certainly other milestones that we all know about.
00:20:26 I purchased a Finnegan system
00:20:29 in 1974 and
00:20:32 first started taking a look at direct liquid induction
00:20:35 in March of 75.
00:20:38 In 77 was when we moved to micro-LC-MS
00:20:41 to get better sensitivity.
00:20:44 In 81 where I saw what Bruce just described
00:20:47 at Asilomar. That was a pivotal point to me at Asilomar
00:20:50 to see those results he just showed you.
00:20:53 They were extremely exciting to me. I distinctly remember that day
00:20:56 and Neil Reed gave a talk that showed their instrument
00:20:59 which I had never even heard about SIACS of course then.
00:21:02 It had a box. All these things leading to their instrument.
00:21:05 It was an empty box and I said I think I can help you fill in that box.
00:21:08 We've been down a long road since that time.
00:21:11 And then ion spray as you just heard it described
00:21:14 a little bit. I want to tell you what led us to that.
00:21:17 Barriers to development.
00:21:20 There's a lot of negative people in all areas
00:21:23 and there certainly was an incompatibility mindset.
00:21:26 Mass spectroscopists including myself didn't want to think about
00:21:29 putting liquid into the mass spectrometer. We take that for granted now
00:21:32 although I remind you that we don't put it into the mass spectrometer.
00:21:35 We spray at it and we put ions in it. That's what we want after all in the first place.
00:21:38 There was clearly a mindset in those days that we didn't want to
00:21:41 dirty these instruments and burn the filament out.
00:21:44 That was a barrier for sure. There was little precedence
00:21:47 other than Horning's work that you just heard.
00:21:50 I too acknowledge his pioneering efforts there
00:21:53 as well as the demonstration of the feasibility of DLI
00:21:56 by Mike Baldwin and Professor McLafferty
00:21:59 in the early 70s.
00:22:02 The other comment was why not just collect the peak and put it in the probe.
00:22:05 You can still think about that. We still see that with
00:22:08 Maldi right now. I want to see online Maldi, true online Maldi
00:22:11 LCMS. I once made the mistake of saying
00:22:14 you'd never see online fab and I've learned not to
00:22:17 say that anymore so I'm not going to say we're not going to see online
00:22:20 and of course there have been some feasibility demonstrated but I don't think
00:22:23 any of us want to buy it yet.
00:22:26 That was a mindset and an immature LC equipment.
00:22:29 I made a lot of enemies. I still seem to be able to do that
00:22:32 by criticizing equipment. The Waters equipment was a joke
00:22:35 in terms of competing with a tank of helium.
00:22:38 In 1974 and 5 and 6
00:22:41 those pumps went in and out. They went in and out
00:22:44 but I mean their flow rate went in and out and everything was all over the place
00:22:47 and it couldn't deliver a steady stream of solvent and we depended
00:22:50 upon a steady stream of that effluent. So those were barriers
00:22:53 to make this work. Why bother to? Every
00:22:56 technique you should answer this question, is this worth doing?
00:22:59 Well GCMS was certainly showing practicality
00:23:02 and this was 1974 now so you've got to have a mindset
00:23:05 some of you may not have even been around at that time
00:23:08 but GCMS was in its infancy and clearly starting to be
00:23:11 sold and work and it was clear to me that HPLC
00:23:14 was going to be a technique that was going to be
00:23:17 important and we needed to know what those peaks were
00:23:20 and that's why I do LCMS. And separation science
00:23:23 and mass spectrometry are just a natural combination
00:23:26 not natural that it's easy to put them together but natural that we need them together
00:23:29 that if you're going to have a chromatographic peak and a separated mixture
00:23:32 you want to have a mass spectrum of those peaks. So that was why bother
00:23:35 to me. Why we embarked on this
00:23:38 Why won't my advancement go?
00:23:41 Parallel technologies at that time, micro HPLC
00:23:44 techniques were just beginning very very much in their infancy
00:23:47 and I soon learned that if we were going to get more sensitivity we had to
00:23:50 reduce the flow. API mass spectrometry
00:23:53 you just heard about that from Bruce that was on the horizon
00:23:56 it was there and only a few of us saw it. There was a lot of people
00:23:59 that just didn't buy into it. Tandem mass spectrometry
00:24:02 that was an exciting area. I remember taking the two or three day course
00:24:05 at Purdue with Graham and colleagues to learn
00:24:08 and become familiar with that. And then this ion evaporation interface
00:24:11 that Bruce just described. That was terribly exciting. That was pivotal
00:24:14 for me to see those results that he just showed at El Silamar in 1981
00:24:17 I distinctly remember that. Now let me take you on these
00:24:20 benchmarks in my laboratory and my experience
00:24:23 with this thing where I bought that Finnegan twin stack
00:24:26 in 1974 and in March of that year
00:24:29 started doing what we now call infusion or even
00:24:32 FIA, trying to get ion current. And it was not until
00:24:35 a year later that we actually did it online. And this was
00:24:38 off hours in the night time
00:24:41 when the service laboratory could be used for interesting things.
00:24:44 The interface, if you will, was a glass
00:24:47 tube. It was quarter inch OD
00:24:50 and I can't remember the inside diameter, 100 microns
00:24:53 or so. And when I see all this nano spray it just makes me
00:24:56 shiver to think of all the headaches I used to have with a 5 micron hole here
00:24:59 plugging this thing. And it was just dumb determination
00:25:02 that kept me going. I could not and I never did
00:25:05 promote that everybody should do this. This was headache city.
00:25:08 This was enough to drive you to beating your kids and drinking alcohol
00:25:11 and everything. You literally had
00:25:14 success by playing the odds. And I could tell you many
00:25:17 stories that I won't. But this was ground down
00:25:20 to fit inside the ion source of the Finnegan 3300
00:25:23 and I did it on a belt sander in the machine shop. I had to take a
00:25:26 course to get the key at night. To graduate from the course
00:25:29 you got the key at night and I'd go in and put it on a belt sander
00:25:32 and I'd get these broken down. I'd take a spare source to make sure it fit
00:25:35 I'd get impatient and push too hard and it would break it right off.
00:25:38 Right there. So you make lots of these things. And it was real fun
00:25:41 to demonstrate that they were open by putting high pressure helium
00:25:44 on here and shooting it across the laboratory at 300 PSI.
00:25:47 That's a real shocking experience.
00:25:50 And of course it bounced off the walls and I never told
00:25:53 the department too much about that. I did always
00:25:56 make sure I stayed away from it. I need some help with balancing. There we go.
00:25:59 There's that glass tube. Literally you could buy this
00:26:02 in a meter length and cut it off. I spent a lot of time making it.
00:26:05 There's the split. A new probe valve. This was a split
00:26:08 at 1 mL per minute. About 1% would go into the mass spectrometer.
00:26:11 There's the inlet of the 3300. And this was clearly the Achilles heel.
00:26:14 It was a much worse Achilles heel than we have now.
00:26:17 But keeping that open was a pain. I had a T there with a septum in it
00:26:20 where I could inject if I didn't
00:26:23 get squirted in the eye because this was under high pressure.
00:26:26 There wasn't a reodine injector or a Velco injector at that time.
00:26:29 And I learned soon the importance of eyeglasses
00:26:32 in the laboratory because I would inject through the septum
00:26:35 and either the plunger would go to the ceiling or the liquid squirt out of my face.
00:26:38 So there was no chromatography there. It was just getting it to work.
00:26:41 That's why I say it was a year later before we actually got online results.
00:26:44 But that was the early DLI. This probably
00:26:47 was one of the first HPLC systems on wheels, on a cart
00:26:50 that we all now do. This belonged to Jerry Meinwald
00:26:53 in the Department of Chemistry at Cornell and I knew he had it
00:26:56 and I said, if I put it on a cart and build this thing
00:26:59 and give it to you, can I use your HPLC after hours?
00:27:02 And he was on the fifth floor and I was on the second and I would literally go up
00:27:05 and wait for his students to be done with it and come down and work all night long
00:27:08 off hours to make this work and couple it with the Finnegan 3300
00:27:11 and did quite a lot of that.
00:27:14 This is just one example. I used to experiment with colors and slides
00:27:17 and this was one of the failures, but these are corticosteroids
00:27:20 and this was online DLI LC-MS.
00:27:23 We had fragmentation not from ion chemistry
00:27:26 but from heat, the hot ion source, and we did a lot of things
00:27:29 with that, but that was a hard way of doing it.
00:27:32 This was an improvement, believe it or not.
00:27:35 This is a photograph that Bob Boykster made
00:27:38 in, I don't remember when, 79 or 80.
00:27:41 This is the direct probe, the DLI probe that Hewlett-Packard
00:27:44 marketed and Extrel at the time also co-marketed this device
00:27:47 and had a diaphragm pinhole here
00:27:50 and we sprayed that in. This replaced the glass probe
00:27:53 and believe it or not, it was a big improvement, although it still had that little hole.
00:27:56 1% of the total effluent went through.
00:27:59 This was HP's drawing at the time. The diaphragm, a laser drilled
00:28:02 5 micron hole right there and effluent
00:28:05 at 1 mL per minute from the LC would come by, go past
00:28:08 that hole, squirt into the ion source, the mass spectrometer.
00:28:11 99% would go to the bottle on the floor. We'd use water,
00:28:14 cooling water, in here to cool the tip because it was in contact
00:28:17 with the ion source. It was usually 250 C or greater.
00:28:20 That was an advance for DLI. The biggest advance
00:28:23 is you didn't blast anything against the wall when it slipped off the pressure
00:28:26 device. You just replaced the diaphragm pinhole and
00:28:29 sonicated it and played the odds. I like this one
00:28:32 because it made the mass spectrometer look like a tractor or a steam engine
00:28:35 because one way to increase the pumping
00:28:38 in a simple way is to cryopump and we now know
00:28:41 that. HP had a big thing that
00:28:44 you could pump nitrogen in and the thing would erupt like this every once
00:28:47 in a while and after a while I got used to it but in early days
00:28:50 it would scare me and anybody around me but this was the Hewlett-Packard
00:28:53 5985B that did an awful lot of this work.
00:28:56 These are compounds trichloromethazide
00:28:59 and reserpine. Heckling drug testing days and I'm taking
00:29:02 the days when I moved across campus out of the chemistry department to the
00:29:05 racehorse drug testing program and I defy you even today
00:29:08 to get these through without druidization through GCMS.
00:29:11 Trichloromethazide, diuretic, reserpine. If you all wonder why
00:29:14 everybody's using reserpine, it's from horses. It's a great tranquilizer.
00:29:17 I wouldn't want to show in this mixed audience what
00:29:20 reserpine does to a horse. Ask me in private and I'll tell you.
00:29:23 But it's tough to do it at 10 pg per ml.
00:29:26 In fact, this was 1981 or 2
00:29:29 and only recently did we have a paper in Jazz Mass
00:29:32 where we showed 10 pg per ml by
00:29:35 LCMS, API LCMS of that compound
00:29:38 in horse urine. It's very low levels.
00:29:41 And this was 3 micrograms, I think, negative ion
00:29:44 of each of these compounds and that was done by the
00:29:47 HP DLI probe. Showed it could be done. Here's the mass spectrum
00:29:50 positive ion. Many of us know that very well. Negative ion
00:29:53 detection. So that was a breakthrough. This extended what you could do
00:29:56 by GCMS. Now we move to micro LCMS because
00:29:59 it's in this racehorse drug testing business and trace analysis is
00:30:02 real important in that area and we needed to get more
00:30:05 sensitivity and my colleague on the bench
00:30:08 right down there, Bill McFadden, brought to my attention this.
00:30:11 1976, Bill. I visited Finnegan and you showed me a photocopy
00:30:14 a bad photocopy, I might add. I couldn't read the address
00:30:17 of the Jasko Familic micro LC system.
00:30:20 And I purchased that thing in 1976 or
00:30:23 7 and we still have it. We don't use it for micro LC
00:30:26 but we use it for infusion, if you will. Delivering it
00:30:29 instead of the other little pump. It's a true syringe pump
00:30:32 and it actually had a syringe. Glass syringe which would break.
00:30:35 The column was there. It was Teflon tubing and this
00:30:38 operated at 5 to 20 microliters per minute and really did
00:30:41 give us an increase in sensitivity. I converted
00:30:44 or modified the DLI probe
00:30:47 from HP to a micro LC DLI probe.
