Episode 48: Using LC-MS & GC-MS to Decode Photoredox Catalyst Stability episode artwork

EPISODE · Feb 17, 2026 · 35 MIN

Episode 48: Using LC-MS & GC-MS to Decode Photoredox Catalyst Stability

from Concentrating on Chromatography · host David Oliva

In this episode of Concentrating on Chromatography, we sit down with Lindsay Repka to discuss how LC-MS and GC-MS transformed her lab’s approach to photoredox chemistry.What began as a project to develop a visible-light photocrosslinking handle unexpectedly led to a major discovery: the solvent (DMF) was reacting with the photocatalyst itself. Using high-resolution LC-MS, Lindsay’s team observed multiple solvent adducts forming — sometimes with complete catalyst consumption. That discovery reshaped their research direction.Drawing from her ACS Northeast presentation and this in-depth conversation, Lindsay explains:🔬 How photoredox catalysts become activated under visible light📊 Why LC-MS was essential when NMR couldn’t resolve complex mixtures📈 How to design reproducible calibration curves for percent catalyst remaining📉 Why extracted ion chromatograms (EIC) outperform total ion chromatograms (TIC) at low concentrations⚗️ How solvent activation chemistry led to selective N-demethylation🧪 Why GC-MS with an internal standard streamlined reaction screening📐 What relative response factors mean — and why they can’t always be assumed constant🧑‍🔬 Practical tips for improving reproducibility (microbalances, deoxygenated solvents, temperature control)This episode is a rare deep dive into both LC-MS and GC-MS within the same research project, showing how chromatography-driven insight can turn unexpected degradation into productive new reactivity.If you work in:* Photoredox chemistry* Reaction optimization* Mass spectrometry method development* Catalyst screening* Academic synthetic chemistry…this conversation will resonate.🧪 Key Topics Covered* Photocatalyst stability in DMF, DCE, and MeCN* Demethylation under mild visible-light conditions* High-resolution Q-TOF LC-MS quantitation* Internal standard methodology in GC-MS* Signal-to-noise improvement using extracted ion chromatograms* Reaction reproducibility and quality control strategy🎙 About the GuestLindsay Repka is a chemistry professor at Middlebury College whose research explores photoredox chemistry, catalyst stability, and visible-light-driven transformations. Her lab emphasizes both mechanistic insight and hands-on student training in advanced analytical instrumentation.If you enjoy conversations at the intersection of chromatography and real-world chemistry research:👍 Like💬 Comment with your LC-MS / GC-MS questions🔔 Subscribe for more episodes of

In this episode of Concentrating on Chromatography, we sit down with Lindsay Repka to discuss how LC-MS and GC-MS transformed her lab’s approach to photoredox chemistry.What began as a project to develop a visible-light photocrosslinking handle unexpectedly led to a major discovery: the solvent (DMF) was reacting with the photocatalyst itself. Using high-resolution LC-MS, Lindsay’s team observed multiple solvent adducts forming — sometimes with complete catalyst consumption. That discovery reshaped their research direction.Drawing from her ACS Northeast presentation and this in-depth conversation, Lindsay explains:🔬 How photoredox catalysts become activated under visible light📊 Why LC-MS was essential when NMR couldn’t resolve complex mixtures📈 How to design reproducible calibration curves for percent catalyst remaining📉 Why extracted ion chromatograms (EIC) outperform total ion chromatograms (TIC) at low concentrations⚗️ How solvent activation chemistry led to selective N-demethylation🧪 Why GC-MS with an internal standard streamlined reaction screening📐 What relative response factors mean — and why they can’t always be assumed constant🧑‍🔬 Practical tips for improving reproducibility (microbalances, deoxygenated solvents, temperature control)This episode is a rare deep dive into both LC-MS and GC-MS within the same research project, showing how chromatography-driven insight can turn unexpected degradation into productive new reactivity.If you work in:* Photoredox chemistry* Reaction optimization* Mass spectrometry method development* Catalyst screening* Academic synthetic chemistry…this conversation will resonate.🧪 Key Topics Covered* Photocatalyst stability in DMF, DCE, and MeCN* Demethylation under mild visible-light conditions* High-resolution Q-TOF LC-MS quantitation* Internal standard methodology in GC-MS* Signal-to-noise improvement using extracted ion chromatograms* Reaction reproducibility and quality control strategy🎙 About the GuestLindsay Repka is a chemistry professor at Middlebury College whose research explores photoredox chemistry, catalyst stability, and visible-light-driven transformations. Her lab emphasizes both mechanistic insight and hands-on student training in advanced analytical instrumentation.If you enjoy conversations at the intersection of chromatography and real-world chemistry research:👍 Like💬 Comment with your LC-MS / GC-MS questions🔔 Subscribe for more episodes of

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Episode 48: Using LC-MS & GC-MS to Decode Photoredox Catalyst Stability

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This episode was published on February 17, 2026.

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In this episode of Concentrating on Chromatography, we sit down with Lindsay Repka to discuss how LC-MS and GC-MS transformed her lab’s approach to photoredox chemistry.What began as a project to develop a visible-light photocrosslinking handle...

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