Identifying falsified COVID-19 vaccines by analysing vaccine vial label and excipient profiles using MALDI-ToF mass spectrometry

Benediktus Yohan Arman; Rebecca Clarke; Tehmina Bharucha; Laura Gomez Fernandez; John Walsby-Tickle; Michael Deats; Sara Mosca; Qianqi Lin; Sneha Banerjee; Shrikrishna R. Chunekar; Kundan D. Patil; Sunil Gairola; Susanna Dunachie; Hamid A. Merchant; Robert Stokes; Rutendo Kuwana; Alexandrine Maes; Jean Philippe Charrier; Fay Probert; Céline Caillet; Pavel Matousek; James McCullagh; Paul N. Newton; Nicole Zitzmann; Bevin Gangadharan

doi:10.1038/s41541-024-01051-3

Identifying falsified COVID-19 vaccines by analysing vaccine vial label and excipient profiles using MALDI-ToF mass spectrometry

Benediktus Yohan Arman, Rebecca Clarke, Tehmina Bharucha, Laura Gomez Fernandez, John Walsby-Tickle, Michael Deats, Sara Mosca, Qianqi Lin, Sneha Banerjee, Shrikrishna R. Chunekar, Kundan D. Patil, Sunil Gairola, Susanna Dunachie, Hamid A. Merchant, Robert Stokes, Rutendo Kuwana, Alexandrine Maes, Jean Philippe Charrier, Fay Probert, Céline CailletPavel Matousek, James McCullagh, Paul N. Newton^*, Nicole Zitzmann, Bevin Gangadharan^*

^*Corresponding author for this work

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Abstract

The rapid development and worldwide distribution of COVID-19 vaccines is a remarkable achievement of biomedical research and logistical implementation. However, these developments are associated with the risk of a surge of substandard and falsified (SF) vaccines, as illustrated by the 184 incidents with SF and diverted COVID-19 vaccines which have been reported during the pandemic in 48 countries, with a paucity of methods for their detection in supply chains. In this context, matrix-assisted laser desorption ionisation-time of flight (MALDI-ToF) mass spectrometry (MS) is globally available for fast and accurate analysis of bacteria in patient samples, offering a potentially accessible solution to identify SF vaccines. We analysed the COVISHIELD™ COVID-19 vaccine; falsified versions of which were found in India, Myanmar and Uganda. We demonstrate for the first time that analysis of spectra from the vaccine vial label and its adhesive could be used as a novel approach to detect falsified vaccines. Vials tested by this approach could be retained in the supply chain since it is non-invasive. We also assessed whether MALDI-ToF MS could be used to distinguish the COVISHIELD™ vaccine from surrogates of falsified vaccines and the effect of temperature on vaccine stability. Both polysorbate 80 and L-histidine excipients of the genuine vaccine could be detected by the presence of a unique combination of MALDI-ToF MS peaks which allowed us to distinguish between the genuine vaccines and falsified vaccine surrogates. Furthermore, even if a falsified product contained polysorbate 80 at the same concentration as used in the genuine vaccine, the characteristic spectral profile of polysorbate 80 used in genuine products is a reliable internal marker for vaccine authenticity. Our findings demonstrate that MALDI-ToF MS analysis of extracts from vial labels and the vaccine excipients themselves can be used independently to detect falsified vaccines. This approach has the potential to be integrated into the national regulatory standards and WHO’s Prevent, Detect, and Respond strategy as a novel effective tool for detecting falsified vaccines.

Original language	English
Article number	19
Journal	npj Vaccines
Volume	10
Issue number	1
Early online date	30 Jan 2025
DOIs	https://doi.org/10.1038/s41541-024-01051-3
Publication status	E-pub ahead of print/First online - 30 Jan 2025

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Arman, B. Y., Clarke, R., Bharucha, T., Gomez Fernandez, L., Walsby-Tickle, J., Deats, M., Mosca, S., Lin, Q., Banerjee, S., Chunekar, S. R., Patil, K. D., Gairola, S., Dunachie, S., Merchant, H. A., Stokes, R., Kuwana, R., Maes, A., Charrier, J. P., Probert, F., ... Gangadharan, B. (2025). Identifying falsified COVID-19 vaccines by analysing vaccine vial label and excipient profiles using MALDI-ToF mass spectrometry. npj Vaccines, 10(1), Article 19. Advance online publication. https://doi.org/10.1038/s41541-024-01051-3