00:30:50 So this is a homemade one with the same diaphragm in there.
00:30:53 So the total effluent. The key was that micro LC, the total effluent
00:30:56 and no more split and their peak concentration was higher
00:30:59 and we had better sensitivity. And we pushed back the limits
00:31:02 there. I used to jokingly say that this technique is real easy. I always
00:31:05 admitted that it wasn't. But you could show that a young child
00:31:08 could do this, which was my son at the time. Now he's
00:31:11 three times that high. But the probe is inside
00:31:14 the mass spectrometer. The micro bore column
00:31:17 this is usually 25 centimeter long.
00:31:20 One millimeter ID was part of the probe and the injector was right there.
00:31:23 And it really did improve sensitivity. Well then we used
00:31:26 this micro pump from ABI at the time or actually Bob Brownlee
00:31:29 the late Bob Brownlee generously provided that. We still had that very
00:31:32 instrument working in our laboratory.
00:31:35 And these are results that were representative of what we do. Tom Covey
00:31:38 personally did these. This is diethylstibestrol. The key is tissue
00:31:41 and urine analysis. You need good sensitivity. Here's a UV chromatogram
00:31:44 and this my friends, manufacturers and users are what
00:31:47 chromatograms from mass spectrometers are supposed to look like
00:31:50 without smoothing. Not ratty peaks and crummy stuff. We want
00:31:53 accurate areas of those things. And when you do it right, when the moon is right
00:31:56 and you've got a good person like Tom Covey, this is what chromatograms can look like.
00:31:59 This is 50 nanograms.
00:32:02 I think it was selected ion monitoring at the time. Easily detecting that sort of
00:32:05 level. So that's what microLCMS did to us
00:32:08 for us by DLI. But I knew at that time
00:32:11 that that was a hard way to make a living.
00:32:14 And it was tough. And it was only blind, dumb determination that pushed us.
00:32:17 And when I saw the capability of atmospheric pressure ionization
00:32:20 that Bruce just talked about, I knew I had to get involved
00:32:23 in that. Even though I had seen Elvin Horning's work
00:32:26 in the early 70's, I didn't
00:32:29 catch on until I could see that there was a commercial instrument that I could
00:32:32 somehow get access to. I used to show this slide
00:32:35 and people would, either it didn't sink in. You ever try to get a duck wet?
00:32:38 They don't get wet. It doesn't sink in. You've got to
00:32:41 wash them with soap before they really get wet. And people were like ducks.
00:32:44 They couldn't conceive that you could make ions at atmospheric pressure.
00:32:47 What a difference 10-15 years makes.
00:32:50 So we don't have to show that slide anymore.
00:32:53 This is a TAGA 6000. It was before it was called
00:32:56 an E. They extended it from 450 mass range
00:32:59 to the massive mass range of 1200.
00:33:02 And that was what the early TAGA
00:33:05 looked like. TAGA, I might add, was trace atmospheric
00:33:08 gas analyzer. The thing was made to put in a van and drive around a dump
00:33:11 site and sniff the air. No LCMS.
00:33:14 It was people like us that suggested maybe we could do LCMS.
00:33:17 Well there is the HP DLI probe. This was Peter Dawson's
00:33:20 instrument at NRC in Ottawa. And I saw
00:33:23 and talked with the Sykes folks in
00:33:26 Minneapolis in 1981. 3? 1983
00:33:29 I think. And made a date. This was
00:33:32 June 83 and by
00:33:35 July 1st, just before our July 4th
00:33:38 I think that's when it was. And early, very early July, less than a month later
00:33:41 I was in their laboratory. Bruce Thompson met with me
00:33:44 in Peter Dawson's lab. And I had solvents and real samples.
00:33:47 And this was a physics laboratory and they didn't know. We had an audience
00:33:50 of physics people. We heard comments earlier about physics folks
00:33:53 and how we ought to work with them. But they were in awe that we were doing
00:33:56 real chemistry. And so that probe was converted.
00:33:59 I went there with the understanding that Bruce was going to somehow
00:34:02 help me make this work. And it took urine extracts and so forth.
00:34:05 And that was our first LCMS results. This is the origin of the
00:34:08 pneumatic nebulizer. This messy
00:34:11 looking thing that got real hot and black. We worked one week intensely
00:34:14 from early in the morning to late at night. And accomplished it.
00:34:17 There's a chronodischarge needle. And that became the heated pneumatic
00:34:20 nebulizer. This is the drawing we had in the 82 paper
00:34:23 or 80 whatever year it was. Analytical chemistry.
00:34:26 And Ross asked about stainless steel or
00:34:29 mesh, wire mesh. The way we finally made this thing work. This is the
00:34:32 DLI probe with a pinhole diaphragm. I spent all week trying to
00:34:35 keep that open. And did so. This is the nebulization
00:34:38 coaxially. And this is a, I think it was a
00:34:41 platinum mesh that Peter somehow
00:34:44 had laying around. Until we put that in there, it didn't work very well.
00:34:47 We had to break up those droplets. But that probe allowed us to get
00:34:50 these results. A UV chromatogram and extract ion
00:34:53 chroma profiles. MSMS for urine extracts of
00:34:56 sulfa drugs. I see today there's a poster on sulfa drugs.
00:34:59 Sulfa drugs work very well with this technique. And I believe
00:35:02 this was the first real world application of online LC-MSMS
00:35:05 in this paper. I want to show you with interest
00:35:08 this. You can't see this very well. These mass spectra
00:35:11 are from a HP data system. The science data system
00:35:14 in 1980, whatever it was, was a dog.
00:35:17 And I took numbers and entered it into the
00:35:20 HP data system. And that's the way I plotted the spectra. I never omitted that in the paper.
00:35:23 But their data system didn't make the mass spectra plots like I
00:35:26 wanted to. I still have some concerns here and there. But
00:35:29 we'll talk about that. This is the instrument
00:35:32 that Bruce showed you. I spent almost
00:35:35 two years drumming up 525,000 U.S. dollars.
00:35:38 At that time, in 1984, that was a lot of money.
00:35:41 And EPA finally funded our work. And CyEx, to their credit,
00:35:44 let us earn off the last chunk of it. About a third
00:35:47 of it. And Tom Covey was a new student with me. And this is in that
00:35:50 blank laboratory right after we got it. And we got it just days before
00:35:53 ASMS in 1984. So we could say we really did
00:35:56 have a triple quadruple for ASMS. Of course, nobody asked or cared.
00:35:59 At that time, this was our business.
00:36:02 This was the working end of our laboratory animal.
00:36:05 This was actually not a real one.
00:36:08 I have a story about Tom Covey hijacking this horse
00:36:11 with a truck in the wintertime. But in any case, there were times
00:36:14 with this early instrument that I wanted to get a real horse, lift the tail, and let it
00:36:17 really come out. But this was the origin
00:36:20 of our, the exit, I guess, of our DLI interface.
00:36:23 We did away with that with that pressure tubing, if you can see it.
00:36:26 But we did a lot of equine drug testing. Where is that sensor up back there?
00:36:29 And this is the heat and pneumatic nebulizer that you heard about.
00:36:32 And Bruce described that. And with that, we did
00:36:35 this work that he showed. This was one minute window
00:36:38 from there to there. That's the story he described.
00:36:41 And this was paradigm scanning. And that was a real exciting thing for us.
00:36:44 I might give you one little story that the autosampler injecting
00:36:47 every minute needed a graduate student to put, whose name
00:36:50 was Ed Lee at the time, to put the sent vials in the
00:36:53 same hole. Because the autosampler spent too much time reaching over and getting
00:36:56 to the, and we still have that problem to these days. Autosamplers don't work
00:36:59 fast enough. My time is up. Oh, iron spray.
00:37:02 How could I miss that? Is my time really up? Yeah.
00:37:05 Alright. Iron spray. These are the key people.
00:37:08 This is the father of iron spray, Andres Bruins, who
00:37:11 came and wanted to do electric spray. I said, go for it. He spent three
00:37:14 weeks of headaches and said, there's got to be a better way.
00:37:17 Tom Covey, who was there at the time, and Ed Lee, and that threesome was a
00:37:20 hell of a team in that time to make this work.
00:37:23 And this is this ion evaporation interface that Bruce described.
00:37:26 And it was from that that we got the pneumatic nebulization idea for iron spray.
00:37:29 It was not a novel idea. And we could get spectra like these that we know
00:37:32 now we can regularly get. That was our original drawing
00:37:35 in 86 in Cincinnati. I'm almost done, Ross.
00:37:38 That's the system as we designed it and
00:37:41 built it. And it looked like this. And Sykes copied that and
00:37:44 made that plastic front end, as you're all familiar with. These are students.
00:37:47 Some people are surprised I have so few students, but it's quality, not quantity,
00:37:50 that helps. And these folks have done a great job.
00:37:53 Postdocs, a number in this area. And these
00:37:56 three are here with me at the present time at Cornell.
00:37:59 And these are visiting scientists that have come and stayed in my laboratory.
00:38:02 Andres Bruins at the top of the list, chronologically.
00:38:05 And key people, Timothy Wachs, who is still with me,
00:38:08 keeps things going when I travel and do other things. And these other people,
00:38:11 and they kept veterinary college. And these are the people that make
00:38:14 things possible by giving money. And almost all these people
00:38:17 are still currently providing the research.
00:38:20 I'll close with just one group shot of several people
00:38:23 of these representative people. So I thank you, Ross, for the opportunity to
00:38:26 present this. And sorry it was so fast, but thank you very much.
00:38:29 Applause
00:38:32 Applause
00:38:35 Applause
00:38:38 We're very proud today to have Bill McFadden
00:38:41 come out of retirement and honor us
00:38:44 with some of his stories
00:38:47 about the early days in LC-MS.
00:38:50 Bill's title is
00:38:53 LC-MS, How Did We Ever Do It?
00:39:02 What am I doing here?
00:39:06 When Ross Willoughby called me
00:39:09 and asked if I'd like to give a review paper,
00:39:12 I pointed out to him that I have been
00:39:15 completely inactive in mass spectrometry
00:39:18 for eight years. Well, you know,
00:39:21 he sort of rubbed my ego a little bit and said,
00:39:24 oh, that's all right, Bill. We don't need to hear anything new.
00:39:27 All we want to do is hear about the wonderful things you used to do.
00:39:30 And so I thought, that's good.
00:39:33 But what I didn't realize at the time
00:39:36 was when I started to bring out my material,
00:39:39 I'd forgotten everything I used to do.
00:39:42 So in any event,
00:39:45 I feel a very appropriate title is
00:39:48 How Did We Ever Do This?
00:39:51 And on the first slide, am I supposed to do something here?
00:39:54 Do I get these?
00:39:57 Nobody instructed me and I
00:40:00 I hate to waste a whole minute and a half
00:40:03 just getting a slide. It says
00:40:06 forward, hit forward.
00:40:09 This first slide
00:40:12 really says it all.
00:40:15 I have here the, do you hear me
00:40:18 when I talk this way, away from the mic?
00:40:21 Good. I have here a very old slide
00:40:24 which shows a comparison
00:40:27 between the conditions for gas chromatography
00:40:30 and liquid chromatography.
00:40:33 And if we look down here, carrier, chemical nature,
00:40:36 gas additives, stability of samples and so on,
00:40:39 everything is beautiful. And I used to tell people
00:40:42 in the sixties, gas chromatography is easy,
00:40:45 just get into it and don't worry about it.
00:40:48 But when we come over here to liquid chromatography,
00:40:51 we find everything is
00:40:54 unacceptable. We have high flows
00:40:57 of a carrier gas, somewhere in the range of about
00:41:00 a hundred times more than we could possibly
00:41:03 want to consider. We're going to add horrible
00:41:06 buffers to this thing.
00:41:09 And we're going to want to work with samples
00:41:12 that we can't evaporate into a mass spectrometer.
00:41:15 So it really is a very big problem.
00:41:18 And looking at it in the
00:41:21 1960s and 1970s,
00:41:24 we know why we wanted to do it. GCMS
00:41:27 was so successful. But
00:41:30 we also had the emergence
00:41:33 of high pressure liquid chromatography,
00:41:36 a very important thing that sort of catalyzed
00:41:39 together and people said we've got to have liquid chromatography
00:41:42 with mass spectrometry. Now
00:41:45 this slide shows the first four people
00:41:48 that really published in this subject. And I think
00:41:51 it's very interesting to point out the first of these
00:41:54 was done in Russia by Tallrose in 1968.
