High‐throughput mass spectrometry analysis using immediate drop‐on‐demand technology coupled with an open port sampling interface

Rationale The sampling throughput of immediate drop‐on‐demand technology (I.DOT) coupled with an open port sampling interface (OPSI) is limited by software communication. To enable much‐needed high‐throughput mass spectrometry (MS) analysis capabilities, a novel software was developed that allows fo...

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Bibliographic Details
Published in:Rapid communications in mass spectrometry 2024-02, Vol.38 (4), p.e9687-n/a
Main Authors: Kertesz, Vilmos, Carper, Dana L., Cahill, John F.
Format: Article
Language:English
Subjects:
demand technology
high throughput sampling
immediate drop-on
open port sampling interface
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Summary:Rationale The sampling throughput of immediate drop‐on‐demand technology (I.DOT) coupled with an open port sampling interface (OPSI) is limited by software communication. To enable much‐needed high‐throughput mass spectrometry (MS) analysis capabilities, a novel software was developed that allows for flexible sample selection from a 96‐well plate and for maximized analysis throughput using I.DOT/OPSI‐MS coupling. Methods Wells of a 96‐well I.DOT plate were filled with propranolol solution and were used to test maximum sampling throughput strategies to minimize analysis time. Demonstration of chemical reaction monitoring was done using acid‐catalyzed ring closure of 2,3‐diaminonaphthalene (DAN) with nitrite to form 2,3‐naphthotriazole (NAT). Analytes were detected in positive electrospray ionization mode using selected reaction monitoring. Results A maximum throughput of 1.54 s/sample (7.41 min/96‐well plate with three technical replicates) was achieved, and it was limited by the peak width of the MS signal resulting in an occasional slight overlap between the peaks. Relative standard deviation was 10 ± 1% with all tested sampling strategies. Chemical reaction monitoring of DAN to NAT using nitrite was successfully accomplished with 2 s/sample throughout showing almost complete transformation in 10 min with no signal overlap. Conclusions This work illustrates the development of a noncontact, automated I.DOT/OPSI‐MS system with improved throughput achieved through an optimized software interface. Its achievable analysis time and precision make it a viable approach for drug discovery and in situ reaction monitoring studies.
ISSN:0951-4198
1097-0231
DOI:10.1002/rcm.9687