Gurus of Gas Chromatography

What is the state of GC and GC×GC today?

Giorgia: From my point of view, GC and GC×GC are both now “mature” techniques, and their growth curve is beginning to plateau. State-of-the-art GC machines are of very high quality. In particular, MS detectors are improving in performance exponentially, making GC and GC×GC coupled with MS a powerful and versatile tool in many areas. Some improvements are still necessary, or desirable, such as new column stationary phases, better inertness of connections, and more intuitive hardware, but I doubt these will have a revolutionary impact on the field.

One current downside is the still-limited acceptance of GC×GC as a routine technique. It is still seen as mainly suited for research purposes, but it is actually mature and robust enough to be used more routinely. However, the power of GC×GC is actually essential for very challenging applications, and this will hopefully help boost its acceptance and use.

Peter: I’d agree with Giorgia that GC is a rather mature technology – and I’d say it’s poised to produce a profusion of compact devices with low energy consumption, mostly within the context of GC-MS. The role of MS is becoming understandably dominant, and it occupies a central role in our expanding molecular-level knowledge of the world.

Apart from the introduction of GC×GC itself, there have been many noteworthy developments, including fused-silica capillary GC, Deans Switch multidimensional GC, improved speed, introduction of new stationary phases, increased power and decreased device size (in some cases miniaturized), novel injection approaches, new detectors, and many more. I believe that GC×GC, fused-silica capillary GC and GC-MS evolution have been particularly important.

Kevin: It feels like the GC industry is currently trying to reinvent itself with more compact and user friendly systems. Indeed, there have been exceptional developments in detector power, but front-end automated sample preparation systems are becoming more advanced and capable, as well. Now more than ever, we have more choices of different accessories and detectors to upgrade GC systems and make them more capable and more powerful.

How does GC fit into your research?

Peter: I work primarily with GC×GC – a technique that grabbed my attention from my first encounter with it. Now,having witnessed its evolution over almost two decades, I’m fortunate enough to work with five to six of these systems, using different modulators and MS detectors, to support my everyday research.

Such approaches are, of course, essential for expanding our understanding of the world we live in at a molecular level. However, focusing more closely on foods, as I do in my own research, novel sample preparation approaches and the application of GC×GC-MS are now allowing us to perform in-depth investigations into contaminants (at parts per billion or trillion levels). We are now able to pinpoint compounds responsible for specific aromas, enable fine optimization of industrial processes, identify food components potentially beneficial for human health, monitor storage condition effects, and more.

Giorgia: GC×GC has been the most revolutionary invention in the field since the introduction of capillary columns, providing a new level of understanding of GC-amenable samples. And it has played an important role in my career. I first experienced GC×GC as a PhD student and have not strayed from it since – even when I had to build my own modulator because of budget restrictions. From then until now, it’s given me great satisfaction in terms of my personal career and research advancements. In fact, GC×GC has altered many paradigms in the field of food analysis.

Two main examples from my research are the application of GC×GC to fingerprinting the volatile profile of foods, opening the door to omics disciplines in this space for quality and authenticity control, and the detailed characterization of food contaminants. In the latter case, GC×GC is crucial for elucidating mineral oil saturated hydrocarbons and alkylated mineral oil aromatic hydrocarbons (MOSH and MOAH) – key food contaminants that can be differentiated only by using this technique.

Kevin: When I was a graduate student, I had the opportunity to decide whether my graduate work would focus on GC or highperformance liquid chromatography (HPLC). I chose HPLC, because my assessment at that time was that it was a much more exciting field in which to focus. Indeed, LC-MS continued to be strong and still is today. It was many years before GC became a regular part of my research activities. However, focusing on the environmental impact of unconventional oil and gas extraction in Texas provided many opportunities for methodological innovation. Today, we’ve developed a suite of methods for measuring water contaminants, such as the use of headspace GC and GC-MS for the monitoring of volatile and semi-volatile organic compounds in groundwater and treated oilfield wastewater. These methods have been developed within my team using combined targeted and untargeted analysis conditions – made necessary by the complexity of oil samples and tendency to use proprietary chemicals in unconventional oil and gas extraction.
 