00:41:57 Shortly I'll show the slide
00:42:00 and we'll see that his results were not wonderful,
00:42:03 but he must be credited as giving the introduction
00:42:06 of this game. From there,
00:42:09 and I'm wanting to emphasize how everybody
00:42:12 really builds on something that happened before them.
00:42:15 Fred McLaperty, very cleverly,
00:42:18 said the trouble with Tallrose is he
00:42:21 took a very small amount of his sample into the mass spec
00:42:24 and he wanted to do electron impact.
00:42:27 We'll take a larger amount and we'll
00:42:30 do chemical ionization. And that was
00:42:33 what Fred came out with, building as I say
00:42:36 on what Tallrose had done with the original DLI.
00:42:39 At about the same time
00:42:42 we had Ray Scott, who was a chromatographer
00:42:45 but well known
00:42:48 around a lot of mass spectrometry
00:42:51 in the 1960 period.
00:42:54 And he came along with a moving wire.
00:42:57 This moving wire, a picture of which I'll show you later,
00:43:00 was available commercially
00:43:03 and it had been used to take sample off a liquid
00:43:06 chromatograph, evaporate the solvent
00:43:09 and take it into a flame ionization detector.
00:43:12 So that's where the
00:43:15 moving wire system came from. And then of course
00:43:18 we've already heard a great deal of the
00:43:21 comments about Evan Horning's work with the
00:43:24 atmospheric pressure ionization. Names that should
00:43:27 be on here are Dave
00:43:30 Carroll and Zydig, Ismael Zydig.
00:43:33 And they were the people in the
00:43:36 laboratory who were actually doing the work.
00:43:39 And where did the idea come from for this API?
00:43:42 Dave Carroll had worked with a company that made
00:43:45 this drift mass spectrometer.
00:43:48 Kind of a poor instrument actually because the resolution was
00:43:51 terrible. It wasn't a mass spectrometer at all and
00:43:54 operated at high pressure and just let ions drift down
00:43:57 a tube. But they used an atmospheric
00:44:00 pressure ionization source, so that's what he
00:44:03 was dealing with. Now, on the next slide
00:44:06 this is the work of Talrose.
00:44:09 And we look very quickly, we see, my gosh
00:44:12 the chromatography is slow, very wide
00:44:15 peaks. He was doing electron impact
00:44:18 on compounds, methylene and benzene
00:44:21 and naphthalene that weren't very important for
00:44:24 electron impact anyway. And his sensitivity
00:44:27 was incredibly low because of the fact that
00:44:30 he was taking such a small amount into the
00:44:33 mass spectrometer. Of course, as I say then
00:44:36 Fred McLaperty said, let's take
00:44:39 a larger amount and we'll use
00:44:42 the solvent in the carrier as
00:44:45 the chemical ionization gas. Very brilliant concept
00:44:48 at the time because chemical ionization had been fairly
00:44:51 well established, but we also had very well controlled
00:44:54 gas, methane and butane and helium
00:44:57 and it depended what you wanted to do with it.
00:45:00 Now again, here was the chromatogram from
00:45:03 a UV detector and you'll notice
00:45:06 kind of bumpy peaks he was getting off of these
00:45:09 steroids, but one must always remember
00:45:12 when you're looking at the first results that somebody
00:45:15 comes out with, they don't always
00:45:18 look so good, but they're the pioneers and the ones that we've
00:45:21 got to respect. And the next slide
00:45:24 was, oh, I'm sorry, I'm a little out of
00:45:27 line, it doesn't matter. This slide then is the work that
00:45:30 Horning did. Horning and Dave Carroll
00:45:33 and Ziddig was the API source.
00:45:36 And you might say, how in the world
00:45:39 did we see in 1974
00:45:42 this kind of work going on and we didn't
00:45:45 seem to pay any attention to it? Well, it's
00:45:48 not as if we didn't pay attention to it. I actually
00:45:51 spent two times going down to Horning's lab, spent
00:45:54 two or three very delightful weeks with them,
00:45:57 but what was driving us
00:46:00 at the time was electron impact.
00:46:03 Everybody wants electron impact
00:46:06 so they can compare with the standard
00:46:09 spectra. And when you said, well, we have this
00:46:12 nice API source and it gives pretty
00:46:15 good results, as you can see, a selected ion
00:46:18 monitor here, derivative of glycine,
00:46:21 people weren't interested in that.
00:46:24 And, you know, in case you think, well, did we all
00:46:27 just forget about it? Somewhere in the middle
00:46:30 70s, at a meeting in
00:46:33 St. Louis, we had a whole symposium on API
00:46:36 sources. So it was in front
00:46:39 of us. But, you know, it's hard to say.
00:46:42 Should we be driven by our
00:46:45 customers? I think the answer is yes
00:46:48 because the customer is ultimately the one that's
00:46:51 going to buy an instrument. But on the other hand,
00:46:54 you might feel that the scientist
00:46:57 should just go in there and do his work and do what he
00:47:00 thinks is right. The problem with that is you've
00:47:03 always got to get a sponsor. So we're driven
00:47:06 by a lot of things, not just what we want to do.
00:47:09 And then I promised, as I promised,
00:47:12 the result of Ray Scott. And it was
00:47:15 really quite good. This is the result of a
00:47:18 fermentation extract. This is the
00:47:21 ultraviolet. No, this is the ultraviolet.
00:47:24 This was a total ion monitor of it.
00:47:27 And this was a selected ion monitor of it. And as
00:47:30 you can see on the selected ion monitor, quite
00:47:33 good separations and very nice looking spectra.
00:47:36 Well, what comes next
00:47:39 now? Oh, I thought I should show you this
00:47:42 little slide. Here are these wires, these
00:47:45 tubes of wires that come in through a vacuum lock,
00:47:48 in through the mass spectrometer and out again.
00:47:51 And the problem with that, of course, was you could only hold a
00:47:54 very small amount of sample on this wire.
00:47:57 So we at Finnegan thought
00:48:00 about how we can improve in this because it had the advantage of
00:48:03 electron impact. And we felt, well, we'll go
00:48:06 from that and we'll put a broad belt
00:48:09 on it where we can take more sample.
00:48:12 But in addition, there were other things going on. There
00:48:15 were attempts, for example, at membranes. They have the
00:48:18 disadvantage that a membrane, of course, has
00:48:21 your solvent and solute
00:48:24 are going to have fairly close polarities.
00:48:27 Since they've got such close polarities or personalities,
00:48:30 if you like, it's very difficult to get a separation
00:48:33 on them. Look, here is, got Bruce
00:48:36 Thompson's name here and he was starting to do the ion
00:48:39 evaporation that we've just heard of at that time.
00:48:42 1976. We had,
00:48:45 as I mentioned, we expanded the belt to
00:48:48 take a larger amount of sample.
00:48:51 And then, of course, there was direct liquid introduction.
00:48:54 That was an extension of McLafferty's and it was primarily
00:48:57 pioneered in the commercial world
00:49:00 by Hewlett-Packard with Malera, one of the
00:49:03 important, Malera and Chris
00:49:06 Kenyon being the important developers in
00:49:09 that. And then, of course, about that same time
00:49:12 in this late 70s, we had
00:49:15 Marvin Vestal, Gene Fertel, and Takauchi
00:49:18 in Japan doing nebulization
00:49:21 and which, in a related way, with
00:49:24 the DLI work. Now this, again,
00:49:27 you start to think of this and you see this all together and you say,
00:49:30 gee, there's the DLI. Now we're starting to get
00:49:33 to nebulize it. And if you think of all the things that are
00:49:36 commonly being used today, you see there's a
00:49:39 whole pattern of the whole picture and it's actually
00:49:42 come together. And I only
00:49:45 regret that I haven't been able to be a part of it.
00:49:48 This machine, you've already seen it from a picture
00:49:51 from Jack Henion. And I've
00:49:54 often wondered why in the world chromatographers
00:49:57 cannot be browbeaten into going to
00:50:00 liquid chromatography. This is the Jasko
00:50:03 Familic, a commercial instrument that was
00:50:06 available in the middle 70s. I used to
00:50:09 implore people, if you want to do
00:50:12 LC-MS, go to micro-LC
00:50:15 because then you've reduced your problems by a
00:50:18 factor of 100. That's a big reduction in a
00:50:21 problem, you know. How many people could I convince?
00:50:24 A few Brits. They're very brave souls.
00:50:27 Jack Henion, who I
00:50:30 was delightfully grateful that he acknowledges
00:50:33 my contribution there. But the real
00:50:36 thing is, even today
00:50:39 the chromatographer is still
00:50:42 reluctant to go
00:50:45 into the small quantity. Why? He says,
00:50:48 Well, we can't get as good as separations,
00:50:51 we can't control our pumps as well, and
00:50:54 we've got all our methods worked out. Well, of course you have.
00:50:57 But if you don't try the other, you're never going to get it.
00:51:00 And if you look on your program today, it's rather
00:51:03 interesting that right on the top of our today's
00:51:06 program, on the next column,
00:51:09 there's a micro-LC
00:51:12 paper being given, or was given in one of the other
00:51:15 sessions. Now, I thought you might
00:51:18 be interested in seeing the kind of results that you could get
00:51:21 with a belt using
00:51:24 small columns and low flows. This was done
00:51:27 on aflatoxins. We have
00:51:30 this is the UV, we have the total ion monitor,
00:51:33 and we have the four samples here
00:51:36 showing very nice separation, very nice
00:51:39 results. But how
00:51:42 interested are people? These are electron impact, by the way.
00:51:45 How interested are people in doing that? If you've got to
00:51:48 use a liquid, sorry, a micro-liquid
00:51:51 chromatograph, we don't want it.
00:51:54 Now, I want to show a couple of results
00:51:57 that were available
00:52:00 in this period.
00:52:03 This was done by
00:52:06 Thruston and McGuire, EPA people,
00:52:09 in 1980 on a tannery extract.
00:52:12 Quite good results, nothing extremely
00:52:15 hard, dihydroxy, whatever that is,
00:52:18 I can't, phenylpropanol, not the hardest
00:52:21 compounds in the world, but not a bad piece of LC-MS
00:52:24 work. At the same time, we also
00:52:27 had a great deal of work being
00:52:30 done by Hewlett-Packard, and this is the kind of results
00:52:33 they were showing. The slide doesn't show up quite so well,
00:52:36 but this is Hewlett-Packard work
00:52:39 done by Chris Kenyon on these sugar derivatives.
00:52:42 Incidentally, how many people can see this fuzzy
00:52:45 little thing down here? Can you see that at all?
00:52:48 Or is this, it's hidden out, is it? Well, it doesn't matter.
00:52:51 It's not important at all. These are old slides,
00:52:54 you know, and since we're no longer allowed to put
00:52:57 the names of the
00:53:00 sponsor or
00:53:03 manufacturer on a slide, I had to take and block
00:53:06 that fuzzy little thing out. That's the F-word that you might
00:53:09 guess.
00:53:12 Now,
00:53:15 going on, where are we going from here?
00:53:18 We've got DLI, and we've got
00:53:21 the belt. Both of them are showing plenty of
00:53:24 results, and there's a lot of customers. A hundred
00:53:27 people or so using these things around the world in the
00:53:30 late 70s, but it wasn't enough.
00:53:33 We knew we had to get more, and look at what
00:53:36 we're doing. We had thermospray.
00:53:39 Marvin Vestal will be talking about that, and that was
00:53:42 discovered in the late 70s, a serendipitous
00:53:45 result. And in this time,
00:53:48 1980 or so, 84, 12
00:53:51 papers. That's a rather interesting historical
00:53:54 fact that we'll talk a little bit more about.
00:53:57 Suchiya was doing liquid surface ionization,
00:54:00 and more work was coming out of Thomson's lab.
00:54:03 And also, perhaps one of the biggest things we've
00:54:06 seen to date, Dr. Finn, Whitehouse,
00:54:09 and Yamashita published on the
00:54:12 electrospray. Again,
00:54:15 coming back to the idea that we all
00:54:18 stand on someone else's shoulders,
00:54:21 the first electrospray was actually done by
00:54:24 Malcolm Dole in about 1960 and published
00:54:27 in 1968. And if
00:54:30 Malcolm had been around a lot of good mass spectrometers,
00:54:33 it's just possible that the work of Finn
00:54:36 would not have been 1984. It might have been 1974.