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title = "Identifying falsified COVID-19 vaccines by analysing vaccine vial label and excipient profiles using MALDI-ToF mass spectrometry",

abstract = "The rapid development and worldwide distribution of COVID-19 vaccines is a remarkable achievement of biomedical research and logistical implementation. However, these developments are associated with the risk of a surge of substandard and falsified (SF) vaccines, as illustrated by the 184 incidents with SF and diverted COVID-19 vaccines which have been reported during the pandemic in 48 countries, with a paucity of methods for their detection in supply chains. In this context, matrix-assisted laser desorption ionisation-time of flight (MALDI-ToF) mass spectrometry (MS) is globally available for fast and accurate analysis of bacteria in patient samples, offering a potentially accessible solution to identify SF vaccines. We analysed the COVISHIELD{\texttrademark} COVID-19 vaccine; falsified versions of which were found in India, Myanmar and Uganda. We demonstrate for the first time that analysis of spectra from the vaccine vial label and its adhesive could be used as a novel approach to detect falsified vaccines. Vials tested by this approach could be retained in the supply chain since it is non-invasive. We also assessed whether MALDI-ToF MS could be used to distinguish the COVISHIELD{\texttrademark} vaccine from surrogates of falsified vaccines and the effect of temperature on vaccine stability. Both polysorbate 80 and L-histidine excipients of the genuine vaccine could be detected by the presence of a unique combination of MALDI-ToF MS peaks which allowed us to distinguish between the genuine vaccines and falsified vaccine surrogates. Furthermore, even if a falsified product contained polysorbate 80 at the same concentration as used in the genuine vaccine, the characteristic spectral profile of polysorbate 80 used in genuine products is a reliable internal marker for vaccine authenticity. Our findings demonstrate that MALDI-ToF MS analysis of extracts from vial labels and the vaccine excipients themselves can be used independently to detect falsified vaccines. This approach has the potential to be integrated into the national regulatory standards and WHO{\textquoteright}s Prevent, Detect, and Respond strategy as a novel effective tool for detecting falsified vaccines.",

author = "Arman, {Benediktus Yohan} and Rebecca Clarke and Tehmina Bharucha and {Gomez Fernandez}, Laura and John Walsby-Tickle and Michael Deats and Sara Mosca and Qianqi Lin and Sneha Banerjee and Chunekar, {Shrikrishna R.} and Patil, {Kundan D.} and Sunil Gairola and Susanna Dunachie and Merchant, {Hamid A.} and Robert Stokes and Rutendo Kuwana and Alexandrine Maes and Charrier, {Jean Philippe} and Fay Probert and C{\'e}line Caillet and Pavel Matousek and James McCullagh and Newton, {Paul N.} and Nicole Zitzmann and Bevin Gangadharan",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = jan,

day = "30",

doi = "10.1038/s41541-024-01051-3",

language = "English",

volume = "10",

journal = "npj Vaccines",

issn = "2059-0105",

publisher = "Nature Publishing Group",

number = "1",

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Arman, BY, Clarke, R, Bharucha, T, Gomez Fernandez, L, Walsby-Tickle, J, Deats, M, Mosca, S, Lin, Q, Banerjee, S, Chunekar, SR, Patil, KD, Gairola, S, Dunachie, S, Merchant, HA, Stokes, R, Kuwana, R, Maes, A, Charrier, JP, Probert, F, Caillet, C, Matousek, P, McCullagh, J, Newton, PN, Zitzmann, N & Gangadharan, B 2025, 'Identifying falsified COVID-19 vaccines by analysing vaccine vial label and excipient profiles using MALDI-ToF mass spectrometry', npj Vaccines, vol. 10, no. 1, 19. https://doi.org/10.1038/s41541-024-01051-3

TY - JOUR

T1 - Identifying falsified COVID-19 vaccines by analysing vaccine vial label and excipient profiles using MALDI-ToF mass spectrometry

AU - Arman, Benediktus Yohan

AU - Clarke, Rebecca

AU - Bharucha, Tehmina

AU - Gomez Fernandez, Laura

AU - Walsby-Tickle, John

AU - Deats, Michael

AU - Mosca, Sara

AU - Lin, Qianqi

AU - Banerjee, Sneha

AU - Chunekar, Shrikrishna R.

AU - Patil, Kundan D.