How do the International Symposium on Capillary Chromatography and the Comprehensive Two-Dimensional Gas Chromatography (ISCC & GC×GC) symposia typically support your work – and the overall field?

Giorgia: The Riva meetings are, for me, a place of inspiration and confrontation, where the most passionate and advanced scientists gather together to exchange ideas and opinions. The pleasant, cozy environment of Riva del Garda facilitates networking and professional exchanges, making these meetings unique! After every meeting, I come back to my lab with a bunch of new ideas to explore.

Kevin: The ISCC meeting in Riva del Garda, Italy, was the first international conference I ever attended. It was my PhD advisor’s favorite, and it quickly became mine as well. Riva is the premier international meeting for all things GC, for capillary LC, for microscale and electrically-driven separations, and even for multidimensional separations — not just GC×GC, but LC×LC, as well. One of my proudest moments was being able to introduce the scientific community to the vacuum ultra-violet (VUV) detector for GC for the first time at the 2012 Riva del Garda meeting.

Peter: I am involved in the general organization of the GC×GC Symposium. Apart from enjoying the beauty of the location and meeting with long-time friends, I usually leave Riva with an abiding admiration for the best presenters and presentations. It’s a very important venue for exchanging ideas about the whole field.

Riva 2020 has sadly been canceled. What impact will this have, and how can the community respond?

Peter: The impact of the coronavirus pandemic on the economy is extreme, including the cancellation of Riva 2020. In fact, many events around the world are being postponed by a year. I would like to think of the next “RIVA” being a greatly attended event, with an enhanced pleasure of just being together as a community and truly appreciating the wonderful location. I hope to see the general scientific community intensely engaged in avoiding a similar situation in the future, and also united in facing the environmental challenges awaiting us in the future.

Kevin: It’s difficult to forecast the future of the event with this year’s cancellation. The ongoing pandemic will change many things, including a large number of conference cancellations and postponements. But, we still have the US meeting in Fort Worth 2021 to look forward to, and hopefully we’ll be back in Riva for 2022!

Giorgia: The cancellation of Riva is an unfortunate situation, which will have a negative impact on exchange both among scientists, and between scientists and industry. The relaxed environment of Riva del Garda has always guaranteed fruitful interactions, while the disconnect offered by leisure time outside the conference allows attendees to focus totally on networking while attending the event itself. The technology and connectivity available to us today may compensate in part for this missed opportunity, but it will not be the same. In this period of uncertainty, I think the community will act to strengthen our virtual connections until we can meet again.

What do you see in your crystal ball for GC’s future, and what developments will help it get there?

Giorgia: In my opinion, two main factors continue to cause a bottleneck in the field: sample preparation and data handling. I’d like to see more effort on automation and miniaturization of sample preparation at a reasonable cost, to match and complement the high performance achievable with modern GC instruments. On the other side, data handling still remains an unavoidable hurdle. Algorithms need to be improved to make integration more robust, and, at the same time, they should provide support to extract useful information from the overwhelming amount of data generated by the multidimensional and ultra-sensitive techniques available today.

Peter: I expect further major developments in MS and sample preparation, but fewer in chromatography. Benefits will spring from the use of faster, more compact and environmentally friendly automated machines. The work of analysts will be made much easier, along with decreasing emphasis on their role in operating the instrumentation.

Kevin: I see the merging of more advanced data science techniques and analytical measurements. Given the power and choices of front-end sample preparation, high-efficiency chromatographic separations, and back-end detection, researchers have a myriad of means to create methods to differentiate samples of interest or perform ultratrace analysis. Tools like machine learning and artificial intelligence will also become more routine in chromatography systems. GC can profile volatile and semi-volatile compounds in just about any sample; as Giorgia says, we need more and more robust and user-friendly means to process data, and I think those tools are emerging quickly.