00:54:40 But again, it took people to sort of pick up on these
00:54:43 things and see just what
00:54:46 all has been done.
00:54:49 Another important point, of course, at this stage is
00:54:53 Dr. Browner and Ross Willoughby were coming out with
00:54:56 aerosol generation. And their reason
00:54:59 was exactly the reason why
00:55:02 I worked with
00:55:05 the Bell. They wanted to get electron impact systems.
00:55:08 And this has turned out to be the more popular
00:55:11 electron impact system because
00:55:14 the Bell had two kinds of people.
00:55:17 Those who could make it work and those who couldn't make it work.
00:55:20 And unfortunately, I think there were more
00:55:23 of the latter. And as a consequence,
00:55:26 they were saying, I don't want this darn belt rumbling
00:55:29 through my ion source. I once heard it
00:55:32 sort of compared to a gardener having an
00:55:35 elephant sort of walking around through his garden.
00:55:38 And they felt this was not a nice thing
00:55:41 to do to a mass spectrometer.
00:55:44 And in addition, at that time, we had a lot of interest
00:55:47 in supercritical fluid chromatography.
00:55:50 Somehow or another, that seems to have gone on the wayside.
00:55:53 But it was back in that
00:55:56 middle 80 period, there were some very important
00:55:59 developments coming along there.
00:56:02 And so just to continue on,
00:56:05 other important trends that were coming along were
00:56:08 thermospray in this period was the most prominent.
00:56:11 I think there's no question that from about 1980
00:56:14 up until the latter part to about
00:56:17 1990, thermospray was clearly the most
00:56:20 important LC-MS system. And it was
00:56:23 providing good sensitivity
00:56:26 and ease of operation. And now
00:56:29 what is not so here is it could be
00:56:32 coupled up with another new thing coming
00:56:35 in mass spectrometry, what is today very common,
00:56:38 MS-MS in its various many forms
00:56:41 today. Of course, at the beginning,
00:56:44 in my particular environment, we used to think of that as a
00:56:47 triple quad. But there's other things too.
00:56:50 And continuous flow fab
00:56:53 was starting to come along.
00:56:56 And also, we were just on the edge of starting to see
00:56:59 zone electrophoresis. Now,
00:57:02 I believe that's my last slide.
00:57:05 Oh no, this is slide two of three, but I'm not showing the third one.
00:57:09 Other things, micro-LC
00:57:12 was starting to be used a little more
00:57:15 and they're showing that there are a variety of techniques
00:57:18 you can start to get electron impact from if you use
00:57:21 micro-LC. These were
00:57:24 the Stenhagen group in Sweden and
00:57:27 Takauchi and Ishii. Ishii was very, very
00:57:30 he was the Japanese that would really push micro-LC.
00:57:33 And also, aerosol
00:57:36 beam generation was coming along and that
00:57:39 was perhaps the main basic development.
00:57:42 Now, in 1989,
00:57:45 we had five new laboratories reporting
00:57:48 on LC-MS. That almost
00:57:51 sounds silly when you think of it, but
00:57:54 look at this slide.
00:57:57 In the 80s, we had less than 20 papers at these meetings
00:58:00 on LC-MS. Of course, it came along
00:58:03 quickly, so that by the time we're out to the 90s,
00:58:06 we're somewhere in the range of 150 papers.
00:58:09 Now, I'm not going to bother to take into account
00:58:12 how many we've got here today. I leave that as an
00:58:15 exercise to the student.
00:58:18 Anyway, my last slide.
00:58:21 The important thing today is our work with high molecular
00:58:24 weight. Why do I show a crummy
00:58:27 cartoon like this? And the important
00:58:30 thing about this cartoon isn't even on it.
00:58:33 Not mass, but we mentioned, gee, I shouldn't
00:58:36 have tried mass 2500. This
00:58:39 cartoon was, came out, we
00:58:42 came out with this or saw this about
00:58:45 1978. And in
00:58:48 1978, it was a big deal to
00:58:51 think of mass 2500. In fact, we used to
00:58:54 at that time, we were trying to improve it and expand
00:58:57 our range into 1000. And so
00:59:00 you can see how far we've come in the last
00:59:03 decade or two. I
00:59:06 really wish I had been a bigger part of it, but I wasn't.
00:59:09 I want to thank Ross very much for
00:59:12 having me here. And I want to say that it's
00:59:15 been a pleasure. And with a little bit of luck,
00:59:18 maybe 10 years from now, you'll have another paper back
00:59:21 here, or sorry, another symposium back here.
00:59:24 And I'll be invited to give a paper again.
00:59:36 I meant to warn you it'll be the same paper.
00:59:44 That's pretty good for
00:59:47 being a little rusty, Bill. That was a great lecture.
00:59:50 The next
00:59:53 speaker is Marvin Vestal,
00:59:56 20 years lost in the interface between
00:59:59 LC and Mass Spec.
01:00:02 Ross, it's certainly a pleasure to be here.
01:00:05 It's nice to be on a program where I'm not the oldest
01:00:08 speaker.
01:00:14 These are hard acts
01:00:17 to follow, but fortunately I get to speak before John
01:00:20 Vestal, so I know we'll get the last word.
01:00:23 I just wanted to say one personal thing about Bill.
01:00:26 Bill and I both graduated from the University of Utah.
01:00:29 I think he was about 20 years ahead of me.
01:00:32 But we both
01:00:35 benefited from being mentored by Austin
01:00:38 Baroftig, who's one of the people in this business that
01:00:41 I think not many people know as well as they should.
01:00:44 But he's certainly been a great help to me at the
01:00:47 University of Utah.
01:00:53 That's my title, and I asked my colleagues
01:00:56 at Perceptive to come up with a suitable cartoon to illustrate this,
01:00:59 but they were all too busy getting ready for their own presentation,
01:01:02 so you'll have to imagine what you like.
01:01:05 I was thinking of some bald-headed old scientist
01:01:08 sort of bewildered between a dripping faucet
01:01:11 and an instrument, but you'll have to imagine
01:01:14 for yourself.
01:01:17 Bill did a lot of this already,
01:01:20 so I won't repeat it all, but when I was thinking about this,
01:01:23 I thought, you know, what were the things that
01:01:26 had gone before this in mass spectrometry, which kind of led us
01:01:29 to where we were when we started out.
01:01:32 Going back to the
01:01:35 is this the pointer?
01:01:38 Going back in the 30s, there was some work by Loeb
01:01:41 and his students on spray ionization,
01:01:44 and in particular, a paper by Chapman in 1938
01:01:47 where he observed ions in a mobility apparatus,
01:01:50 which clearly were the right mobility to be solvated
01:01:53 in molecular ions. He didn't do any mass spectrometry,
01:01:56 so of course, none of us took it seriously.
01:01:59 I must confess, I wasn't even aware of this paper until sometime
01:02:02 in the late 70s when we started observing ions and we were trying
01:02:05 to explain where they came from. But he certainly observed
01:02:08 ions from spray ionization back in the 30s.
01:02:11 And of course, Dole's work has already been alluded to also,
01:02:14 where he was making ions by spray techniques, but wasn't able
01:02:17 to do mass spectrometry on them, so we never took it seriously
01:02:20 until John showed us the error of our ways.
01:02:23 Also in this period was chemical ionization,
01:02:26 which was really kind of the first new ionization technique
01:02:29 which allowed people to get molecular ions on things
01:02:32 that were otherwise difficult, so it gave us an alternative
01:02:35 to electron impact. And I think field desorption
01:02:38 was kind of the first technique that really
01:02:41 started dealing with non-volatile molecules.
01:02:44 The first laser desorption work was in 1972,
01:02:47 not with LC separation, but with the
01:02:50 showing that you could start to get less volatile materials
01:02:53 in this way, and the other work that's been referred to
01:02:56 in terms of the pioneers of LC-MS.
01:02:59 And the last one on here, which you may not be able to see,
01:03:02 but it's behind the table,
01:03:05 is the work that Friedman and his coworkers did at Brookhaven
01:03:08 where they showed that fast heating from relatively
01:03:11 inert surfaces allowed you to get quite non-volatile
01:03:14 molecules into the gas phase as ions.
01:03:17 They did some small peptides and so forth,
01:03:20 and it was really this work that led us to thinking about
01:03:23 how we might do LC-MS on relatively non-volatile molecules.
01:03:33 Is there a focus on that?
01:03:36 This is basically the same table as Bill showed, at least my version
01:03:39 of his table, and so I won't belabor it as what the problem was,
01:03:42 but I think the major problem with LC-MS
01:03:45 is that, as he said, people wanted
01:03:48 to do one milliliter per minute of aqueous
01:03:51 effluent. If you couldn't do that, they really
01:03:54 didn't think it was a serious LC-MS technique.
01:03:57 And they also wanted to do electron impact, if possible,
01:04:00 because they wanted to be able to compare with the library.
01:04:03 So that was kind of the boundary conditions
01:04:06 that we had going into the game.
01:04:09 So Calvin Blakely and I, who had
01:04:12 built a cross-beam apparatus for doing ion-molecule
01:04:15 reactions, in which we studied complicated systems
01:04:18 like H3 plus colliding with D2, et cetera,
01:04:21 and got data ad nauseum on the
01:04:24 reaction cross-sections, et cetera,
01:04:27 proposed to NIH in, I think, 1975
01:04:30 to build what we called a cross-beam LC-MS.
01:04:33 And this is a schematic diagram of that apparatus,
01:04:36 which I think may even be from the proposal,
01:04:39 I'm not sure, in which we used
01:04:42 six diffusion pumps, varying from a small
01:04:45 4,200 liter per second here, which is a fat 10-inch
01:04:48 pump, a 4-inch pump, and
01:04:51 several smaller pumps, a huge mechanical pump pumping
01:04:54 on this vaporization region. There were six
01:04:57 mechanical pumps, I believe, and five diffusion pumps,
01:05:00 and a CO2 laser. Because what we
01:05:03 proposed to do was take a liquid jet out of the
01:05:06 end of a tube here, which we knew would come up,
01:05:09 and in a reduced pressure region
01:05:12 hit that jet with a CO2 laser.
01:05:15 So this is where the cross-beam idea came from. We were going to
01:05:18 vaporize the sample in free space without it touching
01:05:21 any surfaces, because we knew if it touched surfaces, we would get
01:05:24 pyrolysis. And we wanted to be able to
01:05:27 vaporize intact, non-volatile molecules, and then ionize them
01:05:30 by either electron impact or by chemical ionization.
01:05:33 So the elaborate pumping was to get the pressure low enough to do
01:05:36 electron impact. The electron impact source was
01:05:39 let's see, where was that? That was down here, I believe.
01:05:42 We produced chemical ionization up here,
01:05:45 and anyway, a very
01:05:48 elaborate apparatus, and Calvin dug out of his file,
01:05:51 being very well organized, he dug out an old picture of this
01:05:54 apparatus, which you may or may not be able to see.
01:05:57 It looks a little dark in this.
01:06:00 We really did have an LC on it. Here it is. It's a Perkin-Elmer
01:06:03 syringe pump LC, which was, I think, the world's
01:06:06 largest LC, and it fit very well
01:06:09 with the rest of the apparatus, as you can see.
01:06:12 The CO2 laser is up on top here. The beam went down
01:06:15 through here. There's a 12-inch aluminum cube here, which is
01:06:18 the center of the world, with pumps coming out in all directions.
01:06:21 It looks rather neater than it was because the mechanical pumps
01:06:24 were over here in the other room. There was a small hole in the wall here
01:06:27 where the lines went through. Well, this system
01:06:30 actually worked, and it worked well enough for us to get our NIH
01:06:33 grant renewed so we could go on and do some more work,
01:06:36 and I think that's the main purpose that this apparatus
01:06:39 served, was to get us started.
01:06:42 We did do both EI and CI spectra.
01:06:45 Mary Jane McAdams, alias Finney,
01:06:48 got her PhD thesis running a lot of
01:06:51 samples on this instrument. This is
01:06:54 CI and EI spectra on this
01:06:57 molecule here. I don't think you can see the EI spectrum,
01:07:00 but it's there.