AU - Gairola, Sunil

AU - Dunachie, Susanna

AU - Merchant, Hamid A.

AU - Stokes, Robert

AU - Kuwana, Rutendo

AU - Maes, Alexandrine

AU - Charrier, Jean Philippe

AU - Probert, Fay

AU - Caillet, Céline

AU - Matousek, Pavel

AU - McCullagh, James

AU - Newton, Paul N.

AU - Zitzmann, Nicole

AU - Gangadharan, Bevin

PY - 2025/1/30

Y1 - 2025/1/30

N2 - The rapid development and worldwide distribution of COVID-19 vaccines is a remarkable achievement of biomedical research and logistical implementation. However, these developments are associated with the risk of a surge of substandard and falsified (SF) vaccines, as illustrated by the 184 incidents with SF and diverted COVID-19 vaccines which have been reported during the pandemic in 48 countries, with a paucity of methods for their detection in supply chains. In this context, matrix-assisted laser desorption ionisation-time of flight (MALDI-ToF) mass spectrometry (MS) is globally available for fast and accurate analysis of bacteria in patient samples, offering a potentially accessible solution to identify SF vaccines. We analysed the COVISHIELD™ COVID-19 vaccine; falsified versions of which were found in India, Myanmar and Uganda. We demonstrate for the first time that analysis of spectra from the vaccine vial label and its adhesive could be used as a novel approach to detect falsified vaccines. Vials tested by this approach could be retained in the supply chain since it is non-invasive. We also assessed whether MALDI-ToF MS could be used to distinguish the COVISHIELD™ vaccine from surrogates of falsified vaccines and the effect of temperature on vaccine stability. Both polysorbate 80 and L-histidine excipients of the genuine vaccine could be detected by the presence of a unique combination of MALDI-ToF MS peaks which allowed us to distinguish between the genuine vaccines and falsified vaccine surrogates. Furthermore, even if a falsified product contained polysorbate 80 at the same concentration as used in the genuine vaccine, the characteristic spectral profile of polysorbate 80 used in genuine products is a reliable internal marker for vaccine authenticity. Our findings demonstrate that MALDI-ToF MS analysis of extracts from vial labels and the vaccine excipients themselves can be used independently to detect falsified vaccines. This approach has the potential to be integrated into the national regulatory standards and WHO’s Prevent, Detect, and Respond strategy as a novel effective tool for detecting falsified vaccines.

AB - The rapid development and worldwide distribution of COVID-19 vaccines is a remarkable achievement of biomedical research and logistical implementation. However, these developments are associated with the risk of a surge of substandard and falsified (SF) vaccines, as illustrated by the 184 incidents with SF and diverted COVID-19 vaccines which have been reported during the pandemic in 48 countries, with a paucity of methods for their detection in supply chains. In this context, matrix-assisted laser desorption ionisation-time of flight (MALDI-ToF) mass spectrometry (MS) is globally available for fast and accurate analysis of bacteria in patient samples, offering a potentially accessible solution to identify SF vaccines. We analysed the COVISHIELD™ COVID-19 vaccine; falsified versions of which were found in India, Myanmar and Uganda. We demonstrate for the first time that analysis of spectra from the vaccine vial label and its adhesive could be used as a novel approach to detect falsified vaccines. Vials tested by this approach could be retained in the supply chain since it is non-invasive. We also assessed whether MALDI-ToF MS could be used to distinguish the COVISHIELD™ vaccine from surrogates of falsified vaccines and the effect of temperature on vaccine stability. Both polysorbate 80 and L-histidine excipients of the genuine vaccine could be detected by the presence of a unique combination of MALDI-ToF MS peaks which allowed us to distinguish between the genuine vaccines and falsified vaccine surrogates. Furthermore, even if a falsified product contained polysorbate 80 at the same concentration as used in the genuine vaccine, the characteristic spectral profile of polysorbate 80 used in genuine products is a reliable internal marker for vaccine authenticity. Our findings demonstrate that MALDI-ToF MS analysis of extracts from vial labels and the vaccine excipients themselves can be used independently to detect falsified vaccines. This approach has the potential to be integrated into the national regulatory standards and WHO’s Prevent, Detect, and Respond strategy as a novel effective tool for detecting falsified vaccines.

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JF - npj Vaccines

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M1 - 19

ER -

Identifying falsified COVID-19 vaccines by analysing vaccine vial label and excipient profiles using MALDI-ToF mass spectrometry

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