01:07:03 So we were able to get both kinds of spectra, and this
01:07:06 worked, actually, up to about a half a milliliter per minute.
01:07:09 We were trying to do one milliliter per minute, but we really couldn't do EI
01:07:12 spectra above about a half a milliliter a minute.
01:07:15 This shows the driving force behind
01:07:18 this was to be able to do matching
01:07:21 with the library. This is adenosine, which we considered a rather
01:07:24 non-volatile molecule in those days. It didn't give a
01:07:27 real strong molecular ion, but you can see in the library it's there,
01:07:30 and it's also there in our spectrum. So we were able to match
01:07:33 the libraries of a number of compounds
01:07:36 with the spectra that we were getting
01:07:39 from this apparatus. This shows the sort of
01:07:42 kind of sensitivity that we were able to get. This is 80 nanograms injected
01:07:45 of hexachlorobenzene
01:07:48 in the negative ion mode, which admittedly was a fairly favorable case
01:07:51 because it's a strong electron capturing. And we have
01:07:54 a paranoid here blown up by a factor of 10. And of course,
01:07:57 this is chlorine and Cl2 minus, which are not very interesting,
01:08:00 but were there as a result of this sample.
01:08:03 And we really did do LC-MS on this. I believe this is
01:08:06 from this period and not later. Some of these slides
01:08:09 kind of run together after a while, but I think this is from
01:08:12 Mary Jane's thesis. These are some polynuclear aromatic
01:08:15 compounds. In fact, I recognize these. These are anthracene
01:08:18 and phenanthrene, that doublet there, which is resolved.
01:08:21 Respectable LC-MS under the most favorable conditions,
01:08:24 although when I think about how hard we had to work
01:08:27 to get some of these data, it looks easier now than it did then.
01:08:31 Well, we went from that apparatus. We realized after a while
01:08:34 that heating the, well, actually I forgot
01:08:37 the most important part of it. It didn't really work as advertised.
01:08:40 We weren't able to vaporize the liquid jet by
01:08:43 hitting it with a CO2 laser. Because when you try to
01:08:46 heat liquid droplets with a laser in free space, they
01:08:49 start evaporating. They evaporate on one side and they go off
01:08:52 the other direction. And so that never really
01:08:55 worked. In fact, we tried it. What we found is we made
01:08:58 beautiful ice sculptures inside of our vacuum
01:09:01 system. And so we decided we had the
01:09:04 world's most expensive ice machine.
01:09:07 But if we moved the laser over a little bit so we heated
01:09:10 the end of the capillary tube, we discovered we in fact could
01:09:13 vaporize the liquid and we could get good spectra. And
01:09:16 somewhat to our surprise, even relatively labile molecules
01:09:19 like adenosine worked perfectly okay this way.
01:09:22 So, well, we thought maybe we don't have to heat over such a small
01:09:25 region after all. So if we're going to heat only the end
01:09:28 of a tube, a laser seems like kind of the hard way to do it.
01:09:31 It's a little moist. So our next idea is thinking we
01:09:34 still needed to have a very high power density
01:09:37 in order to vaporize over a very small region. Otherwise
01:09:40 we would get pyrolysis. So the next
01:09:43 most dense source we could think of was an oxy-hydrogen
01:09:46 torch. Which, from a practical
01:09:49 point of view, there may be some problems with this. But in fact
01:09:53 we did make this work. This was actually a ray of four torches
01:09:56 around the capillary tube. Now this was all atmospheric
01:09:59 pressure now, so we vaporized, shot into the
01:10:02 vacuum system with a skimmer.
01:10:05 Any particles or droplets hit this
01:10:08 heated probe here, were vaporized, and we were only doing
01:10:11 chemical ionization with this. We gave up on the electron
01:10:14 impact fairly early, realizing that the amount of pumping
01:10:17 required to do this was probably not worth the trouble and that
01:10:20 we would really accept it as a useful technique.
01:10:23 So we produced ions, deflected them into a quadrupole
01:10:26 analyzer, and the rest is fairly
01:10:29 well known. This instrument actually was moved to
01:10:32 Jim McCloskey's laboratory, who was one of our collaborators
01:10:35 in this early work. And in fact it was through his efforts that
01:10:38 we were able to get the NIH grant in the first place, because he was well
01:10:41 known in biological mass spectrometry.
01:10:44 The rest of us were physical chemists, and at that time
01:10:47 it was very suspicious of physical chemists coming along trying to get money
01:10:50 out of the granting system.
01:10:53 Klaus Biemann was the chairman of the
01:10:56 site visiting committee that gave us the money, and the fact that Jim
01:10:59 had been one of his students, I'm sure helped immensely
01:11:02 in his review of our proposal.
01:11:05 So, this instrument
01:11:08 was actually moved to Jim's lab. It was
01:11:11 in continuous service, more or less, until about a year ago
01:11:14 when it was finally taken out of service,
01:11:17 and he published an enormous amount of excellent work, particularly
01:11:20 on identifying previously unknown nucleosides using this instrument.
01:11:23 Now we did, as time went along, replace this with different
01:11:26 versions of the vaporizer, which I will mention a little bit
01:11:29 later.
01:11:32 I should wait to show this one.
01:11:35 While we were evaluating this instrument, and trying to tune it up and figure
01:11:38 out how to make it work better, John Carmond and I,
01:11:41 who was one of my students at the University of Houston,
01:11:44 we were doing a series of experiments in which we were
01:11:47 injecting adenosine to see how the system responded,
01:11:50 and at one point
01:11:53 we noticed that the response had changed rather markedly.
01:11:56 We were getting a lot more molecular ion, and things were rather
01:11:59 different, but we obviously had found the magic tuning
01:12:02 condition, so it worked. At that point, Calvin Blakely
01:12:05 walked in and looked at the instrument, and looked at some of the dials
01:12:08 with red currents and so forth, and he said,
01:12:11 and watched this peak come out, and he said,
01:12:14 did you inject that sample before or after the filament burned out?
01:12:17 And we said, well, we must have injected it before,
01:12:20 because clearly the filament had burned out because the emission gauge was
01:12:23 reading zero, but just for the fun of it, we injected another sample,
01:12:26 and sure enough, we still got a signal.
01:12:29 I don't know whether this is the actual
01:12:32 original data, but it was taken within a few days
01:12:35 of that observation. This is adenosine
01:12:38 injecting one microgram, just a flow injection experiment.
01:12:41 This is with the filament on, and you can see we're getting a small
01:12:44 molecular ion here. We have a peak here
01:12:47 which has a little tail on it, which is mainly the 136 fragment
01:12:50 ion, and lots of background in our total ion current.
01:12:53 At this point, we turned
01:12:56 the filament off.
01:12:59 In fact, this is the 136 trace, I'm sure. There was a little bit of tailing
01:13:02 on the 136. This is the total ion current.
01:13:05 We turned the filament off intentionally this time,
01:13:08 and did a couple more injections, and you can see we got a very strong
01:13:11 molecular ion signal, a very weak fragment ion signal,
01:13:14 and almost no background.
01:13:17 Well, we scratched our head about this a little bit,
01:13:20 and we had kind of looked a few times for ions without having the filament on,
01:13:23 not really expecting to see anything.
01:13:26 And I have to confess, at this point, even though they had published
01:13:29 a paper a few months earlier than this using mass spectrometry
01:13:32 for ion evaporation experiments, at the time we made this
01:13:35 observation, I was totally unaware of Bruce Thompson
01:13:38 and Ehrbarn's work, and was somewhat
01:13:41 embarrassed when I went to the Journal of Chemical Physics,
01:13:44 and I think it was an issue of the journal which also
01:13:47 had one of our papers on a different subject in it,
01:13:50 but I had not read his paper, of course, because I wasn't really
01:13:53 interested in what he was doing, or at least I didn't know that I was interested in it
01:13:56 at the time, and discovered that they'd already explained a lot of these phenomena
01:13:59 that we later realized were responsible
01:14:02 for ion evaporation, or what we
01:14:05 called at the time direct thermospray ionization, but clearly
01:14:08 it's very closely related to what he was observing
01:14:11 and what electrospray has made even more
01:14:14 prominent lately.
01:14:17 Well, obviously even an
01:14:20 oxyhydrogen torch is not a very good way to heat the end of a tube,
01:14:23 and we started increasing the length
01:14:26 of the heated region. Our next version used a
01:14:29 copper block about an inch long in which we put some cartridge
01:14:32 heaters, and vaporized directly into the chemical ionization
01:14:35 source, extracted the ions
01:14:38 out to the mass spectrometer, and this was really kind of the
01:14:41 first commercial version of the thermospray system.
01:14:44 It worked quite well, and we found that
01:14:47 even though we heated over a longer length, it didn't
01:14:50 make any difference. We still got about the same kind of results. In fact, we got
01:14:53 rather better results than we were able to get with the oxyhydrogen
01:14:56 torch, because we could control this much more accurately.
01:14:59 About this time, Gordon Ferguson, who's in the audience,
01:15:02 joined us at the university
01:15:05 and said, gee, that's, you know, if we
01:15:08 heated the whole, just heated the capillary tube directly by conduction,
01:15:11 we could have really good control over it, and we could put thermocouples
01:15:14 along it and really monitor what's going on.
01:15:17 And so he developed the electronics and
01:15:20 really was the one who did that work of
01:15:23 going to a probe that had a
01:15:26 heated capillary, and this is
01:15:29 an example of a spectrum from that system
01:15:32 which we, the first time we saw really large non-volatile
01:15:35 systems, we could see glucagon, and
01:15:38 somewhat to our surprise, as we got up to larger molecules,
01:15:41 we started seeing higher charge states. This is the 3 plus
01:15:44 and 4 plus states of glucagon.
01:15:47 We probably had the 1 and 2 plus too, but our quadrupole mass spectrometer
01:15:50 was really struggling by the time it got to mass 1200, so we
01:15:53 really couldn't look any higher than that. And
01:15:56 several of my students and associates applied this to things like
01:15:59 peptide sequencing, and I intended to have a slide
01:16:02 of that, but it got lost in the shuffle somewhere.
01:16:05 But quite a lot of work was done sequencing peptides
01:16:08 by enzyme digestion
01:16:11 using immobilized enzymes on columns.
01:16:14 But we were at the nanomole level to be able
01:16:17 to do this. Typically 1 to 10 nanomoles of sample
01:16:20 was required, and that was not really acceptable
01:16:23 to the protein chemists. This is the
01:16:26 version that really became the standard for thermospray,
01:16:29 the heated capillary, and we found we could
01:16:32 heat over a very long length and still get good results.
01:16:35 And the reason for that is shown on this slide
01:16:38 where we've measured, in fact Gordon, I believe,
01:16:41 did these experiments initially. We put thermocouples all along the tube
01:16:44 so we could measure the temperature along the tube, and
01:16:47 the interpretation of this profile is that you're getting,
01:16:50 you start to get vaporization at some point in the tube, it continues
01:16:53 and if you put too much heat in, you get complete vaporization
01:16:56 before you get out of the tube, and then you do get pyrolysis
01:16:59 and all sorts of bad things happening. But if you control
01:17:02 the heat input so that this interface
01:17:05 moves out to the end here, then you can get nebulization
01:17:08 and only partial vaporization
01:17:11 and it works beautifully, and that's the way that thermospray
01:17:14 was done, and I guess is still done in some places
01:17:17 these days. So we coined
01:17:20 this word thermospray to define what we were doing.
01:17:23 It was contrary to some
01:17:26 people's suggestion, and I think Bill may have been responsible for this
01:17:29 suggestion first, that it really meant
01:17:32 equal applications of heat and prayer was what was required
01:17:35 to make it work. That was not really the
01:17:38 actual coining of the word was
01:17:41 here. I guess I'm out of time.
01:17:44 I would like to just put this into a little bit
01:17:47 of context of the other developments in LCMS
01:17:50 and ionization techniques. We were developing
01:17:53 thermospray in the 80s here, and Bill
01:17:56 alluded to some of this before,
01:17:59 but I think what happened in 1988
01:18:02 has changed the world as far as mass spectrometry
01:18:05 and LCMS is concerned. Of course, that's electrospray and MALDI,
01:18:08 and these are the techniques which we are
01:18:11 working on presently, and I think everybody else is in
01:18:14 one form or another who are interested in large non-volatile molecules.
01:18:17 I will skip our other
01:18:20 contributions to LCMS, which are more recent and
01:18:23 probably not so exciting, and conclude with the acknowledgments
01:18:26 of the people who really did all of this work. My colleagues
01:18:29 at the University of Utah helped get this started, including
01:18:32 Charlie Edmonds, who worked in Jim McCloskey's lab and did a lot of the
01:18:35 beautiful early applications. Calvin Blakely you will see all the
01:18:38 way across here because he's been a vital part
01:18:41 of my efforts in this area from the beginning until recently.
01:18:44 We are continuing to do some LCMS work at
01:18:47 Perceptive, but I'm not talking about that now. These students
01:18:50 in particular are the ones who
01:18:53 did most of the work that I'm talking about now.
01:18:56 I'd like to just finish with a photograph.
01:18:59 Hank Fales is responsible for this.
01:19:02 I don't know whether he's in the audience or not, but that's Hank there
01:19:05 if you don't recognize him from about 20 years ago.
01:19:08 He came down and spent a sabbatical few months with us in
01:19:11 Houston, and while he was there he bought
01:19:14 t-shirts for the group. His says, I guess that's supposed
01:19:17 to be honorary or ornery. I'm not sure which vestal is virgin.
01:19:20 And this is the head virgin down here.
01:19:23 Mary Jane McAdams was the one who did
01:19:26 the early work with the LCMS. This is Calvin Blakely
01:19:29 if you don't know him. Dwayne Harden did some work with laser
01:19:32 desorption for moving belts, and Joe Hiller worked
01:19:35 on photo dissociation. Julie Robeson
01:19:38 went off and got a degree and became an MD
01:19:41 so she's really successful. Thank you very much.
01:19:44 There's a change in the program today.
01:19:47 Professor Briner had the flu
01:19:50 and couldn't make it
01:19:53 to the meeting this year.
01:19:56 Fortunately, the organizer of this session was a graduate
01:19:59 student at Georgia Tech
01:20:02 about 15 or 20 years ago
01:20:05 when particle beam was developed.
01:20:08 So I am honored to be here today
01:20:11 True to form
01:20:14 with Professor Briner
01:20:17 I call him Rick now
01:20:20 because it's a few years after I graduated.
01:20:23 The time I was at Georgia Tech, it was Professor Briner.
01:20:26 He would always
01:20:29 drop things off at me
01:20:32 and say, you know,
01:20:35 I'm not going to do this anymore.
01:20:38 He would always drop things
01:20:41 on you at the last minute.
01:20:44 Friday afternoon at 5 o'clock he gave me a call
01:20:47 and said that he wasn't coming to the session today.
01:20:50 I was faced with the responsibility of preparing
01:20:53 a lecture. So I do not have polished
01:20:56 slides, but I do have some insights
01:20:59 about the early days and hopefully
01:21:02 from a graduate student's perspective
01:21:05 it may be of interest to you.
01:21:21 Since I didn't have a title slide, I was asked
01:21:24 to give a plenary lecture at the Aerosol Conference
01:21:27 a year or so ago. The title was Aerosols
01:21:30 and Analytical Chemistry. Ignorance is not always bliss.
01:21:33 I thought that might be appropriate for this lecture
01:21:36 because when I went to Georgia Tech
01:21:39 in 1977
01:21:42 I was a first year graduate student.
01:21:45 Professor Briner was a
01:21:48 first year assistant professor.
01:21:51 I was sort of the first group of graduate students.
01:21:54 Professor Briner had worked in
01:21:57 Weinfurtner's group as a post-doc
01:22:00 and really had distinguished himself
01:22:03 more in the field of atomic spectroscopy
01:22:06 than either liquid chromatography or mass
01:22:09 spectrometry. But he had an idea that
01:22:12 possibly there could be
01:22:15 some advancement in the field of LC-MS
01:22:18 if someone took a different perspective
01:22:21 and really looked at the aerosol process
01:22:24 more thoroughly rather than
01:22:27 the traditional mass spec approach looking at ions
01:22:30 or the liquid chromatography approach looking at condensed
01:22:33 phase.
01:22:36 So I thought that was fairly interesting.
01:22:39 I picked a graduate
01:22:42 advisor a year or so later
01:22:45 and was excited about
01:22:48 starting a career in LC-MS.
01:22:51 I read the reviews by Bill McFadden in the late 70s.
01:22:54 There was an excellent review by Fred McLafferty
01:22:57 and Patrick Carpino and George Guisson.
01:23:00 I didn't have a basis of
01:23:03 30 years of input to develop
01:23:06 or to attack this problem.
01:23:09 I really was a young graduate student
01:23:12 with not a technical basis learning how to do
01:23:15 research in a laboratory that
01:23:18 had no mass spectrometers
01:23:21 nor did we have a liquid chromatograph.
01:23:24 We didn't even have an LC pump.
01:23:27 But we did have a few instruments to measure particles
01:23:30 and some insights in aerosols.
01:23:33 So that's the perspective
01:23:36 that I began my career at Georgia Tech.
01:23:39 Just another comment.
01:23:42 This is
01:23:45 data, real data
01:23:48 from LC-MS.
01:23:51 Particle beam LC-MS in the early 80s
01:23:54 showing
01:23:57 the state of the pumping
01:24:00 world back in those days.
01:24:03 You see the reciprocating pumps
01:24:06 fluctuations in the baseline.
01:24:09 The world has come a long way
01:24:12 in the last 15 or 20 years
01:24:15 in terms of pump technology, fittings, and so on.
01:24:18 Another point of view, you see all my data
01:24:21 was collected on a strip chart recorder.
01:24:24 I didn't have a mass spectrometer until
01:24:27 four years into my thesis.
01:24:30 Basically, when the aerospace department
01:24:33 at Georgia Tech bought a new
01:24:36 CI Hewlett Packard GC-MS
01:24:39 they gave me their old
01:24:42 EI only instrument.
01:24:45 So I couldn't do any other ionization mode but EI.
01:24:48 So I didn't have a choice but to develop an LC-MS
01:24:51 technique that could do EI.
01:24:54 I only had a singly pumped system.
01:24:57 And the only way to detect signal on this instrument was a strip chart recorder.
01:25:00 The way I quantitated was by cutting and weighing.
01:25:03 So for those of you
01:25:06 who have PCs with 200 MHz
01:25:09 processors, only a few short
01:25:12 years ago people were still cutting and weighing.
01:25:15 You didn't have automated data reduction.
01:25:18 But you could still think about problems and solve problems
01:25:21 and look at processes.
01:25:24 So as I said,
01:25:27 I didn't have an LC
01:25:30 in this process.
01:25:33 This is some work
01:25:36 that I performed over about
01:25:39 a three and a half or four year period.
01:25:42 This work wasn't funded either.
01:25:45 More insight to graduate students.
01:25:48 So I used to have to get hangers and try to steal
01:25:51 stainless steel out of the stock room
01:25:54 through the cracks
01:25:57 in the mesh
01:26:00 and use the student shop.
01:26:03 I made just about every part that you'll see today
01:26:06 myself in a machine shop.
01:26:09 So maybe this is a lesson.
01:26:12 You don't have to be funded to solve problems either.
01:26:15 But it took me five and a half years to get my degree.
01:26:18 So if you're funded, you could probably do it faster.
01:26:21 So as I said,
01:26:24 I had a syringe pump
01:26:27 to deliver liquid to the system.
01:26:30 I machined all the parts.
01:26:33 This is a glass chamber.
01:26:36 I borrowed a roughing pump from the
01:26:39 physical chemistry group across the hall.
01:26:42 I did have a flange mount
01:26:45 with a conflat flange.
01:26:49 I could attach this device
01:26:52 to borrowed instruments in other labs.
01:26:55 So our approach was
01:26:58 to study the aerosol process
01:27:01 and hopefully
01:27:04 get rid of the solvent.
01:27:07 Bill McFadden pointed out in his review
01:27:10 very clearly that you needed a 10 to the 4th enrichment
01:27:13 of this liquid in an interface
01:27:16 to do EI.
01:27:19 So it was pretty straightforward for me.
01:27:22 I didn't have to read the old literature.
01:27:25 I just had to figure out a way to get rid of 99.99%
01:27:28 of all the stuff going into the system
01:27:31 and make sure that 0.01% was all solute.
01:27:34 That was pretty straightforward.
01:27:37 It was hard to do, but the problem was easy to define.
01:27:40 So the approach was to generate
01:27:43 particles. I used a Berglund-Lew design
01:27:46 that was published by an aerosol group
01:27:49 at Minnesota. It makes small uniform
01:27:52 particles. The problem was that this
01:27:55 picture is an idealized picture.
01:27:58 In reality, you don't get
01:28:01 an aerosol coming out
01:28:04 of an aerosol generator to go straight down the tube
01:28:07 and into the mass spectrometer. Usually it went off at a
01:28:10 dog-leg angle and stuck in the side of the wall.
01:28:13 You had droplets dripping, and that certainly
01:28:16 wasn't a very efficient or effective
01:28:19 LC-MS.
01:28:22 We deserted this design for
01:28:25 a more sophisticated approach.
01:28:28 We thought that we could control the direction of the
01:28:31 particles by using induction.
01:28:34 This was a standard technique.
01:28:37 Bruce Thompson alluded to using induction techniques to
01:28:40 charge his spray. Well, if you applied
01:28:43 several hundred volts to this
01:28:46 cylindrical electrode, you could charge the
01:28:49 uniform particles very
01:28:52 uniformly. Then we had
01:28:55 deflection plates, and we tried to
01:28:58 pulse the particles.
01:29:01 Again, the picture looks better than the performance
01:29:04 Most of the time, the liquid impacted with the walls,
01:29:07 and it was better on the drawing board
01:29:10 than in reality.
01:29:13 Another important point is, as we all know today,
01:29:16 charged particles don't follow straight lines.
01:29:19 They repel each other, right?
01:29:22 We know that this is a very divergent aerosol.
01:29:25 Again, the tubes coated with the aerosol
01:29:28 and nothing ever made it into the mass spectrometer.
01:29:31 How did we heat this system?
01:29:34 We learned something from that, and I had to steal some more
01:29:37 stock metals and build another system.
01:29:40 Actually, I used to have to buy
01:29:43 the glass blowers
01:29:46 cases of beer
01:29:49 to make all these
01:29:52 chambers were made out of glass.
01:29:55 I had to beg these glass blowers
01:29:58 to make all the parts. Each one of these systems
01:30:01 took probably three to six months to have made
01:30:04 because it was a slow, tedious
01:30:07 get-in-line process. But we won the intramural
01:30:10 softball championship at Georgia Tech, so
01:30:13 there were some side benefits.
01:30:16 This was just a more sophisticated version
01:30:19 of the last induction charge device
01:30:22 with more electrodes trying to control
01:30:25 the direction of charged particles in a vacuum
01:30:28 more clearly. What you see by this is
01:30:31 you have uniform droplets, you have uniform
01:30:34 charge on droplets, you have sophisticated optics
01:30:37 trying to control the direction. We tried to pump
01:30:40 more and more, and as
01:30:43 the more sophisticated we got, the more complex
01:30:46 we got, the result was really that you
01:30:49 collected liquid further downstream.
01:30:52 You weren't really
01:30:55 doing LC-MS.
01:30:58 Just another version.
01:31:01 These are all in my thesis, if you want to
01:31:04 I put
01:31:07 failures as well as successes in my
01:31:10 thesis. Again, this was a mesh design
01:31:13 longer. In fact, I had
01:31:16 a design that was over a meter long at one
01:31:19 time, and I actually quantitated the liquid
01:31:22 from one end to the other and found that I lost
01:31:25 virtually none of the liquid into the vapor phase.
01:31:31 So I decided that the meat machine shop
01:31:34 isn't really how I was going to solve this problem.
01:31:37 I think that maybe one of the lessons
01:31:40 of this is that
01:31:43 a PhD is supposed to be a research degree, a learning degree.
01:31:46 In this process, I was learning how to do research,
01:31:49 and building apparatus is probably not the
01:31:52 first place to start. It's certainly
01:31:55 time-consuming. So I went to the
01:31:58 library
01:32:01 and started to learn about
01:32:04 aerosol physics and about thermodynamics and about
01:32:07 the physical processes involved in creating
01:32:10 aerosols. This is just another version
01:32:13 of the vacuum system. Longer, more sophisticated,
01:32:16 another six months, but no
01:32:19 LC-MS.
01:32:22 Finally, I read a few
01:32:25 papers, and ha-ha, we weren't
01:32:28 evaporating any of the solvent. I wasn't getting the
01:32:31 10 to the 4th enrichment.
01:32:34 I got this huge infrared lamp, and I figured
01:32:37 Marvin could afford a CO2 laser.
01:32:41 I went to the hardware store and bought the biggest
01:32:44 infrared lamp I could.
01:32:47 I had been to the library. I had the calculations.
01:32:50 I actually figured out the radiant flux
01:32:53 after I built it, of course.
01:32:56 I was a slow learner.
01:32:59 It wasn't enough energy to evaporate the particle
01:33:02 going 10 to the 3rd centimeters
01:33:05 per second with that amount of energy.
01:33:08 I needed a laser if I wanted to do something like that.
01:33:11 After 15 years, Marvin said that the particles move
01:33:14 when you do that anyway, so I'm glad I didn't have
01:33:17 a laser.
01:33:20 I went on, and this is actually the first
01:33:23 particle beam,
01:33:26 or we called it magic interface.
01:33:29 The real revelation
01:33:32 or insight after all those previous
01:33:35 designs was that you don't spray into a
01:33:38 vacuum. You spray into atmospheric pressure.
01:33:41 Because you have high heat transport, you have
01:33:44 orders of magnitude more heat transport at atmospheric
01:33:47 pressure, and you could evaporate all the solvent
01:33:50 at atmospheric pressure, change the phase
01:33:53 or change the state of the mobile phase
01:33:56 components into the gas phase.
01:33:59 The less volatile solutes or analytes would stay as
01:34:02 microparticles.
01:34:05 Friedlander
01:34:08 had published a paper in the late
01:34:11 60s, I believe, describing
01:34:14 aerosol beams. It was very different than
01:34:17 molecular beams, but it was clear that you could have
01:34:20 highly collimated particle beams
01:34:23 with uniform particle
01:34:26 size, and you could shoot beams
01:34:29 over very long distances and remove the
01:34:32 gases radially. So, after those
01:34:35 insights were gained,
01:34:38 it was simple to develop an interface where you
01:34:41 simply desolvated at atmospheric
01:34:44 pressure, used the natural aerodynamic
01:34:47 processes and viscous forces to
01:34:50 drive the aerosol through a nozzle
01:34:53 and get your 10 to the
01:34:56 4th enrichment of solute on the axis
01:34:59 of a particle beam and remove all the solvent vapor
01:35:02 due to radial expansion.
01:35:05 And I have a few...
01:35:08 So, that's sort of the progression.
01:35:11 And I have a few slides of the early
01:35:14 devices.
01:35:17 Thanks, Jack.
01:35:27 This is just what it was all about.
01:35:30 Electron impact was not only the goal
01:35:33 at that time, but also the only alternative
01:35:36 I had since I had an EI-only instrument with one
01:35:39 small pump. I had to make it work
01:35:42 with a low gas load.
01:35:45 This is a collection of a particle beam
01:35:48 just to show you that, in fact, the solutes
01:35:51 did make it across a vacuum. These are dry
01:35:54 solute particles. This is the first
01:35:57 chromatograph, and I
01:36:00 found it in my slides. And actually, I
01:36:03 wasn't responsible for collecting it. Paul Winkler was
01:36:06 after I left. So, although I
01:36:09 probably get credit for this, Paul was actually the person
01:36:12 who did the first particle beam LC-MS
01:36:15 at Georgia Tech after
01:36:18 I left.
01:36:22 This is the first interface. All glass.
01:36:25 This is the desolvation chamber. This is the monodisperse
01:36:28 aerosol generator. This is a particle beam interface.
01:36:31 These are all the parts that I made by hand
01:36:34 in the shop. So, if I
01:36:37 can't make a living in mass spectrometry in the future,
01:36:40 I can always get a job in a machine shop,
01:36:43 I think, after that experience.
01:36:46 Anyway, this is a Hewlett-Packard
01:36:50 5930A,
01:36:53 if you recall.
01:36:56 And there's the strip chart recorder that I used to
01:36:59 collect data. And so, maybe the lesson is
01:37:02 go to the library,
01:37:05 think a little bit before you spend a lot of time building complex
01:37:08 apparatus. And I think, you know,
01:37:11 I've developed a philosophy over the years that you
01:37:14 really should look at fundamentals before you jump into
01:37:17 costly development projects.
01:37:20 And I learned the hard way. Ultimately, we had
01:37:23 an interface that had the same ion source geometry
01:37:26 as a traditional GCMS. And that was the goal.
01:37:29 You could essentially introduce
01:37:32 solute into a mass
01:37:35 spectrometer with an EI source and
01:37:38 tune and calibrate and operate
01:37:41 the instrument in the classical manner.
01:37:44 This is just to reinforce
01:37:47 that you basically look at fundamentals
01:37:50 before you waste a lot of time building
01:37:53 systems. And that's it.
01:37:56 Thank you.
01:37:59 This afternoon
01:38:02 is familiar to us all.
01:38:05 John Fenn, and his
01:38:08 title is Electrospray Ionization Mass Spectrometry.
01:38:11 The MS tail that wagged the LC dog.
01:38:20 Bill McFadden said that
01:38:23 he found when he sat down and started to think about what
01:38:26 he was going to talk about that happened some years ago, he'd forgotten
01:38:29 everything. Well, let me
01:38:32 tell him that he's got something to look forward to because I'm a bit
01:38:35 older than he is. And if
01:38:38 he waited till he was my age to sit down, he wouldn't remember
01:38:41 anything.
01:38:44 In fact,
01:38:47 I'm at the age now where
01:38:50 the famous Supreme Court Judge Oliver
01:38:53 Wendell Holmes is my role model.
01:38:56 He was active at the bench into his
01:38:59 nineties, if you remember. And there are a number of stories
01:39:02 about him. One of my favorite ones was
01:39:05 one afternoon when he was sitting on the veranda
01:39:08 of a country club with an octogenarian
01:39:11 friend of his as they were having a drink before going into
01:39:14 dinner. This barefoot young girl
01:39:17 came running across the lawn in front of him and behind her was a young
01:39:20 man chasing her. And as they passed
01:39:23 Holmes turned to his friend and says, isn't that a lovely
01:39:26 sight? That barefoot lass
01:39:29 tripping across the greensward and behind her in hot
01:39:32 blooded pursuit, that eager young man.
01:39:35 And his friend looked
01:39:38 and thought him on it and said, well, yes, Holmes, he said, but
01:39:41 I've forgotten why.
01:39:50 Actually, it was
01:39:53 a liquid chromatographer that got me into
01:39:56 electrospray, although he had
01:39:59 been tipped off by a
01:40:02 mass spectrometrist. And so
01:40:05 I became
01:40:08 fascinated with the
01:40:11 way electrospray works,
01:40:14 how ions are formed or not formed. And I've done
01:40:17 really very little in liquid chromatography.
01:40:20 And so I have forgotten why
01:40:23 the electrospray
01:40:26 is so important in LC.
01:40:29 We've heard ample reasons why it should be.
01:40:32 So you'll forgive me if I don't
01:40:35 do honors, do justification to the
01:40:38 chromatographic half of this
01:40:41 title.
01:40:44 To my knowledge, well, I'll just tell you, it was
01:40:47 John Woods who was working for VG up at the time who
01:40:50 discovered Malcolm Dole's paper in the Journal of
01:40:53 Chemophysics, and he brought it down to Yale. That was
01:40:56 the year after I got to Yale from Princeton
01:40:59 and showed it to Sandy Lipsky.
01:41:02 And Sandy Lipsky, who was a combination mass spectrometrist
01:41:05 and chromatographer, had a young man,
01:41:08 Chaba Horvath, working with him. Chaba Horvath was also
01:41:11 spending part of his time in the chemical engineering department.
01:41:14 And Sandy showed this paper to Chaba.
01:41:17 This was Malcolm Dole's first paper on electrospray.
01:41:20 And Chaba noticed that my name,
01:41:23 Dole had been kind enough to reference
01:41:26 some of our early papers on free jet
01:41:29 expansions and acceleration of heavy molecules by light ones.
01:41:32 And so Chaba said,
01:41:35 Hey, John Fenn has just arrived at Yale. You ought to come over and talk to him.
01:41:38 So Sandy Lipsky came over and showed me Malcolm Dole's
01:41:41 paper. And I got
01:41:44 kind of excited about it because to me at that time it was another
01:41:47 application of these supersonic free jets, these big leaks
01:41:50 into vacuum systems, which I'd been having a love affair with for
01:41:53 then many years. And in fact,
01:41:56 I had a new young graduate student who had just come in.
01:41:59 This was 73 or so.
01:42:02 And we had bigger vacuum pumps than Dole did
01:42:05 and understood a little bit more about free jet expansions
01:42:08 than he did. And so I asked this young man,
01:42:11 Mike Lebowski, whether he'd be willing to repeat Dole's
01:42:14 experiments. And so he did. He built a system
01:42:17 and we repeated Dole's experiments.
01:42:20 But then we quit and he quit pretty much for the
01:42:23 same reasons. Dole was convinced, and so were
01:42:26 we, that if we got the big ions that he thought he was getting,
01:42:29 that
01:42:32 electron multipliers, these big ions
01:42:35 would not produce secondary electrons when they struck a dyno
01:42:38 unless they were accelerated up to half a million volts.
01:42:41 This is what Lou,
01:42:44 what's his name, and Bob Buehler
01:42:47 and Lou Friedman down at
01:42:50 the University of New York at
01:42:53 Brookhaven had discovered
01:42:56 with their big water clusters. And we didn't want to,
01:42:59 he was in a hotbed of accelerator builders, so
01:43:02 half a million volts was nothing to him, but we didn't want it around our lab.
01:43:05 And so we gave up because
01:43:08 if you've ever used a vibrating reed electrometer, you know
01:43:11 it's a terrible machine to have to humor.
01:43:14 So we forgot about it, and then some years later
01:43:17 when a young Japanese chap came to my lab,
01:43:20 Mashimichi Yamashita, and wondered
01:43:23 what he ought to do some research on. He was going to visit from
01:43:26 Japan for a year. And I said, let's go back and take a look
01:43:29 at electrospray again. And instead
01:43:32 of using great big molecules like Dole was
01:43:35 trying to do, we'll use little ones. Because we had a little
01:43:38 quadrupole mass spectrometer, and we said we can analyze these little
01:43:41 ions if we get an interquadrupole mass spectrometer. And so
01:43:44 Gatto, as we called him, put the system together that we
01:43:47 started all our work on, and so I've been having a love affair
01:43:50 with these charged droplets ever since.
01:43:53 To get back to where
01:43:56 LC and ES get together,
01:43:59 the first reference to this combination
01:44:02 that I know of was in fact by Dole himself.
01:44:05 How do I get the first slide?
01:44:17 Of course, there's the man that started it all. This is Malcolm Dole.
01:44:20 I almost went to graduate school
01:44:23 at Northwestern just after he'd arrived there
01:44:26 as an assistant professor, but for a number of reasons
01:44:29 which I won't tell you with now, I went to Yale instead. I'd gotten an offer
01:44:32 from both places. Mainly the thing that
01:44:35 made my final decision for me was
01:44:38 that the treasurer of Berea
01:44:41 College where I'd gone to school
01:44:44 was taking his son up to be a freshman at Yale that fall
01:44:47 and he offered me a ride from the middle of Kentucky
01:44:50 up to New Haven with all my luggage
01:44:53 and that was the straw that
01:44:56 delayed my meeting Malcolm Dole for 50 years.
01:44:59 I didn't meet him at all until an ASMS meeting
01:45:02 in San Diego in 1985
01:45:05 and we had a delightful time, an encounter
01:45:08 with each other and kept up some correspondence until
01:45:11 he died. And he was
01:45:14 also the first guy that put LC
01:45:17 and electrospray together.
01:45:20 Not in quite the same way that we've been
01:45:23 speaking about because he used
01:45:26 I shouldn't say LC, I should say chromatography
01:45:29 he used chromatography to analyze
01:45:32 his electrospray ions instead of using electrospray
01:45:35 ions to analyze his chromatographic
01:45:38 peaks. You may remember that
01:45:41 after giving up on the mass spectrometry
01:45:44 mass analysis part of his
01:45:47 ion work, he used what he called, what was then known
01:45:50 as plasma chromatography in which today we call ion
01:45:53 mobility. So if I may be permitted
01:45:56 a pun, Dole was not only first with electrospray
01:45:59 but he was first with electrospray and chromatography.
01:46:02 But
01:46:05 here is the device
01:46:08 which he used
01:46:11 I guess, is this thing dead?
01:46:21 Oh, it's on here.
01:46:24 It's okay now?
01:46:35 Is that alright?
01:46:40 It was a vertical machine
01:46:43 here's his electrospray
01:46:46 rising up, being lifted by the
01:46:49 special gradient along here. This was a chamber
01:46:52 which he could sweep his nitrogen through
01:46:55 and in all his work, as those of you who have looked at his papers
01:46:58 know, he always had his
01:47:01 bath gas. He was the one, the thing that Dole really
01:47:04 recognized was he needed the enthalpy of
01:47:07 a bath gas to provide for
01:47:10 evaporating the solvent from the droplets.
01:47:13 People had been trying to inject electrically charged droplets
01:47:16 into vacuum systems for a long time in what is known as
01:47:19 electro-hydrodynamic ionization
01:47:22 and they always got into trouble because
01:47:25 there was nothing in the vacuum to evaporate the solvent
01:47:28 and so it didn't evaporate. And Dole recognized the importance
01:47:31 of needing this bath gas. So he always used bath gas
01:47:34 and it was atmospheric pressure. But he always had it concurrently
01:47:37 because he didn't
01:47:40 understand and appreciate, he never fooled around with
01:47:43 free jets at all, that the adiabatic expansion that takes place
01:47:46 in this free jet cools things down and brings about re-solvation
01:47:49 if you don't have all the solvent vapor out. And there was no provision
01:47:52 in his way, his system here, to remove any solvent
01:47:55 vapor. So all his ions were
01:47:58 pretty much solvated. They went on
01:48:01 up into this aperture here, into his drift tube
01:48:04 and from there, that's what he was using to
01:48:07 analyze these ions, beginning about 1973
01:48:10 after he moved to Baylor from Northwestern, having retired
01:48:13 from Northwestern.
01:48:16 And it was at that ASMS
01:48:19 meeting in San Diego that I was telling you
01:48:22 about that I recognized Dole
01:48:25 pointed him out in the audience and asked him to stand up
01:48:28 and take a bow. And this
01:48:31 apparently pleased him greatly because he later sent me a copy of his
01:48:34 autobiography and
01:48:37 a very nice little book which I commend to you called
01:48:40 My Life in the Golden Age of America.
01:48:43 And the fact that he was
01:48:46 recognized at that
01:48:49 meeting really gave him a big thing. He labeled it as a very
01:48:52 remarkable event when he was down there and that happened.
01:48:55 And he also referred to the fact that after that session
01:48:58 was over, what he called the eminent mass
01:49:01 spectrometrist, Professor Paul Cabali
01:49:04 came up to him and said,
01:49:07 Professor Dole, isn't it nice that you're still alive
01:49:10 while electrospray that you started is beginning to
01:49:13 get some attention. Fortunately, Dole
01:49:16 lived long enough to go to the first electrospray workshop
01:49:19 which was run by ASMS up in Chicago
01:49:22 and by that time there was a real
01:49:25 good sized crowd of people working in the field and so he had
01:49:28 the satisfaction of realizing that
01:49:31 this work, which was really a very minor portion of his
01:49:34 research effort that he didn't count as all that
01:49:37 important at the time, had
01:49:40 such far-reaching effects. I don't know what he'd think
01:49:43 if he knew today
01:49:46 I think there were some close to 800 papers
01:49:49 published involving electrospray one way or another in
01:49:52 1996.
01:49:55 The next slide shows some of his
01:49:58 plasma chromatographs.
01:50:01 This is the pure solvent. This is what he obtained
01:50:04 with a mixture of polyethylene glycols
01:50:07 from a mixture of 51,000
01:50:10 and 250,000 and the thing that bothered
01:50:13 him was, here's the 51,000, here's the 200,000
01:50:16 and the drift
01:50:19 time for the 51,000 is longer than for the 200,000
01:50:22 and it just
01:50:25 didn't make any sense to him and it was
01:50:28 if you realize the difference between
01:50:31 this spectrum here
01:50:34 and this spectrum here, this is 25 degrees. When he
01:50:37 raised the temperature of his bath gas to 75 degrees
01:50:40 this is what he got. When he went to 125 degrees this is what he
01:50:43 got. Practically everything he was seeing in his peaks
01:50:46 were solvents
01:50:49 droplets
01:50:52 probably
01:50:55 recondensing around the ions
01:50:58 during the free jet expansion.
01:51:01 Well, in the right way around
01:51:04 the first record that I found
01:51:07 in which an LC was hooked
01:51:10 to an electrospray apparatus is in this patent
01:51:13 by Wade Fite in 1980
01:51:16 and it's a fairly complete patent.
01:51:19 Here's his design. I don't know, is this in the way so you can't see it?
01:51:22 I hope not. Here is his design
01:51:25 built on Dole's system
01:51:28 and here is his electrospray needle
01:51:31 spraying in an aperture into the vacuum system
01:51:34 and a quadrupole mass spectrometer
01:51:37 and
01:51:40 Ross tells me, he did build this equipment
01:51:43 and he did get some ions with it but it was kind of doomed to failure for the same reason
01:51:46 that Dole had his problems. There's no provision
01:51:49 for providing enough heat
01:51:52 to vaporize things and a means of heating enough
01:51:55 so that you get the temperature high enough so that recondensation
01:51:58 can occur or for getting rid of the solvent vapor.
01:52:01 And so it was doomed to failure
01:52:04 and nothing much ever
01:52:07 did come out of it. It was sometime
01:52:10 after that
01:52:13 you can see this is essentially the thing
01:52:16 that was in the first slide and then he was showing the possibility of adding
01:52:19 stage pumping here but otherwise things are much the same
01:52:22 and he also had a variety of
01:52:25 arrangements for his electrospray needle
01:52:28 and he took the trouble, this is Wade Fite
01:52:31 showing various kinds of shapes that you could make the injection
01:52:34 needle at its end and
01:52:37 with some implication that perhaps one of them would work better than the other
01:52:40 although there was no evidence or no data in the patent
01:52:43 to indicate that he'd ever done any
01:52:46 real experiments.
01:52:49 This paper has
01:52:52 liquid chromatographs and electrospray
01:52:55 in the title and
01:52:58 there's a lot more chromatography
01:53:01 in the title than there is in the paper.
01:53:04 Because the last paragraph
01:53:07 in that paper pointed out
01:53:10 that we realized because we had
01:53:13 discovered by then that you had to have pretty low flow rates in order to get
01:53:16 a good electrostatic dispersion of the liquid
01:53:19 and that meant micro-bore
01:53:22 chromatography and those things weren't very common now but we
01:53:25 borrowed what was called a micro-bore column from somebody
01:53:28 it was fairly thin, I don't remember what it was, and hooked it up with
01:53:31 an injection valve
01:53:34 which we could squirt in a sample
01:53:37 of 20, I think it was
01:53:40 20 or 30 microliters
01:53:43 and the column was such that the elution time
01:53:46 for the one peak that we had, we only put one column in
01:53:49 was 52 minutes
01:53:52 so we forgot about that
01:53:55 but this paper was the first one in which
01:53:58 what's now become familiar to all of you, our version of the
01:54:01 electrospray ion source with the counter current gas flow
01:54:04 to help dry things out before the solvent vapor
01:54:07 gets out of the gas
01:54:10 that entrains the ions and comes out here to the free jet expansion
01:54:13 and on into the mass spectrometer
01:54:16 that was
01:54:19 we did do a few experiments later and this is the general
01:54:22 scheme of things
01:54:25 and, oh dear, this is upside down but
01:54:28 that's alright, we did actually get some peaks
01:54:31 these were the ones that were shown for the UV detector
01:54:34 but these are the peaks that came out and these are only a few minutes wide
01:54:37 but our chromatography was just absolutely ridiculous
01:54:40 so I will hasten on
01:54:43 and here, these are the guys that, as you already heard
01:54:46 were the first ones to make electrospray
01:54:49 and chromatography really work and do bonafide chromatography
01:54:52 Jack Hennion and his colleagues
01:54:55 along with Bill Budde from the EPA
01:54:58 and
01:55:01 they got bonafide
01:55:04 peaks
01:55:07 you've already seen this
01:55:10 they were using
01:55:13 what they call a pneumatic assist
01:55:16 a blast of gas to help atomize the liquids
01:55:19 because he knew too, by that time he had found out
01:55:22 that electrostatic dispersion of liquid flow rates
01:55:25 of the one milliliter a minute
01:55:28 flow rate that everybody was using then in chromatographers
01:55:31 just plain wouldn't work
01:55:34 now the story I heard, and Jack will have to avouch for its truth
01:55:37 do I really have to stop now?
01:55:40 everybody can leave if they want to leave
01:55:43 I'm the last one, let me finish the sentence
01:55:46 you don't have to ask any questions
01:55:50 Jack, as he's already mentioned
01:55:53 got this tagger machine from Cyax
01:55:56 and
01:55:59 we had published a couple of papers on electrospray by that time
01:56:02 and Andres Bruins
01:56:05 and Tom Cully
01:56:08 had read them
01:56:11 and they were having some trouble with some dyes
01:56:14 and so they wanted to try electrospray
01:56:17 and it was very easy to do because they had this atmospheric pressure
01:56:20 now this is a story I heard Jack, you can deny it or not
01:56:23 so one week when he was away, they bootlegged it and put it in anyway
01:56:26 and when he came back, he was very impressed with the results that we got
01:56:29 they got
01:56:32 what? another one?
01:56:35 well, I don't know
01:56:38 but anyway, here it is with the offset
01:56:41 from the orifice leading into the vacuum system
01:56:44 and these are the bona fide
01:56:47 respectable chromatograms that they've got
01:56:50 here is ion spray LCMS for example
01:56:53 two monosulfated azo dyes
01:56:56 extracted from fortified wastewater
01:56:59 I don't know what it was waste from
01:57:02 but selected ion monitoring of
01:57:05 the negative ions
01:57:08 and I noticed that the flow rate
01:57:11 was 40 microliters a minute
01:57:14 now the big
01:57:17 advantage claimed by
01:57:20 ion spray as they call it
01:57:23 pneumatic assist was
01:57:26 one to use large flow rates
01:57:29 but practically all of the good
01:57:32 spectra that I've ever seen have always been taken
01:57:35 at flow rates that were down very close to
01:57:38 with pure electrospray
01:57:41 I think this was good
01:57:44 bona fide advertising
01:57:52 and actually they could get even at these low flow rates
01:57:55 which of course worked better because the charge to mass ratio was better
01:57:58 or more stable, it was very difficult to get stable
01:58:01 sprays at any flow rates above
01:58:04 5 or 10 microliters a minute
01:58:07 so as you know today everybody including you at Packard
01:58:10 can now offer electrospray
01:58:13 with flow rates up to 1 milliliter a minute
01:58:16 and the bandwagon is really rumbling down the street
01:58:19 I got off it a long time ago and maybe it's about time
01:58:22 for me to get back on. Thank you very much for your attention
01:58:25 and now you're all dismissed
01:58:38 I'd like to thank the
01:58:41 speakers today for a very informative
01:58:44 and entertaining session
01:58:47 thank the audience
A slate of speakers at an American Society for Mass Spectrometry event talk about their experiences working in liquid chromatography and mass spectrometry in the 1960s and 70s. The speakers are Bruce A. Thompson, Jack Henion, William McFadden, Marvin Vestal, Ross Willoughby, and John Fenn.
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Cite as
American Society for Mass Spectrometry. “Pioneers in LC/MS.” Vhs, June 3, 1997. Science History Institute DVD and Video Collection, Box 2. Science History Institute. Philadelphia. https://digital.sciencehistory.org/works/vdijcts.
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